NetBSD/sys/dev/ic/rtw.c

4328 lines
107 KiB
C
Raw Normal View History

/* $NetBSD: rtw.c,v 1.60 2005/12/13 05:10:55 dyoung Exp $ */
/*-
* Copyright (c) 2004, 2005 David Young. All rights reserved.
*
* Programmed for NetBSD by David Young.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. The name of David Young may not be used to endorse or promote
* products derived from this software without specific prior
* written permission.
*
* THIS SOFTWARE IS PROVIDED BY David Young ``AS IS'' AND ANY
* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
* THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
* PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL David
* Young BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
* TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY
* OF SUCH DAMAGE.
*/
/*
* Device driver for the Realtek RTL8180 802.11 MAC/BBP.
*/
#include <sys/cdefs.h>
__KERNEL_RCSID(0, "$NetBSD: rtw.c,v 1.60 2005/12/13 05:10:55 dyoung Exp $");
#include "bpfilter.h"
#include <sys/param.h>
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
#include <sys/sysctl.h>
2005-02-27 03:26:58 +03:00
#include <sys/systm.h>
#include <sys/callout.h>
2005-02-27 03:26:58 +03:00
#include <sys/mbuf.h>
#include <sys/malloc.h>
#include <sys/kernel.h>
#include <sys/time.h>
#include <sys/types.h>
#include <machine/endian.h>
#include <machine/bus.h>
#include <machine/intr.h> /* splnet */
#include <uvm/uvm_extern.h>
2005-02-27 03:26:58 +03:00
#include <net/if.h>
#include <net/if_media.h>
#include <net/if_ether.h>
#include <net80211/ieee80211_netbsd.h>
#include <net80211/ieee80211_var.h>
#include <net80211/ieee80211_radiotap.h>
2005-02-27 03:26:58 +03:00
#if NBPFILTER > 0
#include <net/bpf.h>
2005-02-27 03:26:58 +03:00
#endif
#include <dev/ic/rtwreg.h>
#include <dev/ic/rtwvar.h>
#include <dev/ic/rtwphyio.h>
#include <dev/ic/rtwphy.h>
#include <dev/ic/smc93cx6var.h>
#define KASSERT2(__cond, __msg) \
do { \
if (!(__cond)) \
panic __msg ; \
} while (0)
static int rtw_rfprog_fallback = 0;
static int rtw_host_rfio = 0;
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
#ifdef RTW_DEBUG
int rtw_debug = 0;
static int rtw_rxbufs_limit = RTW_RXQLEN;
#endif /* RTW_DEBUG */
#define NEXT_ATTACH_STATE(sc, state) do { \
DPRINTF(sc, RTW_DEBUG_ATTACH, \
("%s: attach state %s\n", __func__, #state)); \
sc->sc_attach_state = state; \
} while (0)
static int rtw_xmtr_restart = 0;
static int rtw_do_chip_reset = 0;
static int rtw_ring_reset = 0;
int rtw_dwelltime = 200; /* milliseconds */
static struct ieee80211_cipher rtw_cipher_wep;
static void rtw_start(struct ifnet *);
static void rtw_reset_oactive(struct rtw_softc *);
static struct mbuf *rtw_beacon_alloc(struct rtw_softc *,
struct ieee80211_node *);
static u_int rtw_txring_next(struct rtw_regs *, struct rtw_txdesc_blk *);
static void rtw_io_enable(struct rtw_regs *, uint8_t, int);
static int rtw_key_delete(struct ieee80211com *, const struct ieee80211_key *);
static int rtw_key_set(struct ieee80211com *, const struct ieee80211_key *,
const u_int8_t[IEEE80211_ADDR_LEN]);
static void rtw_key_update_end(struct ieee80211com *);
static void rtw_key_update_begin(struct ieee80211com *);
static int rtw_wep_decap(struct ieee80211_key *, struct mbuf *, int);
static void rtw_wep_setkeys(struct rtw_softc *, struct ieee80211_key *, int);
static void rtw_led_attach(struct rtw_led_state *, void *);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
static void rtw_led_init(struct rtw_regs *);
static void rtw_led_slowblink(void *);
static void rtw_led_fastblink(void *);
static void rtw_led_set(struct rtw_led_state *, struct rtw_regs *, int);
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
static int rtw_sysctl_verify_rfio(SYSCTLFN_PROTO);
static int rtw_sysctl_verify_rfprog(SYSCTLFN_PROTO);
#ifdef RTW_DEBUG
static void rtw_print_txdesc(struct rtw_softc *, const char *,
struct rtw_txsoft *, struct rtw_txdesc_blk *, int);
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
static int rtw_sysctl_verify_debug(SYSCTLFN_PROTO);
static int rtw_sysctl_verify_rxbufs_limit(SYSCTLFN_PROTO);
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
#endif /* RTW_DEBUG */
/*
* Setup sysctl(3) MIB, hw.rtw.*
*
* TBD condition CTLFLAG_PERMANENT on being an LKM or not
*/
SYSCTL_SETUP(sysctl_rtw, "sysctl rtw(4) subtree setup")
{
int rc;
const struct sysctlnode *cnode, *rnode;
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
if ((rc = sysctl_createv(clog, 0, NULL, &rnode,
CTLFLAG_PERMANENT, CTLTYPE_NODE, "hw", NULL,
NULL, 0, NULL, 0, CTL_HW, CTL_EOL)) != 0)
goto err;
if ((rc = sysctl_createv(clog, 0, &rnode, &rnode,
CTLFLAG_PERMANENT, CTLTYPE_NODE, "rtw",
"Realtek RTL818x 802.11 controls",
NULL, 0, NULL, 0, CTL_CREATE, CTL_EOL)) != 0)
goto err;
if ((rc = sysctl_createv(clog, 0, &rnode, &cnode,
CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT,
"chip_reset", SYSCTL_DESCR("Gratuitously reset chip on rcvr error"),
NULL, 0, &rtw_do_chip_reset, 0,
CTL_CREATE, CTL_EOL)) != 0)
goto err;
if ((rc = sysctl_createv(clog, 0, &rnode, &cnode,
CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT,
"ring_reset", SYSCTL_DESCR("Reset ring pointers on rcvr error"),
NULL, 0, &rtw_ring_reset, 0,
CTL_CREATE, CTL_EOL)) != 0)
goto err;
if ((rc = sysctl_createv(clog, 0, &rnode, &cnode,
CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT,
"xmtr_restart",
SYSCTL_DESCR("Gratuitously reset xmtr on rcvr error"),
NULL, 0, &rtw_xmtr_restart, 0,
CTL_CREATE, CTL_EOL)) != 0)
goto err;
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
#ifdef RTW_DEBUG
/* control debugging printfs */
if ((rc = sysctl_createv(clog, 0, &rnode, &cnode,
CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT,
"debug", SYSCTL_DESCR("Enable RTL818x debugging output"),
rtw_sysctl_verify_debug, 0, &rtw_debug, 0,
CTL_CREATE, CTL_EOL)) != 0)
goto err;
/* Limit rx buffers, for simulating resource exhaustion. */
if ((rc = sysctl_createv(clog, 0, &rnode, &cnode,
CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT,
"rxbufs_limit",
SYSCTL_DESCR("Set rx buffers limit"),
rtw_sysctl_verify_rxbufs_limit, 0, &rtw_rxbufs_limit, 0,
CTL_CREATE, CTL_EOL)) != 0)
goto err;
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
#endif /* RTW_DEBUG */
/* set fallback RF programming method */
if ((rc = sysctl_createv(clog, 0, &rnode, &cnode,
CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT,
"rfprog_fallback",
SYSCTL_DESCR("Set fallback RF programming method"),
rtw_sysctl_verify_rfprog, 0, &rtw_rfprog_fallback, 0,
CTL_CREATE, CTL_EOL)) != 0)
goto err;
/* force host to control RF I/O bus */
if ((rc = sysctl_createv(clog, 0, &rnode, &cnode,
CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT,
"host_rfio", SYSCTL_DESCR("Enable host control of RF I/O"),
rtw_sysctl_verify_rfio, 0, &rtw_host_rfio, 0,
CTL_CREATE, CTL_EOL)) != 0)
goto err;
return;
err:
printf("%s: sysctl_createv failed (rc = %d)\n", __func__, rc);
}
static int
rtw_sysctl_verify(SYSCTLFN_ARGS, int lower, int upper)
{
int error, t;
struct sysctlnode node;
node = *rnode;
t = *(int*)rnode->sysctl_data;
node.sysctl_data = &t;
error = sysctl_lookup(SYSCTLFN_CALL(&node));
if (error || newp == NULL)
return (error);
if (t < lower || t > upper)
return (EINVAL);
*(int*)rnode->sysctl_data = t;
return (0);
}
static int
rtw_sysctl_verify_rfprog(SYSCTLFN_ARGS)
{
return rtw_sysctl_verify(SYSCTLFN_CALL(__UNCONST(rnode)), 0,
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
MASK_AND_RSHIFT(RTW_CONFIG4_RFTYPE_MASK, RTW_CONFIG4_RFTYPE_MASK));
}
static int
rtw_sysctl_verify_rfio(SYSCTLFN_ARGS)
{
return rtw_sysctl_verify(SYSCTLFN_CALL(__UNCONST(rnode)), 0, 1);
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
}
#ifdef RTW_DEBUG
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
static int
rtw_sysctl_verify_debug(SYSCTLFN_ARGS)
{
return rtw_sysctl_verify(SYSCTLFN_CALL(__UNCONST(rnode)),
0, RTW_DEBUG_MAX);
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
}
static int
rtw_sysctl_verify_rxbufs_limit(SYSCTLFN_ARGS)
{
return rtw_sysctl_verify(SYSCTLFN_CALL(__UNCONST(rnode)),
0, RTW_RXQLEN);
}
static void
rtw_print_regs(struct rtw_regs *regs, const char *dvname, const char *where)
{
#define PRINTREG32(sc, reg) \
RTW_DPRINTF(RTW_DEBUG_REGDUMP, \
("%s: reg[ " #reg " / %03x ] = %08x\n", \
dvname, reg, RTW_READ(regs, reg)))
#define PRINTREG16(sc, reg) \
RTW_DPRINTF(RTW_DEBUG_REGDUMP, \
("%s: reg[ " #reg " / %03x ] = %04x\n", \
dvname, reg, RTW_READ16(regs, reg)))
#define PRINTREG8(sc, reg) \
RTW_DPRINTF(RTW_DEBUG_REGDUMP, \
("%s: reg[ " #reg " / %03x ] = %02x\n", \
dvname, reg, RTW_READ8(regs, reg)))
RTW_DPRINTF(RTW_DEBUG_REGDUMP, ("%s: %s\n", dvname, where));
PRINTREG32(regs, RTW_IDR0);
PRINTREG32(regs, RTW_IDR1);
PRINTREG32(regs, RTW_MAR0);
PRINTREG32(regs, RTW_MAR1);
PRINTREG32(regs, RTW_TSFTRL);
PRINTREG32(regs, RTW_TSFTRH);
PRINTREG32(regs, RTW_TLPDA);
PRINTREG32(regs, RTW_TNPDA);
PRINTREG32(regs, RTW_THPDA);
PRINTREG32(regs, RTW_TCR);
PRINTREG32(regs, RTW_RCR);
PRINTREG32(regs, RTW_TINT);
PRINTREG32(regs, RTW_TBDA);
PRINTREG32(regs, RTW_ANAPARM);
PRINTREG32(regs, RTW_BB);
PRINTREG32(regs, RTW_PHYCFG);
PRINTREG32(regs, RTW_WAKEUP0L);
PRINTREG32(regs, RTW_WAKEUP0H);
PRINTREG32(regs, RTW_WAKEUP1L);
PRINTREG32(regs, RTW_WAKEUP1H);
PRINTREG32(regs, RTW_WAKEUP2LL);
PRINTREG32(regs, RTW_WAKEUP2LH);
PRINTREG32(regs, RTW_WAKEUP2HL);
PRINTREG32(regs, RTW_WAKEUP2HH);
PRINTREG32(regs, RTW_WAKEUP3LL);
PRINTREG32(regs, RTW_WAKEUP3LH);
PRINTREG32(regs, RTW_WAKEUP3HL);
PRINTREG32(regs, RTW_WAKEUP3HH);
PRINTREG32(regs, RTW_WAKEUP4LL);
PRINTREG32(regs, RTW_WAKEUP4LH);
PRINTREG32(regs, RTW_WAKEUP4HL);
PRINTREG32(regs, RTW_WAKEUP4HH);
PRINTREG32(regs, RTW_DK0);
PRINTREG32(regs, RTW_DK1);
PRINTREG32(regs, RTW_DK2);
PRINTREG32(regs, RTW_DK3);
PRINTREG32(regs, RTW_RETRYCTR);
PRINTREG32(regs, RTW_RDSAR);
PRINTREG32(regs, RTW_FER);
PRINTREG32(regs, RTW_FEMR);
PRINTREG32(regs, RTW_FPSR);
PRINTREG32(regs, RTW_FFER);
/* 16-bit registers */
PRINTREG16(regs, RTW_BRSR);
PRINTREG16(regs, RTW_IMR);
PRINTREG16(regs, RTW_ISR);
PRINTREG16(regs, RTW_BCNITV);
PRINTREG16(regs, RTW_ATIMWND);
PRINTREG16(regs, RTW_BINTRITV);
PRINTREG16(regs, RTW_ATIMTRITV);
PRINTREG16(regs, RTW_CRC16ERR);
PRINTREG16(regs, RTW_CRC0);
PRINTREG16(regs, RTW_CRC1);
PRINTREG16(regs, RTW_CRC2);
PRINTREG16(regs, RTW_CRC3);
PRINTREG16(regs, RTW_CRC4);
PRINTREG16(regs, RTW_CWR);
/* 8-bit registers */
PRINTREG8(regs, RTW_CR);
PRINTREG8(regs, RTW_9346CR);
PRINTREG8(regs, RTW_CONFIG0);
PRINTREG8(regs, RTW_CONFIG1);
PRINTREG8(regs, RTW_CONFIG2);
PRINTREG8(regs, RTW_MSR);
PRINTREG8(regs, RTW_CONFIG3);
PRINTREG8(regs, RTW_CONFIG4);
PRINTREG8(regs, RTW_TESTR);
PRINTREG8(regs, RTW_PSR);
PRINTREG8(regs, RTW_SCR);
PRINTREG8(regs, RTW_PHYDELAY);
PRINTREG8(regs, RTW_CRCOUNT);
PRINTREG8(regs, RTW_PHYADDR);
PRINTREG8(regs, RTW_PHYDATAW);
PRINTREG8(regs, RTW_PHYDATAR);
PRINTREG8(regs, RTW_CONFIG5);
PRINTREG8(regs, RTW_TPPOLL);
PRINTREG16(regs, RTW_BSSID16);
PRINTREG32(regs, RTW_BSSID32);
#undef PRINTREG32
#undef PRINTREG16
#undef PRINTREG8
}
#endif /* RTW_DEBUG */
void
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
rtw_continuous_tx_enable(struct rtw_softc *sc, int enable)
{
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
struct rtw_regs *regs = &sc->sc_regs;
uint32_t tcr;
tcr = RTW_READ(regs, RTW_TCR);
tcr &= ~RTW_TCR_LBK_MASK;
if (enable)
tcr |= RTW_TCR_LBK_CONT;
else
tcr |= RTW_TCR_LBK_NORMAL;
RTW_WRITE(regs, RTW_TCR, tcr);
RTW_SYNC(regs, RTW_TCR, RTW_TCR);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_set_access(regs, RTW_ACCESS_ANAPARM);
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
rtw_txdac_enable(sc, !enable);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_set_access(regs, RTW_ACCESS_ANAPARM);/* XXX Voodoo from Linux. */
rtw_set_access(regs, RTW_ACCESS_NONE);
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
}
#ifdef RTW_DEBUG
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
static const char *
rtw_access_string(enum rtw_access access)
{
switch (access) {
case RTW_ACCESS_NONE:
return "none";
case RTW_ACCESS_CONFIG:
return "config";
case RTW_ACCESS_ANAPARM:
return "anaparm";
default:
return "unknown";
}
}
#endif /* RTW_DEBUG */
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
static void
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_set_access1(struct rtw_regs *regs, enum rtw_access naccess)
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
{
KASSERT(naccess >= RTW_ACCESS_NONE && naccess <= RTW_ACCESS_ANAPARM);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
KASSERT(regs->r_access >= RTW_ACCESS_NONE &&
regs->r_access <= RTW_ACCESS_ANAPARM);
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
if (naccess == regs->r_access)
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
return;
switch (naccess) {
case RTW_ACCESS_NONE:
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
switch (regs->r_access) {
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
case RTW_ACCESS_ANAPARM:
rtw_anaparm_enable(regs, 0);
/*FALLTHROUGH*/
case RTW_ACCESS_CONFIG:
rtw_config0123_enable(regs, 0);
/*FALLTHROUGH*/
case RTW_ACCESS_NONE:
break;
}
break;
case RTW_ACCESS_CONFIG:
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
switch (regs->r_access) {
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
case RTW_ACCESS_NONE:
rtw_config0123_enable(regs, 1);
/*FALLTHROUGH*/
case RTW_ACCESS_CONFIG:
break;
case RTW_ACCESS_ANAPARM:
rtw_anaparm_enable(regs, 0);
break;
}
break;
case RTW_ACCESS_ANAPARM:
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
switch (regs->r_access) {
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
case RTW_ACCESS_NONE:
rtw_config0123_enable(regs, 1);
/*FALLTHROUGH*/
case RTW_ACCESS_CONFIG:
rtw_anaparm_enable(regs, 1);
/*FALLTHROUGH*/
case RTW_ACCESS_ANAPARM:
break;
}
break;
}
}
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
void
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_set_access(struct rtw_regs *regs, enum rtw_access access)
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
{
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_set_access1(regs, access);
RTW_DPRINTF(RTW_DEBUG_ACCESS,
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
("%s: access %s -> %s\n", __func__,
rtw_access_string(regs->r_access),
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
rtw_access_string(access)));
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
regs->r_access = access;
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
}
/*
* Enable registers, switch register banks.
*/
void
rtw_config0123_enable(struct rtw_regs *regs, int enable)
{
uint8_t ecr;
ecr = RTW_READ8(regs, RTW_9346CR);
ecr &= ~(RTW_9346CR_EEM_MASK | RTW_9346CR_EECS | RTW_9346CR_EESK);
if (enable)
ecr |= RTW_9346CR_EEM_CONFIG;
else {
RTW_WBW(regs, RTW_9346CR, MAX(RTW_CONFIG0, RTW_CONFIG3));
ecr |= RTW_9346CR_EEM_NORMAL;
}
RTW_WRITE8(regs, RTW_9346CR, ecr);
RTW_SYNC(regs, RTW_9346CR, RTW_9346CR);
}
/* requires rtw_config0123_enable(, 1) */
void
rtw_anaparm_enable(struct rtw_regs *regs, int enable)
{
uint8_t cfg3;
cfg3 = RTW_READ8(regs, RTW_CONFIG3);
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
cfg3 |= RTW_CONFIG3_CLKRUNEN;
if (enable)
cfg3 |= RTW_CONFIG3_PARMEN;
else
cfg3 &= ~RTW_CONFIG3_PARMEN;
RTW_WRITE8(regs, RTW_CONFIG3, cfg3);
RTW_SYNC(regs, RTW_CONFIG3, RTW_CONFIG3);
}
/* requires rtw_anaparm_enable(, 1) */
void
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
rtw_txdac_enable(struct rtw_softc *sc, int enable)
{
uint32_t anaparm;
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
struct rtw_regs *regs = &sc->sc_regs;
anaparm = RTW_READ(regs, RTW_ANAPARM);
if (enable)
anaparm &= ~RTW_ANAPARM_TXDACOFF;
else
anaparm |= RTW_ANAPARM_TXDACOFF;
RTW_WRITE(regs, RTW_ANAPARM, anaparm);
RTW_SYNC(regs, RTW_ANAPARM, RTW_ANAPARM);
}
static __inline int
rtw_chip_reset1(struct rtw_regs *regs, const char *dvname)
{
uint8_t cr;
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
int i;
RTW_WRITE8(regs, RTW_CR, RTW_CR_RST);
RTW_WBR(regs, RTW_CR, RTW_CR);
for (i = 0; i < 1000; i++) {
if ((cr = RTW_READ8(regs, RTW_CR) & RTW_CR_RST) == 0) {
RTW_DPRINTF(RTW_DEBUG_RESET,
("%s: reset in %dus\n", dvname, i));
return 0;
}
RTW_RBR(regs, RTW_CR, RTW_CR);
DELAY(10); /* 10us */
}
printf("%s: reset failed\n", dvname);
return ETIMEDOUT;
}
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
static __inline int
rtw_chip_reset(struct rtw_regs *regs, const char *dvname)
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
{
uint32_t tcr;
/* from Linux driver */
tcr = RTW_TCR_CWMIN | RTW_TCR_MXDMA_2048 |
LSHIFT(7, RTW_TCR_SRL_MASK) | LSHIFT(7, RTW_TCR_LRL_MASK);
RTW_WRITE(regs, RTW_TCR, tcr);
RTW_WBW(regs, RTW_CR, RTW_TCR);
return rtw_chip_reset1(regs, dvname);
}
static int
rtw_wep_decap(struct ieee80211_key *k, struct mbuf *m, int hdrlen)
{
struct ieee80211_key keycopy;
RTW_DPRINTF(RTW_DEBUG_KEY, ("%s:\n", __func__));
keycopy = *k;
keycopy.wk_flags &= ~IEEE80211_KEY_SWCRYPT;
return (*ieee80211_cipher_wep.ic_decap)(&keycopy, m, hdrlen);
}
static int
rtw_key_delete(struct ieee80211com *ic, const struct ieee80211_key *k)
{
struct rtw_softc *sc = ic->ic_ifp->if_softc;
u_int keyix = k->wk_keyix;
DPRINTF(sc, RTW_DEBUG_KEY, ("%s: delete key %u\n", __func__, keyix));
if (keyix >= IEEE80211_WEP_NKID)
return 0;
if (k->wk_keylen != 0)
sc->sc_flags &= ~RTW_F_DK_VALID;
return 1;
}
static int
rtw_key_set(struct ieee80211com *ic, const struct ieee80211_key *k,
const u_int8_t mac[IEEE80211_ADDR_LEN])
{
struct rtw_softc *sc = ic->ic_ifp->if_softc;
DPRINTF(sc, RTW_DEBUG_KEY, ("%s: set key %u\n", __func__, k->wk_keyix));
if (k->wk_keyix >= IEEE80211_WEP_NKID)
return 0;
sc->sc_flags &= ~RTW_F_DK_VALID;
return 1;
}
static void
rtw_key_update_begin(struct ieee80211com *ic)
{
#ifdef RTW_DEBUG
struct ifnet *ifp = ic->ic_ifp;
struct rtw_softc *sc = ifp->if_softc;
#endif
DPRINTF(sc, RTW_DEBUG_KEY, ("%s:\n", __func__));
}
static void
rtw_key_update_end(struct ieee80211com *ic)
{
struct ifnet *ifp = ic->ic_ifp;
struct rtw_softc *sc = ifp->if_softc;
DPRINTF(sc, RTW_DEBUG_KEY, ("%s:\n", __func__));
if ((sc->sc_flags & RTW_F_DK_VALID) != 0 ||
(sc->sc_flags & RTW_F_ENABLED) == 0 ||
(sc->sc_flags & RTW_F_INVALID) != 0)
return;
rtw_io_enable(&sc->sc_regs, RTW_CR_RE | RTW_CR_TE, 0);
rtw_wep_setkeys(sc, ic->ic_nw_keys, ic->ic_def_txkey);
rtw_io_enable(&sc->sc_regs, RTW_CR_RE | RTW_CR_TE,
(ifp->if_flags & IFF_RUNNING) != 0);
}
static __inline int
rtw_key_hwsupp(uint32_t flags, const struct ieee80211_key *k)
{
if (k->wk_cipher->ic_cipher != IEEE80211_CIPHER_WEP)
return 0;
return ((flags & RTW_C_RXWEP_40) != 0 && k->wk_keylen == 5) ||
((flags & RTW_C_RXWEP_104) != 0 && k->wk_keylen == 13);
}
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
static void
rtw_wep_setkeys(struct rtw_softc *sc, struct ieee80211_key *wk, int txkey)
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
{
uint8_t psr, scr;
int i, tx_key_len;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
struct rtw_regs *regs;
union rtw_keys *rk;
regs = &sc->sc_regs;
rk = &sc->sc_keys;
(void)memset(rk->rk_keys, 0, sizeof(rk->rk_keys));
/* Temporarily use software crypto for all keys. */
for (i = 0; i < IEEE80211_WEP_NKID; i++) {
if (wk[i].wk_cipher == &rtw_cipher_wep)
wk[i].wk_cipher = &ieee80211_cipher_wep;
}
rtw_set_access(regs, RTW_ACCESS_CONFIG);
psr = RTW_READ8(regs, RTW_PSR);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
scr = RTW_READ8(regs, RTW_SCR);
scr &= ~(RTW_SCR_KM_MASK | RTW_SCR_TXSECON | RTW_SCR_RXSECON);
if ((sc->sc_ic.ic_flags & IEEE80211_F_PRIVACY) == 0)
goto out;
if (!rtw_key_hwsupp(sc->sc_flags, &wk[txkey]))
goto out;
tx_key_len = wk[txkey].wk_keylen;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
switch (tx_key_len) {
case 5:
scr |= RTW_SCR_KM_WEP40;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
break;
case 13:
scr |= RTW_SCR_KM_WEP104;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
break;
default:
goto out;
}
scr |= RTW_SCR_RXSECON;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
for (i = 0; i < IEEE80211_WEP_NKID; i++) {
if (wk[i].wk_keylen != tx_key_len ||
wk[i].wk_cipher->ic_cipher != IEEE80211_CIPHER_WEP)
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
continue;
/* h/w will decrypt, s/w still strips headers */
wk[i].wk_cipher = &rtw_cipher_wep;
(void)memcpy(rk->rk_keys[i], wk[i].wk_key, wk[i].wk_keylen);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
}
out:
RTW_WRITE8(regs, RTW_PSR, psr & ~RTW_PSR_PSEN);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
bus_space_write_region_4(regs->r_bt, regs->r_bh,
RTW_DK0, rk->rk_words,
sizeof(rk->rk_words) / sizeof(rk->rk_words[0]));
bus_space_barrier(regs->r_bt, regs->r_bh, RTW_DK0, sizeof(rk->rk_words),
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
BUS_SPACE_BARRIER_SYNC);
RTW_WBW(regs, RTW_DK0, RTW_PSR);
RTW_WRITE8(regs, RTW_PSR, psr);
RTW_WBW(regs, RTW_PSR, RTW_SCR);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
RTW_WRITE8(regs, RTW_SCR, scr);
RTW_SYNC(regs, RTW_SCR, RTW_SCR);
rtw_set_access(regs, RTW_ACCESS_NONE);
sc->sc_flags |= RTW_F_DK_VALID;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
}
static __inline int
rtw_recall_eeprom(struct rtw_regs *regs, const char *dvname)
{
int i;
uint8_t ecr;
ecr = RTW_READ8(regs, RTW_9346CR);
ecr = (ecr & ~RTW_9346CR_EEM_MASK) | RTW_9346CR_EEM_AUTOLOAD;
RTW_WRITE8(regs, RTW_9346CR, ecr);
RTW_WBR(regs, RTW_9346CR, RTW_9346CR);
/* wait 25ms for completion */
for (i = 0; i < 250; i++) {
ecr = RTW_READ8(regs, RTW_9346CR);
if ((ecr & RTW_9346CR_EEM_MASK) == RTW_9346CR_EEM_NORMAL) {
RTW_DPRINTF(RTW_DEBUG_RESET,
("%s: recall EEPROM in %dus\n", dvname, i * 100));
return 0;
}
RTW_RBR(regs, RTW_9346CR, RTW_9346CR);
DELAY(100);
}
printf("%s: recall EEPROM failed\n", dvname);
return ETIMEDOUT;
}
static __inline int
rtw_reset(struct rtw_softc *sc)
{
int rc;
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
uint8_t config1;
sc->sc_flags &= ~RTW_F_DK_VALID;
if ((rc = rtw_chip_reset(&sc->sc_regs, sc->sc_dev.dv_xname)) != 0)
return rc;
if ((rc = rtw_recall_eeprom(&sc->sc_regs, sc->sc_dev.dv_xname)) != 0)
;
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
config1 = RTW_READ8(&sc->sc_regs, RTW_CONFIG1);
RTW_WRITE8(&sc->sc_regs, RTW_CONFIG1, config1 & ~RTW_CONFIG1_PMEN);
/* TBD turn off maximum power saving? */
return 0;
}
static __inline int
rtw_txdesc_dmamaps_create(bus_dma_tag_t dmat, struct rtw_txsoft *descs,
u_int ndescs)
{
int i, rc = 0;
for (i = 0; i < ndescs; i++) {
rc = bus_dmamap_create(dmat, MCLBYTES, RTW_MAXPKTSEGS, MCLBYTES,
0, 0, &descs[i].ts_dmamap);
if (rc != 0)
break;
}
return rc;
}
static __inline int
rtw_rxdesc_dmamaps_create(bus_dma_tag_t dmat, struct rtw_rxsoft *descs,
u_int ndescs)
{
int i, rc = 0;
for (i = 0; i < ndescs; i++) {
rc = bus_dmamap_create(dmat, MCLBYTES, 1, MCLBYTES, 0, 0,
&descs[i].rs_dmamap);
if (rc != 0)
break;
}
return rc;
}
static __inline void
rtw_rxdesc_dmamaps_destroy(bus_dma_tag_t dmat, struct rtw_rxsoft *descs,
u_int ndescs)
{
int i;
for (i = 0; i < ndescs; i++) {
if (descs[i].rs_dmamap != NULL)
bus_dmamap_destroy(dmat, descs[i].rs_dmamap);
}
}
static __inline void
rtw_txdesc_dmamaps_destroy(bus_dma_tag_t dmat, struct rtw_txsoft *descs,
u_int ndescs)
{
int i;
for (i = 0; i < ndescs; i++) {
if (descs[i].ts_dmamap != NULL)
bus_dmamap_destroy(dmat, descs[i].ts_dmamap);
}
}
static __inline void
rtw_srom_free(struct rtw_srom *sr)
{
sr->sr_size = 0;
if (sr->sr_content == NULL)
return;
free(sr->sr_content, M_DEVBUF);
sr->sr_content = NULL;
}
static void
rtw_srom_defaults(struct rtw_srom *sr, uint32_t *flags, uint8_t *cs_threshold,
enum rtw_rfchipid *rfchipid, uint32_t *rcr)
{
*flags |= (RTW_F_DIGPHY|RTW_F_ANTDIV);
*cs_threshold = RTW_SR_ENERGYDETTHR_DEFAULT;
*rcr |= RTW_RCR_ENCS1;
*rfchipid = RTW_RFCHIPID_PHILIPS;
}
static int
rtw_srom_parse(struct rtw_srom *sr, uint32_t *flags, uint8_t *cs_threshold,
enum rtw_rfchipid *rfchipid, uint32_t *rcr, enum rtw_locale *locale,
const char *dvname)
{
int i;
const char *rfname, *paname;
char scratch[sizeof("unknown 0xXX")];
uint16_t srom_version;
uint8_t mac[IEEE80211_ADDR_LEN];
*flags &= ~(RTW_F_DIGPHY|RTW_F_DFLANTB|RTW_F_ANTDIV);
*rcr &= ~(RTW_RCR_ENCS1 | RTW_RCR_ENCS2);
srom_version = RTW_SR_GET16(sr, RTW_SR_VERSION);
printf("%s: SROM version %d.%d", dvname,
srom_version >> 8, srom_version & 0xff);
if (srom_version <= 0x0101) {
printf(" is not understood, limping along with defaults\n");
rtw_srom_defaults(sr, flags, cs_threshold, rfchipid, rcr);
return 0;
}
printf("\n");
for (i = 0; i < IEEE80211_ADDR_LEN; i++)
mac[i] = RTW_SR_GET(sr, RTW_SR_MAC + i);
RTW_DPRINTF(RTW_DEBUG_ATTACH,
("%s: EEPROM MAC %s\n", dvname, ether_sprintf(mac)));
*cs_threshold = RTW_SR_GET(sr, RTW_SR_ENERGYDETTHR);
if ((RTW_SR_GET(sr, RTW_SR_CONFIG2) & RTW_CONFIG2_ANT) != 0)
*flags |= RTW_F_ANTDIV;
/* Note well: the sense of the RTW_SR_RFPARM_DIGPHY bit seems
* to be reversed.
*/
if ((RTW_SR_GET(sr, RTW_SR_RFPARM) & RTW_SR_RFPARM_DIGPHY) == 0)
*flags |= RTW_F_DIGPHY;
if ((RTW_SR_GET(sr, RTW_SR_RFPARM) & RTW_SR_RFPARM_DFLANTB) != 0)
*flags |= RTW_F_DFLANTB;
*rcr |= LSHIFT(MASK_AND_RSHIFT(RTW_SR_GET(sr, RTW_SR_RFPARM),
RTW_SR_RFPARM_CS_MASK), RTW_RCR_ENCS1);
if ((RTW_SR_GET(sr, RTW_SR_CONFIG0) & RTW_CONFIG0_WEP104) != 0)
*flags |= RTW_C_RXWEP_104;
*flags |= RTW_C_RXWEP_40; /* XXX */
*rfchipid = RTW_SR_GET(sr, RTW_SR_RFCHIPID);
switch (*rfchipid) {
case RTW_RFCHIPID_GCT: /* this combo seen in the wild */
rfname = "GCT GRF5101";
paname = "Winspring WS9901";
break;
case RTW_RFCHIPID_MAXIM:
rfname = "Maxim MAX2820"; /* guess */
paname = "Maxim MAX2422"; /* guess */
break;
case RTW_RFCHIPID_INTERSIL:
rfname = "Intersil HFA3873"; /* guess */
paname = "Intersil <unknown>";
break;
case RTW_RFCHIPID_PHILIPS: /* this combo seen in the wild */
rfname = "Philips SA2400A";
paname = "Philips SA2411";
break;
case RTW_RFCHIPID_RFMD:
/* this is the same front-end as an atw(4)! */
rfname = "RFMD RF2948B, " /* mentioned in Realtek docs */
"LNA: RFMD RF2494, " /* mentioned in Realtek docs */
"SYN: Silicon Labs Si4126"; /* inferred from
* reference driver
*/
paname = "RFMD RF2189"; /* mentioned in Realtek docs */
break;
case RTW_RFCHIPID_RESERVED:
rfname = paname = "reserved";
break;
default:
snprintf(scratch, sizeof(scratch), "unknown 0x%02x", *rfchipid);
rfname = paname = scratch;
}
printf("%s: RF: %s, PA: %s\n", dvname, rfname, paname);
switch (RTW_SR_GET(sr, RTW_SR_CONFIG0) & RTW_CONFIG0_GL_MASK) {
case RTW_CONFIG0_GL_USA:
case _RTW_CONFIG0_GL_USA:
*locale = RTW_LOCALE_USA;
break;
case RTW_CONFIG0_GL_EUROPE:
*locale = RTW_LOCALE_EUROPE;
break;
case RTW_CONFIG0_GL_JAPAN:
*locale = RTW_LOCALE_JAPAN;
break;
default:
*locale = RTW_LOCALE_UNKNOWN;
break;
}
return 0;
}
/* Returns -1 on failure. */
static int
rtw_srom_read(struct rtw_regs *regs, uint32_t flags, struct rtw_srom *sr,
const char *dvname)
{
int rc;
struct seeprom_descriptor sd;
uint8_t ecr;
(void)memset(&sd, 0, sizeof(sd));
ecr = RTW_READ8(regs, RTW_9346CR);
if ((flags & RTW_F_9356SROM) != 0) {
RTW_DPRINTF(RTW_DEBUG_ATTACH, ("%s: 93c56 SROM\n", dvname));
sr->sr_size = 256;
sd.sd_chip = C56_66;
} else {
RTW_DPRINTF(RTW_DEBUG_ATTACH, ("%s: 93c46 SROM\n", dvname));
sr->sr_size = 128;
sd.sd_chip = C46;
}
ecr &= ~(RTW_9346CR_EEDI | RTW_9346CR_EEDO | RTW_9346CR_EESK |
RTW_9346CR_EEM_MASK | RTW_9346CR_EECS);
ecr |= RTW_9346CR_EEM_PROGRAM;
RTW_WRITE8(regs, RTW_9346CR, ecr);
sr->sr_content = malloc(sr->sr_size, M_DEVBUF, M_NOWAIT);
if (sr->sr_content == NULL) {
printf("%s: unable to allocate SROM buffer\n", dvname);
return ENOMEM;
}
(void)memset(sr->sr_content, 0, sr->sr_size);
/* RTL8180 has a single 8-bit register for controlling the
* 93cx6 SROM. There is no "ready" bit. The RTL8180
* input/output sense is the reverse of read_seeprom's.
*/
sd.sd_tag = regs->r_bt;
sd.sd_bsh = regs->r_bh;
sd.sd_regsize = 1;
sd.sd_control_offset = RTW_9346CR;
sd.sd_status_offset = RTW_9346CR;
sd.sd_dataout_offset = RTW_9346CR;
sd.sd_CK = RTW_9346CR_EESK;
sd.sd_CS = RTW_9346CR_EECS;
sd.sd_DI = RTW_9346CR_EEDO;
sd.sd_DO = RTW_9346CR_EEDI;
2005-02-27 03:26:58 +03:00
/* make read_seeprom enter EEPROM read/write mode */
sd.sd_MS = ecr;
sd.sd_RDY = 0;
/* TBD bus barriers */
if (!read_seeprom(&sd, sr->sr_content, 0, sr->sr_size/2)) {
printf("%s: could not read SROM\n", dvname);
free(sr->sr_content, M_DEVBUF);
sr->sr_content = NULL;
return -1; /* XXX */
}
2005-02-27 03:26:58 +03:00
/* end EEPROM read/write mode */
RTW_WRITE8(regs, RTW_9346CR,
(ecr & ~RTW_9346CR_EEM_MASK) | RTW_9346CR_EEM_NORMAL);
RTW_WBRW(regs, RTW_9346CR, RTW_9346CR);
if ((rc = rtw_recall_eeprom(regs, dvname)) != 0)
return rc;
#ifdef RTW_DEBUG
{
int i;
RTW_DPRINTF(RTW_DEBUG_ATTACH,
("\n%s: serial ROM:\n\t", dvname));
for (i = 0; i < sr->sr_size/2; i++) {
if (((i % 8) == 0) && (i != 0))
RTW_DPRINTF(RTW_DEBUG_ATTACH, ("\n\t"));
RTW_DPRINTF(RTW_DEBUG_ATTACH,
(" %04x", sr->sr_content[i]));
}
RTW_DPRINTF(RTW_DEBUG_ATTACH, ("\n"));
}
#endif /* RTW_DEBUG */
return 0;
}
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
static void
rtw_set_rfprog(struct rtw_regs *regs, enum rtw_rfchipid rfchipid,
const char *dvname)
{
uint8_t cfg4;
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
const char *method;
cfg4 = RTW_READ8(regs, RTW_CONFIG4) & ~RTW_CONFIG4_RFTYPE_MASK;
switch (rfchipid) {
default:
cfg4 |= LSHIFT(rtw_rfprog_fallback, RTW_CONFIG4_RFTYPE_MASK);
method = "fallback";
break;
case RTW_RFCHIPID_INTERSIL:
cfg4 |= RTW_CONFIG4_RFTYPE_INTERSIL;
method = "Intersil";
break;
case RTW_RFCHIPID_PHILIPS:
cfg4 |= RTW_CONFIG4_RFTYPE_PHILIPS;
method = "Philips";
break;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
case RTW_RFCHIPID_GCT: /* XXX a guess */
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
case RTW_RFCHIPID_RFMD:
cfg4 |= RTW_CONFIG4_RFTYPE_RFMD;
method = "RFMD";
break;
}
RTW_WRITE8(regs, RTW_CONFIG4, cfg4);
RTW_WBR(regs, RTW_CONFIG4, RTW_CONFIG4);
RTW_DPRINTF(RTW_DEBUG_INIT,
("%s: %s RF programming method, %#02x\n", dvname, method,
RTW_READ8(regs, RTW_CONFIG4)));
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
}
static __inline void
rtw_init_channels(enum rtw_locale locale,
struct ieee80211_channel (*chans)[IEEE80211_CHAN_MAX+1],
const char *dvname)
{
int i;
const char *name = NULL;
#define ADD_CHANNEL(_chans, _chan) do { \
(*_chans)[_chan].ic_flags = IEEE80211_CHAN_B; \
(*_chans)[_chan].ic_freq = \
ieee80211_ieee2mhz(_chan, (*_chans)[_chan].ic_flags);\
} while (0)
switch (locale) {
case RTW_LOCALE_USA: /* 1-11 */
name = "USA";
for (i = 1; i <= 11; i++)
ADD_CHANNEL(chans, i);
break;
case RTW_LOCALE_JAPAN: /* 1-14 */
name = "Japan";
ADD_CHANNEL(chans, 14);
for (i = 1; i <= 14; i++)
ADD_CHANNEL(chans, i);
break;
case RTW_LOCALE_EUROPE: /* 1-13 */
name = "Europe";
for (i = 1; i <= 13; i++)
ADD_CHANNEL(chans, i);
break;
default: /* 10-11 allowed by most countries */
name = "<unknown>";
for (i = 10; i <= 11; i++)
ADD_CHANNEL(chans, i);
break;
}
printf("%s: Geographic Location %s\n", dvname, name);
#undef ADD_CHANNEL
}
static __inline void
rtw_identify_country(struct rtw_regs *regs, enum rtw_locale *locale)
{
uint8_t cfg0 = RTW_READ8(regs, RTW_CONFIG0);
switch (cfg0 & RTW_CONFIG0_GL_MASK) {
case RTW_CONFIG0_GL_USA:
case _RTW_CONFIG0_GL_USA:
*locale = RTW_LOCALE_USA;
break;
case RTW_CONFIG0_GL_JAPAN:
*locale = RTW_LOCALE_JAPAN;
break;
case RTW_CONFIG0_GL_EUROPE:
*locale = RTW_LOCALE_EUROPE;
break;
default:
*locale = RTW_LOCALE_UNKNOWN;
break;
}
}
static __inline int
rtw_identify_sta(struct rtw_regs *regs, uint8_t (*addr)[IEEE80211_ADDR_LEN],
const char *dvname)
{
static const uint8_t empty_macaddr[IEEE80211_ADDR_LEN] = {
0x00, 0x00, 0x00, 0x00, 0x00, 0x00
};
uint32_t idr0 = RTW_READ(regs, RTW_IDR0),
idr1 = RTW_READ(regs, RTW_IDR1);
(*addr)[0] = MASK_AND_RSHIFT(idr0, BITS(0, 7));
(*addr)[1] = MASK_AND_RSHIFT(idr0, BITS(8, 15));
(*addr)[2] = MASK_AND_RSHIFT(idr0, BITS(16, 23));
(*addr)[3] = MASK_AND_RSHIFT(idr0, BITS(24 ,31));
(*addr)[4] = MASK_AND_RSHIFT(idr1, BITS(0, 7));
(*addr)[5] = MASK_AND_RSHIFT(idr1, BITS(8, 15));
if (IEEE80211_ADDR_EQ(addr, empty_macaddr)) {
printf("%s: could not get mac address, attach failed\n",
dvname);
return ENXIO;
}
printf("%s: 802.11 address %s\n", dvname, ether_sprintf(*addr));
return 0;
}
static uint8_t
rtw_chan2txpower(struct rtw_srom *sr, struct ieee80211com *ic,
struct ieee80211_channel *chan)
{
u_int idx = RTW_SR_TXPOWER1 + ieee80211_chan2ieee(ic, chan) - 1;
KASSERT2(idx >= RTW_SR_TXPOWER1 && idx <= RTW_SR_TXPOWER14,
("%s: channel %d out of range", __func__,
idx - RTW_SR_TXPOWER1 + 1));
return RTW_SR_GET(sr, idx);
}
static void
rtw_txdesc_blk_init_all(struct rtw_txdesc_blk *tdb)
{
int pri;
/* nfree: the number of free descriptors in each ring.
* The beacon ring is a special case: I do not let the
* driver use all of the descriptors on the beacon ring.
* The reasons are two-fold:
*
* (1) A BEACON descriptor's OWN bit is (apparently) not
* updated, so the driver cannot easily know if the descriptor
* belongs to it, or if it is racing the NIC. If the NIC
* does not OWN every descriptor, then the driver can safely
* update the descriptors when RTW_TBDA points at tdb_next.
*
* (2) I hope that the NIC will process more than one BEACON
* descriptor in a single beacon interval, since that will
* enable multiple-BSS support. Since the NIC does not
* clear the OWN bit, there is no natural place for it to
* stop processing BEACON desciptors. Maybe it will *not*
* stop processing them! I do not want to chance the NIC
* looping around and around a saturated beacon ring, so
* I will leave one descriptor unOWNed at all times.
*/
u_int nfree[RTW_NTXPRI] =
{RTW_NTXDESCLO, RTW_NTXDESCMD, RTW_NTXDESCHI,
RTW_NTXDESCBCN - 1};
for (pri = 0; pri < RTW_NTXPRI; pri++) {
tdb[pri].tdb_nfree = nfree[pri];
tdb[pri].tdb_next = 0;
}
}
static int
rtw_txsoft_blk_init(struct rtw_txsoft_blk *tsb)
{
int i;
struct rtw_txsoft *ts;
SIMPLEQ_INIT(&tsb->tsb_dirtyq);
SIMPLEQ_INIT(&tsb->tsb_freeq);
for (i = 0; i < tsb->tsb_ndesc; i++) {
ts = &tsb->tsb_desc[i];
ts->ts_mbuf = NULL;
SIMPLEQ_INSERT_TAIL(&tsb->tsb_freeq, ts, ts_q);
}
tsb->tsb_tx_timer = 0;
return 0;
}
static void
rtw_txsoft_blk_init_all(struct rtw_txsoft_blk *tsb)
{
int pri;
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
for (pri = 0; pri < RTW_NTXPRI; pri++)
rtw_txsoft_blk_init(&tsb[pri]);
}
static __inline void
rtw_rxdescs_sync(struct rtw_rxdesc_blk *rdb, int desc0, int nsync, int ops)
{
KASSERT(nsync <= rdb->rdb_ndesc);
/* sync to end of ring */
if (desc0 + nsync > rdb->rdb_ndesc) {
bus_dmamap_sync(rdb->rdb_dmat, rdb->rdb_dmamap,
offsetof(struct rtw_descs, hd_rx[desc0]),
sizeof(struct rtw_rxdesc) * (rdb->rdb_ndesc - desc0), ops);
nsync -= (rdb->rdb_ndesc - desc0);
desc0 = 0;
}
KASSERT(desc0 < rdb->rdb_ndesc);
KASSERT(nsync <= rdb->rdb_ndesc);
KASSERT(desc0 + nsync <= rdb->rdb_ndesc);
/* sync what remains */
bus_dmamap_sync(rdb->rdb_dmat, rdb->rdb_dmamap,
offsetof(struct rtw_descs, hd_rx[desc0]),
sizeof(struct rtw_rxdesc) * nsync, ops);
}
static void
rtw_txdescs_sync(struct rtw_txdesc_blk *tdb, u_int desc0, u_int nsync, int ops)
{
/* sync to end of ring */
if (desc0 + nsync > tdb->tdb_ndesc) {
bus_dmamap_sync(tdb->tdb_dmat, tdb->tdb_dmamap,
tdb->tdb_ofs + sizeof(struct rtw_txdesc) * desc0,
sizeof(struct rtw_txdesc) * (tdb->tdb_ndesc - desc0),
ops);
nsync -= (tdb->tdb_ndesc - desc0);
desc0 = 0;
}
/* sync what remains */
bus_dmamap_sync(tdb->tdb_dmat, tdb->tdb_dmamap,
tdb->tdb_ofs + sizeof(struct rtw_txdesc) * desc0,
sizeof(struct rtw_txdesc) * nsync, ops);
}
static void
rtw_txdescs_sync_all(struct rtw_txdesc_blk *tdb)
{
int pri;
for (pri = 0; pri < RTW_NTXPRI; pri++) {
rtw_txdescs_sync(&tdb[pri], 0, tdb[pri].tdb_ndesc,
BUS_DMASYNC_PREREAD|BUS_DMASYNC_PREWRITE);
}
}
static void
rtw_rxbufs_release(bus_dma_tag_t dmat, struct rtw_rxsoft *desc)
{
int i;
struct rtw_rxsoft *rs;
for (i = 0; i < RTW_RXQLEN; i++) {
rs = &desc[i];
if (rs->rs_mbuf == NULL)
continue;
bus_dmamap_sync(dmat, rs->rs_dmamap, 0,
rs->rs_dmamap->dm_mapsize, BUS_DMASYNC_POSTREAD);
bus_dmamap_unload(dmat, rs->rs_dmamap);
m_freem(rs->rs_mbuf);
rs->rs_mbuf = NULL;
}
}
static __inline int
rtw_rxsoft_alloc(bus_dma_tag_t dmat, struct rtw_rxsoft *rs)
{
int rc;
struct mbuf *m;
2005-02-27 03:26:58 +03:00
MGETHDR(m, M_DONTWAIT, MT_DATA);
if (m == NULL)
return ENOBUFS;
2005-02-27 03:26:58 +03:00
MCLGET(m, M_DONTWAIT);
if ((m->m_flags & M_EXT) == 0) {
m_freem(m);
return ENOBUFS;
}
m->m_pkthdr.len = m->m_len = m->m_ext.ext_size;
if (rs->rs_mbuf != NULL)
bus_dmamap_unload(dmat, rs->rs_dmamap);
rs->rs_mbuf = NULL;
rc = bus_dmamap_load_mbuf(dmat, rs->rs_dmamap, m, BUS_DMA_NOWAIT);
if (rc != 0) {
m_freem(m);
return -1;
}
rs->rs_mbuf = m;
return 0;
}
static int
rtw_rxsoft_init_all(bus_dma_tag_t dmat, struct rtw_rxsoft *desc,
int *ndesc, const char *dvname)
{
int i, rc = 0;
struct rtw_rxsoft *rs;
for (i = 0; i < RTW_RXQLEN; i++) {
rs = &desc[i];
/* we're in rtw_init, so there should be no mbufs allocated */
KASSERT(rs->rs_mbuf == NULL);
#ifdef RTW_DEBUG
if (i == rtw_rxbufs_limit) {
printf("%s: TEST hit %d-buffer limit\n", dvname, i);
rc = ENOBUFS;
break;
}
#endif /* RTW_DEBUG */
if ((rc = rtw_rxsoft_alloc(dmat, rs)) != 0) {
printf("%s: rtw_rxsoft_alloc failed, %d buffers, "
"rc %d\n", dvname, i, rc);
break;
}
}
*ndesc = i;
return rc;
}
static __inline void
rtw_rxdesc_init(struct rtw_rxdesc_blk *rdb, struct rtw_rxsoft *rs,
int idx, int kick)
{
int is_last = (idx == rdb->rdb_ndesc - 1);
uint32_t ctl, octl, obuf;
struct rtw_rxdesc *rd = &rdb->rdb_desc[idx];
obuf = rd->rd_buf;
rd->rd_buf = htole32(rs->rs_dmamap->dm_segs[0].ds_addr);
ctl = LSHIFT(rs->rs_mbuf->m_len, RTW_RXCTL_LENGTH_MASK) |
RTW_RXCTL_OWN | RTW_RXCTL_FS | RTW_RXCTL_LS;
if (is_last)
ctl |= RTW_RXCTL_EOR;
octl = rd->rd_ctl;
rd->rd_ctl = htole32(ctl);
RTW_DPRINTF(
kick ? (RTW_DEBUG_RECV_DESC | RTW_DEBUG_IO_KICK)
: RTW_DEBUG_RECV_DESC,
("%s: rd %p buf %08x -> %08x ctl %08x -> %08x\n", __func__, rd,
le32toh(obuf), le32toh(rd->rd_buf), le32toh(octl),
le32toh(rd->rd_ctl)));
/* sync the mbuf */
bus_dmamap_sync(rdb->rdb_dmat, rs->rs_dmamap, 0,
rs->rs_dmamap->dm_mapsize, BUS_DMASYNC_PREREAD);
/* sync the descriptor */
bus_dmamap_sync(rdb->rdb_dmat, rdb->rdb_dmamap,
RTW_DESC_OFFSET(hd_rx, idx), sizeof(struct rtw_rxdesc),
BUS_DMASYNC_PREREAD|BUS_DMASYNC_PREWRITE);
}
static void
rtw_rxdesc_init_all(struct rtw_rxdesc_blk *rdb, struct rtw_rxsoft *ctl, int kick)
{
int i;
struct rtw_rxdesc *rd;
struct rtw_rxsoft *rs;
for (i = 0; i < rdb->rdb_ndesc; i++) {
rd = &rdb->rdb_desc[i];
rs = &ctl[i];
rtw_rxdesc_init(rdb, rs, i, kick);
}
}
static void
rtw_io_enable(struct rtw_regs *regs, uint8_t flags, int enable)
{
uint8_t cr;
RTW_DPRINTF(RTW_DEBUG_IOSTATE, ("%s: %s 0x%02x\n", __func__,
enable ? "enable" : "disable", flags));
cr = RTW_READ8(regs, RTW_CR);
/* XXX reference source does not enable MULRW */
#if 0
/* enable PCI Read/Write Multiple */
cr |= RTW_CR_MULRW;
#endif
RTW_RBW(regs, RTW_CR, RTW_CR); /* XXX paranoia? */
if (enable)
cr |= flags;
else
cr &= ~flags;
RTW_WRITE8(regs, RTW_CR, cr);
RTW_SYNC(regs, RTW_CR, RTW_CR);
}
static void
rtw_intr_rx(struct rtw_softc *sc, uint16_t isr)
{
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
#define IS_BEACON(__fc0) \
((__fc0 & (IEEE80211_FC0_TYPE_MASK | IEEE80211_FC0_SUBTYPE_MASK)) ==\
(IEEE80211_FC0_TYPE_MGT | IEEE80211_FC0_SUBTYPE_BEACON))
static const int ratetbl[4] = {2, 4, 11, 22}; /* convert rates:
* hardware -> net80211
*/
u_int next, nproc = 0;
int hwrate, len, rate, rssi, sq;
uint32_t hrssi, hstat, htsfth, htsftl;
struct rtw_rxdesc *rd;
struct rtw_rxsoft *rs;
struct rtw_rxdesc_blk *rdb;
struct mbuf *m;
struct ifnet *ifp = &sc->sc_if;
struct ieee80211_node *ni;
struct ieee80211_frame_min *wh;
rdb = &sc->sc_rxdesc_blk;
KASSERT(rdb->rdb_next < rdb->rdb_ndesc);
for (next = rdb->rdb_next; ; next = (next + 1) % rdb->rdb_ndesc) {
rtw_rxdescs_sync(rdb, next, 1,
BUS_DMASYNC_POSTREAD|BUS_DMASYNC_POSTWRITE);
rd = &rdb->rdb_desc[next];
rs = &sc->sc_rxsoft[next];
hstat = le32toh(rd->rd_stat);
hrssi = le32toh(rd->rd_rssi);
htsfth = le32toh(rd->rd_tsfth);
htsftl = le32toh(rd->rd_tsftl);
RTW_DPRINTF(RTW_DEBUG_RECV_DESC,
("%s: rxdesc[%d] hstat %08x hrssi %08x htsft %08x%08x\n",
__func__, next, hstat, hrssi, htsfth, htsftl));
++nproc;
/* still belongs to NIC */
if ((hstat & RTW_RXSTAT_OWN) != 0) {
if (nproc > 1)
break;
/* sometimes the NIC skips to the 0th descriptor */
rtw_rxdescs_sync(rdb, 0, 1,
BUS_DMASYNC_POSTREAD|BUS_DMASYNC_POSTWRITE);
rd = &rdb->rdb_desc[0];
if ((rd->rd_stat & htole32(RTW_RXSTAT_OWN)) != 0)
break;
RTW_DPRINTF(RTW_DEBUG_BUGS,
("%s: NIC skipped from rxdesc[%u] to rxdesc[0]\n",
sc->sc_dev.dv_xname, next));
next = rdb->rdb_ndesc - 1;
continue;
}
#ifdef RTW_DEBUG
#define PRINTSTAT(flag) do { \
if ((hstat & flag) != 0) { \
printf("%s" #flag, delim); \
delim = ","; \
} \
} while (0)
if ((rtw_debug & RTW_DEBUG_RECV_DESC) != 0) {
const char *delim = "<";
printf("%s: ", sc->sc_dev.dv_xname);
if ((hstat & RTW_RXSTAT_DEBUG) != 0) {
printf("status %08x", hstat);
PRINTSTAT(RTW_RXSTAT_SPLCP);
PRINTSTAT(RTW_RXSTAT_MAR);
PRINTSTAT(RTW_RXSTAT_PAR);
PRINTSTAT(RTW_RXSTAT_BAR);
PRINTSTAT(RTW_RXSTAT_PWRMGT);
PRINTSTAT(RTW_RXSTAT_CRC32);
PRINTSTAT(RTW_RXSTAT_ICV);
printf(">, ");
}
}
#endif /* RTW_DEBUG */
if ((hstat & RTW_RXSTAT_IOERROR) != 0) {
printf("%s: DMA error/FIFO overflow %08x, "
"rx descriptor %d\n", sc->sc_dev.dv_xname,
hstat & RTW_RXSTAT_IOERROR, next);
ifp->if_ierrors++;
goto next;
}
len = MASK_AND_RSHIFT(hstat, RTW_RXSTAT_LENGTH_MASK);
if (len < IEEE80211_MIN_LEN) {
sc->sc_ic.ic_stats.is_rx_tooshort++;
goto next;
}
2005-01-31 05:51:17 +03:00
/* CRC is included with the packet; trim it off. */
len -= IEEE80211_CRC_LEN;
hwrate = MASK_AND_RSHIFT(hstat, RTW_RXSTAT_RATE_MASK);
if (hwrate >= sizeof(ratetbl) / sizeof(ratetbl[0])) {
printf("%s: unknown rate #%d\n", sc->sc_dev.dv_xname,
MASK_AND_RSHIFT(hstat, RTW_RXSTAT_RATE_MASK));
ifp->if_ierrors++;
goto next;
}
rate = ratetbl[hwrate];
#ifdef RTW_DEBUG
RTW_DPRINTF(RTW_DEBUG_RECV_DESC,
("rate %d.%d Mb/s, time %08x%08x\n", (rate * 5) / 10,
(rate * 5) % 10, htsfth, htsftl));
#endif /* RTW_DEBUG */
if ((hstat & RTW_RXSTAT_RES) != 0 &&
sc->sc_ic.ic_opmode != IEEE80211_M_MONITOR)
goto next;
/* if bad flags, skip descriptor */
if ((hstat & RTW_RXSTAT_ONESEG) != RTW_RXSTAT_ONESEG) {
printf("%s: too many rx segments\n",
sc->sc_dev.dv_xname);
goto next;
}
bus_dmamap_sync(sc->sc_dmat, rs->rs_dmamap, 0,
rs->rs_dmamap->dm_mapsize, BUS_DMASYNC_POSTREAD);
m = rs->rs_mbuf;
/* if temporarily out of memory, re-use mbuf */
switch (rtw_rxsoft_alloc(sc->sc_dmat, rs)) {
case 0:
break;
case ENOBUFS:
printf("%s: rtw_rxsoft_alloc(, %d) failed, "
"dropping packet\n", sc->sc_dev.dv_xname, next);
goto next;
default:
/* XXX shorten rx ring, instead? */
panic("%s: could not load DMA map\n",
sc->sc_dev.dv_xname);
}
if (sc->sc_rfchipid == RTW_RFCHIPID_PHILIPS)
rssi = MASK_AND_RSHIFT(hrssi, RTW_RXRSSI_RSSI);
else {
rssi = MASK_AND_RSHIFT(hrssi, RTW_RXRSSI_IMR_RSSI);
/* TBD find out each front-end's LNA gain in the
* front-end's units
*/
if ((hrssi & RTW_RXRSSI_IMR_LNA) == 0)
rssi |= 0x80;
}
sq = MASK_AND_RSHIFT(hrssi, RTW_RXRSSI_SQ);
/* Note well: now we cannot recycle the rs_mbuf unless
* we restore its original length.
*/
m->m_pkthdr.rcvif = ifp;
m->m_pkthdr.len = m->m_len = len;
wh = mtod(m, struct ieee80211_frame_min *);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
if (!IS_BEACON(wh->i_fc[0]))
sc->sc_led_state.ls_event |= RTW_LED_S_RX;
/* TBD use _MAR, _BAR, _PAR flags as hints to _find_rxnode? */
ni = ieee80211_find_rxnode(&sc->sc_ic, wh);
sc->sc_tsfth = htsfth;
#ifdef RTW_DEBUG
if ((ifp->if_flags & (IFF_DEBUG|IFF_LINK2)) ==
(IFF_DEBUG|IFF_LINK2)) {
ieee80211_dump_pkt(mtod(m, uint8_t *), m->m_pkthdr.len,
rate, rssi);
}
#endif /* RTW_DEBUG */
#if NBPFILTER > 0
if (sc->sc_radiobpf != NULL) {
struct ieee80211com *ic = &sc->sc_ic;
struct rtw_rx_radiotap_header *rr = &sc->sc_rxtap;
rr->rr_tsft =
htole64(((uint64_t)htsfth << 32) | htsftl);
if ((hstat & RTW_RXSTAT_SPLCP) != 0)
rr->rr_flags = IEEE80211_RADIOTAP_F_SHORTPRE;
rr->rr_flags = 0;
rr->rr_rate = rate;
rr->rr_chan_freq = htole16(ic->ic_curchan->ic_freq);
rr->rr_chan_flags = htole16(ic->ic_curchan->ic_flags);
rr->rr_antsignal = rssi;
rr->rr_barker_lock = htole16(sq);
bpf_mtap2(sc->sc_radiobpf, (caddr_t)rr,
sizeof(sc->sc_rxtapu), m);
}
#endif /* NPBFILTER > 0 */
ieee80211_input(&sc->sc_ic, m, ni, rssi, htsftl);
ieee80211_free_node(ni);
next:
rtw_rxdesc_init(rdb, rs, next, 0);
}
rdb->rdb_next = next;
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
KASSERT(rdb->rdb_next < rdb->rdb_ndesc);
return;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
#undef IS_BEACON
}
static void
rtw_txsoft_release(bus_dma_tag_t dmat, struct ieee80211com *ic,
struct rtw_txsoft *ts)
{
struct mbuf *m;
struct ieee80211_node *ni;
m = ts->ts_mbuf;
ni = ts->ts_ni;
KASSERT(m != NULL);
KASSERT(ni != NULL);
ts->ts_mbuf = NULL;
ts->ts_ni = NULL;
bus_dmamap_sync(dmat, ts->ts_dmamap, 0, ts->ts_dmamap->dm_mapsize,
BUS_DMASYNC_POSTWRITE);
bus_dmamap_unload(dmat, ts->ts_dmamap);
m_freem(m);
ieee80211_free_node(ni);
}
static void
rtw_txsofts_release(bus_dma_tag_t dmat, struct ieee80211com *ic,
struct rtw_txsoft_blk *tsb)
{
struct rtw_txsoft *ts;
while ((ts = SIMPLEQ_FIRST(&tsb->tsb_dirtyq)) != NULL) {
rtw_txsoft_release(dmat, ic, ts);
SIMPLEQ_REMOVE_HEAD(&tsb->tsb_dirtyq, ts_q);
SIMPLEQ_INSERT_TAIL(&tsb->tsb_freeq, ts, ts_q);
}
tsb->tsb_tx_timer = 0;
}
static __inline void
rtw_collect_txpkt(struct rtw_softc *sc, struct rtw_txdesc_blk *tdb,
struct rtw_txsoft *ts, int ndesc)
{
uint32_t hstat;
int data_retry, rts_retry;
struct rtw_txdesc *tdn;
const char *condstring;
struct ifnet *ifp = &sc->sc_if;
rtw_txsoft_release(sc->sc_dmat, &sc->sc_ic, ts);
tdb->tdb_nfree += ndesc;
tdn = &tdb->tdb_desc[ts->ts_last];
hstat = le32toh(tdn->td_stat);
rts_retry = MASK_AND_RSHIFT(hstat, RTW_TXSTAT_RTSRETRY_MASK);
data_retry = MASK_AND_RSHIFT(hstat, RTW_TXSTAT_DRC_MASK);
ifp->if_collisions += rts_retry + data_retry;
if ((hstat & RTW_TXSTAT_TOK) != 0)
condstring = "ok";
else {
ifp->if_oerrors++;
condstring = "error";
}
DPRINTF(sc, RTW_DEBUG_XMIT_DESC,
("%s: ts %p txdesc[%d, %d] %s tries rts %u data %u\n",
sc->sc_dev.dv_xname, ts, ts->ts_first, ts->ts_last,
condstring, rts_retry, data_retry));
}
static void
rtw_reset_oactive(struct rtw_softc *sc)
{
short oflags;
int pri;
struct rtw_txsoft_blk *tsb;
struct rtw_txdesc_blk *tdb;
oflags = sc->sc_if.if_flags;
for (pri = 0; pri < RTW_NTXPRI; pri++) {
tsb = &sc->sc_txsoft_blk[pri];
tdb = &sc->sc_txdesc_blk[pri];
if (!SIMPLEQ_EMPTY(&tsb->tsb_freeq) && tdb->tdb_nfree > 0)
sc->sc_if.if_flags &= ~IFF_OACTIVE;
}
if (oflags != sc->sc_if.if_flags) {
DPRINTF(sc, RTW_DEBUG_OACTIVE,
("%s: reset OACTIVE\n", __func__));
}
}
/* Collect transmitted packets. */
static __inline void
rtw_collect_txring(struct rtw_softc *sc, struct rtw_txsoft_blk *tsb,
struct rtw_txdesc_blk *tdb, int force)
{
int ndesc;
struct rtw_txsoft *ts;
while ((ts = SIMPLEQ_FIRST(&tsb->tsb_dirtyq)) != NULL) {
ndesc = 1 + ts->ts_last - ts->ts_first;
if (ts->ts_last < ts->ts_first)
ndesc += tdb->tdb_ndesc;
KASSERT(ndesc > 0);
rtw_txdescs_sync(tdb, ts->ts_first, ndesc,
BUS_DMASYNC_POSTREAD|BUS_DMASYNC_POSTWRITE);
if (force) {
int i;
for (i = ts->ts_first; ; i = RTW_NEXT_IDX(tdb, i)) {
tdb->tdb_desc[i].td_stat &=
~htole32(RTW_TXSTAT_OWN);
if (i == ts->ts_last)
break;
}
rtw_txdescs_sync(tdb, ts->ts_first, ndesc,
BUS_DMASYNC_PREREAD|BUS_DMASYNC_PREWRITE);
} else if ((tdb->tdb_desc[ts->ts_last].td_stat &
2005-02-27 03:26:58 +03:00
htole32(RTW_TXSTAT_OWN)) != 0)
break;
rtw_collect_txpkt(sc, tdb, ts, ndesc);
SIMPLEQ_REMOVE_HEAD(&tsb->tsb_dirtyq, ts_q);
SIMPLEQ_INSERT_TAIL(&tsb->tsb_freeq, ts, ts_q);
}
/* no more pending transmissions, cancel watchdog */
if (ts == NULL)
tsb->tsb_tx_timer = 0;
rtw_reset_oactive(sc);
}
static void
rtw_intr_tx(struct rtw_softc *sc, uint16_t isr)
{
int pri;
struct rtw_txsoft_blk *tsb;
struct rtw_txdesc_blk *tdb;
struct ifnet *ifp = &sc->sc_if;
for (pri = 0; pri < RTW_NTXPRI; pri++) {
tsb = &sc->sc_txsoft_blk[pri];
tdb = &sc->sc_txdesc_blk[pri];
rtw_collect_txring(sc, tsb, tdb, 0);
}
if ((isr & RTW_INTR_TX) != 0)
rtw_start(ifp);
return;
}
static void
rtw_intr_beacon(struct rtw_softc *sc, uint16_t isr)
{
u_int next;
uint32_t tsfth, tsftl;
struct ieee80211com *ic;
struct rtw_txdesc_blk *tdb = &sc->sc_txdesc_blk[RTW_TXPRIBCN];
struct rtw_txsoft_blk *tsb = &sc->sc_txsoft_blk[RTW_TXPRIBCN];
struct mbuf *m;
tsfth = RTW_READ(&sc->sc_regs, RTW_TSFTRH);
tsftl = RTW_READ(&sc->sc_regs, RTW_TSFTRL);
if ((isr & (RTW_INTR_TBDOK|RTW_INTR_TBDER)) != 0) {
next = rtw_txring_next(&sc->sc_regs, tdb);
RTW_DPRINTF(RTW_DEBUG_BEACON,
("%s: beacon ring %sprocessed, isr = %#04" PRIx16
", next %u expected %u, %" PRIu64 "\n", __func__,
(next == tdb->tdb_next) ? "" : "un", isr, next,
tdb->tdb_next, (uint64_t)tsfth << 32 | tsftl));
if ((RTW_READ8(&sc->sc_regs, RTW_TPPOLL) & RTW_TPPOLL_BQ) == 0){
rtw_collect_txring(sc, tsb, tdb, 1);
tdb->tdb_next = 0;
}
}
/* Start beacon transmission. */
if ((isr & RTW_INTR_BCNINT) != 0 &&
sc->sc_ic.ic_state == IEEE80211_S_RUN &&
SIMPLEQ_EMPTY(&tsb->tsb_dirtyq)) {
RTW_DPRINTF(RTW_DEBUG_BEACON,
("%s: beacon prep. time, isr = %#04" PRIx16
", %16" PRIu64 "\n", __func__, isr,
(uint64_t)tsfth << 32 | tsftl));
ic = &sc->sc_ic;
m = rtw_beacon_alloc(sc, ic->ic_bss);
if (m == NULL) {
printf("%s: could not allocate beacon\n",
sc->sc_dev.dv_xname);
return;
}
m->m_pkthdr.rcvif = (void *)ieee80211_ref_node(ic->ic_bss);
IF_ENQUEUE(&sc->sc_beaconq, m);
rtw_start(&sc->sc_if);
}
}
static void
rtw_intr_atim(struct rtw_softc *sc)
{
/* TBD */
return;
}
#ifdef RTW_DEBUG
static void
rtw_dump_rings(struct rtw_softc *sc)
{
struct rtw_txdesc_blk *tdb;
struct rtw_rxdesc *rd;
struct rtw_rxdesc_blk *rdb;
int desc, pri;
if ((rtw_debug & RTW_DEBUG_IO_KICK) == 0)
return;
for (pri = 0; pri < RTW_NTXPRI; pri++) {
tdb = &sc->sc_txdesc_blk[pri];
printf("%s: txpri %d ndesc %d nfree %d\n", __func__, pri,
tdb->tdb_ndesc, tdb->tdb_nfree);
for (desc = 0; desc < tdb->tdb_ndesc; desc++)
rtw_print_txdesc(sc, ".", NULL, tdb, desc);
}
rdb = &sc->sc_rxdesc_blk;
for (desc = 0; desc < RTW_RXQLEN; desc++) {
rd = &rdb->rdb_desc[desc];
printf("%s: %sctl %08x rsvd0/rssi %08x buf/tsftl %08x "
"rsvd1/tsfth %08x\n", __func__,
(desc >= rdb->rdb_ndesc) ? "UNUSED " : "",
le32toh(rd->rd_ctl), le32toh(rd->rd_rssi),
le32toh(rd->rd_buf), le32toh(rd->rd_tsfth));
}
}
#endif /* RTW_DEBUG */
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
static void
rtw_hwring_setup(struct rtw_softc *sc)
{
int pri;
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
struct rtw_regs *regs = &sc->sc_regs;
struct rtw_txdesc_blk *tdb;
sc->sc_txdesc_blk[RTW_TXPRILO].tdb_basereg = RTW_TLPDA;
sc->sc_txdesc_blk[RTW_TXPRILO].tdb_base = RTW_RING_BASE(sc, hd_txlo);
sc->sc_txdesc_blk[RTW_TXPRIMD].tdb_basereg = RTW_TNPDA;
sc->sc_txdesc_blk[RTW_TXPRIMD].tdb_base = RTW_RING_BASE(sc, hd_txmd);
sc->sc_txdesc_blk[RTW_TXPRIHI].tdb_basereg = RTW_THPDA;
sc->sc_txdesc_blk[RTW_TXPRIHI].tdb_base = RTW_RING_BASE(sc, hd_txhi);
sc->sc_txdesc_blk[RTW_TXPRIBCN].tdb_basereg = RTW_TBDA;
sc->sc_txdesc_blk[RTW_TXPRIBCN].tdb_base = RTW_RING_BASE(sc, hd_bcn);
for (pri = 0; pri < RTW_NTXPRI; pri++) {
tdb = &sc->sc_txdesc_blk[pri];
RTW_WRITE(regs, tdb->tdb_basereg, tdb->tdb_base);
RTW_DPRINTF(RTW_DEBUG_XMIT_DESC,
("%s: reg[tdb->tdb_basereg] <- %" PRIxPTR "\n", __func__,
(uintptr_t)tdb->tdb_base));
}
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
RTW_WRITE(regs, RTW_RDSAR, RTW_RING_BASE(sc, hd_rx));
RTW_DPRINTF(RTW_DEBUG_RECV_DESC,
("%s: reg[RDSAR] <- %" PRIxPTR "\n", __func__,
(uintptr_t)RTW_RING_BASE(sc, hd_rx)));
RTW_SYNC(regs, RTW_TLPDA, RTW_RDSAR);
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
}
static int
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
rtw_swring_setup(struct rtw_softc *sc)
{
int rc;
struct rtw_rxdesc_blk *rdb;
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
rtw_txdesc_blk_init_all(&sc->sc_txdesc_blk[0]);
rtw_txsoft_blk_init_all(&sc->sc_txsoft_blk[0]);
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
rdb = &sc->sc_rxdesc_blk;
if ((rc = rtw_rxsoft_init_all(sc->sc_dmat, sc->sc_rxsoft, &rdb->rdb_ndesc,
sc->sc_dev.dv_xname)) != 0 && rdb->rdb_ndesc == 0) {
printf("%s: could not allocate rx buffers\n",
sc->sc_dev.dv_xname);
return rc;
}
2005-02-27 03:26:58 +03:00
rdb = &sc->sc_rxdesc_blk;
rtw_rxdescs_sync(rdb, 0, rdb->rdb_ndesc,
BUS_DMASYNC_POSTREAD|BUS_DMASYNC_POSTWRITE);
rtw_rxdesc_init_all(rdb, sc->sc_rxsoft, 1);
rdb->rdb_next = 0;
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
rtw_txdescs_sync_all(&sc->sc_txdesc_blk[0]);
return 0;
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
}
static void
rtw_txdesc_blk_init(struct rtw_txdesc_blk *tdb)
{
int i;
(void)memset(tdb->tdb_desc, 0,
sizeof(tdb->tdb_desc[0]) * tdb->tdb_ndesc);
for (i = 0; i < tdb->tdb_ndesc; i++)
tdb->tdb_desc[i].td_next = htole32(RTW_NEXT_DESC(tdb, i));
}
static u_int
rtw_txring_next(struct rtw_regs *regs, struct rtw_txdesc_blk *tdb)
{
return (le32toh(RTW_READ(regs, tdb->tdb_basereg)) - tdb->tdb_base) /
sizeof(struct rtw_txdesc);
}
static void
rtw_txring_fixup(struct rtw_softc *sc)
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
{
int pri;
u_int next;
struct rtw_txdesc_blk *tdb;
struct rtw_regs *regs = &sc->sc_regs;
for (pri = 0; pri < RTW_NTXPRI; pri++) {
tdb = &sc->sc_txdesc_blk[pri];
next = rtw_txring_next(regs, tdb);
if (tdb->tdb_next == next)
continue;
printf("%s: tx-ring %d expected next %u, read %u\n", __func__,
pri, tdb->tdb_next, next);
tdb->tdb_next = next;
}
}
static void
rtw_rxring_fixup(struct rtw_softc *sc)
{
u_int next;
uint32_t rdsar;
struct rtw_rxdesc_blk *rdb;
rdsar = le32toh(RTW_READ(&sc->sc_regs, RTW_RDSAR));
next = (rdsar - RTW_RING_BASE(sc, hd_rx)) / sizeof(struct rtw_rxdesc);
rdb = &sc->sc_rxdesc_blk;
if (rdb->rdb_next != next) {
printf("%s: rx-ring expected next %u, read %u\n", __func__,
rdb->rdb_next, next);
rdb->rdb_next = next;
}
}
static void
rtw_txdescs_reset(struct rtw_softc *sc)
{
int pri;
for (pri = 0; pri < RTW_NTXPRI; pri++) {
rtw_collect_txring(sc, &sc->sc_txsoft_blk[pri],
&sc->sc_txdesc_blk[pri], 1);
}
}
static void
rtw_intr_ioerror(struct rtw_softc *sc, uint16_t isr)
{
uint8_t cr = 0;
int xmtr = 0, rcvr = 0;
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
struct rtw_regs *regs = &sc->sc_regs;
if ((isr & RTW_INTR_TXFOVW) != 0) {
printf("%s: tx fifo underflow\n", sc->sc_dev.dv_xname);
rcvr = xmtr = 1;
cr |= RTW_CR_TE | RTW_CR_RE;
}
if ((isr & (RTW_INTR_RDU|RTW_INTR_RXFOVW)) != 0) {
cr |= RTW_CR_RE;
rcvr = 1;
}
RTW_DPRINTF(RTW_DEBUG_BUGS, ("%s: restarting xmit/recv, isr %" PRIx16
"\n", sc->sc_dev.dv_xname, isr));
#ifdef RTW_DEBUG
rtw_dump_rings(sc);
#endif /* RTW_DEBUG */
rtw_io_enable(regs, cr, 0);
2005-02-27 03:26:58 +03:00
/* Collect rx'd packets. Refresh rx buffers. */
if (rcvr)
rtw_intr_rx(sc, 0);
/* Collect tx'd packets. XXX let's hope this stops the transmit
* timeouts.
*/
if (xmtr)
rtw_txdescs_reset(sc);
RTW_WRITE16(regs, RTW_IMR, 0);
RTW_SYNC(regs, RTW_IMR, RTW_IMR);
if (rtw_do_chip_reset) {
rtw_chip_reset1(regs, sc->sc_dev.dv_xname);
rtw_wep_setkeys(sc, sc->sc_ic.ic_nw_keys,
sc->sc_ic.ic_def_txkey);
}
rtw_rxdesc_init_all(&sc->sc_rxdesc_blk, &sc->sc_rxsoft[0], 1);
#ifdef RTW_DEBUG
rtw_dump_rings(sc);
#endif /* RTW_DEBUG */
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
RTW_WRITE16(regs, RTW_IMR, sc->sc_inten);
RTW_SYNC(regs, RTW_IMR, RTW_IMR);
if (rcvr)
rtw_rxring_fixup(sc);
rtw_io_enable(regs, cr, 1);
if (xmtr)
rtw_txring_fixup(sc);
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
}
static __inline void
rtw_suspend_ticks(struct rtw_softc *sc)
{
RTW_DPRINTF(RTW_DEBUG_TIMEOUT,
("%s: suspending ticks\n", sc->sc_dev.dv_xname));
sc->sc_do_tick = 0;
}
static __inline void
rtw_resume_ticks(struct rtw_softc *sc)
{
uint32_t tsftrl0, tsftrl1, next_tick;
tsftrl0 = RTW_READ(&sc->sc_regs, RTW_TSFTRL);
tsftrl1 = RTW_READ(&sc->sc_regs, RTW_TSFTRL);
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
next_tick = tsftrl1 + 1000000;
RTW_WRITE(&sc->sc_regs, RTW_TINT, next_tick);
sc->sc_do_tick = 1;
RTW_DPRINTF(RTW_DEBUG_TIMEOUT,
("%s: resume ticks delta %#08x now %#08x next %#08x\n",
sc->sc_dev.dv_xname, tsftrl1 - tsftrl0, tsftrl1, next_tick));
}
static void
rtw_intr_timeout(struct rtw_softc *sc)
{
RTW_DPRINTF(RTW_DEBUG_TIMEOUT, ("%s: timeout\n", sc->sc_dev.dv_xname));
if (sc->sc_do_tick)
rtw_resume_ticks(sc);
return;
}
int
rtw_intr(void *arg)
{
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
int i;
struct rtw_softc *sc = arg;
struct rtw_regs *regs = &sc->sc_regs;
uint16_t isr;
struct ifnet *ifp = &sc->sc_if;
/*
* If the interface isn't running, the interrupt couldn't
* possibly have come from us.
*/
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
if ((sc->sc_flags & RTW_F_ENABLED) == 0 ||
(ifp->if_flags & IFF_RUNNING) == 0 ||
(sc->sc_dev.dv_flags & DVF_ACTIVE) == 0) {
RTW_DPRINTF(RTW_DEBUG_INTR, ("%s: stray interrupt\n", sc->sc_dev.dv_xname));
return (0);
}
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
for (i = 0; i < 10; i++) {
isr = RTW_READ16(regs, RTW_ISR);
RTW_WRITE16(regs, RTW_ISR, isr);
RTW_WBR(regs, RTW_ISR, RTW_ISR);
if (sc->sc_intr_ack != NULL)
(*sc->sc_intr_ack)(regs);
if (isr == 0)
break;
#ifdef RTW_DEBUG
#define PRINTINTR(flag) do { \
if ((isr & flag) != 0) { \
printf("%s" #flag, delim); \
delim = ","; \
} \
} while (0)
if ((rtw_debug & RTW_DEBUG_INTR) != 0 && isr != 0) {
const char *delim = "<";
printf("%s: reg[ISR] = %x", sc->sc_dev.dv_xname, isr);
PRINTINTR(RTW_INTR_TXFOVW);
PRINTINTR(RTW_INTR_TIMEOUT);
PRINTINTR(RTW_INTR_BCNINT);
PRINTINTR(RTW_INTR_ATIMINT);
PRINTINTR(RTW_INTR_TBDER);
PRINTINTR(RTW_INTR_TBDOK);
PRINTINTR(RTW_INTR_THPDER);
PRINTINTR(RTW_INTR_THPDOK);
PRINTINTR(RTW_INTR_TNPDER);
PRINTINTR(RTW_INTR_TNPDOK);
PRINTINTR(RTW_INTR_RXFOVW);
PRINTINTR(RTW_INTR_RDU);
PRINTINTR(RTW_INTR_TLPDER);
PRINTINTR(RTW_INTR_TLPDOK);
PRINTINTR(RTW_INTR_RER);
PRINTINTR(RTW_INTR_ROK);
printf(">\n");
}
#undef PRINTINTR
#endif /* RTW_DEBUG */
if ((isr & RTW_INTR_RX) != 0)
rtw_intr_rx(sc, isr & RTW_INTR_RX);
if ((isr & RTW_INTR_TX) != 0)
rtw_intr_tx(sc, isr & RTW_INTR_TX);
if ((isr & RTW_INTR_BEACON) != 0)
rtw_intr_beacon(sc, isr & RTW_INTR_BEACON);
if ((isr & RTW_INTR_ATIMINT) != 0)
rtw_intr_atim(sc);
if ((isr & RTW_INTR_IOERROR) != 0)
rtw_intr_ioerror(sc, isr & RTW_INTR_IOERROR);
if ((isr & RTW_INTR_TIMEOUT) != 0)
rtw_intr_timeout(sc);
}
return 1;
}
/* Must be called at splnet. */
static void
rtw_stop(struct ifnet *ifp, int disable)
{
int pri;
struct rtw_softc *sc = (struct rtw_softc *)ifp->if_softc;
struct ieee80211com *ic = &sc->sc_ic;
struct rtw_regs *regs = &sc->sc_regs;
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
if ((sc->sc_flags & RTW_F_ENABLED) == 0)
return;
rtw_suspend_ticks(sc);
ieee80211_new_state(ic, IEEE80211_S_INIT, -1);
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
if ((sc->sc_flags & RTW_F_INVALID) == 0) {
/* Disable interrupts. */
RTW_WRITE16(regs, RTW_IMR, 0);
RTW_WBW(regs, RTW_TPPOLL, RTW_IMR);
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
/* Stop the transmit and receive processes. First stop DMA,
* then disable receiver and transmitter.
*/
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
RTW_WRITE8(regs, RTW_TPPOLL, RTW_TPPOLL_SALL);
RTW_SYNC(regs, RTW_TPPOLL, RTW_IMR);
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
rtw_io_enable(&sc->sc_regs, RTW_CR_RE|RTW_CR_TE, 0);
}
for (pri = 0; pri < RTW_NTXPRI; pri++) {
rtw_txsofts_release(sc->sc_dmat, &sc->sc_ic,
&sc->sc_txsoft_blk[pri]);
}
rtw_rxbufs_release(sc->sc_dmat, &sc->sc_rxsoft[0]);
if (disable)
rtw_disable(sc);
/* Mark the interface as not running. Cancel the watchdog timer. */
ifp->if_flags &= ~(IFF_RUNNING | IFF_OACTIVE);
ifp->if_timer = 0;
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
return;
}
const char *
rtw_pwrstate_string(enum rtw_pwrstate power)
{
switch (power) {
case RTW_ON:
return "on";
case RTW_SLEEP:
return "sleep";
case RTW_OFF:
return "off";
default:
return "unknown";
}
}
/* XXX For Maxim, I am using the RFMD settings gleaned from the
* reference driver, plus a magic Maxim "ON" value that comes from
* the Realtek document "Windows PG for Rtl8180."
*/
static void
rtw_maxim_pwrstate(struct rtw_regs *regs, enum rtw_pwrstate power,
int before_rf, int digphy)
{
uint32_t anaparm;
anaparm = RTW_READ(regs, RTW_ANAPARM);
anaparm &= ~(RTW_ANAPARM_RFPOW_MASK | RTW_ANAPARM_TXDACOFF);
switch (power) {
case RTW_OFF:
if (before_rf)
return;
anaparm |= RTW_ANAPARM_RFPOW_MAXIM_OFF;
anaparm |= RTW_ANAPARM_TXDACOFF;
break;
case RTW_SLEEP:
if (!before_rf)
return;
anaparm |= RTW_ANAPARM_RFPOW_MAXIM_SLEEP;
anaparm |= RTW_ANAPARM_TXDACOFF;
break;
case RTW_ON:
if (!before_rf)
return;
anaparm |= RTW_ANAPARM_RFPOW_MAXIM_ON;
break;
}
RTW_DPRINTF(RTW_DEBUG_PWR,
("%s: power state %s, %s RF, reg[ANAPARM] <- %08x\n",
__func__, rtw_pwrstate_string(power),
(before_rf) ? "before" : "after", anaparm));
RTW_WRITE(regs, RTW_ANAPARM, anaparm);
RTW_SYNC(regs, RTW_ANAPARM, RTW_ANAPARM);
}
/* XXX I am using the RFMD settings gleaned from the reference
2005-02-27 03:26:58 +03:00
* driver. They agree
*/
static void
rtw_rfmd_pwrstate(struct rtw_regs *regs, enum rtw_pwrstate power,
int before_rf, int digphy)
{
uint32_t anaparm;
anaparm = RTW_READ(regs, RTW_ANAPARM);
anaparm &= ~(RTW_ANAPARM_RFPOW_MASK | RTW_ANAPARM_TXDACOFF);
switch (power) {
case RTW_OFF:
if (before_rf)
return;
anaparm |= RTW_ANAPARM_RFPOW_RFMD_OFF;
anaparm |= RTW_ANAPARM_TXDACOFF;
break;
case RTW_SLEEP:
if (!before_rf)
return;
anaparm |= RTW_ANAPARM_RFPOW_RFMD_SLEEP;
anaparm |= RTW_ANAPARM_TXDACOFF;
break;
case RTW_ON:
if (!before_rf)
return;
anaparm |= RTW_ANAPARM_RFPOW_RFMD_ON;
break;
}
RTW_DPRINTF(RTW_DEBUG_PWR,
("%s: power state %s, %s RF, reg[ANAPARM] <- %08x\n",
__func__, rtw_pwrstate_string(power),
(before_rf) ? "before" : "after", anaparm));
RTW_WRITE(regs, RTW_ANAPARM, anaparm);
RTW_SYNC(regs, RTW_ANAPARM, RTW_ANAPARM);
}
static void
rtw_philips_pwrstate(struct rtw_regs *regs, enum rtw_pwrstate power,
int before_rf, int digphy)
{
uint32_t anaparm;
anaparm = RTW_READ(regs, RTW_ANAPARM);
anaparm &= ~(RTW_ANAPARM_RFPOW_MASK | RTW_ANAPARM_TXDACOFF);
switch (power) {
case RTW_OFF:
if (before_rf)
return;
anaparm |= RTW_ANAPARM_RFPOW_PHILIPS_OFF;
anaparm |= RTW_ANAPARM_TXDACOFF;
break;
case RTW_SLEEP:
if (!before_rf)
return;
anaparm |= RTW_ANAPARM_RFPOW_PHILIPS_SLEEP;
anaparm |= RTW_ANAPARM_TXDACOFF;
break;
case RTW_ON:
if (!before_rf)
return;
if (digphy) {
anaparm |= RTW_ANAPARM_RFPOW_DIG_PHILIPS_ON;
/* XXX guess */
anaparm |= RTW_ANAPARM_TXDACOFF;
} else
anaparm |= RTW_ANAPARM_RFPOW_ANA_PHILIPS_ON;
break;
}
RTW_DPRINTF(RTW_DEBUG_PWR,
("%s: power state %s, %s RF, reg[ANAPARM] <- %08x\n",
__func__, rtw_pwrstate_string(power),
(before_rf) ? "before" : "after", anaparm));
RTW_WRITE(regs, RTW_ANAPARM, anaparm);
RTW_SYNC(regs, RTW_ANAPARM, RTW_ANAPARM);
}
static void
rtw_pwrstate0(struct rtw_softc *sc, enum rtw_pwrstate power, int before_rf,
int digphy)
{
struct rtw_regs *regs = &sc->sc_regs;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_set_access(regs, RTW_ACCESS_ANAPARM);
(*sc->sc_pwrstate_cb)(regs, power, before_rf, digphy);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_set_access(regs, RTW_ACCESS_NONE);
return;
}
static int
rtw_pwrstate(struct rtw_softc *sc, enum rtw_pwrstate power)
{
int rc;
RTW_DPRINTF(RTW_DEBUG_PWR,
("%s: %s->%s\n", __func__,
rtw_pwrstate_string(sc->sc_pwrstate), rtw_pwrstate_string(power)));
if (sc->sc_pwrstate == power)
return 0;
rtw_pwrstate0(sc, power, 1, sc->sc_flags & RTW_F_DIGPHY);
rc = rtw_rf_pwrstate(sc->sc_rf, power);
rtw_pwrstate0(sc, power, 0, sc->sc_flags & RTW_F_DIGPHY);
switch (power) {
case RTW_ON:
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
/* TBD set LEDs */
break;
case RTW_SLEEP:
/* TBD */
break;
case RTW_OFF:
/* TBD */
break;
}
if (rc == 0)
sc->sc_pwrstate = power;
else
sc->sc_pwrstate = RTW_OFF;
return rc;
}
static int
rtw_tune(struct rtw_softc *sc)
{
struct ieee80211com *ic = &sc->sc_ic;
u_int chan;
int rc;
int antdiv = sc->sc_flags & RTW_F_ANTDIV,
dflantb = sc->sc_flags & RTW_F_DFLANTB;
chan = ieee80211_chan2ieee(ic, ic->ic_curchan);
if (chan == IEEE80211_CHAN_ANY)
panic("%s: chan == IEEE80211_CHAN_ANY\n", __func__);
if (chan == sc->sc_cur_chan) {
RTW_DPRINTF(RTW_DEBUG_TUNE,
2005-02-27 03:26:58 +03:00
("%s: already tuned chan #%d\n", __func__, chan));
return 0;
}
rtw_suspend_ticks(sc);
rtw_io_enable(&sc->sc_regs, RTW_CR_RE | RTW_CR_TE, 0);
/* TBD wait for Tx to complete */
KASSERT((sc->sc_flags & RTW_F_ENABLED) != 0);
if ((rc = rtw_phy_init(&sc->sc_regs, sc->sc_rf,
rtw_chan2txpower(&sc->sc_srom, ic, ic->ic_curchan), sc->sc_csthr,
ic->ic_curchan->ic_freq, antdiv, dflantb, RTW_ON)) != 0) {
/* XXX condition on powersaving */
printf("%s: phy init failed\n", sc->sc_dev.dv_xname);
}
sc->sc_cur_chan = chan;
rtw_io_enable(&sc->sc_regs, RTW_CR_RE | RTW_CR_TE, 1);
rtw_resume_ticks(sc);
return rc;
}
void
rtw_disable(struct rtw_softc *sc)
{
int rc;
if ((sc->sc_flags & RTW_F_ENABLED) == 0)
return;
/* turn off PHY */
if ((sc->sc_flags & RTW_F_INVALID) == 0 &&
(rc = rtw_pwrstate(sc, RTW_OFF)) != 0) {
printf("%s: failed to turn off PHY (%d)\n",
sc->sc_dev.dv_xname, rc);
}
if (sc->sc_disable != NULL)
(*sc->sc_disable)(sc);
sc->sc_flags &= ~RTW_F_ENABLED;
}
int
rtw_enable(struct rtw_softc *sc)
{
if ((sc->sc_flags & RTW_F_ENABLED) == 0) {
if (sc->sc_enable != NULL && (*sc->sc_enable)(sc) != 0) {
printf("%s: device enable failed\n",
sc->sc_dev.dv_xname);
return (EIO);
}
sc->sc_flags |= RTW_F_ENABLED;
}
return (0);
}
static void
rtw_transmit_config(struct rtw_regs *regs)
{
uint32_t tcr;
tcr = RTW_READ(regs, RTW_TCR);
tcr |= RTW_TCR_CWMIN;
tcr &= ~RTW_TCR_MXDMA_MASK;
tcr |= RTW_TCR_MXDMA_256;
tcr |= RTW_TCR_SAT; /* send ACK as fast as possible */
tcr &= ~RTW_TCR_LBK_MASK;
tcr |= RTW_TCR_LBK_NORMAL; /* normal operating mode */
/* set short/long retry limits */
tcr &= ~(RTW_TCR_SRL_MASK|RTW_TCR_LRL_MASK);
tcr |= LSHIFT(4, RTW_TCR_SRL_MASK) | LSHIFT(4, RTW_TCR_LRL_MASK);
tcr &= ~RTW_TCR_CRC; /* NIC appends CRC32 */
RTW_WRITE(regs, RTW_TCR, tcr);
RTW_SYNC(regs, RTW_TCR, RTW_TCR);
}
static __inline void
rtw_enable_interrupts(struct rtw_softc *sc)
{
struct rtw_regs *regs = &sc->sc_regs;
sc->sc_inten = RTW_INTR_RX|RTW_INTR_TX|RTW_INTR_BEACON|RTW_INTR_ATIMINT;
sc->sc_inten |= RTW_INTR_IOERROR|RTW_INTR_TIMEOUT;
RTW_WRITE16(regs, RTW_IMR, sc->sc_inten);
RTW_WBW(regs, RTW_IMR, RTW_ISR);
RTW_WRITE16(regs, RTW_ISR, 0xffff);
RTW_SYNC(regs, RTW_IMR, RTW_ISR);
/* XXX necessary? */
if (sc->sc_intr_ack != NULL)
(*sc->sc_intr_ack)(regs);
}
static void
rtw_set_nettype(struct rtw_softc *sc, enum ieee80211_opmode opmode)
{
uint8_t msr;
/* I'm guessing that MSR is protected as CONFIG[0123] are. */
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_set_access(&sc->sc_regs, RTW_ACCESS_CONFIG);
msr = RTW_READ8(&sc->sc_regs, RTW_MSR) & ~RTW_MSR_NETYPE_MASK;
switch (opmode) {
case IEEE80211_M_AHDEMO:
case IEEE80211_M_IBSS:
msr |= RTW_MSR_NETYPE_ADHOC_OK;
break;
case IEEE80211_M_HOSTAP:
msr |= RTW_MSR_NETYPE_AP_OK;
break;
case IEEE80211_M_MONITOR:
/* XXX */
msr |= RTW_MSR_NETYPE_NOLINK;
break;
case IEEE80211_M_STA:
msr |= RTW_MSR_NETYPE_INFRA_OK;
break;
}
RTW_WRITE8(&sc->sc_regs, RTW_MSR, msr);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_set_access(&sc->sc_regs, RTW_ACCESS_NONE);
}
#define rtw_calchash(addr) \
(ether_crc32_be((addr), IEEE80211_ADDR_LEN) >> 26)
static void
rtw_pktfilt_load(struct rtw_softc *sc)
{
struct rtw_regs *regs = &sc->sc_regs;
struct ieee80211com *ic = &sc->sc_ic;
struct ethercom *ec = &sc->sc_ec;
struct ifnet *ifp = &sc->sc_if;
int hash;
uint32_t hashes[2] = { 0, 0 };
struct ether_multi *enm;
struct ether_multistep step;
/* XXX might be necessary to stop Rx/Tx engines while setting filters */
sc->sc_rcr &= ~RTW_RCR_PKTFILTER_MASK;
sc->sc_rcr &= ~(RTW_RCR_MXDMA_MASK | RTW_RCR_RXFTH_MASK);
sc->sc_rcr |= RTW_RCR_PKTFILTER_DEFAULT;
/* MAC auto-reset PHY (huh?) */
sc->sc_rcr |= RTW_RCR_ENMARP;
/* DMA whole Rx packets, only. Set Tx DMA burst size to 1024 bytes. */
sc->sc_rcr |= RTW_RCR_MXDMA_1024 | RTW_RCR_RXFTH_WHOLE;
switch (ic->ic_opmode) {
case IEEE80211_M_MONITOR:
sc->sc_rcr |= RTW_RCR_MONITOR;
break;
case IEEE80211_M_AHDEMO:
case IEEE80211_M_IBSS:
/* receive broadcasts in our BSS */
sc->sc_rcr |= RTW_RCR_ADD3;
break;
default:
break;
}
ifp->if_flags &= ~IFF_ALLMULTI;
/* XXX accept all broadcast if scanning */
if ((ifp->if_flags & IFF_BROADCAST) != 0)
sc->sc_rcr |= RTW_RCR_AB; /* accept all broadcast */
if (ifp->if_flags & IFF_PROMISC) {
sc->sc_rcr |= RTW_RCR_AB; /* accept all broadcast */
allmulti:
ifp->if_flags |= IFF_ALLMULTI;
goto setit;
}
/*
* Program the 64-bit multicast hash filter.
*/
ETHER_FIRST_MULTI(step, ec, enm);
while (enm != NULL) {
/* XXX */
if (memcmp(enm->enm_addrlo, enm->enm_addrhi,
ETHER_ADDR_LEN) != 0)
goto allmulti;
hash = rtw_calchash(enm->enm_addrlo);
hashes[hash >> 5] |= (1 << (hash & 0x1f));
sc->sc_rcr |= RTW_RCR_AM;
ETHER_NEXT_MULTI(step, enm);
}
/* all bits set => hash is useless */
if (~(hashes[0] & hashes[1]) == 0)
goto allmulti;
setit:
if (ifp->if_flags & IFF_ALLMULTI) {
sc->sc_rcr |= RTW_RCR_AM; /* accept all multicast */
hashes[0] = hashes[1] = 0xffffffff;
}
RTW_WRITE(regs, RTW_MAR0, hashes[0]);
RTW_WRITE(regs, RTW_MAR1, hashes[1]);
RTW_WRITE(regs, RTW_RCR, sc->sc_rcr);
RTW_SYNC(regs, RTW_MAR0, RTW_RCR); /* RTW_MAR0 < RTW_MAR1 < RTW_RCR */
DPRINTF(sc, RTW_DEBUG_PKTFILT,
("%s: RTW_MAR0 %08x RTW_MAR1 %08x RTW_RCR %08x\n",
sc->sc_dev.dv_xname, RTW_READ(regs, RTW_MAR0),
RTW_READ(regs, RTW_MAR1), RTW_READ(regs, RTW_RCR)));
return;
}
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
static struct mbuf *
rtw_beacon_alloc(struct rtw_softc *sc, struct ieee80211_node *ni)
{
struct ieee80211com *ic = &sc->sc_ic;
struct mbuf *m;
struct ieee80211_beacon_offsets boff;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
if ((m = ieee80211_beacon_alloc(ic, ni, &boff)) != NULL) {
RTW_DPRINTF(RTW_DEBUG_BEACON,
("%s: m %p len %u\n", __func__, m, m->m_len));
}
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
return m;
}
/* Must be called at splnet. */
static int
rtw_init(struct ifnet *ifp)
{
struct rtw_softc *sc = (struct rtw_softc *)ifp->if_softc;
struct ieee80211com *ic = &sc->sc_ic;
struct rtw_regs *regs = &sc->sc_regs;
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
int rc = 0;
if ((rc = rtw_enable(sc)) != 0)
goto out;
/* Cancel pending I/O and reset. */
rtw_stop(ifp, 0);
DPRINTF(sc, RTW_DEBUG_TUNE, ("%s: channel %d freq %d flags 0x%04x\n",
__func__, ieee80211_chan2ieee(ic, ic->ic_curchan),
ic->ic_curchan->ic_freq, ic->ic_curchan->ic_flags));
if ((rc = rtw_pwrstate(sc, RTW_OFF)) != 0)
goto out;
if ((rc = rtw_swring_setup(sc)) != 0)
goto out;
rtw_transmit_config(regs);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_set_access(regs, RTW_ACCESS_CONFIG);
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
RTW_WRITE8(regs, RTW_MSR, 0x0); /* no link */
RTW_WBW(regs, RTW_MSR, RTW_BRSR);
/* long PLCP header, 1Mb/2Mb basic rate */
RTW_WRITE16(regs, RTW_BRSR, RTW_BRSR_MBR8180_2MBPS);
RTW_SYNC(regs, RTW_BRSR, RTW_BRSR);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_set_access(regs, RTW_ACCESS_ANAPARM);
rtw_set_access(regs, RTW_ACCESS_NONE);
/* XXX from reference sources */
RTW_WRITE(regs, RTW_FEMR, 0xffff);
RTW_SYNC(regs, RTW_FEMR, RTW_FEMR);
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
rtw_set_rfprog(regs, sc->sc_rfchipid, sc->sc_dev.dv_xname);
RTW_WRITE8(regs, RTW_PHYDELAY, sc->sc_phydelay);
/* from Linux driver */
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
RTW_WRITE8(regs, RTW_CRCOUNT, RTW_CRCOUNT_MAGIC);
RTW_SYNC(regs, RTW_PHYDELAY, RTW_CRCOUNT);
rtw_enable_interrupts(sc);
rtw_pktfilt_load(sc);
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
rtw_hwring_setup(sc);
rtw_wep_setkeys(sc, ic->ic_nw_keys, ic->ic_def_txkey);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_io_enable(regs, RTW_CR_RE|RTW_CR_TE, 1);
ifp->if_flags |= IFF_RUNNING;
ic->ic_state = IEEE80211_S_INIT;
RTW_WRITE16(regs, RTW_BSSID16, 0x0);
RTW_WRITE(regs, RTW_BSSID32, 0x0);
rtw_resume_ticks(sc);
rtw_set_nettype(sc, IEEE80211_M_MONITOR);
At last, I have rtw w/ Philips RF receiving packets. I added some sysctls to aid debugging: * hw.rtw.debug -- enable debugging * hw.rtw.flush_rfio -- Linux voodoo: possibly makes the MAC "flush" bits down the serial bus to the RF * hw.rtw.host_rfio: force the host to bang bits to the RF, instead of the MAC banging bits * hw.rtw.rfio_delay: after telling the MAC to bang bits to the RF front-end, delay rfio_delay microseconds. * hw.rtw.rfprog_fallback: there is this notion of the "RF programming method." I believe the choice influences the polarity/timing of the serial bus used to program the RF front-end. I know the correct choice for Intersil/RFMD/Philips front-ends, only. For all other front-ends, I "fallback" to rfprog_fallback. Make rtw_txdac_enable take an rtw_softc argument. I will probably revert this change. Add some Linux voodoo to rtw_continuous_tx_enable. I will probably revert this change. Important: add rtw_set_rfprog, which sets the correct RF programming method. This change and the following change are probably responsible for making the Philips RF work. Important: RTW_CONFIG1 is an 8-bit register, treat it that way! Important: RTW_BRSR is 16-bit, RTW_CRCOUNT, RTW_PHYDELAY, and RTW_MSR are 8-bit: treat them that way! Vastly simplify rtw_resume_ticks. Note to self: set the LED state to match the power state. Hedge against the possibility that RTW_MSR is protected as RTW_CONFIG[0123] are, meanwhile reworking that section of rtw_init a little. Add sc_anaparm, which isn't used, yet....
2004-12-13 03:48:02 +03:00
if (ic->ic_opmode == IEEE80211_M_MONITOR)
return ieee80211_new_state(ic, IEEE80211_S_RUN, -1);
else
return ieee80211_new_state(ic, IEEE80211_S_SCAN, -1);
out:
printf("%s: interface not running\n", sc->sc_dev.dv_xname);
return rc;
}
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
static __inline void
rtw_led_init(struct rtw_regs *regs)
{
uint8_t cfg0, cfg1;
rtw_set_access(regs, RTW_ACCESS_CONFIG);
cfg0 = RTW_READ8(regs, RTW_CONFIG0);
cfg0 |= RTW_CONFIG0_LEDGPOEN;
RTW_WRITE8(regs, RTW_CONFIG0, cfg0);
cfg1 = RTW_READ8(regs, RTW_CONFIG1);
RTW_DPRINTF(RTW_DEBUG_LED,
("%s: read %" PRIx8 " from reg[CONFIG1]\n", __func__, cfg1));
cfg1 &= ~RTW_CONFIG1_LEDS_MASK;
cfg1 |= RTW_CONFIG1_LEDS_TX_RX;
RTW_WRITE8(regs, RTW_CONFIG1, cfg1);
rtw_set_access(regs, RTW_ACCESS_NONE);
}
2005-02-27 03:26:58 +03:00
/*
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
* IEEE80211_S_INIT: LED1 off
*
* IEEE80211_S_AUTH,
* IEEE80211_S_ASSOC,
* IEEE80211_S_SCAN: LED1 blinks @ 1 Hz, blinks at 5Hz for tx/rx
*
* IEEE80211_S_RUN: LED1 on, blinks @ 5Hz for tx/rx
*/
static void
rtw_led_newstate(struct rtw_softc *sc, enum ieee80211_state nstate)
{
struct rtw_led_state *ls;
ls = &sc->sc_led_state;
switch (nstate) {
case IEEE80211_S_INIT:
rtw_led_init(&sc->sc_regs);
callout_stop(&ls->ls_slow_ch);
callout_stop(&ls->ls_fast_ch);
ls->ls_slowblink = 0;
ls->ls_actblink = 0;
ls->ls_default = 0;
break;
case IEEE80211_S_SCAN:
callout_schedule(&ls->ls_slow_ch, RTW_LED_SLOW_TICKS);
callout_schedule(&ls->ls_fast_ch, RTW_LED_FAST_TICKS);
/*FALLTHROUGH*/
case IEEE80211_S_AUTH:
case IEEE80211_S_ASSOC:
ls->ls_default = RTW_LED1;
ls->ls_actblink = RTW_LED1;
ls->ls_slowblink = RTW_LED1;
break;
case IEEE80211_S_RUN:
ls->ls_slowblink = 0;
break;
}
rtw_led_set(ls, &sc->sc_regs, sc->sc_hwverid);
}
static void
rtw_led_set(struct rtw_led_state *ls, struct rtw_regs *regs, int hwverid)
{
uint8_t led_condition;
bus_size_t ofs;
uint8_t mask, newval, val;
led_condition = ls->ls_default;
if (ls->ls_state & RTW_LED_S_SLOW)
led_condition ^= ls->ls_slowblink;
if (ls->ls_state & (RTW_LED_S_RX|RTW_LED_S_TX))
led_condition ^= ls->ls_actblink;
RTW_DPRINTF(RTW_DEBUG_LED,
("%s: LED condition %" PRIx8 "\n", __func__, led_condition));
switch (hwverid) {
default:
case 'F':
ofs = RTW_PSR;
newval = mask = RTW_PSR_LEDGPO0 | RTW_PSR_LEDGPO1;
if (led_condition & RTW_LED0)
newval &= ~RTW_PSR_LEDGPO0;
if (led_condition & RTW_LED1)
newval &= ~RTW_PSR_LEDGPO1;
break;
case 'D':
ofs = RTW_9346CR;
mask = RTW_9346CR_EEM_MASK | RTW_9346CR_EEDI | RTW_9346CR_EECS;
newval = RTW_9346CR_EEM_PROGRAM;
if (led_condition & RTW_LED0)
newval |= RTW_9346CR_EEDI;
if (led_condition & RTW_LED1)
newval |= RTW_9346CR_EECS;
break;
}
val = RTW_READ8(regs, ofs);
RTW_DPRINTF(RTW_DEBUG_LED,
("%s: read %" PRIx8 " from reg[%#02" PRIxPTR "]\n", __func__, val,
(uintptr_t)ofs));
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
val &= ~mask;
val |= newval;
RTW_WRITE8(regs, ofs, val);
RTW_DPRINTF(RTW_DEBUG_LED,
("%s: wrote %" PRIx8 " to reg[%#02" PRIxPTR "]\n", __func__, val,
(uintptr_t)ofs));
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
RTW_SYNC(regs, ofs, ofs);
}
static void
rtw_led_fastblink(void *arg)
{
int ostate, s;
struct rtw_softc *sc = (struct rtw_softc *)arg;
struct rtw_led_state *ls = &sc->sc_led_state;
s = splnet();
ostate = ls->ls_state;
ls->ls_state ^= ls->ls_event;
if ((ls->ls_event & RTW_LED_S_TX) == 0)
ls->ls_state &= ~RTW_LED_S_TX;
if ((ls->ls_event & RTW_LED_S_RX) == 0)
ls->ls_state &= ~RTW_LED_S_RX;
ls->ls_event = 0;
if (ostate != ls->ls_state)
rtw_led_set(ls, &sc->sc_regs, sc->sc_hwverid);
splx(s);
callout_schedule(&ls->ls_fast_ch, RTW_LED_FAST_TICKS);
}
static void
rtw_led_slowblink(void *arg)
{
int s;
struct rtw_softc *sc = (struct rtw_softc *)arg;
struct rtw_led_state *ls = &sc->sc_led_state;
s = splnet();
ls->ls_state ^= RTW_LED_S_SLOW;
rtw_led_set(ls, &sc->sc_regs, sc->sc_hwverid);
splx(s);
callout_schedule(&ls->ls_slow_ch, RTW_LED_SLOW_TICKS);
}
static __inline void
rtw_led_attach(struct rtw_led_state *ls, void *arg)
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
{
callout_init(&ls->ls_fast_ch);
callout_init(&ls->ls_slow_ch);
callout_setfunc(&ls->ls_fast_ch, rtw_led_fastblink, arg);
callout_setfunc(&ls->ls_slow_ch, rtw_led_slowblink, arg);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
}
static int
rtw_ioctl(struct ifnet *ifp, u_long cmd, caddr_t data)
{
int rc = 0, s;
struct rtw_softc *sc = ifp->if_softc;
struct ifreq *ifr = (struct ifreq *)data;
s = splnet();
switch (cmd) {
case SIOCSIFFLAGS:
if ((ifp->if_flags & IFF_UP) != 0) {
if ((sc->sc_flags & RTW_F_ENABLED) != 0) {
rtw_pktfilt_load(sc);
} else
rc = rtw_init(ifp);
RTW_PRINT_REGS(&sc->sc_regs, ifp->if_xname, __func__);
} else if ((sc->sc_flags & RTW_F_ENABLED) != 0) {
RTW_PRINT_REGS(&sc->sc_regs, ifp->if_xname, __func__);
rtw_stop(ifp, 1);
}
break;
case SIOCADDMULTI:
case SIOCDELMULTI:
if (cmd == SIOCADDMULTI)
rc = ether_addmulti(ifr, &sc->sc_ec);
else
rc = ether_delmulti(ifr, &sc->sc_ec);
if (rc != ENETRESET)
break;
if (ifp->if_flags & IFF_RUNNING)
rtw_pktfilt_load(sc);
rc = 0;
break;
default:
if ((rc = ieee80211_ioctl(&sc->sc_ic, cmd, data)) != ENETRESET)
break;
if ((sc->sc_flags & RTW_F_ENABLED) != 0)
rc = rtw_init(ifp);
else
rc = 0;
break;
}
splx(s);
return rc;
}
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
/* Select a transmit ring with at least one h/w and s/w descriptor free.
* Return 0 on success, -1 on failure.
*/
static __inline int
rtw_txring_choose(struct rtw_softc *sc, struct rtw_txsoft_blk **tsbp,
struct rtw_txdesc_blk **tdbp, int pri)
{
struct rtw_txsoft_blk *tsb;
struct rtw_txdesc_blk *tdb;
KASSERT(pri >= 0 && pri < RTW_NTXPRI);
tsb = &sc->sc_txsoft_blk[pri];
tdb = &sc->sc_txdesc_blk[pri];
if (SIMPLEQ_EMPTY(&tsb->tsb_freeq) || tdb->tdb_nfree == 0) {
if (tsb->tsb_tx_timer == 0)
tsb->tsb_tx_timer = 5;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
*tsbp = NULL;
*tdbp = NULL;
return -1;
}
*tsbp = tsb;
*tdbp = tdb;
return 0;
}
static __inline struct mbuf *
rtw_80211_dequeue(struct rtw_softc *sc, struct ifqueue *ifq, int pri,
struct rtw_txsoft_blk **tsbp, struct rtw_txdesc_blk **tdbp,
struct ieee80211_node **nip, short *if_flagsp)
{
struct mbuf *m;
if (IF_IS_EMPTY(ifq))
return NULL;
if (rtw_txring_choose(sc, tsbp, tdbp, pri) == -1) {
DPRINTF(sc, RTW_DEBUG_XMIT_RSRC, ("%s: no ring %d descriptor\n",
__func__, pri));
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
*if_flagsp |= IFF_OACTIVE;
sc->sc_if.if_timer = 1;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
return NULL;
}
IF_DEQUEUE(ifq, m);
*nip = (struct ieee80211_node *)m->m_pkthdr.rcvif;
m->m_pkthdr.rcvif = NULL;
KASSERT(*nip != NULL);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
return m;
}
/* Point *mp at the next 802.11 frame to transmit. Point *tsbp
* at the driver's selection of transmit control block for the packet.
*/
static __inline int
rtw_dequeue(struct ifnet *ifp, struct rtw_txsoft_blk **tsbp,
struct rtw_txdesc_blk **tdbp, struct mbuf **mp,
struct ieee80211_node **nip)
{
int pri;
struct ether_header *eh;
struct mbuf *m0;
struct rtw_softc *sc;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
short *if_flagsp;
sc = (struct rtw_softc *)ifp->if_softc;
DPRINTF(sc, RTW_DEBUG_XMIT,
("%s: enter %s\n", sc->sc_dev.dv_xname, __func__));
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
if_flagsp = &ifp->if_flags;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
if (sc->sc_ic.ic_state == IEEE80211_S_RUN &&
(*mp = rtw_80211_dequeue(sc, &sc->sc_beaconq, RTW_TXPRIBCN, tsbp,
tdbp, nip, if_flagsp)) != NULL) {
DPRINTF(sc, RTW_DEBUG_XMIT, ("%s: dequeue beacon frame\n",
__func__));
return 0;
}
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
if ((*mp = rtw_80211_dequeue(sc, &sc->sc_ic.ic_mgtq, RTW_TXPRIMD, tsbp,
tdbp, nip, if_flagsp)) != NULL) {
DPRINTF(sc, RTW_DEBUG_XMIT, ("%s: dequeue mgt frame\n",
__func__));
return 0;
}
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
if (sc->sc_ic.ic_state != IEEE80211_S_RUN) {
DPRINTF(sc, RTW_DEBUG_XMIT, ("%s: not running\n", __func__));
return 0;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
}
*mp = NULL;
IFQ_POLL(&ifp->if_snd, m0);
if (m0 == NULL) {
DPRINTF(sc, RTW_DEBUG_XMIT, ("%s: no frame ready\n",
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
__func__));
return 0;
}
pri = ((m0->m_flags & M_PWR_SAV) != 0) ? RTW_TXPRIHI : RTW_TXPRIMD;
if (rtw_txring_choose(sc, tsbp, tdbp, pri) == -1) {
DPRINTF(sc, RTW_DEBUG_XMIT_RSRC, ("%s: no ring %d descriptor\n",
__func__, pri));
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
*if_flagsp |= IFF_OACTIVE;
sc->sc_if.if_timer = 1;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
return 0;
}
IFQ_DEQUEUE(&ifp->if_snd, m0);
if (m0 == NULL) {
DPRINTF(sc, RTW_DEBUG_XMIT, ("%s: no frame ready\n",
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
__func__));
return 0;
}
DPRINTF(sc, RTW_DEBUG_XMIT, ("%s: dequeue data frame\n", __func__));
ifp->if_opackets++;
#if NBPFILTER > 0
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
if (ifp->if_bpf)
bpf_mtap(ifp->if_bpf, m0);
#endif
eh = mtod(m0, struct ether_header *);
*nip = ieee80211_find_txnode(&sc->sc_ic, eh->ether_dhost);
if (*nip == NULL) {
/* NB: ieee80211_find_txnode does stat+msg */
m_freem(m0);
return -1;
}
if ((m0 = ieee80211_encap(&sc->sc_ic, m0, *nip)) == NULL) {
DPRINTF(sc, RTW_DEBUG_XMIT, ("%s: encap error\n", __func__));
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
ifp->if_oerrors++;
return -1;
}
DPRINTF(sc, RTW_DEBUG_XMIT, ("%s: leave\n", __func__));
*mp = m0;
return 0;
}
static int
rtw_seg_too_short(bus_dmamap_t dmamap)
{
int i;
for (i = 0; i < dmamap->dm_nsegs; i++) {
if (dmamap->dm_segs[i].ds_len < 4) {
printf("%s: segment too short\n", __func__);
return 1;
}
}
return 0;
}
/* TBD factor with atw_start */
static struct mbuf *
rtw_dmamap_load_txbuf(bus_dma_tag_t dmat, bus_dmamap_t dmam, struct mbuf *chain,
u_int ndescfree, short *ifflagsp, const char *dvname)
{
int first, rc;
struct mbuf *m, *m0;
m0 = chain;
/*
* Load the DMA map. Copy and try (once) again if the packet
* didn't fit in the alloted number of segments.
*/
for (first = 1;
((rc = bus_dmamap_load_mbuf(dmat, dmam, m0,
BUS_DMA_WRITE|BUS_DMA_NOWAIT)) != 0 ||
dmam->dm_nsegs > ndescfree || rtw_seg_too_short(dmam)) && first;
first = 0) {
if (rc == 0)
bus_dmamap_unload(dmat, dmam);
MGETHDR(m, M_DONTWAIT, MT_DATA);
if (m == NULL) {
printf("%s: unable to allocate Tx mbuf\n",
dvname);
break;
}
if (m0->m_pkthdr.len > MHLEN) {
MCLGET(m, M_DONTWAIT);
if ((m->m_flags & M_EXT) == 0) {
printf("%s: cannot allocate Tx cluster\n",
dvname);
m_freem(m);
break;
}
}
m_copydata(m0, 0, m0->m_pkthdr.len, mtod(m, caddr_t));
m->m_pkthdr.len = m->m_len = m0->m_pkthdr.len;
m_freem(m0);
m0 = m;
m = NULL;
}
if (rc != 0) {
printf("%s: cannot load Tx buffer, rc = %d\n", dvname, rc);
m_freem(m0);
return NULL;
} else if (rtw_seg_too_short(dmam)) {
printf("%s: cannot load Tx buffer, segment too short\n",
dvname);
bus_dmamap_unload(dmat, dmam);
m_freem(m0);
return NULL;
} else if (dmam->dm_nsegs > ndescfree) {
printf("%s: too many tx segments\n", dvname);
bus_dmamap_unload(dmat, dmam);
m_freem(m0);
return NULL;
}
return m0;
}
#ifdef RTW_DEBUG
static void
rtw_print_txdesc(struct rtw_softc *sc, const char *action,
struct rtw_txsoft *ts, struct rtw_txdesc_blk *tdb, int desc)
{
struct rtw_txdesc *td = &tdb->tdb_desc[desc];
DPRINTF(sc, RTW_DEBUG_XMIT_DESC, ("%s: %p %s txdesc[%d] next %#08x "
"buf %#08x ctl0 %#08x ctl1 %#08x len %#08x\n",
sc->sc_dev.dv_xname, ts, action, desc,
le32toh(td->td_buf), le32toh(td->td_next),
le32toh(td->td_ctl0), le32toh(td->td_ctl1),
le32toh(td->td_len)));
}
#endif /* RTW_DEBUG */
static void
rtw_start(struct ifnet *ifp)
{
uint8_t tppoll;
int desc, i, lastdesc, npkt, rate;
uint32_t proto_ctl0, ctl0, ctl1;
bus_dmamap_t dmamap;
struct ieee80211com *ic;
struct ieee80211_duration *d0;
struct ieee80211_frame_min *wh;
struct ieee80211_node *ni;
struct mbuf *m0;
struct rtw_softc *sc;
struct rtw_txsoft_blk *tsb;
struct rtw_txdesc_blk *tdb;
struct rtw_txsoft *ts;
struct rtw_txdesc *td;
struct ieee80211_key *k;
sc = (struct rtw_softc *)ifp->if_softc;
ic = &sc->sc_ic;
DPRINTF(sc, RTW_DEBUG_XMIT,
("%s: enter %s\n", sc->sc_dev.dv_xname, __func__));
if ((ifp->if_flags & (IFF_RUNNING|IFF_OACTIVE)) != IFF_RUNNING)
goto out;
/* XXX do real rate control */
proto_ctl0 = RTW_TXCTL0_RTSRATE_1MBPS;
if ((ic->ic_flags & IEEE80211_F_SHPREAMBLE) != 0)
proto_ctl0 |= RTW_TXCTL0_SPLCP;
for (;;) {
if (rtw_dequeue(ifp, &tsb, &tdb, &m0, &ni) == -1)
continue;
if (m0 == NULL)
break;
wh = mtod(m0, struct ieee80211_frame_min *);
if ((wh->i_fc[1] & IEEE80211_FC1_WEP) != 0 &&
(k = ieee80211_crypto_encap(ic, ni, m0)) == NULL) {
m_freem(m0);
break;
} else
k = NULL;
ts = SIMPLEQ_FIRST(&tsb->tsb_freeq);
dmamap = ts->ts_dmamap;
m0 = rtw_dmamap_load_txbuf(sc->sc_dmat, dmamap, m0,
tdb->tdb_nfree, &ifp->if_flags, sc->sc_dev.dv_xname);
if (m0 == NULL || dmamap->dm_nsegs == 0) {
DPRINTF(sc, RTW_DEBUG_XMIT,
("%s: fail dmamap load\n", __func__));
goto post_dequeue_err;
}
/* Note well: rtw_dmamap_load_txbuf may have created
* a new chain, so we must find the header once
* more.
*/
wh = mtod(m0, struct ieee80211_frame_min *);
/* XXX do real rate control */
if ((wh->i_fc[0] & IEEE80211_FC0_TYPE_MASK) ==
IEEE80211_FC0_TYPE_MGT)
rate = 2;
else
rate = MAX(2, ieee80211_get_rate(ic));
#ifdef RTW_DEBUG
if ((ifp->if_flags & (IFF_DEBUG|IFF_LINK2)) ==
(IFF_DEBUG|IFF_LINK2)) {
ieee80211_dump_pkt(mtod(m0, uint8_t *),
(dmamap->dm_nsegs == 1) ? m0->m_pkthdr.len
: sizeof(wh),
rate, 0);
}
#endif /* RTW_DEBUG */
ctl0 = proto_ctl0 |
LSHIFT(m0->m_pkthdr.len, RTW_TXCTL0_TPKTSIZE_MASK);
switch (rate) {
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
default:
case 2:
ctl0 |= RTW_TXCTL0_RATE_1MBPS;
break;
case 4:
ctl0 |= RTW_TXCTL0_RATE_2MBPS;
break;
case 11:
ctl0 |= RTW_TXCTL0_RATE_5MBPS;
break;
case 22:
ctl0 |= RTW_TXCTL0_RATE_11MBPS;
break;
}
/* XXX >= ? Compare after fragmentation? */
if (m0->m_pkthdr.len > ic->ic_rtsthreshold)
ctl0 |= RTW_TXCTL0_RTSEN;
if (k != NULL) {
ctl0 |= LSHIFT(k->wk_keyix, RTW_TXCTL0_KEYID_MASK) &
RTW_TXCTL0_KEYID_MASK;
}
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
if ((wh->i_fc[0] & IEEE80211_FC0_TYPE_MASK) ==
IEEE80211_FC0_TYPE_MGT) {
ctl0 &= ~(RTW_TXCTL0_SPLCP | RTW_TXCTL0_RTSEN);
if ((wh->i_fc[0] & IEEE80211_FC0_SUBTYPE_MASK) ==
IEEE80211_FC0_SUBTYPE_BEACON)
ctl0 |= RTW_TXCTL0_BEACON;
}
if (ieee80211_compute_duration(wh, m0->m_pkthdr.len,
ic->ic_flags, ic->ic_fragthreshold,
rate, &ts->ts_d0, &ts->ts_dn, &npkt,
(ifp->if_flags & (IFF_DEBUG|IFF_LINK2)) ==
(IFF_DEBUG|IFF_LINK2)) == -1) {
DPRINTF(sc, RTW_DEBUG_XMIT,
("%s: fail compute duration\n", __func__));
goto post_load_err;
}
d0 = &ts->ts_d0;
*(uint16_t*)wh->i_dur = htole16(d0->d_data_dur);
ctl1 = LSHIFT(d0->d_plcp_len, RTW_TXCTL1_LENGTH_MASK) |
LSHIFT(d0->d_rts_dur, RTW_TXCTL1_RTSDUR_MASK);
if (d0->d_residue)
ctl1 |= RTW_TXCTL1_LENGEXT;
/* TBD fragmentation */
ts->ts_first = tdb->tdb_next;
rtw_txdescs_sync(tdb, ts->ts_first, dmamap->dm_nsegs,
BUS_DMASYNC_PREWRITE);
KASSERT(ts->ts_first < tdb->tdb_ndesc);
#if NBPFILTER > 0
if (ic->ic_rawbpf != NULL)
bpf_mtap((caddr_t)ic->ic_rawbpf, m0);
if (sc->sc_radiobpf != NULL) {
struct rtw_tx_radiotap_header *rt = &sc->sc_txtap;
rt->rt_flags = 0;
rt->rt_rate = rate;
rt->rt_chan_freq = htole16(ic->ic_curchan->ic_freq);
rt->rt_chan_flags = htole16(ic->ic_curchan->ic_flags);
bpf_mtap2(sc->sc_radiobpf, (caddr_t)rt,
sizeof(sc->sc_txtapu), m0);
}
#endif /* NPBFILTER > 0 */
for (i = 0, lastdesc = desc = ts->ts_first;
i < dmamap->dm_nsegs;
i++, desc = RTW_NEXT_IDX(tdb, desc)) {
if (dmamap->dm_segs[i].ds_len > RTW_TXLEN_LENGTH_MASK) {
DPRINTF(sc, RTW_DEBUG_XMIT_DESC,
("%s: seg too long\n", __func__));
goto post_load_err;
}
td = &tdb->tdb_desc[desc];
td->td_ctl0 = htole32(ctl0);
if (i != 0)
td->td_ctl0 |= htole32(RTW_TXCTL0_OWN);
td->td_ctl1 = htole32(ctl1);
td->td_buf = htole32(dmamap->dm_segs[i].ds_addr);
td->td_len = htole32(dmamap->dm_segs[i].ds_len);
lastdesc = desc;
#ifdef RTW_DEBUG
rtw_print_txdesc(sc, "load", ts, tdb, desc);
#endif /* RTW_DEBUG */
}
KASSERT(desc < tdb->tdb_ndesc);
ts->ts_ni = ni;
KASSERT(ni != NULL);
ts->ts_mbuf = m0;
ts->ts_last = lastdesc;
tdb->tdb_desc[ts->ts_last].td_ctl0 |= htole32(RTW_TXCTL0_LS);
tdb->tdb_desc[ts->ts_first].td_ctl0 |=
htole32(RTW_TXCTL0_FS);
#ifdef RTW_DEBUG
rtw_print_txdesc(sc, "FS on", ts, tdb, ts->ts_first);
rtw_print_txdesc(sc, "LS on", ts, tdb, ts->ts_last);
#endif /* RTW_DEBUG */
tdb->tdb_nfree -= dmamap->dm_nsegs;
tdb->tdb_next = desc;
rtw_txdescs_sync(tdb, ts->ts_first, dmamap->dm_nsegs,
BUS_DMASYNC_PREREAD|BUS_DMASYNC_PREWRITE);
tdb->tdb_desc[ts->ts_first].td_ctl0 |=
htole32(RTW_TXCTL0_OWN);
#ifdef RTW_DEBUG
rtw_print_txdesc(sc, "OWN on", ts, tdb, ts->ts_first);
#endif /* RTW_DEBUG */
rtw_txdescs_sync(tdb, ts->ts_first, 1,
BUS_DMASYNC_PREREAD|BUS_DMASYNC_PREWRITE);
SIMPLEQ_REMOVE_HEAD(&tsb->tsb_freeq, ts_q);
SIMPLEQ_INSERT_TAIL(&tsb->tsb_dirtyq, ts, ts_q);
if (tsb != &sc->sc_txsoft_blk[RTW_TXPRIBCN])
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
sc->sc_led_state.ls_event |= RTW_LED_S_TX;
tsb->tsb_tx_timer = 5;
ifp->if_timer = 1;
tppoll = RTW_READ8(&sc->sc_regs, RTW_TPPOLL);
tppoll &= ~RTW_TPPOLL_SALL;
tppoll |= tsb->tsb_poll & RTW_TPPOLL_ALL;
RTW_WRITE8(&sc->sc_regs, RTW_TPPOLL, tppoll);
RTW_SYNC(&sc->sc_regs, RTW_TPPOLL, RTW_TPPOLL);
}
out:
DPRINTF(sc, RTW_DEBUG_XMIT, ("%s: leave\n", __func__));
return;
post_load_err:
bus_dmamap_unload(sc->sc_dmat, dmamap);
m_freem(m0);
post_dequeue_err:
ieee80211_free_node(ni);
return;
}
static void
rtw_idle(struct rtw_regs *regs)
{
int active;
/* request stop DMA; wait for packets to stop transmitting. */
RTW_WRITE8(regs, RTW_TPPOLL, RTW_TPPOLL_SALL);
RTW_WBR(regs, RTW_TPPOLL, RTW_TPPOLL);
for (active = 0; active < 300 &&
(RTW_READ8(regs, RTW_TPPOLL) & RTW_TPPOLL_ACTIVE) != 0; active++)
DELAY(10);
printf("%s: transmit DMA idle in %dus\n", __func__, active * 10);
}
static void
rtw_watchdog(struct ifnet *ifp)
{
int pri, tx_timeouts = 0;
struct rtw_softc *sc;
struct rtw_txsoft_blk *tsb;
sc = ifp->if_softc;
ifp->if_timer = 0;
if ((sc->sc_flags & RTW_F_ENABLED) == 0)
return;
for (pri = 0; pri < RTW_NTXPRI; pri++) {
tsb = &sc->sc_txsoft_blk[pri];
if (tsb->tsb_tx_timer == 0)
continue;
else if (--tsb->tsb_tx_timer == 0) {
if (SIMPLEQ_EMPTY(&tsb->tsb_dirtyq))
continue;
printf("%s: transmit timeout, priority %d\n",
ifp->if_xname, pri);
ifp->if_oerrors++;
tx_timeouts++;
} else
ifp->if_timer = 1;
}
if (tx_timeouts > 0) {
/* Stop Tx DMA, disable xmtr, flush Tx rings, enable xmtr,
* reset s/w tx-ring pointers, and start transmission.
*
* TBD Stop/restart just the broken rings?
*/
rtw_idle(&sc->sc_regs);
rtw_io_enable(&sc->sc_regs, RTW_CR_TE, 0);
rtw_txdescs_reset(sc);
rtw_io_enable(&sc->sc_regs, RTW_CR_TE, 1);
rtw_txring_fixup(sc);
rtw_start(ifp);
}
ieee80211_watchdog(&sc->sc_ic);
return;
}
static void
rtw_next_scan(void *arg)
{
struct ieee80211com *ic = arg;
int s;
/* don't call rtw_start w/o network interrupts blocked */
s = splnet();
if (ic->ic_state == IEEE80211_S_SCAN)
ieee80211_next_scan(ic);
splx(s);
}
static void
rtw_join_bss(struct rtw_softc *sc, uint8_t *bssid, uint16_t intval0)
{
uint16_t bcnitv, bintritv, intval;
int i;
struct rtw_regs *regs = &sc->sc_regs;
for (i = 0; i < IEEE80211_ADDR_LEN; i++)
RTW_WRITE8(regs, RTW_BSSID + i, bssid[i]);
RTW_SYNC(regs, RTW_BSSID16, RTW_BSSID32);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_set_access(regs, RTW_ACCESS_CONFIG);
intval = MIN(intval0, PRESHIFT(RTW_BCNITV_BCNITV_MASK));
bcnitv = RTW_READ16(regs, RTW_BCNITV) & ~RTW_BCNITV_BCNITV_MASK;
bcnitv |= LSHIFT(intval, RTW_BCNITV_BCNITV_MASK);
RTW_WRITE16(regs, RTW_BCNITV, bcnitv);
/* interrupt host 1ms before the TBTT */
bintritv = RTW_READ16(regs, RTW_BINTRITV) & ~RTW_BINTRITV_BINTRITV;
bintritv |= LSHIFT(1000, RTW_BINTRITV_BINTRITV);
RTW_WRITE16(regs, RTW_BINTRITV, bintritv);
/* magic from Linux */
RTW_WRITE16(regs, RTW_ATIMWND, LSHIFT(1, RTW_ATIMWND_ATIMWND));
RTW_WRITE16(regs, RTW_ATIMTRITV, LSHIFT(2, RTW_ATIMTRITV_ATIMTRITV));
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_set_access(regs, RTW_ACCESS_NONE);
rtw_io_enable(regs, RTW_CR_RE | RTW_CR_TE, 1);
}
/* Synchronize the hardware state with the software state. */
static int
rtw_newstate(struct ieee80211com *ic, enum ieee80211_state nstate, int arg)
{
struct ifnet *ifp = ic->ic_ifp;
struct rtw_softc *sc = (struct rtw_softc *)ifp->if_softc;
enum ieee80211_state ostate;
int error;
ostate = ic->ic_state;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_led_newstate(sc, nstate);
if (nstate == IEEE80211_S_INIT) {
callout_stop(&sc->sc_scan_ch);
sc->sc_cur_chan = IEEE80211_CHAN_ANY;
return (*sc->sc_mtbl.mt_newstate)(ic, nstate, arg);
}
if (ostate == IEEE80211_S_INIT && nstate != IEEE80211_S_INIT)
rtw_pwrstate(sc, RTW_ON);
if ((error = rtw_tune(sc)) != 0)
return error;
switch (nstate) {
case IEEE80211_S_INIT:
panic("%s: unexpected state IEEE80211_S_INIT\n", __func__);
break;
case IEEE80211_S_SCAN:
if (ostate != IEEE80211_S_SCAN) {
(void)memset(ic->ic_bss->ni_bssid, 0,
IEEE80211_ADDR_LEN);
rtw_set_nettype(sc, IEEE80211_M_MONITOR);
}
callout_reset(&sc->sc_scan_ch, rtw_dwelltime * hz / 1000,
rtw_next_scan, ic);
break;
case IEEE80211_S_RUN:
switch (ic->ic_opmode) {
case IEEE80211_M_HOSTAP:
case IEEE80211_M_IBSS:
rtw_set_nettype(sc, IEEE80211_M_MONITOR);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
/*FALLTHROUGH*/
case IEEE80211_M_AHDEMO:
case IEEE80211_M_STA:
rtw_join_bss(sc, ic->ic_bss->ni_bssid,
ic->ic_bss->ni_intval);
break;
case IEEE80211_M_MONITOR:
break;
}
rtw_set_nettype(sc, ic->ic_opmode);
break;
case IEEE80211_S_ASSOC:
case IEEE80211_S_AUTH:
break;
}
if (nstate != IEEE80211_S_SCAN)
callout_stop(&sc->sc_scan_ch);
return (*sc->sc_mtbl.mt_newstate)(ic, nstate, arg);
}
2005-01-04 04:00:30 +03:00
/* Extend a 32-bit TSF timestamp to a 64-bit timestamp. */
static uint64_t
rtw_tsf_extend(struct rtw_regs *regs, uint32_t rstamp)
{
uint32_t tsftl, tsfth;
tsfth = RTW_READ(regs, RTW_TSFTRH);
tsftl = RTW_READ(regs, RTW_TSFTRL);
if (tsftl < rstamp) /* Compensate for rollover. */
tsfth--;
return ((uint64_t)tsfth << 32) | rstamp;
}
static void
2005-01-04 04:00:30 +03:00
rtw_ibss_merge(struct rtw_softc *sc, struct ieee80211_node *ni, uint32_t rstamp)
{
uint8_t tppoll;
2005-01-04 04:00:30 +03:00
if (le64toh(ni->ni_tstamp.tsf) < rtw_tsf_extend(&sc->sc_regs, rstamp))
return;
if (ieee80211_ibss_merge(ni) == ENETRESET) {
/* Stop beacon queue. Kick state machine to synchronize
* with the new IBSS.
*/
tppoll = RTW_READ8(&sc->sc_regs, RTW_TPPOLL);
tppoll |= RTW_TPPOLL_SBQ;
RTW_WRITE8(&sc->sc_regs, RTW_TPPOLL, tppoll);
(void)ieee80211_new_state(&sc->sc_ic, IEEE80211_S_RUN, -1);
2005-01-04 04:00:30 +03:00
}
return;
}
static void
rtw_recv_mgmt(struct ieee80211com *ic, struct mbuf *m,
struct ieee80211_node *ni, int subtype, int rssi, uint32_t rstamp)
{
struct ifnet *ifp = ic->ic_ifp;
struct rtw_softc *sc = (struct rtw_softc *)ifp->if_softc;
2005-01-04 04:00:30 +03:00
(*sc->sc_mtbl.mt_recv_mgmt)(ic, m, ni, subtype, rssi, rstamp);
switch (subtype) {
case IEEE80211_FC0_SUBTYPE_PROBE_RESP:
case IEEE80211_FC0_SUBTYPE_BEACON:
2005-01-04 04:00:30 +03:00
if (ic->ic_opmode != IEEE80211_M_IBSS ||
ic->ic_state != IEEE80211_S_RUN)
return;
rtw_ibss_merge(sc, ni, rstamp);
break;
default:
break;
}
return;
}
static struct ieee80211_node *
rtw_node_alloc(struct ieee80211_node_table *nt)
{
struct ifnet *ifp = nt->nt_ic->ic_ifp;
struct rtw_softc *sc = (struct rtw_softc *)ifp->if_softc;
struct ieee80211_node *ni = (*sc->sc_mtbl.mt_node_alloc)(nt);
DPRINTF(sc, RTW_DEBUG_NODE,
("%s: alloc node %p\n", sc->sc_dev.dv_xname, ni));
return ni;
}
static void
rtw_node_free(struct ieee80211_node *ni)
{
struct ieee80211com *ic = ni->ni_ic;
struct ifnet *ifp = ic->ic_ifp;
struct rtw_softc *sc = (struct rtw_softc *)ifp->if_softc;
DPRINTF(sc, RTW_DEBUG_NODE,
("%s: freeing node %p %s\n", sc->sc_dev.dv_xname, ni,
ether_sprintf(ni->ni_bssid)));
(*sc->sc_mtbl.mt_node_free)(ni);
}
static int
rtw_media_change(struct ifnet *ifp)
{
int error;
error = ieee80211_media_change(ifp);
if (error == ENETRESET) {
if ((ifp->if_flags & (IFF_RUNNING|IFF_UP)) ==
(IFF_RUNNING|IFF_UP))
rtw_init(ifp); /* XXX lose error */
error = 0;
}
return error;
}
static void
rtw_media_status(struct ifnet *ifp, struct ifmediareq *imr)
{
struct rtw_softc *sc = ifp->if_softc;
if ((sc->sc_flags & RTW_F_ENABLED) == 0) {
imr->ifm_active = IFM_IEEE80211 | IFM_NONE;
imr->ifm_status = 0;
return;
}
ieee80211_media_status(ifp, imr);
}
void
rtw_power(int why, void *arg)
{
struct rtw_softc *sc = arg;
struct ifnet *ifp = &sc->sc_if;
int s;
DPRINTF(sc, RTW_DEBUG_PWR,
("%s: rtw_power(%d,)\n", sc->sc_dev.dv_xname, why));
s = splnet();
switch (why) {
case PWR_STANDBY:
/* XXX do nothing. */
break;
case PWR_SUSPEND:
rtw_stop(ifp, 0);
if (sc->sc_power != NULL)
(*sc->sc_power)(sc, why);
break;
case PWR_RESUME:
if (ifp->if_flags & IFF_UP) {
if (sc->sc_power != NULL)
(*sc->sc_power)(sc, why);
rtw_init(ifp);
}
break;
case PWR_SOFTSUSPEND:
case PWR_SOFTSTANDBY:
case PWR_SOFTRESUME:
break;
}
splx(s);
}
/* rtw_shutdown: make sure the interface is stopped at reboot time. */
void
rtw_shutdown(void *arg)
{
struct rtw_softc *sc = arg;
rtw_stop(&sc->sc_if, 1);
}
static __inline void
rtw_setifprops(struct ifnet *ifp, const char *dvname, void *softc)
{
(void)memcpy(ifp->if_xname, dvname, IFNAMSIZ);
ifp->if_softc = softc;
ifp->if_flags = IFF_SIMPLEX | IFF_BROADCAST | IFF_MULTICAST |
IFF_NOTRAILERS;
ifp->if_ioctl = rtw_ioctl;
ifp->if_start = rtw_start;
ifp->if_watchdog = rtw_watchdog;
ifp->if_init = rtw_init;
ifp->if_stop = rtw_stop;
}
static __inline void
rtw_set80211props(struct ieee80211com *ic)
{
int nrate;
ic->ic_phytype = IEEE80211_T_DS;
ic->ic_opmode = IEEE80211_M_STA;
ic->ic_caps = IEEE80211_C_PMGT | IEEE80211_C_IBSS |
IEEE80211_C_HOSTAP | IEEE80211_C_MONITOR;
nrate = 0;
ic->ic_sup_rates[IEEE80211_MODE_11B].rs_rates[nrate++] =
IEEE80211_RATE_BASIC | 2;
ic->ic_sup_rates[IEEE80211_MODE_11B].rs_rates[nrate++] =
IEEE80211_RATE_BASIC | 4;
ic->ic_sup_rates[IEEE80211_MODE_11B].rs_rates[nrate++] = 11;
ic->ic_sup_rates[IEEE80211_MODE_11B].rs_rates[nrate++] = 22;
ic->ic_sup_rates[IEEE80211_MODE_11B].rs_nrates = nrate;
}
static __inline void
rtw_set80211methods(struct rtw_mtbl *mtbl, struct ieee80211com *ic)
{
mtbl->mt_newstate = ic->ic_newstate;
ic->ic_newstate = rtw_newstate;
mtbl->mt_recv_mgmt = ic->ic_recv_mgmt;
ic->ic_recv_mgmt = rtw_recv_mgmt;
mtbl->mt_node_free = ic->ic_node_free;
ic->ic_node_free = rtw_node_free;
mtbl->mt_node_alloc = ic->ic_node_alloc;
ic->ic_node_alloc = rtw_node_alloc;
ic->ic_crypto.cs_key_delete = rtw_key_delete;
ic->ic_crypto.cs_key_set = rtw_key_set;
ic->ic_crypto.cs_key_update_begin = rtw_key_update_begin;
ic->ic_crypto.cs_key_update_end = rtw_key_update_end;
}
static __inline void
rtw_establish_hooks(struct rtw_hooks *hooks, const char *dvname,
void *arg)
{
/*
* Make sure the interface is shutdown during reboot.
*/
hooks->rh_shutdown = shutdownhook_establish(rtw_shutdown, arg);
if (hooks->rh_shutdown == NULL)
printf("%s: WARNING: unable to establish shutdown hook\n",
dvname);
/*
* Add a suspend hook to make sure we come back up after a
* resume.
*/
hooks->rh_power = powerhook_establish(rtw_power, arg);
if (hooks->rh_power == NULL)
printf("%s: WARNING: unable to establish power hook\n",
dvname);
}
static __inline void
rtw_disestablish_hooks(struct rtw_hooks *hooks, const char *dvname,
void *arg)
{
if (hooks->rh_shutdown != NULL)
shutdownhook_disestablish(hooks->rh_shutdown);
if (hooks->rh_power != NULL)
powerhook_disestablish(hooks->rh_power);
}
static __inline void
rtw_init_radiotap(struct rtw_softc *sc)
{
memset(&sc->sc_rxtapu, 0, sizeof(sc->sc_rxtapu));
sc->sc_rxtap.rr_ihdr.it_len = htole16(sizeof(sc->sc_rxtapu));
sc->sc_rxtap.rr_ihdr.it_present = htole32(RTW_RX_RADIOTAP_PRESENT);
memset(&sc->sc_txtapu, 0, sizeof(sc->sc_txtapu));
sc->sc_txtap.rt_ihdr.it_len = htole16(sizeof(sc->sc_txtapu));
sc->sc_txtap.rt_ihdr.it_present = htole32(RTW_TX_RADIOTAP_PRESENT);
}
static int
rtw_txsoft_blk_setup(struct rtw_txsoft_blk *tsb, u_int qlen)
{
SIMPLEQ_INIT(&tsb->tsb_dirtyq);
SIMPLEQ_INIT(&tsb->tsb_freeq);
tsb->tsb_ndesc = qlen;
tsb->tsb_desc = malloc(qlen * sizeof(*tsb->tsb_desc), M_DEVBUF,
M_NOWAIT);
if (tsb->tsb_desc == NULL)
return ENOMEM;
return 0;
}
static void
rtw_txsoft_blk_cleanup_all(struct rtw_softc *sc)
{
int pri;
struct rtw_txsoft_blk *tsb;
for (pri = 0; pri < RTW_NTXPRI; pri++) {
tsb = &sc->sc_txsoft_blk[pri];
free(tsb->tsb_desc, M_DEVBUF);
tsb->tsb_desc = NULL;
}
}
static int
rtw_txsoft_blk_setup_all(struct rtw_softc *sc)
{
int pri, rc = 0;
int qlen[RTW_NTXPRI] =
{RTW_TXQLENLO, RTW_TXQLENMD, RTW_TXQLENHI, RTW_TXQLENBCN};
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
struct rtw_txsoft_blk *tsbs;
tsbs = sc->sc_txsoft_blk;
for (pri = 0; pri < RTW_NTXPRI; pri++) {
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rc = rtw_txsoft_blk_setup(&tsbs[pri], qlen[pri]);
if (rc != 0)
break;
}
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
tsbs[RTW_TXPRILO].tsb_poll = RTW_TPPOLL_LPQ | RTW_TPPOLL_SLPQ;
tsbs[RTW_TXPRIMD].tsb_poll = RTW_TPPOLL_NPQ | RTW_TPPOLL_SNPQ;
tsbs[RTW_TXPRIHI].tsb_poll = RTW_TPPOLL_HPQ | RTW_TPPOLL_SHPQ;
tsbs[RTW_TXPRIBCN].tsb_poll = RTW_TPPOLL_BQ | RTW_TPPOLL_SBQ;
return rc;
}
static void
rtw_txdesc_blk_setup(struct rtw_txdesc_blk *tdb, struct rtw_txdesc *desc,
u_int ndesc, bus_addr_t ofs, bus_addr_t physbase)
{
tdb->tdb_ndesc = ndesc;
tdb->tdb_desc = desc;
tdb->tdb_physbase = physbase;
tdb->tdb_ofs = ofs;
(void)memset(tdb->tdb_desc, 0,
sizeof(tdb->tdb_desc[0]) * tdb->tdb_ndesc);
rtw_txdesc_blk_init(tdb);
tdb->tdb_next = 0;
}
static void
rtw_txdesc_blk_setup_all(struct rtw_softc *sc)
{
rtw_txdesc_blk_setup(&sc->sc_txdesc_blk[RTW_TXPRILO],
&sc->sc_descs->hd_txlo[0], RTW_NTXDESCLO,
RTW_RING_OFFSET(hd_txlo), RTW_RING_BASE(sc, hd_txlo));
rtw_txdesc_blk_setup(&sc->sc_txdesc_blk[RTW_TXPRIMD],
&sc->sc_descs->hd_txmd[0], RTW_NTXDESCMD,
RTW_RING_OFFSET(hd_txmd), RTW_RING_BASE(sc, hd_txmd));
rtw_txdesc_blk_setup(&sc->sc_txdesc_blk[RTW_TXPRIHI],
&sc->sc_descs->hd_txhi[0], RTW_NTXDESCHI,
RTW_RING_OFFSET(hd_txhi), RTW_RING_BASE(sc, hd_txhi));
rtw_txdesc_blk_setup(&sc->sc_txdesc_blk[RTW_TXPRIBCN],
&sc->sc_descs->hd_bcn[0], RTW_NTXDESCBCN,
RTW_RING_OFFSET(hd_bcn), RTW_RING_BASE(sc, hd_bcn));
}
static struct rtw_rf *
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_rf_attach(struct rtw_softc *sc, enum rtw_rfchipid rfchipid, int digphy)
{
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
rtw_rf_write_t rf_write;
struct rtw_rf *rf;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
switch (rfchipid) {
default:
rf_write = rtw_rf_hostwrite;
break;
case RTW_RFCHIPID_INTERSIL:
case RTW_RFCHIPID_PHILIPS:
case RTW_RFCHIPID_GCT: /* XXX a guess */
case RTW_RFCHIPID_RFMD:
rf_write = (rtw_host_rfio) ? rtw_rf_hostwrite : rtw_rf_macwrite;
break;
}
switch (rfchipid) {
case RTW_RFCHIPID_MAXIM:
rf = rtw_max2820_create(&sc->sc_regs, rf_write, 0);
sc->sc_pwrstate_cb = rtw_maxim_pwrstate;
break;
case RTW_RFCHIPID_PHILIPS:
rf = rtw_sa2400_create(&sc->sc_regs, rf_write, digphy);
sc->sc_pwrstate_cb = rtw_philips_pwrstate;
break;
case RTW_RFCHIPID_RFMD:
/* XXX RFMD has no RF constructor */
sc->sc_pwrstate_cb = rtw_rfmd_pwrstate;
/*FALLTHROUGH*/
default:
return NULL;
}
rf->rf_continuous_tx_cb =
(rtw_continuous_tx_cb_t)rtw_continuous_tx_enable;
rf->rf_continuous_tx_arg = (void *)sc;
return rf;
}
/* Revision C and later use a different PHY delay setting than
* revisions A and B.
*/
static uint8_t
rtw_check_phydelay(struct rtw_regs *regs, uint32_t old_rcr)
{
#define REVAB (RTW_RCR_MXDMA_UNLIMITED | RTW_RCR_AICV)
#define REVC (REVAB | RTW_RCR_RXFTH_WHOLE)
uint8_t phydelay = LSHIFT(0x6, RTW_PHYDELAY_PHYDELAY);
RTW_WRITE(regs, RTW_RCR, REVAB);
RTW_WBW(regs, RTW_RCR, RTW_RCR);
RTW_WRITE(regs, RTW_RCR, REVC);
RTW_WBR(regs, RTW_RCR, RTW_RCR);
if ((RTW_READ(regs, RTW_RCR) & REVC) == REVC)
phydelay |= RTW_PHYDELAY_REVC_MAGIC;
RTW_WRITE(regs, RTW_RCR, old_rcr); /* restore RCR */
RTW_SYNC(regs, RTW_RCR, RTW_RCR);
return phydelay;
#undef REVC
}
void
rtw_attach(struct rtw_softc *sc)
{
struct ifnet *ifp = &sc->sc_if;
struct ieee80211com *ic = &sc->sc_ic;
struct rtw_txsoft_blk *tsb;
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
int pri, rc;
rtw_cipher_wep = ieee80211_cipher_wep;
rtw_cipher_wep.ic_decap = rtw_wep_decap;
NEXT_ATTACH_STATE(sc, DETACHED);
switch (RTW_READ(&sc->sc_regs, RTW_TCR) & RTW_TCR_HWVERID_MASK) {
case RTW_TCR_HWVERID_F:
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
sc->sc_hwverid = 'F';
break;
case RTW_TCR_HWVERID_D:
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
sc->sc_hwverid = 'D';
break;
default:
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
sc->sc_hwverid = '?';
break;
}
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
printf("%s: hardware version %c\n", sc->sc_dev.dv_xname,
sc->sc_hwverid);
rc = bus_dmamem_alloc(sc->sc_dmat, sizeof(struct rtw_descs),
RTW_DESC_ALIGNMENT, 0, &sc->sc_desc_segs, 1, &sc->sc_desc_nsegs,
0);
if (rc != 0) {
printf("%s: could not allocate hw descriptors, error %d\n",
sc->sc_dev.dv_xname, rc);
goto err;
}
NEXT_ATTACH_STATE(sc, FINISH_DESC_ALLOC);
rc = bus_dmamem_map(sc->sc_dmat, &sc->sc_desc_segs,
sc->sc_desc_nsegs, sizeof(struct rtw_descs),
(caddr_t*)&sc->sc_descs, BUS_DMA_COHERENT);
if (rc != 0) {
printf("%s: could not map hw descriptors, error %d\n",
sc->sc_dev.dv_xname, rc);
goto err;
}
NEXT_ATTACH_STATE(sc, FINISH_DESC_MAP);
rc = bus_dmamap_create(sc->sc_dmat, sizeof(struct rtw_descs), 1,
sizeof(struct rtw_descs), 0, 0, &sc->sc_desc_dmamap);
if (rc != 0) {
printf("%s: could not create DMA map for hw descriptors, "
"error %d\n", sc->sc_dev.dv_xname, rc);
goto err;
}
NEXT_ATTACH_STATE(sc, FINISH_DESCMAP_CREATE);
sc->sc_rxdesc_blk.rdb_dmat = sc->sc_dmat;
sc->sc_rxdesc_blk.rdb_dmamap = sc->sc_desc_dmamap;
for (pri = 0; pri < RTW_NTXPRI; pri++) {
sc->sc_txdesc_blk[pri].tdb_dmat = sc->sc_dmat;
sc->sc_txdesc_blk[pri].tdb_dmamap = sc->sc_desc_dmamap;
}
rc = bus_dmamap_load(sc->sc_dmat, sc->sc_desc_dmamap, sc->sc_descs,
sizeof(struct rtw_descs), NULL, 0);
if (rc != 0) {
printf("%s: could not load DMA map for hw descriptors, "
"error %d\n", sc->sc_dev.dv_xname, rc);
goto err;
}
NEXT_ATTACH_STATE(sc, FINISH_DESCMAP_LOAD);
if (rtw_txsoft_blk_setup_all(sc) != 0)
goto err;
NEXT_ATTACH_STATE(sc, FINISH_TXCTLBLK_SETUP);
rtw_txdesc_blk_setup_all(sc);
NEXT_ATTACH_STATE(sc, FINISH_TXDESCBLK_SETUP);
sc->sc_rxdesc_blk.rdb_desc = &sc->sc_descs->hd_rx[0];
for (pri = 0; pri < RTW_NTXPRI; pri++) {
tsb = &sc->sc_txsoft_blk[pri];
if ((rc = rtw_txdesc_dmamaps_create(sc->sc_dmat,
&tsb->tsb_desc[0], tsb->tsb_ndesc)) != 0) {
printf("%s: could not load DMA map for "
"hw tx descriptors, error %d\n",
sc->sc_dev.dv_xname, rc);
goto err;
}
}
NEXT_ATTACH_STATE(sc, FINISH_TXMAPS_CREATE);
if ((rc = rtw_rxdesc_dmamaps_create(sc->sc_dmat, &sc->sc_rxsoft[0],
RTW_RXQLEN)) != 0) {
printf("%s: could not load DMA map for hw rx descriptors, "
"error %d\n", sc->sc_dev.dv_xname, rc);
goto err;
}
NEXT_ATTACH_STATE(sc, FINISH_RXMAPS_CREATE);
/* Reset the chip to a known state. */
if (rtw_reset(sc) != 0)
goto err;
NEXT_ATTACH_STATE(sc, FINISH_RESET);
sc->sc_rcr = RTW_READ(&sc->sc_regs, RTW_RCR);
if ((sc->sc_rcr & RTW_RCR_9356SEL) != 0)
sc->sc_flags |= RTW_F_9356SROM;
if (rtw_srom_read(&sc->sc_regs, sc->sc_flags, &sc->sc_srom,
sc->sc_dev.dv_xname) != 0)
goto err;
NEXT_ATTACH_STATE(sc, FINISH_READ_SROM);
if (rtw_srom_parse(&sc->sc_srom, &sc->sc_flags, &sc->sc_csthr,
&sc->sc_rfchipid, &sc->sc_rcr, &sc->sc_locale,
sc->sc_dev.dv_xname) != 0) {
printf("%s: attach failed, malformed serial ROM\n",
sc->sc_dev.dv_xname);
goto err;
}
printf("%s: %s PHY\n", sc->sc_dev.dv_xname,
((sc->sc_flags & RTW_F_DIGPHY) != 0) ? "digital" : "analog");
printf("%s: CS threshold %u\n", sc->sc_dev.dv_xname, sc->sc_csthr);
NEXT_ATTACH_STATE(sc, FINISH_PARSE_SROM);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
sc->sc_rf = rtw_rf_attach(sc, sc->sc_rfchipid,
sc->sc_flags & RTW_F_DIGPHY);
if (sc->sc_rf == NULL) {
printf("%s: attach failed, could not attach RF\n",
sc->sc_dev.dv_xname);
goto err;
}
NEXT_ATTACH_STATE(sc, FINISH_RF_ATTACH);
sc->sc_phydelay = rtw_check_phydelay(&sc->sc_regs, sc->sc_rcr);
RTW_DPRINTF(RTW_DEBUG_ATTACH,
("%s: PHY delay %d\n", sc->sc_dev.dv_xname, sc->sc_phydelay));
if (sc->sc_locale == RTW_LOCALE_UNKNOWN)
rtw_identify_country(&sc->sc_regs, &sc->sc_locale);
rtw_init_channels(sc->sc_locale, &sc->sc_ic.ic_channels,
sc->sc_dev.dv_xname);
if (rtw_identify_sta(&sc->sc_regs, &sc->sc_ic.ic_myaddr,
sc->sc_dev.dv_xname) != 0)
goto err;
NEXT_ATTACH_STATE(sc, FINISH_ID_STA);
rtw_setifprops(ifp, sc->sc_dev.dv_xname, (void*)sc);
IFQ_SET_READY(&ifp->if_snd);
sc->sc_ic.ic_ifp = ifp;
rtw_set80211props(&sc->sc_ic);
rtw_led_attach(&sc->sc_led_state, (void *)sc);
Move the register access mode into struct rtw_regs. Change rtw_set_access, rtw_set_access1 to match. Add a subroutine for setting WEP keys. WEP isn't quite finished, because I have to add the WEP header to Tx packets. Implement the SIOCS80211NWKEY ioctl for setting WEP keys. Program the LEDs based on operating state and packet activity. * On a Revision F RTL8180, blink LED1 at 1Hz to indicate scan/authenticate/associate states. In the run state, turn LED1 on. In every state, blink LED1 at 5Hz to indicate non-beacon tx/rx activity. I would like to use two LEDs, but in all my Rev. F instances, LED0 is not wired to an LED; instead, the first LED is wired to indicate that the card's power is on. * On a Revision D RTL8180, program the LEDs so that LED0 indicates Tx, and LED1 indicates Rx. The Rx LED will blink annoyingly if there are beacons in the air, but at least the Tx LED is useful. * Store the hardware revision in the softc to support my futile attempt at programming LEDs for both Rev. D and Rev. F parts; I never did get Rev. D LEDs to work right. * Add a debug flag RTW_DEBUG_LED for the LED transitions. Add RTW_TPPOLL_ALL, RTW_TPPOLL_SALL to start and stop, respectively, all of the transmit rings. In ad hoc mode, allocate a beacon and load it into the beacon ring. Start the ring. In one trial, the card re-transmitted the beacon ring's contents several times before stopping. More programming and testing for ad hoc mode is necessary. I'm not setting the beacon flag in the transmit descriptor. Revamp the transmit section to make better use of all the transmit rings: beacon queue, high-, low-, and medium-priority rings. Put beacon frames on the beacon ring. All other management frames, and data frames, go on the medium-priority ring. Power-save data frames go on the high-priority ring. (Note that powersaving is not implemented!) This is a work in progress. Send all 802.11 Management frames at 1Mbps. After we put a packet on a transmit ring, tickle the right bit in the TPPOLL to tell RTL8180. Stop all rings on error and in rtw_stop. Use the RF chip type, not the RTL8180 revision, to choose between host- and MAC-controlled RF serial I/O. Now the Netgear MA521 works. Remove bogus definition of bit RTW_TPPOLL_FSWINT.
2005-01-16 14:50:43 +03:00
/*
* Call MI attach routines.
*/
if_attach(ifp);
ieee80211_ifattach(&sc->sc_ic);
rtw_set80211methods(&sc->sc_mtbl, &sc->sc_ic);
/* possibly we should fill in our own sc_send_prresp, since
* the RTL8180 is probably sending probe responses in ad hoc
* mode.
*/
/* complete initialization */
ieee80211_media_init(&sc->sc_ic, rtw_media_change, rtw_media_status);
callout_init(&sc->sc_scan_ch);
rtw_init_radiotap(sc);
#if NBPFILTER > 0
bpfattach2(ifp, DLT_IEEE802_11_RADIO,
sizeof(struct ieee80211_frame) + 64, &sc->sc_radiobpf);
#endif
rtw_establish_hooks(&sc->sc_hooks, sc->sc_dev.dv_xname, (void*)sc);
NEXT_ATTACH_STATE(sc, FINISHED);
ieee80211_announce(ic);
return;
err:
rtw_detach(sc);
return;
}
int
rtw_detach(struct rtw_softc *sc)
{
struct ifnet *ifp = &sc->sc_if;
int pri;
sc->sc_flags |= RTW_F_INVALID;
switch (sc->sc_attach_state) {
case FINISHED:
rtw_stop(ifp, 1);
Miscellaneous changes. Details below. Important changes flagged with []. Using the driver with my Linksys WPC11 ver. 4, it seems to be receiving packets for a change. The WPC11 ver. 4 has a Maxim RF section. My no-name rtw with Philips RF section still does not receive any packets. Keep access-level (analog params > config[0123] registers > none) in sc_access. Add rtw_set_access for changing the access level. Make rtw_continuous_tx_enable and other subroutines use rtw_set_access instead of rtw_config0123_enable and rtw_anaparm_enable. Factor part of the chip-reset code into rtw_chip_reset1. Change the 'struct foo (*bar)[N]'-style arguments to 'struct foo *bar'-style arguments. Consolidate software/hardware Tx/Rx ring setup in rtw_hwring_setup, rtw_swring_setup. Add a new constant, SA2400_OPMODE_DEFAULTS, for the bits that we *always* set in the SA2400 OPMODE register. Factor some code out into rtw_sa2400_calibrate. (Inspired by the Linux driver.) [] When the receiver goes into underrun/overflow state, call a new subroutine, rtw_kick() that stops the Rx/Tx processes, resets the chip, reinitializes the Tx/Rx rings, and restarts Rx/Tx processes. (Inspired by the Linux driver.) [] In rtw_intr_rx, check for too-short packets before calling ieee80211_find_rxnode. I believe this will prevent a repeat of the MCHK exception I saw once on macppc. [] Use seconds-elapased as well as microseconds-elapsed to set the next "due date" for the timeout interrupt. This keeps the driver from programming the timeout to expire too early. [] In rtw_intr, read RTW_ISR at most 10 times, then get out. If the interface is not enabled (RTW_F_ENABLED), then get out. [] In rtw_stop, get out if the interface is not enabled (RTW_F_ENABLED). Block IPL_NET interrupts. Don't read/write any registers if the interface is invalid (RTW_F_INVALID). [] Call rtw_stop in rtw_detach.
2004-12-12 09:37:59 +03:00
rtw_disestablish_hooks(&sc->sc_hooks, sc->sc_dev.dv_xname,
(void*)sc);
callout_stop(&sc->sc_scan_ch);
ieee80211_ifdetach(&sc->sc_ic);
if_detach(ifp);
break;
case FINISH_ID_STA:
case FINISH_RF_ATTACH:
rtw_rf_destroy(sc->sc_rf);
sc->sc_rf = NULL;
/*FALLTHROUGH*/
case FINISH_PARSE_SROM:
case FINISH_READ_SROM:
rtw_srom_free(&sc->sc_srom);
/*FALLTHROUGH*/
case FINISH_RESET:
case FINISH_RXMAPS_CREATE:
rtw_rxdesc_dmamaps_destroy(sc->sc_dmat, &sc->sc_rxsoft[0],
RTW_RXQLEN);
/*FALLTHROUGH*/
case FINISH_TXMAPS_CREATE:
for (pri = 0; pri < RTW_NTXPRI; pri++) {
rtw_txdesc_dmamaps_destroy(sc->sc_dmat,
sc->sc_txsoft_blk[pri].tsb_desc,
sc->sc_txsoft_blk[pri].tsb_ndesc);
}
/*FALLTHROUGH*/
case FINISH_TXDESCBLK_SETUP:
case FINISH_TXCTLBLK_SETUP:
rtw_txsoft_blk_cleanup_all(sc);
/*FALLTHROUGH*/
case FINISH_DESCMAP_LOAD:
bus_dmamap_unload(sc->sc_dmat, sc->sc_desc_dmamap);
/*FALLTHROUGH*/
case FINISH_DESCMAP_CREATE:
bus_dmamap_destroy(sc->sc_dmat, sc->sc_desc_dmamap);
/*FALLTHROUGH*/
case FINISH_DESC_MAP:
bus_dmamem_unmap(sc->sc_dmat, (caddr_t)sc->sc_descs,
sizeof(struct rtw_descs));
/*FALLTHROUGH*/
case FINISH_DESC_ALLOC:
bus_dmamem_free(sc->sc_dmat, &sc->sc_desc_segs,
sc->sc_desc_nsegs);
/*FALLTHROUGH*/
case DETACHED:
NEXT_ATTACH_STATE(sc, DETACHED);
break;
}
return 0;
}
int
rtw_activate(struct device *self, enum devact act)
{
struct rtw_softc *sc = (struct rtw_softc *)self;
int rc = 0, s;
s = splnet();
switch (act) {
case DVACT_ACTIVATE:
rc = EOPNOTSUPP;
break;
case DVACT_DEACTIVATE:
if_deactivate(&sc->sc_if);
break;
}
splx(s);
return rc;
}