NetBSD/sys/arch/arm32/shark/scr.c

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/* $NetBSD: scr.c,v 1.8 2000/03/19 19:14:42 tron Exp $ */
/*
* Copyright 1997
* Digital Equipment Corporation. All rights reserved.
*
* This software is furnished under license and may be used and
* copied only in accordance with the following terms and conditions.
* Subject to these conditions, you may download, copy, install,
* use, modify and distribute this software in source and/or binary
* form. No title or ownership is transferred hereby.
*
* 1) Any source code used, modified or distributed must reproduce
* and retain this copyright notice and list of conditions as
* they appear in the source file.
*
* 2) No right is granted to use any trade name, trademark, or logo of
* Digital Equipment Corporation. Neither the "Digital Equipment
* Corporation" name nor any trademark or logo of Digital Equipment
* Corporation may be used to endorse or promote products derived
* from this software without the prior written permission of
* Digital Equipment Corporation.
*
* 3) This software is provided "AS-IS" and any express or implied
* warranties, including but not limited to, any implied warranties
* of merchantability, fitness for a particular purpose, or
* non-infringement are disclaimed. In no event shall DIGITAL be
* liable for any damages whatsoever, and in particular, DIGITAL
* shall not be liable for special, indirect, consequential, or
* incidental damages or damages for lost profits, loss of
* revenue or loss of use, whether such damages arise in contract,
* negligence, tort, under statute, in equity, at law or otherwise,
* even if advised of the possibility of such damage.
*/
/*
**++
**
** FACILITY:
**
** Driver for smart card
**
** ABSTRACT:
**
** The driver provides access to a Smart Card for the DNARD.
**
** There is no Smart Card silicon. Several i/o pins
** connect to the pads on the Smart Card, and the driver is
** is responsible for driving the signals in accordance with
** ISO 7816-3 (the Smart Card spec)
**
** This driver puts a high load on the system due to the need
** to interrupt at a high rate (up to 50 Khz) during bit detection.
**
**
** The driver is dived into the standard top half ioctl, and bottom
** half interupt. The interrupt is FIQ, which requires its own stack.
** disable_interrupts and restore_interrupts must be used to protect from
** a FIQ. Since splxxx functions do not use this, the bottom half cannot
** use any standard functions (ie like wakeup, timeout, etc.
** Thus the communication from the bottom half
** to the top half uses a "done" bit called masterDone. This bit
** is set by the master state machine when all bottom half work is
** complete. The top half checks/sleeps on this masterDone bit.
**
** The FIQ is driven by Timer 2 (T2)in the sequoia. All times are
** referenced to T2 counts.
**
** The bottom half is done as a several linked state machines.
** The top level machine is the maserSM (ie master State Machine). This
** machine calls mid level protocol machines, ie ATRSM (Answer To Reset
** State Machine), t0SendSM (T=0 Send State Machine), and t0RecvSM (T=0 Recv
** State Machine). These mid level protocol machines in turn call low level
** bit-bashing machines, ie coldResetSM, t0SendByteSM, T0RecvByteSM.
**
** Smart Cards are driven in a command/response mode. Ie you issue a command
** to the Smart Card and it responds. This command/response mode is reflected
** in the structure of the driver. Ie the ioctl gets a command, it
** gives it to the bottom half to execute and goes to sleep. The bottom half
** executes the command and gets the response to from the card and then
** notifies the top half that it has completed. Commands usually complete
** in under a second.
**
**
**
** AUTHORS:
**
** E. J. Grohn
** Digital Equipment Corporation.
**
** CREATION DATE:
**
** 27-July-97
**
**--
*/
/*
**
** INCLUDE FILES
**
*/
1998-07-05 02:18:13 +04:00
#include "opt_ddb.h"
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/ioctl.h>
/* #include <sys/select.h> */
/* #include <sys/tty.h> */
#include <sys/proc.h>
/* #include <sys/user.h> */
#include <sys/conf.h>
/* #include <sys/file.h> */
/* #include <sys/uio.h> */
#include <sys/kernel.h>
/* #include <sys/syslog.h> */
#include <sys/types.h>
#include <sys/device.h>
#include <dev/isa/isavar.h>
#include <machine/cpufunc.h>
/* SCR_DEBUG is the master switch for turning on debugging */
//#define SCR_DEBUG 1
#ifdef SCR_DEBUG
#define KERNEL_DEBUG
#ifdef DDB
#define DEBUGGER printf("file = %s, line = %d\n",__FILE__,__LINE__);Debugger()
#else
#define DEBUGGER panic("file = %s, line = %d\n",__FILE__,__LINE__);
#endif
#else
#define DEBUGGER
#endif
#include <machine/kerndebug.h>
//#include <machine/intr.h>
#include <dev/ic/i8253reg.h>
#include <arch/arm32/shark/hat.h>
#include <arm32/shark/sequoia.h>
#include <machine/scrio.h>
/*
**
** MACRO DEFINITIONS
**
*/
#define scr_lcr scr_cfcr
/*
** Macro to extract the minor device number from the device Identifier
*/
#define SCRUNIT(x) (minor(x))
/*
** Macros to clear/set/test bit flags.
*/
#define SET(t, f) (t) |= (f)
#define CLR(t, f) (t) &= ~(f)
#define ISSET(t, f) ((t) & (f))
#define ISCLR(t, f) ( ((t) & (f)) == 0)
/*
** some macros to assist in debugging
*/
#ifdef SCR_DEBUG
#define KERNEL_DEBUG
#define ASSERT(f) do { if (!(f)) { DEBUGGER;} }while(0)
#define TOGGLE_TEST_PIN() scrToggleTestPin()
#define INVALID_STATE_CMD(sc,state,cmd) invalidStateCmd(sc,state,cmd,__LINE__);
#else
#define ASSERT(f)
#define TOGGLE_TEST_PIN()
//#define INVALID_STATE_CMD(sc,state,cmd) panic("scr: invalid state/cmd, sc = %X, state = %X, cmd = %X, line = %d\n",sc,state,cmd,__LINE__);
#define INVALID_STATE_CMD(sc,state,cmd) sc->bigTrouble = TRUE;
#endif
#ifndef FALSE
#define FALSE 0
#endif
#ifndef TRUE
#define TRUE 1
#endif
/*
** The first and last bytes of the debug control variables is reserved for
** the standard KERN_DEBUG_xxx macros, so we can tailor the middle two bytes
*/
#define SCRPROBE_DEBUG_INFO 0x00000100
#define SCRATTACH_DEBUG_INFO 0x00000200
#define SCROPEN_DEBUG_INFO 0x00000400
#define SCRCLOSE_DEBUG_INFO 0x00000800
#define SCRREAD_DEBUG_INFO 0x00001000
#define SCRWRITE_DEBUG_INFO 0x00002000
#define SCRIOCTL_DEBUG_INFO 0x00004000
#define MASTER_SM_DEBUG_INFO 0x00008000
#define COLD_RESET_SM_DEBUG_INFO 0x00010000
#define ATR_SM_DEBUG_INFO 0x00020000
#define T0_RECV_BYTE_SM_DEBUG_INFO 0x00040000
#define T0_SEND_BYTE_SM_DEBUG_INFO 0x00080000
#define T0_RECV_SM_DEBUG_INFO 0x00100000
#define T0_SEND_SM_DEBUG_INFO 0x00200000
int scrdebug = //SCRPROBE_DEBUG_INFO |
//SCRATTACH_DEBUG_INFO |
//SCROPEN_DEBUG_INFO |
//SCRCLOSE_DEBUG_INFO |
//SCRREAD_DEBUG_INFO |
//SCRWRITE_DEBUG_INFO |
//SCRIOCTL_DEBUG_INFO |
//MASTER_SM_DEBUG_INFO |
//COLD_RESET_SM_DEBUG_INFO|
//ATR_SM_DEBUG_INFO |
//T0_RECV_BYTE_SM_DEBUG_INFO |
//T0_SEND_BYTE_SM_DEBUG_INFO |
//T0_RECV_SM_DEBUG_INFO |
//T0_SEND_SM_DEBUG_INFO |
0;
/*
** the bottom half of the driver is done as several linked state machines
** below are all the states of the machines, and the commands that are
** sent to each machine
*/
/* commands to Master State Machine from ioctl */
#define mcOn 0x0100 /* ioctl on */
#define mcT0DataSend 0x0102 /* ioctl send */
#define mcT0DataRecv 0x0103 /* ioctl recv */
/* commands to Master State Machine from lower state machines */
#define mcColdReset 0x0105 /* cold reset finished */
#define mcATR 0x0106 /* ATR has finished */
#define mcT0Send 0x0108 /* T0 send finished */
#define mcT0Recv 0x010a /* T0 recv finished */
/* states in Master state machine (ms = Master State) */
#define msIdleOff 0x0200 /* in idle state, card powered off */
#define msColdReset 0x0201 /* turning on power, clock, reset */
#define msATR 0x0202 /* getting ATR sequence from card */
#define msIdleOn 0x0203 /* idle, put card powered on */
#define msT0Send 0x0204 /* sending T0 data */
#define msT0Recv 0x0205 /* recving T0 data */
/* commands to T0 send state machine */
#define t0scStart 0x0300 /* start */
#define t0scTWorkWaiting 0x0301 /* work waiting timeout */
/* states in T0 send state machine */
#define t0ssIdle 0x0400 /* idle state */
#define t0ssSendHeader 0x0401 /* send 5 header bytes */
#define t0ssRecvProcedure 0x0402 /* wait for procedure byte */
#define t0ssSendByte 0x0403 /* send 1 byte */
#define t0ssSendData 0x0404 /* send all bytes */
#define t0ssRecvSW1 0x0405 /* wait for sw1 */
#define t0ssRecvSW2 0x0406 /* wait for sw2 */
/* commands to T0 recv state machine */
#define t0rcStart 0x0500 /* start */
#define t0rcTWorkWaiting 0x0501 /* work waiting timeout */
/* states in T0 recv state machine */
#define t0rsIdle 0x0600 /* idle state */
#define t0rsSendHeader 0x0601 /* send 5 header bytes */
#define t0rsRecvProcedure 0x0602 /* wait for procedure byte */
#define t0rsRecvByte 0x0603 /* recv 1 byte */
#define t0rsRecvData 0x0604 /* recv all bytes */
#define t0rsRecvSW1 0x0605 /* wait for sw1 */
#define t0rsRecvSW2 0x0606 /* wait for sw2 */
/* commands to Cold Reset state machine */
#define crcStart 0x0900 /* start */
#define crcT2 0x0902 /* timeout T2 ISO 7816-3, P6, Figure 2 */
/* states in cold reset state machine */
#define crsIdle 0x0a00 /* idle */
#define crsT2Wait 0x0a01 /* wait for T2 ISO 7816-3.P6. Figure 2 */
/* commands to Answer To Reset (ATR) state machine */
#define atrcStart 0x0b00 /* start */
#define atrcT3 0x0b04 /* got T3 timeout */
#define atrcTWorkWaiting 0x0b05 /* work waiting timeout */
/* states in Answer To Reset (ATR) state machine */
#define atrsIdle 0x0c00 /* idle */
#define atrsTS 0x0c01 /* looking for TS, (initial bytes) */
#define atrsT0 0x0c02 /* looking for T0, (format bytes) */
#define atrsTABCD 0x0c03 /* looking for TAx (interface bytes)*/
#define atrsTK 0x0c04 /* looking for TK (history bytes) */
#define atrsTCK 0x0c05 /* looking for TCK (check bytes */
/* commands to T0 Recv Byte state machine */
#define t0rbcStart 0x0d00 /* start */
#define t0rbcAbort 0x0d01 /* abort */
#define t0rbcTFindStartEdge 0x0d02 /* start bit edge search */
#define t0rbcTFindStartMid 0x0d03 /* start bit mid search */
#define t0rbcTClockData 0x0d04 /* data bit search */
#define t0rbcTErrorStart 0x0d05 /* start to send error */
#define t0rbcTErrorStop 0x0d06 /* stop sending error */
/* states in T0 Recv Byte state machine */
#define t0rbsIdle 0x0e00 /* idle */
#define t0rbsFindStartEdge 0x0e01 /* looking for start bit */
#define t0rbsFindStartMid 0x0e02 /* looking for start bit */
#define t0rbsClockData 0x0e03 /* looking for data bits */
#define t0rbsSendError 0x0e04 /* output error bit */
/* commands to T0 Send Byte state machine */
#define t0sbcStart 0x0f00 /* start the machine */
#define t0sbcAbort 0x0f01 /* abort the machine */
#define t0sbcTGuardTime 0x0f02 /* guard time finished */
#define t0sbcTClockData 0x0f03 /* clock time finished */
#define t0sbcTError 0x0f04 /* start to send error */
#define t0sbcTResend 0x0f05 /* if parity error, then wait unfill we can re-send */
/* states in T0 Send Byte state machine */
#define t0sbsIdle 0x1000 /* idle */
#define t0sbsWaitGuardTime 0x1001 /* wait for guard time to finish */
#define t0sbsClockData 0x1002 /* clocking out data & parity */
#define t0sbsWaitError 0x1003 /* waiting for error indicator */
#define t0sbsWaitResend 0x1004 /* waiting to start re-send if error */
/*
** generic middle level state machine commands
** sent by T0 Send Byte & T0 recv Byte to T0 Send and T0 Recv
*/
#define gcT0RecvByte 0x1100 /* receive finished */
#define gcT0RecvByteErr 0x1101 /* receive got error */
#define gcT0SendByte 0x1102 /* send finished */
#define gcT0SendByteErr 0x1103 /* send got error */
/*
**
** below are definitions associated with Smart Card
**
*/
/*
** Frequency of clock sent to card
** NCI's card is running at 1/2 freq, so in debug we can make
** use of this to toggle more debug signals and still be within
** interrupt time budget
*/
#ifdef SCR_DEBUG
#define CARD_FREQ_DEF (3579000/2)
#else
#define CARD_FREQ_DEF (3579000)
#endif
/* byte logic level and msb/lsb coding */
#define CONVENTION_UNKOWN 0
#define CONVENTION_INVERSE 1
#define CONVENTION_DIRECT 2
#define CONVENIONT_INVERSE_ID 0x3f
#define CONVENTION_DIRECT_FIX 0x3b
#define CONVENTION_DIRECT_ID 0x23
/* macros that help us set the T2 count for bit bashing */
#define CLK_COUNT_START (((372 * TIMER_FREQ) / sc->cardFreq) /5)
#define CLK_COUNT_DATA (((372 * TIMER_FREQ) / sc->cardFreq) )
#define START_2_DATA 5
/* default settings to use if not specified in ATR */
#define N_DEFAULT 0 /* guard time default */
#define Fi_DEFAULT 372 /* clock rate conversion default */
#define Di_DEFAULT 1 /* bit rate adjustment factor */
#define Wi_DEFAULT 10 /* waiting time */
/* table for clock rate adjustment in ATR */
int FI2Fi[16] = {372, 372, 558, 744,1116,1488,1860, 0,
0, 512, 768,1024,1536,2048, 0, 0};
/* table for bit rate adjustment in ATR*/
int DI2Di[16] = { 0, 1, 2, 4, 8, 16, 32, 0,
12, 20, 0, 0, 0, 0, 0, 0};
/* values of atrY in the ATR sequence*/
#define ATR_Y_TA 0x10
#define ATR_Y_TB 0x20
#define ATR_Y_TC 0x40
#define ATR_Y_TD 0x80
/* T0,T1,etc information in ATR sequence*/
#define PROTOCOL_T0 0x0001 /* bit 0 for T0 */
#define PROTOCOL_T1 0x0002 /* bit 1 for T1 */
#define PROTOCOL_T2 0x0004 /* bit 2 for T2*/
#define PROTOCOL_T3 0x0008 /* bit 3 for T3*/
/* etc */
/* timeouts for various places - see ISO 7816-3 */
#define T_t2 ((300 * TIMER_FREQ) / sc->cardFreq)
#define T_t3 ((40000 * (TIMER_FREQ/1024)) / (sc->cardFreq/1024))
#define T_WORK_WAITING (((960 * sc->Wi * sc->Fi ) / (sc->cardFreq/1024)) * (TIMER_FREQ/1024))
#define PARITY_ERROR_MAX 3 /* maximum parity errors on 1 byte before giving up */
/*
** its possible for the HAT to wedge. If that happens, all timing is sick, so
** we use timeout below (driven of system sleeps) as a "watchdog"
*/
#define MAX_FIQ_TIME 5 /* maximum time we are willing to run the FIQ */
/* used to decode T0 commands */
#define CMD_BUF_INS_OFF 1 /* offset to INS in header */
#define CMD_BUF_DATA_LEN_OFF 4 /* offset to data length in header */
/*
**
** DATA STRUCTURES
**
*/
typedef unsigned char BYTE;
/* our soft c structure */
struct scr_softc
{
struct device dev;
int open;
/* configuration information */
int status; /* status to be returned */
int cardFreq; /* freq supplied to card */
int convention; /* ie direct or inverse */
int protocolType; /* bit 0 indicates T0, bit 1 indicates T1,etc */
int N; /* guard time */
int Fi; /* clock rate */
int Di; /* bit rate adjustment */
int Wi; /* work waiting time */
int clkCountStartRecv; /* count for clock start bits on recv */
int clkCountDataRecv; /* count for clock data bits on recv*/
int clkCountDataSend; /* count for clock data bits on send */
/* state machines */
int masterS ;
int t0RecvS;
int t0SendS;
int coldResetS;
int ATRS;
int t0RecvByteS;
int t0SendByteS;
/* extra stuff kept for t0send state machine */
int commandCount; /* number of command bytes sent */
int dataCount; /* number of data bytes send/recv */
int dataMax; /* max number of data bytes to send/recv */
/* extra stuff kept for t0RecvByteS, t0SendByteS machines */
void (*t0ByteParent) __P((struct scr_softc *,int)); /* state machine that is controlling this SM */
int shiftBits; /* number of bits shifted */
BYTE shiftByte; /* intermediate value of bit being shifted */
BYTE dataByte; /* actual value of byte */
int shiftParity; /* value of parity */
int shiftParityCount; /* number of retries due to parity error */
/* extra stuff kept for ATR machine */
int atrY; /* indicates if TA,TB,TC,TD is to follow */
int atrK; /* number of historical characters*/
int atrKCount; /* progressive could of historical characters*/
int atrTABCDx; /* the 'i' in TA(i), TB(i), TC(i) and TD(i) */
int atrFi; /* value of Fi */
int atrDi; /* value of Di */
int masterDone; /* flag used by bottom half to tell top half its done */
int bigTrouble; /* david/jim, remove this when the dust settles */
/* pointers used by ioctl */
ScrOn * pIoctlOn; /* pointer to on ioctl data */
ScrT0 * pIoctlT0; /* pointer to T0 ioctl data */
};
/* number of devices */
static int devices = 0;
/* used as reference for tsleep */
static int tsleepIdent;
/*
** only 1 device is using the hat at any one time
** variable below must be acquired using splhigh before using the hat
*/
static int hatLock = FALSE;
/*
** data structures associated with our timeout queue that we run for the
** bottom half of the driver
*/
/* timeout callout structure */
typedef struct callout_t
{
struct callout_t *c_next; /* next callout in queue */
struct scr_softc *c_sc; /* soft c */
int c_arg; /* function argument */
void (*c_func) __P((struct scr_softc*,int)); /* function to call */
int c_time; /* ticks to the event */
}Callout;
/* actual callout array */
#define SCR_CLK_CALLOUT_COUNT 10
static Callout scrClkCalloutArray[SCR_CLK_CALLOUT_COUNT];
/* callout lists */
static Callout *scrClkCallFree; /* free queue */
static Callout scrClkCallTodo; /* todo queue */
/*
** information kept for the clock/FIQ that drives our timeout queue
*/
static int scrClkEnable = 0; /* true if clock enabled */
static void myHatWedge(int nFIQs); /* callback that informs us if FIQ has wedged */
static int scrClkCount; /* number used to set t2 that drives FIQ */
#define HATSTACKSIZE 1024 /* size of stack used during a FIQ */
static unsigned char hatStack[HATSTACKSIZE]; /* actual stack used during a FIQ */
/*
**
** FUNCTIONAL PROTOTYPES
**
*/
/*
**
** functions in top half of driver
**
*/
/* configure routines */
int scrprobe __P((struct device *, void *, void *));
void scrattach __P((struct device *, struct device *, void *));
/* driver entry points routines */
int scropen __P((dev_t dev, int flag, int mode, struct proc *p));
int scrclose __P((dev_t dev, int flag, int mode, struct proc *p));
int scrread __P((dev_t dev, struct uio *uio, int flag));
int scrwrite __P((dev_t dev, struct uio *uio, int flag));
int scrioctl __P((dev_t dev, u_long cmd, caddr_t data, int flag, struct proc *p));
void scrstop __P((struct tty *tp, int flag));
static void initStates __P((struct scr_softc * sc));
/*
**
** functions in bottom half of driver
**
*/
/* top level state machine */
static void masterSM __P((struct scr_softc * sc,int cmd));
/* mid level state machines, ie protocols */
static void t0SendSM __P((struct scr_softc * sc,int cnd));
static void t0RecvSM __P((struct scr_softc * sc,int cnd));
static void ATRSM __P((struct scr_softc * sc,int cnd));
/* low level state machines, ie bash hardware bits */
static void coldResetSM __P((struct scr_softc * sc,int cnd));
static void t0SendByteSM __P((struct scr_softc * sc,int cnd));
static void t0RecvByteSM __P((struct scr_softc * sc,int cnd));
static void cardOff __P((struct scr_softc * sc));
/*
** functions used for our own timeout routines.
** we cannot use system ones as we are running at a spl level
** that can interrupt the system timeout routines
*/
2000-03-17 02:21:05 +03:00
static void scrClkInit __P((void));
static void scrClkStart __P((struct scr_softc* sc,int countPerTick));
static void scrClkAdj __P((int count));
static void scrClkStop __P((void));
static void hatClkIrq __P((int count));
static void scrTimeout __P((void (*func)(struct scr_softc*,int), struct scr_softc*, int arg, int count));
static void scrUntimeout __P((void (*func)(struct scr_softc*,int), struct scr_softc*, int arg));
/* debug functions */
#ifdef SCR_DEBUG
static void invalidStateCmd __P((struct scr_softc* sc,int state,int cmd, int line));
static char * getText __P((int x));
#endif
/* Declare the cdevsw and bdevsw entrypoint routines
*/
cdev_decl(scr);
bdev_decl(scr);
struct cfattach scr_ca =
{
sizeof(struct scr_softc), (cfmatch_t)scrprobe, scrattach
};
extern struct cfdriver scr_cd;
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** scrProbe
**
** This is the probe routine for the Smart Card. Because the
** Smart Card is hard wired, there is no probing to peform. The
** function ensures that a succesfull problem occurs only once.
**
** FORMAL PARAMETERS:
**
** parent - input : pointer to the parent device
** match - not used
** aux - output : pointer to an isa_attach_args structure.
**
** IMPLICIT INPUTS:
**
** none.
**
** IMPLICIT OUTPUTS:
**
** none.
**
** FUNCTION VALUE:
**
** 0 - Probe failed to find the requested device.
** 1 - Probe successfully talked to the device.
**
** SIDE EFFECTS:
**
** none.
**--
*/
int scrprobe(parent, match, aux)
struct device *parent;
void *match;
void *aux;
{
struct isa_attach_args *ia = aux;
int rv = 0;
KERN_DEBUG (scrdebug, SCRPROBE_DEBUG_INFO,("scrprobe: called, name = %s\n",
parent->dv_cfdata->cf_driver->cd_name));
if (strcmp(parent->dv_cfdata->cf_driver->cd_name, "ofisascr") == 0 &&
devices == 0)
{
/* set "devices" to ensure that we respond only once */
devices++;
/* tell the caller that we are not using any resource */
ia->ia_iosize = -1;
ia->ia_irq = -1;
ia->ia_msize = 0;
rv = 1;
KERN_DEBUG (scrdebug, SCRPROBE_DEBUG_INFO,("scrprobe: successful \n"));
}
return (rv);
} /* End scrprobe() */
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** scrattach
**
** Initialize the clock and state machines
**
** FORMAL PARAMETERS:
**
** parent - input : pointer to my parents device structure.
** self - output : pointer to my softc with device structure at front.
** aux - input : pointer to the isa_attach_args structure.
**
** IMPLICIT INPUTS:
**
** nill
**
** IMPLICIT OUTPUTS:
**
** scrconsinit - clock callout functions set
** state machines all at idle
**
** FUNCTION VALUE:
**
** none.
**
** SIDE EFFECTS:
**
** none.
**--
*/
void scrattach(parent, self, aux)
struct device *parent;
struct device *self;
void *aux;
{
struct scr_softc *sc = (void *)self;
printf("\n");
if (!strcmp(parent->dv_cfdata->cf_driver->cd_name, "ofisascr"))
{
KERN_DEBUG (scrdebug, SCRATTACH_DEBUG_INFO,("scrattach: called \n"));
/* set initial state machine values */
scrClkInit();
initStates(sc);
sc->open = FALSE;
}
else
{
panic("scrattach: not on an ISA bus, attach impossible");
} /* End else we aren't on ISA and we can't handle it */
return;
} /* End scrattach() */
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** initStates
**
** sets the state of all machines to idle
**
** FORMAL PARAMETERS:
**
** sc - Pointer to the softc structure.
**
** IMPLICIT INPUTS:
**
** nill
**
** IMPLICIT OUTPUTS:
**
** nill
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
static void initStates(struct scr_softc * sc)
{
sc->masterS = msIdleOff;
sc->t0RecvS = t0rsIdle;
sc->t0SendS = t0ssIdle;
sc->coldResetS = crsIdle;
sc->ATRS = atrsIdle;
sc->t0RecvByteS = t0rbsIdle;
sc->t0SendByteS = t0sbsIdle;
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** scrOpen
**
** Opens the driver. We only let the device be opened
** once for security reasons
**
** FORMAL PARAMETERS:
**
** dev - input : Device identifier consisting of major and minor numbers.
** flag - input : Indicates if this is a blocking I/O call.
** mode - not used.
** p - input : Pointer to the proc structure of the process
** performing the open.
**
** IMPLICIT INPUTS:
**
** none.
**
** IMPLICIT OUTPUTS:
**
** none.
**
** FUNCTION VALUE:
**
** ENXIO - invalid device specified for open.
** EBUSY - The unit is already open
**
** SIDE EFFECTS:
**
** none.
**--
*/
int scropen(dev, flag, mode, p)
dev_t dev;
int flag;
int mode;
struct proc *p;
{
int unit = SCRUNIT(dev);
struct scr_softc *sc;
KERN_DEBUG (scrdebug, SCROPEN_DEBUG_INFO,
("scropen: called with minor device %d and flag 0x%x\n",
unit, flag));
/* Sanity check the minor device number we have been instructed
** to open and set up our softc structure pointer.
*/
if (unit >= scr_cd.cd_ndevs)
{
KERN_DEBUG (scrdebug, SCROPEN_DEBUG_INFO,("\t scropen, return ENXIO\n"));
return (ENXIO);
}
sc = scr_cd.cd_devs[unit];
if (!sc)
{
KERN_DEBUG (scrdebug, SCROPEN_DEBUG_INFO,("\t scropen, return ENXIO\n"));
return (ENXIO);
}
// david,jim - remove ifdef this when NCI can cope with only 1 open
#if 0
if (sc->open)
{
KERN_DEBUG (scrdebug, SCROPEN_DEBUG_INFO,("\t scropen, return EBUSY\n"));
return (EBUSY);
}
/* set all initial conditions */
sc->open = TRUE;
#endif
KERN_DEBUG (scrdebug, SCROPEN_DEBUG_INFO,("scropen: success \n"));
/* Now invoke the line discipline open routine
*/
return 0;
} /* End scropen() */
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** This function closed the driver
**
** FORMAL PARAMETERS:
**
** dev - input : Device identifier consisting of major and minor numbers.
** flag - Not used.
** mode - Not used.
** p - Not used.
**
** IMPLICIT INPUTS:
**
** scr_cd - used to locate the softc structure for the device unit
** identified by dev.
**
** IMPLICIT OUTPUTS:
**
** The device is put into an idle state.
**
** FUNCTION VALUE:
**
** 0 - Always returns success.
**
** SIDE EFFECTS:
**
** none.
**--
*/
int scrclose(dev, flag, mode, p)
dev_t dev;
int flag;
int mode;
struct proc *p;
{
#if 0
int unit = SCRUNIT(dev);
struct scr_softc *sc = scr_cd.cd_devs[unit];
#endif
KERN_DEBUG (scrdebug, SCRCLOSE_DEBUG_INFO,
("scrclose: called for minor device %d flag 0x%x\n",
SCRUNIT(dev), flag));
// david,jim - remove ifdef this when NCI can cope with only 1 open
#if 0
/* Check we are open in the first place
*/
if (sc->open)
{
/* put everything in the idle state */
scrClkInit();
initStates(sc);
sc->open = FALSE;
}
else
{
KERN_DEBUG (scrdebug, SCRCLOSE_DEBUG_INFO,("\t scrclose, device not open\n"));
}
#endif
KERN_DEBUG (scrdebug, SCRCLOSE_DEBUG_INFO,("scrclose exiting\n"));
return(0);
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** scrwrite
**
** not supported
**
** FORMAL PARAMETERS:
**
** dev - input : Device identifier consisting of major and minor numbers.
** uio - input : Pointer to the user I/O information (ie. write data).
** flag - input : Information on how the I/O should be done (eg. blocking
** or non-blocking).
**
** IMPLICIT INPUTS:
**
**
** IMPLICIT OUTPUTS:
**
** none
**
** FUNCTION VALUE:
**
** Returns ENODEV
**
** SIDE EFFECTS:
**
** none
**--
*/
int
scrwrite(dev, uio, flag)
dev_t dev;
struct uio *uio;
int flag;
{
return ENODEV;
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** scrread
**
** not supported
**
** FORMAL PARAMETERS:
**
** dev - input : Device identifier consisting of major and minor numbers.
** uio - input : Pointer to the user I/O information (ie. read buffer).
** flag - input : Information on how the I/O should be done (eg. blocking
** or non-blocking).
**
** IMPLICIT INPUTS:
**
**
** IMPLICIT OUTPUTS:
**
** none
**
** FUNCTION VALUE:
**
** Returns ENODEV
**
** SIDE EFFECTS:
**
** none
**--
*/
int
scrread(dev, uio, flag)
dev_t dev;
struct uio *uio;
int flag;
{
return ENODEV;
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** scrstop
**
** should not be called
**
** FORMAL PARAMETERS:
**
** tp - Pointer to our tty structure.
** flag - Ignored.
**
** IMPLICIT INPUTS:
**
** none.
**
** IMPLICIT OUTPUTS:
**
** none.
**
** FUNCTION VALUE:
**
** none.
**
** SIDE EFFECTS:
**
** none.
**--
*/
void scrstop(tp, flag)
struct tty *tp;
int flag;
{
panic("scrstop: not implemented");
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** tty
**
** should not be called
**
** FORMAL PARAMETERS:
**
** dev - input : Device identifier consisting of major and minor numbers.
**
** IMPLICIT INPUTS:
**
**
** IMPLICIT OUTPUTS:
**
** none
**
** FUNCTION VALUE:
**
** null
**
** SIDE EFFECTS:
**
** none.
**--
*/
struct tty * scrtty(dev)
dev_t dev;
{
panic("scrtty: not implemented");
return NULL;
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** This routine is responsible for performing I/O controls.
**
** There are 4 commands. Status, On, T0 and Off.
**
** Status checks to see if the card is inserted. This command
** does not use the state machines
**
** On turns the card on and gets the ATR sequence from the card.
** This command does use the state machines
**
** T0 is used to read and write the card. This command does use
** the state machines
**
** Off turns the card off. This command does not use the state
** machines.
**
**
** FORMAL PARAMETERS:
**
** dev - input : Device identifier consisting of major and minor numbers.
** cmd - input : The requested IOCTL command to be performed.
** See scrio.h for details
**
**
** Bit Position { 3322222222221111111111
** { 10987654321098765432109876543210
** Meaning | DDDLLLLLLLLLLLLLGGGGGGGGCCCCCCCC
**
** D - Command direction, in/out/both.
** L - Command argument length.
** G - Command group, 't' used for tty.
** C - Actual command enumeration.
**
** data - input/output : Direction depends on the command.
** flag - input : Not used by us but passed to line discipline and ttioctl
** p - input : pointer to proc structure of user.
**
** IMPLICIT INPUTS:
**
** none.
**
** IMPLICIT OUTPUTS:
**
** sc->masterS state of master state machine
**
**
** FUNCTION VALUE:
**
** ENOTTY if not correct ioctl
**
**
** SIDE EFFECTS:
**
**--
*/
int
scrioctl(dev, cmd, data, flag, p)
dev_t dev;
u_long cmd;
caddr_t data;
int flag;
struct proc *p;
{
int unit = SCRUNIT(dev);
struct scr_softc* sc = scr_cd.cd_devs[unit];
int error = 0; /* error value returned */
int masterDoneRetries= 0; /* nuber of times we looked at masterDone */
int done; /* local copy of masterDone */
ScrStatus * pIoctlStatus; /* pointer to status ioctl */
ScrOff * pIoctlOff; /* pointer to off ioctl */
u_int savedInts; /* saved interrupts */
int s; /* saved spl value */
KERN_DEBUG (scrdebug, SCRIOCTL_DEBUG_INFO,
("scrioctl: called for device 0x%x, command 0x%lx, "
"flag 0x%x\n",
unit, cmd, flag));
switch (cmd)
{
/*
** get the status of the card, ie is it in, in but off, in and on
*/
case SCRIOSTATUS:
pIoctlStatus = (ScrStatus*)data;
if (scrGetDetect())
{
savedInts = disable_interrupts(I32_bit | F32_bit);
if (sc->masterS == msIdleOn)
{
pIoctlStatus->status = CARD_ON;
}
else
{
ASSERT(sc->masterS == msIdleOff);
pIoctlStatus->status = CARD_INSERTED;
}
restore_interrupts(savedInts);
}
else
{
pIoctlStatus->status = CARD_REMOVED;
}
break;
/*
** turn the card on and get the ATR sequence
*/
case SCRIOON:
sc->pIoctlOn = (ScrOn*)data;
// acquire the hat lock.
while (1)
{
s = splhigh();
if(!hatLock)
{
hatLock = TRUE;
splx(s);
break;
}
splx(s);
tsleep(&tsleepIdent ,PZERO,"hat", 1);
}
// check to see if the card is in
if(!scrGetDetect())
{
initStates(sc);
cardOff(sc);
// do not call scrClkInit() as it is idle already
sc->pIoctlOn->status = ERROR_CARD_REMOVED;
}
// check to see if we are already on
else if(sc->masterS == msIdleOn)
{
sc->pIoctlOn->status = ERROR_CARD_ON;
}
// card was in, card is off, so lets start it
else
{
// set up the top half
sc->masterDone = FALSE;
sc->bigTrouble = FALSE; /* david/jim, remove this when the dust settles */
// start bottom half
scrClkStart (sc,400);
savedInts = disable_interrupts(I32_bit | F32_bit);
masterSM(sc,mcOn);
restore_interrupts(savedInts);
// see if bottom half done
while (1)
{
// check that we have not looped too many times
if(masterDoneRetries >= MAX_FIQ_TIME * HZ)
{
//printf("MAX_FIQ_TIME reached \n");
// big problems, so reset bottom
savedInts = disable_interrupts(I32_bit | F32_bit);
scrClkInit();
initStates(sc);
cardOff(sc);
sc->status = ERROR_CARD_REMOVED;
sc->masterDone = TRUE;
restore_interrupts(savedInts);
// dont stop clock, done at bottom of case
}
masterDoneRetries ++;
// get done bit
savedInts = disable_interrupts(I32_bit | F32_bit);
done = sc->masterDone;
restore_interrupts(savedInts);
// see if all done
if(done)
{
break;
}
// wait for a while
tsleep(&tsleepIdent ,PZERO,"hat", 1);
}
// stop bottom half
scrClkStop();
/* need to fix up count bits in non hat interrupt time, so */
if (sc->status == ERROR_OK)
{
sc->clkCountStartRecv = CLK_COUNT_START;
sc->clkCountDataRecv = sc->clkCountStartRecv * START_2_DATA;
sc->clkCountDataSend = CLK_COUNT_DATA;
}
/* takes while to turn off all lines, so keep out of hat */
if (sc->masterS != msIdleOn)
{
cardOff(sc);
}
// get the status back from the state machine
sc->pIoctlOn->status = sc->status;
}
// release the hat lock.
s = splhigh();
ASSERT(hatlock);
hatLock = FALSE;
splx(s);
// david,jim hack to stop ioctl memcpy problem, to be removed when problem fixed ejg
if (sc->pIoctlOn->status != ERROR_OK)
{
sc->pIoctlOn->atrLen = 0;
}
break;
/*
** turn the card off
*/
case SCRIOOFF:
pIoctlOff = (ScrOff*)data;
// card off does not requires any state processing, so do work here
initStates(sc);
cardOff(sc);
// do not call scrClkInit() as it is idle already
pIoctlOff->status = ERROR_OK;
break;
/*
** do a T0 read or write
*/
case SCRIOT0:
sc->pIoctlT0 = (ScrT0*)data;
// acquire the hat lock.
while (1)
{
s = splhigh();
if(!hatLock)
{
hatLock = TRUE;
splx(s);
break;
}
splx(s);
tsleep(&tsleepIdent ,PZERO,"hat", 1);
}
// check to see if the card is in
if(!scrGetDetect())
{
initStates(sc);
cardOff(sc);
// do not call scrClkInit() as it is idle already
sc->pIoctlT0->status = ERROR_CARD_REMOVED;
}
// check to see if card is off
else if(sc->masterS == msIdleOff)
{
sc->pIoctlT0->status = ERROR_CARD_OFF;
}
// card was in, card is on, lets do command
else
{
// set up the top half
sc->masterDone = FALSE;
sc->bigTrouble = FALSE; /* david/jim, remove this when the dust settles */
// start bottom half
scrClkStart (sc,sc->clkCountDataSend);
savedInts = disable_interrupts(I32_bit | F32_bit);
if (sc->pIoctlT0->writeBuffer)
{
masterSM(sc,mcT0DataSend);
}
else
{
masterSM(sc,mcT0DataRecv);
}
restore_interrupts(savedInts);
// see if bottom half done
while (1)
{
// check that we have not looped too many times
if(masterDoneRetries >= MAX_FIQ_TIME * HZ)
{
//printf("MAX_FIQ_TIME reached \n");
// big problems, so reset bottom
savedInts = disable_interrupts(I32_bit | F32_bit);
scrClkInit();
initStates(sc);
cardOff(sc);
sc->status = ERROR_CARD_REMOVED;
sc->masterDone = TRUE;
restore_interrupts(savedInts);
}
masterDoneRetries ++;
// get done bit
savedInts = disable_interrupts(I32_bit | F32_bit);
done = sc->masterDone;
restore_interrupts(savedInts);
// see if all done
if(done)
{
break;
}
// wait for a while
tsleep(&tsleepIdent ,PZERO,"hat", 1);
}
// stop bottom half
scrClkStop();
// get the status back from the state machine
sc->pIoctlT0->status = sc->status;
}
// release the hat lock.
s = splhigh();
hatLock = FALSE;
splx(s);
// david, jim hack to stop ioctl memcpy problem, to be removed when problem fixed ejg
if (sc->pIoctlT0->status != ERROR_OK)
{
sc->pIoctlT0->dataLen = 0;
}
break;
default:
KERN_DEBUG (scrdebug, SCRIOCTL_DEBUG_INFO,("\t scrioctl: unknown command, ENOTTY \n"));
error = ENOTTY;
break;
}
KERN_DEBUG (scrdebug, SCRIOCTL_DEBUG_INFO,
("scrioctl: exiting with sc->status %d\n", error));
return (error);
} /* End scrioctl */
/*
**
** All functions below this point are the bottom half of the driver
**
** All are called during a FIQ, except for some functions in masterSM which
** provides the interface between the bottom half and top half of
** the driver (nb masterDone() helps masterSM() out with this interface
** between top and bottom parts of the driver.
**
*/
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** masterSM
**
** This state machine implements the top level state control It
** receives commands to turn the card on, and do T0 reads and T0 writes
** from the scrioctl. It then calls mid level state machine to action
** these commands.
**
** This machine is the only machine to keep state between scrioctl calls.
** Between calls, the state will be either msIdleOff, or msIdleOn. msIdleOff
** indicates that no signals are applied to the card. msidleOn indicates that
** power and clock are supplied to the card, and that the card has performed
** a successful ATR sequence.
**
** This routine gets called during FIQ interrupts and from scrioctl. It is a
** requirement that the scrioctl disables interrupts before calling this function.
**
** NB:- there is no way for the machine to get from msIdleOn to msIdleOff. Since
** this is just a mater of turning all signals off and resetting state machines,
** scrioctl takes a shortcut and resets everything itself. Ie it hits everything
** with a big hammer!!
**
** FORMAL PARAMETERS:
**
** sc - Pointer to the softc structure.
** cmd - command to the state machine, can be from ioctl, or mid level SM
**
** IMPLICIT INPUTS:
**
** sc->masterS state of this machine
** sc->pIoctlT0 pointer to T0 ioctl
**
** IMPLICIT OUTPUTS:
**
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** power and clock applied to card if successful ATR
**--
*/
static void masterSM(struct scr_softc * sc,int cmd)
{
if (sc->bigTrouble) return; // david,jim , remove this when dust settles
switch (sc->masterS)
{
case msIdleOff:
switch (cmd)
{
case mcOn:
if (scrGetDetect())
{
/*
** the card is off, and we want it on
*/
/* set initial values */
sc->status = 0;
sc->convention = CONVENTION_UNKOWN;
sc->protocolType = 0;
sc->N = N_DEFAULT;
sc->Fi = Fi_DEFAULT;
sc->Di = Di_DEFAULT;
sc->Wi = Wi_DEFAULT;
sc->cardFreq = CARD_FREQ_DEF;
sc->clkCountStartRecv = CLK_COUNT_START;
sc->clkCountDataRecv = sc->clkCountStartRecv * START_2_DATA;
sc->clkCountDataSend = CLK_COUNT_DATA;
/* get coldResetSM to turn on power, clock, reset */
sc->masterS = msColdReset;
coldResetSM(sc,crcStart);
}
else
{
/* card not inserted, so just set status and give up */
sc->status = ERROR_CARD_REMOVED;
sc->masterDone = TRUE;
}
break;
default:
INVALID_STATE_CMD(sc,sc->masterS,cmd);
break;
}
break;
case msColdReset:
switch (cmd)
{
case mcColdReset:
/*
** coldResetSM has turned on power, clock , reset
** tell ATRSM to get the ATR sequence from the card
*/
sc->masterS = msATR;
ATRSM(sc,atrcStart);
break;
default:
INVALID_STATE_CMD(sc,sc->masterS,cmd);
break;
}
break;
case msATR:
switch (cmd)
{
case mcATR:
/*
** ATRSM has tried to get ATR sequence, so give
** back results to scrioctl. ATR sequence data
** was copied directly into ioctl data area, so
** no need to copy data
*/
if(sc->status == ERROR_OK)
{
sc->masterS = msIdleOn;
}
else
{
sc->masterS = msIdleOff;
}
sc->masterDone = TRUE;
break;
default:
INVALID_STATE_CMD(sc,sc->masterS,cmd);
break;
}
break;
case msIdleOn:
switch (cmd)
{
// nb there is no command to go to the IdleOff state. This
// is a reset of the state machine, so is done in ioctl
case mcT0DataSend:
/*
** card is on, and we want to T0 Send, so
** as t0SendSM to do work
*/
sc->status = ERROR_OK;
sc->masterS = msT0Send;
t0SendSM(sc,t0scStart);
break;
case mcT0DataRecv:
/*
** card is on, and we want to T0 Recv, so
** as t0RecvSM to do work
*/
sc->status = ERROR_OK;
sc->masterS = msT0Recv;
t0RecvSM(sc,t0rcStart);
break;
default:
INVALID_STATE_CMD(sc,sc->masterS,cmd);
break;
}
break;
case msT0Send:
switch (cmd)
{
case mcT0Send:
/*
** t0SendSM has tried to send , so lets give back results
*/
sc->masterS = msIdleOn;
sc->masterDone = TRUE;
break;
default:
INVALID_STATE_CMD(sc,sc->masterS,cmd);
break;
}
break;
case msT0Recv:
switch (cmd)
{
case mcT0Recv:
/*
** t0RecvSM has tried to recv , so lets give back results
** data was written directly into ioctl data area, so we
** do not need to copy any data
*/
sc->pIoctlT0->dataLen = sc->dataCount;
sc->masterS = msIdleOn;
sc->masterDone = TRUE;
break;
default:
INVALID_STATE_CMD(sc,sc->masterS,cmd);
break;
}
break;
default:
INVALID_STATE_CMD(sc,sc->masterS,cmd);
break;
}
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** t0SendSM
**
** This is the T=0 Send State Machine. It is responsible
** for performing the send part of the ISO 7816-3 T=0
** protocol. It is mid level protocol state machine.
**
** Once started, this machine is driven entirely via the
** FIQ/timeout structure .
**
**
**
** FORMAL PARAMETERS:
**
** sc - Pointer to the softc structure.
** cmd - command to this machine
**
** IMPLICIT INPUTS:
**
** sc->t0SendS state of this machine
** sc->pIoctlT0->command command to send to card
** sc->pIoctlT0->data data to send to card
**
** IMPLICIT OUTPUTS:
**
** sc->status error status from this machine
** sc->pIoctlT0->sw1 command status from card
** sc->pIoctlT0->sw2 command status from card
** sc->status error status from this machine
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
static void t0SendSM (struct scr_softc * sc, int cmd)
{
if (sc->bigTrouble) return; // david,jim , remove this when dust settles
/*
** check for major failures that are common to most states
*/
if (cmd == t0scTWorkWaiting ||
cmd == gcT0RecvByteErr ||
cmd == gcT0SendByteErr
)
{
switch(cmd)
{
case t0scTWorkWaiting:
ASSERT(sc->t0SendS != t0ssIdle);
/* kill all lower machines */
t0SendByteSM(sc,t0sbcAbort);
t0RecvByteSM(sc,t0rbcAbort);
/* set status */
sc->status = ERROR_WORK_WAITING;
break;
case gcT0RecvByteErr: // fall through
case gcT0SendByteErr:
scrUntimeout(t0SendSM, sc, t0scTWorkWaiting);
// done set status, already set in lower machine
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendS,cmd);
break;
}
/* change states */
sc->t0SendS = t0ssIdle;
masterSM(sc,mcT0Send);
return;
}
switch (sc->t0SendS)
{
case t0ssIdle:
switch (cmd)
{
case t0scStart:
/* set initial values */
sc->t0SendS = t0ssSendHeader;
sc->t0ByteParent = t0SendSM;
sc->commandCount = 0;
sc->dataCount = 0;
sc->dataMax = sc->pIoctlT0->command[CMD_BUF_DATA_LEN_OFF];
sc->dataByte = sc->pIoctlT0->command[sc->commandCount];
// get a byte
t0SendByteSM(sc,t0sbcStart);
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendS,cmd);
break;
}
break;
case t0ssSendHeader:
switch (cmd)
{
case gcT0SendByte:
sc->commandCount++;
if (sc->commandCount < CMD_BUF_LEN)
{
sc->dataByte = sc->pIoctlT0->command[sc->commandCount];
t0SendByteSM(sc,t0sbcStart);
}
else
{
ASSERT(sc->commandCount == CMD_BUF_LEN);
sc->t0SendS = t0ssRecvProcedure;
scrTimeout(t0SendSM,sc,t0scTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendS,cmd);
break;
}
break;
case t0ssRecvProcedure:
switch (cmd)
{
case gcT0RecvByte:
scrUntimeout(t0SendSM, sc,t0scTWorkWaiting);
/* see if we should send all remaining bytes */
if ( (sc->dataByte == sc->pIoctlT0->command[CMD_BUF_INS_OFF]) ||
(sc->dataByte == (sc->pIoctlT0->command[CMD_BUF_INS_OFF] ^ 0x01)) )
{
ASSERT(sc->dataCount < sc->dataMax);
sc->t0SendS = t0ssSendData;
sc->dataByte = sc->pIoctlT0->data[sc->dataCount];
t0SendByteSM(sc,t0sbcStart);
sc->dataCount++;
}
/* see if we should send one data byte */
else if ((sc->dataByte == (sc->pIoctlT0->command[CMD_BUF_INS_OFF] ^ 0xFF)) ||
(sc->dataByte == (sc->pIoctlT0->command[CMD_BUF_INS_OFF] ^ 0xFE)) )
{
ASSERT(sc->dataCount < sc->dataMax);
sc->t0SendS = t0ssSendByte;
sc->dataByte = sc->pIoctlT0->data[ sc->dataCount];
t0SendByteSM(sc,t0sbcStart);
sc->dataCount++;
}
/* see if we should extend the work waiting period */
else if (sc->dataByte == 0x60)
{
t0RecvByteSM(sc,t0rbcStart);
scrTimeout(t0SendSM,sc,t0scTWorkWaiting,T_WORK_WAITING);
}
#ifdef ORIGINAL_SW1_CODE /* XXX XXX XXX cgd */
/* see if we have a SW1 byte */
else if ( ((sc->dataByte & 0xf0) == 0x60) || ((sc->dataByte & 0xf0) == 0x90)
&&
sc->dataByte != 0x60)
#else /* XXX XXX XXX cgd */
/* see if we have a SW1 byte */
else if ( ( ((sc->dataByte & 0xf0) == 0x60) || ((sc->dataByte & 0xf0) == 0x90) )
&&
sc->dataByte != 0x60)
#endif /* XXX XXX XXX cgd */
{
sc->pIoctlT0->sw1 = sc->dataByte;
sc->t0SendS = t0ssRecvSW2;
t0RecvByteSM(sc,t0rbcStart);
scrTimeout(t0SendSM,sc,t0scTWorkWaiting,T_WORK_WAITING);
}
/* got bad data byte, log error and get out */
else
{
sc->status = ERROR_BAD_PROCEDURE_BYTE;
/* change state */
sc->t0SendS = t0ssIdle;
masterSM(sc,mcT0Send);
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendS,cmd);
break;
}
break;
case t0ssSendByte:
switch (cmd)
{
case gcT0SendByte:
if (sc->dataCount < sc->dataMax)
{
sc->t0SendS = t0ssRecvProcedure;
}
/* wait for sw1 byte */
else
{
ASSERT(sc->dataCount == sc->dataMax);
sc->t0SendS = t0ssRecvSW1;
}
// ask for another byte
t0RecvByteSM(sc,t0rbcStart);
scrTimeout(t0SendSM,sc,t0scTWorkWaiting,T_WORK_WAITING);
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendS,cmd);
break;
}
break;
case t0ssSendData:
switch (cmd)
{
case gcT0SendByte:
/* send data */
if (sc->dataCount < sc->dataMax)
{
sc->t0SendS = t0ssSendData;
sc->dataByte = sc->pIoctlT0->data[ sc->dataCount];
t0SendByteSM(sc,t0sbcStart);
sc->dataCount++;
}
/* wait for sw1 byte */
else
{
ASSERT(sc->dataCount == sc->dataMax);
sc->t0SendS = t0ssRecvSW1;
t0RecvByteSM(sc,t0rbcStart);
scrTimeout(t0SendSM,sc,t0scTWorkWaiting,T_WORK_WAITING);
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendS,cmd);
break;
}
break;
case t0ssRecvSW1:
switch (cmd)
{
case gcT0RecvByte:
scrUntimeout(t0SendSM, sc,t0scTWorkWaiting);
sc->pIoctlT0->sw1 = sc->dataByte;
sc->t0SendS = t0ssRecvSW2;
t0RecvByteSM(sc,t0rbcStart);
scrTimeout(t0SendSM,sc,t0scTWorkWaiting,T_WORK_WAITING);
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendS,cmd);
break;
}
break;
case t0ssRecvSW2:
switch (cmd)
{
case gcT0RecvByte:
scrUntimeout(t0SendSM, sc,t0scTWorkWaiting);
sc->pIoctlT0->sw2 = sc->dataByte;
sc->t0SendS = t0ssIdle;
masterSM(sc,mcT0Send);
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendS,cmd);
break;
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendS,cmd);
break;
}
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** t0RecvSM
**
** This is the T=0 Recv State Machine. It is responsible
** for performing the recv part of the ISO 7816-3 T=0
** protocol. It is mid level protocol state machine.
**
** Once started, this machine is driven entirely via the
** FIQ/timeout structure .
**
** FORMAL PARAMETERS:
**
** sc - Pointer to the softc structure.
** cmd - command to this machine
**
** IMPLICIT INPUTS:
**
** sc->t0RecvS state of this machine
** sc->pIoctlT0->command command to send to card
**
** IMPLICIT OUTPUTS:
**
** sc->pIoctlT0->data data from card
** sc->pIoctlT0->dataLen size of data from card
** sc->pIoctlT0->sw1 command status from card
** sc->pIoctlT0->sw2 command status from card
** sc->status error status from this machine
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
static void t0RecvSM (struct scr_softc * sc,int cmd)
{
if (sc->bigTrouble) return; // david,jim , remove this when dust settles
/*
** check for major failures that are common to most states
*/
if (cmd == t0rcTWorkWaiting ||
cmd == gcT0RecvByteErr ||
cmd == gcT0SendByteErr )
{
switch(cmd)
{
case t0rcTWorkWaiting:
ASSERT(sc->t0RecvS != t0rsIdle);
/* kill all lower level machines */
t0SendByteSM(sc,t0sbcAbort);
t0RecvByteSM(sc,t0rbcAbort);
/* set status */
sc->status = ERROR_WORK_WAITING;
break;
case gcT0RecvByteErr: // fall through
case gcT0SendByteErr:
/* kill all the timers */
scrUntimeout(t0RecvSM, sc,t0rcTWorkWaiting);
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvS,cmd);
break;
}
/* change state */
sc->t0RecvS = t0rsIdle;
masterSM(sc,mcT0Recv);
/* all done */
return;
}
switch (sc->t0RecvS)
{
case t0rsIdle:
switch (cmd)
{
case t0rcStart:
/* set initial values */
sc->t0RecvS = t0rsSendHeader;
sc->t0ByteParent = t0RecvSM;
sc->commandCount = 0;
sc->dataCount = 0;
sc->dataMax = sc->pIoctlT0->command[CMD_BUF_DATA_LEN_OFF];
if (sc->dataMax == 0)
{
sc->dataMax = 256;
}
sc->dataByte = sc->pIoctlT0->command[sc->commandCount];
t0SendByteSM(sc,t0sbcStart);
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvS,cmd);
break;
}
break;
case t0rsSendHeader:
switch (cmd)
{
case gcT0SendByte:
sc->commandCount++;
if (sc->commandCount < CMD_BUF_LEN)
{
sc->dataByte = sc->pIoctlT0->command[sc->commandCount];
t0SendByteSM(sc,t0sbcStart);
}
else
{
ASSERT(sc->commandCount == CMD_BUF_LEN);
sc->t0RecvS = t0rsRecvProcedure;
scrTimeout(t0RecvSM,sc,t0rcTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvS,cmd);
break;
}
break;
case t0rsRecvProcedure:
switch (cmd)
{
case gcT0RecvByte:
scrUntimeout(t0RecvSM, sc,t0rcTWorkWaiting);
/* see if we should recv all remaining bytes */
if ( (sc->dataByte == sc->pIoctlT0->command[CMD_BUF_INS_OFF]) ||
(sc->dataByte == (sc->pIoctlT0->command[CMD_BUF_INS_OFF] ^ 0x01)) )
{
ASSERT(sc->dataCount < sc->dataMax);
sc->t0RecvS = t0rsRecvData;
scrTimeout(t0RecvSM,sc,t0rcTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
}
/* see if we should send one data byte */
else if ((sc->dataByte == (sc->pIoctlT0->command[CMD_BUF_INS_OFF] ^ 0xFF)) ||
(sc->dataByte == (sc->pIoctlT0->command[CMD_BUF_INS_OFF] ^ 0xFE)) )
{
ASSERT(sc->dataCount < sc->dataMax);
sc->t0RecvS = t0rsRecvByte;
scrTimeout(t0RecvSM,sc,t0rcTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
}
/* see if we should extend the work waiting period */
else if (sc->dataByte == 0x60)
{
t0RecvByteSM(sc,t0rbcStart);
scrTimeout(t0RecvSM,sc,t0rcTWorkWaiting,T_WORK_WAITING);
}
#ifdef ORIGINAL_SW1_CODE /* XXX XXX XXX cgd */
/* see if we have a SW1 byte */
else if ( ((sc->dataByte & 0xf0) == 0x60) || ((sc->dataByte & 0xf0) == 0x90)
&&
sc->dataByte != 0x60)
#else /* XXX XXX XXX cgd */
/* see if we have a SW1 byte */
else if ( ( ((sc->dataByte & 0xf0) == 0x60) || ((sc->dataByte & 0xf0) == 0x90) )
&&
sc->dataByte != 0x60)
#endif /* XXX XXX XXX cgd */
{
sc->pIoctlT0->sw1 = sc->dataByte;
sc->t0RecvS = t0rsRecvSW2;
t0RecvByteSM(sc,t0rbcStart);
scrTimeout(t0RecvSM,sc,t0rcTWorkWaiting,T_WORK_WAITING);
}
/* got bad data byte, log error and get out */
else
{
sc->status = ERROR_BAD_PROCEDURE_BYTE;
/* change state */
sc->t0RecvS = t0rsIdle;
masterSM(sc,mcT0Recv);
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvS,cmd);
break;
}
break;
case t0rsRecvByte:
switch (cmd)
{
case gcT0RecvByte:
/* clock in byte */
scrUntimeout(t0RecvSM, sc,t0rcTWorkWaiting);
sc->pIoctlT0->data[sc->dataCount] = sc->dataByte;
sc->dataCount++;
if (sc->dataCount < sc->dataMax)
{
/* get procedure byte */
sc->t0RecvS = t0rsRecvProcedure;
}
else
{
ASSERT(sc->dataCount == sc->dataMax);
sc->t0RecvS = t0rsRecvSW1;
}
// ask for another byte
scrTimeout(t0RecvSM,sc,t0rcTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvS,cmd);
break;
}
break;
case t0rsRecvData:
switch (cmd)
{
case gcT0RecvByte:
/* clock in data */
scrUntimeout(t0RecvSM, sc,t0rcTWorkWaiting);
sc->pIoctlT0->data[sc->dataCount] = sc->dataByte;
sc->dataCount++;
/* decide if we have all data */
if (sc->dataCount >= sc->dataMax)
{
KERN_DEBUG (scrdebug, T0_RECV_SM_DEBUG_INFO,("\t\tt0RecvSM: changing state to t0rsRecvSW1\n",sc->dataByte));
ASSERT(sc->dataCount == sc->dataMax);
sc->t0RecvS = t0rsRecvSW1;
}
/* ask for another byte */
scrTimeout(t0RecvSM,sc,t0rcTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvS,cmd);
break;
}
break;
case t0rsRecvSW1:
switch (cmd)
{
case gcT0RecvByte:
scrUntimeout(t0RecvSM, sc,t0rcTWorkWaiting);
sc->pIoctlT0->sw1 = sc->dataByte;
sc->t0RecvS = t0rsRecvSW2;
t0RecvByteSM(sc,t0rbcStart);
scrTimeout(t0RecvSM,sc,t0rcTWorkWaiting,T_WORK_WAITING);
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvS,cmd);
break;
}
break;
case t0rsRecvSW2:
switch (cmd)
{
case gcT0RecvByte:
scrUntimeout(t0RecvSM, sc,t0rcTWorkWaiting);
sc->pIoctlT0->sw2 = sc->dataByte;
sc->t0RecvS = t0rsIdle;
masterSM(sc,mcT0Recv);
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvS,cmd);
break;
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvS,cmd);
break;
}
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** coldResetSM
**
** This state machine switches on the power, clock and reset pins
** in the correct order/timing.
** It is a low level bit-bashing state machine.
**
**
** FORMAL PARAMETERS:
**
** sc - Pointer to the softc structure.
** cmd - command to this machine
**
** IMPLICIT INPUTS:
**
** sc->coldResetS state of this machine
**
** IMPLICIT OUTPUTS:
**
** nill
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** signals to card are on
**--
*/
static void coldResetSM(struct scr_softc * sc,int cmd)
{
if (sc->bigTrouble) return; // david,jim , remove this when dust settles
switch (sc->coldResetS)
{
case crsIdle:
switch (cmd)
{
case crcStart:
scrSetReset(TRUE);
scrSetClock(TRUE);
scrSetDataHighZ();
scrSetPower(TRUE);
/* start a t2 timer */
scrTimeout(coldResetSM,sc,crcT2,T_t2);
sc->coldResetS = crsT2Wait;
break;
default:
INVALID_STATE_CMD(sc,sc->masterS,cmd);
break;
}
break;
case crsT2Wait:
switch (cmd)
{
case crcT2:
/* turn off rst */
scrSetReset(FALSE);
/* tell master state machine that we are all done */
sc->coldResetS = crsIdle;
masterSM(sc,mcColdReset);
break;
default:
INVALID_STATE_CMD(sc,sc->masterS,cmd);
break;
}
break;
default:
INVALID_STATE_CMD(sc,sc->coldResetS,cmd);
break;
}
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** ATRSM
**
** This is the Answer To Reset State Machine. It is responsible
** for performing the Answer To Reset as specified in ISO 7816-3.
** It is mid level protocol state machine.
**
** Once started, this machine is driven entirely via the
** FIQ/timeout structure.
**
**
** During the first byte, we have to check if the card is operating
** at full speed or half speed. The first couple of bits are
** checked to see if it is 1/2 speed, and if so, the clock is changed
** and the state adjustes
**
** At the end of the first byte we have to determin the logic being
** used by the card, ie is it active high/low and msb/lsb.
**
**
** FORMAL PARAMETERS:
**
** sc - Pointer to the softc structure.
** cmd - command to this machine
**
** IMPLICIT INPUTS:
**
** sc->pIoctlAtr->atr data from card
** sc->pIoctlT0->sw1 command status from card
** sc->pIoctlT0->sw2 command status from card
** sc->status error status from this machine
**
** IMPLICIT OUTPUTS:
**
** sc->pIoctlOn->atrBuf data from ATR sequence
** sc->pIoctlOn->atrLen size of data from ATR sequence
** sc->status error status from this machine
**
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
static void ATRSM (struct scr_softc * sc,int cmd)
{
int lc;
int tck;
if (sc->bigTrouble) return; // david,jim , remove this when dust settles
/*
** check for major failures that are common to most states
*/
if (cmd == atrcT3 ||
cmd == atrcTWorkWaiting ||
cmd == gcT0RecvByteErr
)
{
switch(cmd)
{
case atrcT3:
scrUntimeout (ATRSM,sc,atrcTWorkWaiting);
sc->status = ERROR_ATR_T3;
t0RecvByteSM(sc,t0rbcAbort);
break;
case atrcTWorkWaiting:
scrUntimeout (ATRSM,sc,atrcT3);
sc->status = ERROR_WORK_WAITING;
t0RecvByteSM(sc,t0rbcAbort);
break;
case gcT0RecvByteErr:
scrUntimeout (ATRSM,sc,atrcT3);
scrUntimeout (ATRSM,sc,atrcTWorkWaiting);
/* done set status, its already set */
break;
default:
INVALID_STATE_CMD(sc,sc->ATRS,cmd);
break;
}
/* change state */
sc->ATRS = atrsIdle;
masterSM(sc,mcATR);
return;
}
switch (sc->ATRS)
{
case atrsIdle:
switch (cmd)
{
case atrcStart:
/* lets start looking */
sc->ATRS = atrsTS;
sc->pIoctlOn->atrLen = 0;
sc->t0ByteParent = ATRSM;
scrTimeout(ATRSM,sc,atrcT3,T_t3 *2); /* by 2 to accomodate 1/2 freq cards */
t0RecvByteSM(sc,t0rbcStart);
break;
default:
INVALID_STATE_CMD(sc,sc->ATRS,cmd);
break;
}
break;
case atrsTS:
switch (cmd)
{
case gcT0RecvByte:
scrUntimeout(ATRSM,sc,atrcT3);
sc->pIoctlOn->atrBuf[sc->pIoctlOn->atrLen] = sc->dataByte;
sc->pIoctlOn->atrLen++;
if(sc->pIoctlOn->atrLen >= ATR_BUF_MAX)
{
#ifdef SCR_DEBUG
DEBUGGER;
#endif
sc->status = ERROR_ATR_TCK;
sc->ATRS = atrsIdle;
masterSM(sc,mcATR);
}
else
{
/* move onto recv T0 */
sc->ATRS = atrsT0;
scrTimeout(ATRSM,sc,atrcTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
}
break;
default:
INVALID_STATE_CMD(sc,sc->ATRS,cmd);
break;
}
break;
case atrsT0:
switch (cmd)
{
case gcT0RecvByte:
scrUntimeout(ATRSM,sc,atrcTWorkWaiting);
sc->pIoctlOn->atrBuf[sc->pIoctlOn->atrLen] = sc->dataByte;
sc->pIoctlOn->atrLen++;
if(sc->pIoctlOn->atrLen >= ATR_BUF_MAX)
{
#ifdef SCR_DEBUG
printf("atrLen >= ATR_BUF_MAX\n");
DEBUGGER;
#endif
sc->status = ERROR_ATR_TCK;
sc->ATRS = atrsIdle;
masterSM(sc,mcATR);
}
else
{
/* store Y & K */
sc->atrY = sc->dataByte & 0xf0;
sc->atrK = sc->dataByte & 0x0f;
sc->atrTABCDx = 1;
sc->atrKCount = 1;
/* if there are no TDx following set T0 protocol */
if (ISCLR(sc->atrY,ATR_Y_TD))
{
sc->protocolType = PROTOCOL_T0;
}
if (sc->atrY)
{
sc->ATRS = atrsTABCD;
scrTimeout(ATRSM,sc,atrcTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
}
else if (sc->atrK)
{
sc->ATRS = atrsTK;
scrTimeout(ATRSM,sc,atrcTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
}
else if (sc->protocolType != PROTOCOL_T0)
{
sc->ATRS = atrsTCK;
scrTimeout(ATRSM,sc,atrcTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
}
else /* got all of ATR */
{
sc->ATRS = atrsIdle;
masterSM(sc,mcATR);
}
}
break;
default:
INVALID_STATE_CMD(sc,sc->ATRS,cmd);
break;
}
break;
case atrsTABCD:
switch (cmd)
{
case gcT0RecvByte:
scrUntimeout(ATRSM,sc,atrcTWorkWaiting);
sc->pIoctlOn->atrBuf[sc->pIoctlOn->atrLen] = sc->dataByte;
sc->pIoctlOn->atrLen++;
if(sc->pIoctlOn->atrLen >= ATR_BUF_MAX)
{
#ifdef SCR_DEBUG
printf("atrLen >= ATR_BUF_MAX\n");
DEBUGGER;
#endif
sc->status = ERROR_ATR_TCK;
sc->ATRS = atrsIdle;
masterSM(sc,mcATR);
}
else
{
if (sc->atrY & ATR_Y_TA)
{
sc->atrY &= ~ATR_Y_TA;
if (sc->atrTABCDx == 1)
{
sc->Fi = FI2Fi[((sc->dataByte >> 4) & 0x0f)];
if (sc->Fi == 0)
{
sc->status = ERROR_ATR_FI_INVALID;
sc->Fi = Fi_DEFAULT;
}
sc->Di = DI2Di[(sc->dataByte & 0x0f)];
if (sc->Di == 0)
{
sc->status = ERROR_ATR_DI_INVALID;
sc->Di = Di_DEFAULT;
}
}
}
else if (sc->atrY & ATR_Y_TB)
{
sc->atrY &= ~ATR_Y_TB;
}
else if (sc->atrY & ATR_Y_TC)
{
sc->atrY &= ~ATR_Y_TC;
if (sc->atrTABCDx == 1)
{
sc->N = sc->dataByte;
}
if (sc->atrTABCDx == 2)
{
sc->Wi = sc->dataByte;
}
}
else
{
ASSERT(sc->atrY & ATR_Y_TD);
sc->atrY &= ~ATR_Y_TD;
/* copy across the y section of TD */
sc->atrY = sc->dataByte;
sc->atrY &= 0xf0;
/* step to the next group of TABCD */
sc->atrTABCDx++;
/* store protocols */
sc->protocolType = (1 << (sc->dataByte &0x0f));
}
/* see what we should do next */
if (sc->atrY)
{
/* just stay in the same state */
scrTimeout(ATRSM,sc,atrcTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
}
else if (sc->atrK)
{
sc->ATRS = atrsTK;
scrTimeout(ATRSM,sc,atrcTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
}
else if (sc->protocolType != PROTOCOL_T0)
{
sc->ATRS = atrsTCK;
scrTimeout(ATRSM,sc,atrcTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
}
else /* got all of ATR */
{
sc->ATRS = atrsIdle;
masterSM(sc,mcATR);
}
}
break;
default:
INVALID_STATE_CMD(sc,sc->ATRS,cmd);
break;
}
break;
case atrsTK:
switch (cmd)
{
case gcT0RecvByte:
scrUntimeout(ATRSM,sc,atrcTWorkWaiting);
sc->pIoctlOn->atrBuf[sc->pIoctlOn->atrLen] = sc->dataByte;
sc->pIoctlOn->atrLen++;
if(sc->pIoctlOn->atrLen >= ATR_BUF_MAX)
{
#ifdef SCR_DEBUG
printf("atrLen >= ATR_BUF_MAX\n");
DEBUGGER;
#endif
sc->status = ERROR_ATR_TCK;
sc->ATRS = atrsIdle;
masterSM(sc,mcATR);
}
else
{
if (sc->atrKCount < sc->atrK)
{
sc->atrKCount++;
scrTimeout(ATRSM,sc,atrcTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
}
else if (sc->protocolType != PROTOCOL_T0)
{
sc->ATRS = atrsTCK;
scrTimeout(ATRSM,sc,atrcTWorkWaiting,T_WORK_WAITING);
t0RecvByteSM(sc,t0rbcStart);
}
else /* got all of ATR */
{
sc->ATRS = atrsIdle;
masterSM(sc,mcATR);
}
}
break;
default:
INVALID_STATE_CMD(sc,sc->ATRS,cmd);
break;
}
break;
case atrsTCK:
switch (cmd)
{
case gcT0RecvByte:
scrUntimeout(ATRSM,sc,atrcTWorkWaiting);
sc->pIoctlOn->atrBuf[sc->pIoctlOn->atrLen] = sc->dataByte;
sc->pIoctlOn->atrLen++;
if(sc->pIoctlOn->atrLen >= ATR_BUF_MAX)
{
#ifdef SCR_DEBUG
printf("atrLen >= ATR_BUF_MAX\n");
DEBUGGER;
#endif
sc->status = ERROR_ATR_TCK;
sc->ATRS = atrsIdle;
masterSM(sc,mcATR);
}
else
{
tck = 0;
for (lc = 1; lc < sc->pIoctlOn->atrLen-1; lc++)
{
tck ^= sc->pIoctlOn->atrBuf[lc];
}
if (tck == sc->pIoctlOn->atrBuf[sc->pIoctlOn->atrLen-1])
{
sc->ATRS = atrsIdle;
masterSM(sc,mcATR);
}
else
{
sc->status = ERROR_ATR_TCK;
sc->ATRS = atrsIdle;
masterSM(sc,mcATR);
}
}
break;
default:
INVALID_STATE_CMD(sc,sc->ATRS,cmd);
break;
}
break;
default:
INVALID_STATE_CMD(sc,sc->ATRS,cmd);
break;
}
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** t0RecvByteSM
**
** This state machine attempts to read 1 byte from a card.
** It is a low level bit-bashing state machine.
**
** Data from the card is async, so the machine scans at
** 5 times the data rate looking for a state bit. Once
** a start bit has been found, it waits for the middle of
** the bit and starts sampling at the bit rate.
**
** Several mid level machines can use this machine, so the value
** sc->t0ByteParent is used to point to back to the mid level machine
**
**
** FORMAL PARAMETERS:
**
** sc - Pointer to the softc structure.
** cmd - command to this machine
**
** IMPLICIT INPUTS:
**
** sc->t0RecvByteS state of this machine
** sc->t0ByteParent mid level machine that started this machine
**
** IMPLICIT OUTPUTS:
**
** sc->shiftByte byte read from the card
** sc->status error value if could not read byte
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
static void t0RecvByteSM(struct scr_softc* sc,int cmd)
{
if (sc->bigTrouble) return; // david,jim , remove this when dust settles
if (cmd == t0rbcAbort)
{
/* kill all the timers */
scrUntimeout(t0RecvByteSM, sc,t0rbcTFindStartEdge);
scrUntimeout(t0RecvByteSM, sc,t0rbcTFindStartMid);
scrUntimeout(t0RecvByteSM, sc,t0rbcTClockData);
scrUntimeout(t0RecvByteSM, sc,t0rbcTErrorStart);
scrUntimeout(t0RecvByteSM, sc,t0rbcTErrorStop);
scrSetDataHighZ();
sc->t0RecvByteS = t0rbsIdle;
return;
}
switch (sc->t0RecvByteS)
{
case t0rbsIdle:
switch (cmd)
{
case t0rbcStart:
/* set initial conditions */
sc->shiftBits = 0;
sc->shiftByte = 0;
sc->shiftParity = 0;
sc->shiftParityCount = 0;
scrClkAdj(sc->clkCountStartRecv); /* recv data clock running at 5 times */
/* check if start bit is already here */
//if (scrGetData())
if (1)
{
/* didn't find it, keep looking */
scrTimeout(t0RecvByteSM,sc,t0rbcTFindStartEdge,sc->clkCountStartRecv);
sc->t0RecvByteS = t0rbsFindStartEdge;
}
else
{
/* found start bit, look for mid bit */
scrTimeout(t0RecvByteSM,sc,t0rbcTFindStartMid,sc->clkCountStartRecv);
sc->t0RecvByteS = t0rbsFindStartMid;
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvByteS,cmd);
break;
}
break;
case t0rbsFindStartEdge:
switch (cmd)
{
case t0rbcTFindStartEdge:
if (scrGetData())
{
/* didn't find it, keep looking */
scrTimeout(t0RecvByteSM,sc,t0rbcTFindStartEdge,sc->clkCountStartRecv);
}
else
{
/* found start bit, look for mid bit */
scrTimeout(t0RecvByteSM,sc,t0rbcTFindStartMid,sc->clkCountStartRecv * 2);
sc->t0RecvByteS = t0rbsFindStartMid;
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvByteS,cmd);
break;
}
break;
case t0rbsFindStartMid:
switch (cmd)
{
case t0rbcTFindStartMid:
if (scrGetData())
{
/* found glitch, so just go back to hunting */
scrTimeout(t0RecvByteSM,sc,t0rbcTFindStartEdge,sc->clkCountStartRecv);
sc->t0RecvByteS = t0rbsFindStartEdge;
}
else
{
/* found start bit, start clocking in data */
TOGGLE_TEST_PIN();
scrTimeout(t0RecvByteSM,sc,t0rbcTClockData,sc->clkCountDataRecv);
sc->t0RecvByteS = t0rbsClockData;
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvByteS,cmd);
break;
}
break;
case t0rbsClockData:
TOGGLE_TEST_PIN();
switch (cmd)
{
case t0rbcTClockData:
if (sc->shiftBits < 8)
{
if (sc->convention == CONVENTION_INVERSE ||
sc->convention == CONVENTION_UNKOWN)
{
/* logic 1 is low, msb is first */
sc->shiftByte <<= 1;
sc->shiftByte &= 0xfe;
if (!scrGetData())
{
sc->shiftByte |= 0x01;
sc->shiftParity++;
}
}
else
{
ASSERT(sc->convention == CONVENTION_DIRECT);
/* logic 1 is high, lsb is first */
sc->shiftByte = sc->shiftByte >> 1;
sc->shiftByte &= 0x7f;
if (scrGetData())
{
sc->shiftParity++;
sc->shiftByte |= 0x80;
}
}
sc->shiftBits++;
/* in TS byte, check if we have a card that works at 1/2 freq */
if (sc->convention == CONVENTION_UNKOWN && /* in TS byte */
sc->shiftBits == 3 && /* test at bit 3 in word */
sc->shiftByte == 4 && /* check for 1/2 freq pattern */
sc->cardFreq == CARD_FREQ_DEF) /* only do this if at full freq */
{
/* adjust counts down to 1/2 freq */
sc->cardFreq = CARD_FREQ_DEF / 2;
sc->clkCountStartRecv = sc->clkCountStartRecv *2;
sc->clkCountDataRecv = sc->clkCountDataRecv *2;
sc->clkCountDataSend = sc->clkCountDataSend *2;
/* adjust this so that we have clocked in only fist bit of TS */
sc->shiftParity = 0;
sc->shiftByte = 0;
sc->shiftBits = 1;
scrTimeout(t0RecvByteSM,sc,t0rbcTClockData,(sc->clkCountDataRecv * 3) /4);
}
else
{
scrTimeout(t0RecvByteSM,sc,t0rbcTClockData,sc->clkCountDataRecv);
}
}
/* clock in parity bit */
else if (sc->shiftBits == 8)
{
if (sc->convention == CONVENTION_INVERSE)
{
if (!scrGetData())
{
sc->shiftParity++;
}
}
else if (sc->convention == CONVENTION_DIRECT)
{
if (scrGetData())
{
sc->shiftParity++;
}
}
else
{
/* sc->convention not set so sort it out */
ASSERT(sc->convention == CONVENTION_UNKOWN);
if (sc->shiftByte == CONVENIONT_INVERSE_ID && scrGetData())
{
sc->convention = CONVENTION_INVERSE;
sc->shiftParity = 0; /* force good parity */
}
else if (sc->shiftByte == CONVENTION_DIRECT_ID && scrGetData())
{
sc->shiftByte = CONVENTION_DIRECT_FIX;
sc->convention = CONVENTION_DIRECT;
sc->shiftParity = 0; /* force good parity */
}
else
{
sc->shiftParity = 1; /* force bad parity */
}
}
if ((sc->shiftParity & 01) == 0)
{
sc->shiftBits++;
scrTimeout(t0RecvByteSM,sc,t0rbcTClockData,sc->clkCountDataRecv);
}
else
{
/* got parity error */
if (sc->shiftParityCount < PARITY_ERROR_MAX)
{
sc->shiftParityCount++;
scrTimeout(t0RecvByteSM,sc,t0rbcTErrorStart,sc->clkCountDataRecv);
sc->t0RecvByteS = t0rbsSendError;
}
else
{
/* too many parity errors, just give up on this sc->dataByte */
sc->status = ERROR_PARITY;
sc->t0RecvByteS = t0rbsIdle;
sc->t0ByteParent(sc,gcT0RecvByteErr);
}
}
}
else
{
sc->dataByte = sc->shiftByte;
sc->t0RecvByteS = t0rbsIdle;
sc->t0ByteParent(sc,gcT0RecvByte);
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvByteS,cmd);
break;
}
break;
case t0rbsSendError:
TOGGLE_TEST_PIN();
switch (cmd)
{
case t0rbcTErrorStart:
/* start sending error bit */
scrSetData(FALSE);
scrTimeout(t0RecvByteSM,sc,t0rbcTErrorStop,sc->clkCountDataRecv * 2);
break;
case t0rbcTErrorStop:
/* stop sending parity error & reset information*/
scrSetData(TRUE);
sc->shiftBits = 0;
sc->shiftByte = 0;
sc->shiftParity = 0;
/* start looking for start bit */
scrTimeout(t0RecvByteSM,sc,t0rbcTFindStartEdge,1);
sc->t0RecvByteS = t0rbsFindStartEdge;
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvByteS,cmd);
break;
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0RecvByteS,cmd);
break;
}
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** t0SendByteSM
**
** This state machine writes 1 byte to a card.
** It is a low level bit-bashing state machine.
**
**
** Several mid level machines can use this machine, so the value
** sc->t0ByteParent is used to point to back to the mid level machine
**
** FORMAL PARAMETERS:
**
** sc - Pointer to the softc structure.
** cmd - command to this machine
**
** IMPLICIT INPUTS:
**
** sc->t0SendByteS state of this machine
** sc->shiftByte byte to write to the card
**
** IMPLICIT OUTPUTS:
**
** sc->status error value if could not read byte
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
//int bigTroubleTest = 0;
static void t0SendByteSM (struct scr_softc * sc,int cmd)
{
//if(bigTroubleTest == 2000)
//{
// INVALID_STATE_CMD(sc, sc->t0SendByteS,cmd);
// bigTroubleTest = 0;
//}
//
//bigTroubleTest++;
if (sc->bigTrouble) return; // david,jim , remove this when dust settles
if (cmd == t0sbcAbort)
{
/* kill all the timers */
scrUntimeout(t0SendByteSM, sc, t0sbcTGuardTime);
scrUntimeout(t0SendByteSM, sc, t0sbcTClockData);
scrUntimeout(t0SendByteSM, sc, t0sbcTError);
scrSetDataHighZ();
return;
}
switch (sc->t0SendByteS)
{
case t0sbsIdle:
switch (cmd)
{
case t0sbcStart:
/* set initial conditions */
sc->shiftBits = 0;
sc->shiftParity = 0;
sc->shiftParityCount = 0;
sc->shiftByte = sc->dataByte;
scrClkAdj(sc->clkCountDataSend); /* send data clock running at 1 ETU */
/* check if we have to wait for guard time */
if (0) /* possible optimization here */
{
/* can send start bit now */
scrTimeout(t0SendByteSM,sc,t0sbcTClockData,sc->clkCountDataSend);
scrSetData(FALSE);
sc->t0SendByteS = t0sbsClockData;
}
else
{
/* need to wait for guard time */
scrTimeout(t0SendByteSM,sc,t0sbcTGuardTime,sc->clkCountDataSend * (12 + sc->N));
sc->t0SendByteS = t0sbsWaitGuardTime;
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendByteS,cmd);
break;
}
break;
case t0sbsWaitGuardTime:
switch (cmd)
{
case t0sbcTGuardTime:
TOGGLE_TEST_PIN();
/* set start bit */
scrTimeout(t0SendByteSM,sc,t0sbcTClockData,sc->clkCountDataSend);
scrSetData(FALSE);
sc->t0SendByteS = t0sbsClockData;
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendByteS,cmd);
break;
}
break;
case t0sbsClockData:
switch (cmd)
{
case t0sbcTClockData:
TOGGLE_TEST_PIN();
/* clock out data bit */
if (sc->shiftBits < 8)
{
if (sc->convention == CONVENTION_INVERSE)
{
if (sc->shiftByte & 0x80)
{
scrSetData(FALSE);
sc->shiftParity++;
}
else
{
scrSetData(TRUE);
}
sc->shiftByte = sc->shiftByte << 1;
}
else
{
ASSERT(sc->convention == CONVENTION_DIRECT);
if (sc->shiftByte & 0x01)
{
scrSetData(TRUE);
sc->shiftParity++;
}
else
{
scrSetData(FALSE);
}
sc->shiftByte = sc->shiftByte >> 1;
}
sc->shiftBits++;
scrTimeout(t0SendByteSM,sc,t0sbcTClockData,sc->clkCountDataSend);
}
/* clock out parity bit */
else if (sc->shiftBits == 8)
{
if ( ((sc->shiftParity & 0x01) && (sc->convention == CONVENTION_INVERSE)) ||
(!(sc->shiftParity & 0x01) && (sc->convention == CONVENTION_DIRECT)) )
{
scrSetData(FALSE);
}
else
{
scrSetData(TRUE);
}
sc->shiftBits++;
scrTimeout(t0SendByteSM,sc,t0sbcTClockData,sc->clkCountDataSend);
}
/* all data shifted out, move onto next state */
else
{
ASSERT(sc->shiftBits > 8);
scrSetData(TRUE);
scrTimeout(t0SendByteSM,sc,t0sbcTError,sc->clkCountDataSend);
sc->t0SendByteS = t0sbsWaitError;
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendByteS,cmd);
break;
}
break;
case t0sbsWaitError:
switch (cmd)
{
case t0sbcTError:
/* no error indicated*/
if (scrGetData())
{
sc->t0SendByteS = t0sbsIdle;
sc->t0ByteParent(sc,gcT0SendByte);
}
/* got error */
else
{
/* got parity error */
if (sc->shiftParityCount < PARITY_ERROR_MAX)
{
sc->shiftParityCount++;
scrTimeout(t0SendByteSM,sc,t0sbcTResend,sc->clkCountDataSend * 2);
sc->t0SendByteS = t0sbsWaitResend;
}
else
{
/* too many parity errors, just give up on this sc->dataByte */
sc->status = ERROR_PARITY;
sc->t0SendByteS = t0sbsIdle;
sc->t0ByteParent(sc,gcT0SendByteErr);
}
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendByteS,cmd);
break;
}
break;
case t0sbsWaitResend:
switch (cmd)
{
case t0sbcTResend:
sc->shiftBits = 0;
sc->shiftParity = 0;
sc->shiftByte = sc->dataByte;
/* set start bit */
scrTimeout(t0SendByteSM,sc,t0sbcTClockData,sc->clkCountDataSend);
scrSetData(FALSE);
sc->t0SendByteS = t0sbsClockData;
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendByteS,cmd);
break;
}
break;
default:
INVALID_STATE_CMD(sc, sc->t0SendByteS,cmd);
break;
}
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** cardOff
**
** Turn all signals to the card off
**
** FORMAL PARAMETERS:
**
** sc - Pointer to the softc structure.
**
** IMPLICIT INPUTS:
**
** nill
**
** IMPLICIT OUTPUTS:
**
** nill
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
static void cardOff (struct scr_softc * sc)
{
scrSetReset(TRUE);
scrSetDataHighZ();
scrSetClock(FALSE);
scrSetPower(FALSE);
}
/*
**
**
** **************** timer routines ***************
**
*/
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** scrClkInit
**
** Init the callout queues. The callout queues are used
** by the timeout/untimeout queues
**
** FORMAL PARAMETERS:
**
** nill
**
** IMPLICIT INPUTS:
**
** nill
**
** IMPLICIT OUTPUTS:
**
** nill
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
static void scrClkInit(void)
{
int lc;
Callout *c;
Callout *new;
scrClkCallTodo.c_next = NULL;
scrClkCallFree = &scrClkCalloutArray[0];
c = scrClkCallFree;
for (lc = 1; lc < SCR_CLK_CALLOUT_COUNT; lc++)
{
new = &scrClkCalloutArray[lc];
c->c_next = new;
c = new;
}
c->c_next = NULL;
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** scrClkStart
**
** This function starts the clock running. The clock is reall the
** HAT clock (High Available Timer) that is using a FIQ (fast interrupt
** request).
**
** FORMAL PARAMETERS:
**
** sc - Pointer to the softc structure.
** countPerTick - value for T2 timer that drives FIQ
**
** IMPLICIT INPUTS:
**
** nill
**
** IMPLICIT OUTPUTS:
**
** nill
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
static void scrClkStart(struct scr_softc * sc,int countPerTick)
{
u_int savedInts;
savedInts = disable_interrupts(I32_bit | F32_bit);
ASSERT(scrClkCallTodo.c_next == NULL);
ASSERT(!scrClkEnable);
scrClkEnable = 1;
scrClkCount = countPerTick;
hatClkOn(countPerTick,
hatClkIrq,
0xdeadbeef,
hatStack + HATSTACKSIZE - sizeof(unsigned),
myHatWedge);
restore_interrupts(savedInts);
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** scrClkAdj
**
** Adjusts the frequence of the clock
**
** FORMAL PARAMETERS:
**
** count - new value for T2 timer that drives FIQ
**
** IMPLICIT INPUTS:
**
** nill
**
** IMPLICIT OUTPUTS:
**
** nill
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
static void scrClkAdj (int count)
{
u_int savedInts;
if (count != scrClkCount)
{
savedInts = disable_interrupts(I32_bit | F32_bit);
ASSERT(scrClkEnable);
scrClkCount = count;
hatClkAdjust(count);
restore_interrupts(savedInts);
}
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** scrClkStop
**
** Stops the clock
**
** FORMAL PARAMETERS:
**
** nill
**
**
** IMPLICIT INPUTS:
**
** nill
**
** IMPLICIT OUTPUTS:
**
** nill
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
static void scrClkStop(void)
{
u_int savedInts;
savedInts = disable_interrupts(I32_bit | F32_bit);
ASSERT(scrClkEnable);
scrClkEnable = 0;
ASSERT(scrClkCallTodo.c_next == NULL);
hatClkOff();
restore_interrupts(savedInts);
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** hatClkIrq
**
** This is what the HAT clock calls. This call drives
** the timeout queues, which in turn drive the state machines
**
** Be very carefully when calling a timeout as the function
** that is called may in turn do timeout/untimeout calls
** before returning
**
** FORMAL PARAMETERS:
**
** int x - not used
**
** IMPLICIT INPUTS:
**
** nill
**
** IMPLICIT OUTPUTS:
**
** nill
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** a timeout may be called if it is due
**--
*/
static void hatClkIrq(int x)
{
register Callout *p1;
register int needsoft =0;
register Callout *c;
register int arg;
register void (*func) __P((struct scr_softc*,int));
struct scr_softc * sc;
ASSERT(scrClkEnable);
for (p1 = scrClkCallTodo.c_next; p1 != NULL; p1 = p1->c_next)
{
p1->c_time -= scrClkCount;
if (p1->c_time > 0)
{
break;
}
needsoft = 1;
if (p1->c_time == 0)
{
break;
}
}
if (needsoft)
{
while ((c = scrClkCallTodo.c_next) != NULL && c->c_time <= 0)
{
func = c->c_func;
sc = c->c_sc;
arg = c->c_arg;
scrClkCallTodo.c_next = c->c_next;
c->c_next = scrClkCallFree;
scrClkCallFree = c;
(*func)(sc,arg);
}
}
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** myHatWedge
**
** Called if the HAT timer becomes clogged/wedged. Not
** used by this driver, we let upper layers recover
** from this condition
**
** FORMAL PARAMETERS:
**
** int nFIQs - not used
**
** IMPLICIT INPUTS:
**
** nill
**
** IMPLICIT OUTPUTS:
**
** nill
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
static void myHatWedge(int nFIQs)
{
#ifdef DEBUG
printf("myHatWedge: nFIQ = %d\n",nFIQs);
#endif
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** scrTimeout
**
** Execute a function after a specified length of time.
**
**
** FORMAL PARAMETERS:
**
** ftn - function to execute
** sc - pointer to soft c
** arg - argument passed to function
** count - number of T2 counts for timeout
**
** IMPLICIT INPUTS:
**
** nill
**
** IMPLICIT OUTPUTS:
**
** nill
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
static void scrTimeout(ftn, sc, arg, count)
void (*ftn) __P((struct scr_softc*,int));
struct scr_softc* sc;
int arg;
register int count;
{
register Callout *new, *p, *t;
ASSERT(scrClkEnable);
if (count <= 0)
{
count = 1;
}
/* Fill in the next free fcallout structure. */
if (scrClkCallFree == NULL)
{
panic("timeout table full");
}
new = scrClkCallFree;
scrClkCallFree = new->c_next;
new->c_sc = sc;
new->c_arg = arg;
new->c_func = ftn;
/*
* The time for each event is stored as a difference from the time
* of the previous event on the queue. Walk the queue, correcting
* the counts argument for queue entries passed. Correct the counts
* value for the queue entry immediately after the insertion point
* as well. Watch out for negative c_time values; these represent
* overdue events.
*/
for (p = &scrClkCallTodo; (t = p->c_next) != NULL && count > t->c_time; p = t)
{
if (t->c_time > 0)
{
count -= t->c_time;
}
}
new->c_time = count;
if (t != NULL)
{
t->c_time -= count;
}
/* Insert the new entry into the queue. */
p->c_next = new;
new->c_next = t;
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** scrUntimeout
**
** Cancel previous timeout function call.
**
** FORMAL PARAMETERS:
**
** ftn - function of timeout to cancel
** sc - sc of timeout to cancel
** arg - arg of timeout to cancel
**
** IMPLICIT INPUTS:
**
** nill
**
** IMPLICIT OUTPUTS:
**
** nill
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
static void scrUntimeout(ftn, sc, arg)
void (*ftn) __P((struct scr_softc*,int));
struct scr_softc* sc;
int arg;
{
register Callout *p, *t;
ASSERT(scrClkEnable);
for (p = &scrClkCallTodo; (t = p->c_next) != NULL; p = t)
{
if (t->c_func == ftn && t->c_sc == sc && t->c_arg == arg)
{
/* Increment next entry's count. */
if (t->c_next && t->c_time > 0)
{
t->c_next->c_time += t->c_time;
}
/* Move entry from fcallout queue to scrClkCallFree queue. */
p->c_next = t->c_next;
t->c_next = scrClkCallFree;
scrClkCallFree = t;
break;
}
}
}
/******************* routines used only during debugging */
#ifdef SCR_DEBUG
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** invalidStateCmd
**
** Debugging function. Printout information about problem
** and then kick in the debugger or panic
**
** FORMAL PARAMETERS:
**
** sc - pointer to soft c
** state - state of machine
** cmd - command of machine
** line - line that problem was detected
**
**
** IMPLICIT INPUTS:
**
** nill
**
** IMPLICIT OUTPUTS:
**
** nill
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
void invalidStateCmd (struct scr_softc* sc,int state,int cmd,int line)
{
printf("INVALID_STATE_CMD: sc = %X, state = %X, cmd = %X, line = %d\n",sc,state,cmd,line);
DEBUGGER;
}
/*
**++
** FUNCTIONAL DESCRIPTION:
**
** getText
**
** Get text representation of state or command
**
** FORMAL PARAMETERS:
**
** x - state or command
**
** IMPLICIT INPUTS:
**
** nill
**
** IMPLICIT OUTPUTS:
**
** nill
**
** FUNCTION VALUE:
**
** nill
**
** SIDE EFFECTS:
**
** nill
**--
*/
char * getText(int x)
{
switch (x)
{
/* commands to Master State Machine (mc = Master Command )*/
case mcOn: return "mcOn";
case mcT0DataSend: return "mcT0DataSend";
case mcT0DataRecv: return "mcT0DataRecv";
case mcColdReset: return "mcColdReset";
case mcATR: return "mcATR";
case mcT0Send: return "mcT0Send";
case mcT0Recv: return "mcT0Recv";
/* states in Master state machine (ms = Master State) */
case msIdleOff: return "msIdleOff";
case msColdReset: return "msColdReset";
case msATR: return "msATR";
case msIdleOn: return "msIdleOn";
case msT0Send: return "msT0Send";
case msT0Recv: return "msT0Recv";
/* commands to T0 send state machine */
case t0scStart: return "t0scStart";
case t0scTWorkWaiting: return "t0scTWorkWaiting";
/* states in T0 send state machine */
case t0ssIdle: return "t0ssIdle";
case t0ssSendHeader: return "t0ssSendHeader";
case t0ssRecvProcedure: return "t0ssRecvProcedu";
case t0ssSendByte: return "t0ssSendByte";
case t0ssSendData: return "t0ssSendData";
case t0ssRecvSW1: return "t0ssRecvSW1";
case t0ssRecvSW2: return "t0ssRecvSW2";
/* commands to T0 recv state machine */
case t0rcStart: return "t0rcStart";
case t0rcTWorkWaiting: return "t0rcTWorkWaiting";
/* states in T0 recv state machine */
case t0rsIdle: return "t0rsIdle";
case t0rsSendHeader: return "t0rsSendHeader";
case t0rsRecvProcedure: return "t0rsRecvProcedure";
case t0rsRecvByte: return "t0rsRecvByte";
case t0rsRecvData: return "t0rsRecvData";
case t0rsRecvSW1: return "t0rsRecvSW1";
case t0rsRecvSW2: return "t0rsRecvSW2";
/* commands to Answer To Reset (ATR) state machine */
case atrcStart: return "atrcStart";
case atrcT3: return "0x0b04";
case atrcTWorkWaiting: return "atrcTWorkWaiting";
/* states in in Anser To Reset (ATR) state machine */
case atrsIdle: return "atrsIdle";
case atrsTS: return "atrsTS";
case atrsT0: return "atrsT0";
case atrsTABCD: return "atrsTABCD";
case atrsTK: return "atrsTK";
case atrsTCK: return "atrsTCK";
/* commands to T0 Recv Byte state machine */
case t0rbcStart: return "t0rbcStart";
case t0rbcAbort: return "t0rbcAbort";
case t0rbcTFindStartEdge:return "t0rbcTFindStartEdge";
case t0rbcTFindStartMid: return "t0rbcTFindStartMid";
case t0rbcTClockData: return "t0rbcTClockData";
case t0rbcTErrorStart: return "t0rbcTErrorStart";
case t0rbcTErrorStop: return "t0rbcTErrorStop";
/* states in in TO Recv Byte state machine */
case t0rbsIdle: return "t0rbsIdle";
case t0rbsFindStartEdge: return "t0rbcFindStartEdge";
case t0rbsFindStartMid: return "t0rbcFindStartMid";
case t0rbsClockData: return "t0rbcClockData";
case t0rbsSendError: return "t0rbcSendError";
/* commands to T0 Send Byte state machine */
case t0sbcStart: return "t0sbcStart";
case t0sbcAbort: return "t0sbcAbort";
case t0sbcTGuardTime: return "t0sbcTGuardTime";
case t0sbcTClockData: return "t0sbcTClockData";
case t0sbcTError: return "t0sbcTError";
case t0sbcTResend: return "t0sbcTResend";
/* states in in T0 Send Byte state machine */
case t0sbsIdle: return "t0sbsIdle";
case t0sbsClockData: return "t0sbsClockData";
case t0sbsWaitError: return "t0sbsWaitError";
case t0sbsWaitResend: return "t0sbsWaitResend";
case t0sbsWaitGuardTime: return "t0sbsWaitGuardTime";
case gcT0RecvByte: return "gcT0RecvByte";
case gcT0RecvByteErr: return "gcT0RecvByteErr";
case gcT0SendByte: return "gcT0SendByte";
case gcT0SendByteErr: return "gcT0SendByteErr";
case crcStart: return "crcStart";
case crcT2: return "crcT2";
default:
printf("unkown case, %x\n",x);
break;
}
return "???";
}
#endif /* SCR_DEBUG */