/* $NetBSD: gtethreg.h,v 1.4 2005/12/11 12:22:16 christos Exp $ */ /* * Copyright (c) 2002 Allegro Networks, Inc., Wasabi Systems, Inc. * All rights reserved. * * 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. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed for the NetBSD Project by * Allegro Networks, Inc., and Wasabi Systems, Inc. * 4. The name of Allegro Networks, Inc. may not be used to endorse * or promote products derived from this software without specific prior * written permission. * 5. The name of Wasabi Systems, Inc. may not be used to endorse * or promote products derived from this software without specific prior * written permission. * * THIS SOFTWARE IS PROVIDED BY ALLEGRO NETWORKS, INC. AND * WASABI SYSTEMS, INC. ``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 EITHER ALLEGRO NETWORKS, INC. OR WASABI SYSTEMS, INC. * 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. */ #ifndef _DEV_GTETHREG_H_ #define _DEV_GTETHREG_H_ #define ETH__BIT(bit) (1U << (bit)) #define ETH__LLBIT(bit) (1LLU << (bit)) #define ETH__MASK(bit) (ETH__BIT(bit) - 1) #define ETH__LLMASK(bit) (ETH__LLBIT(bit) - 1) #define ETH__GEN(n, off) (0x2400+((n) << 10)+(ETH__ ## off)) #define ETH__EXT(data, bit, len) (((data) >> (bit)) & ETH__MASK(len)) #define ETH__LLEXT(data, bit, len) (((data) >> (bit)) & ETH__LLMASK(len)) #define ETH__CLR(data, bit, len) ((data) &= ~(ETH__MASK(len) << (bit))) #define ETH__INS(new, bit) ((new) << (bit)) #define ETH__LLINS(new, bit) ((uint64_t)(new) << (bit)) /* * Descriptors used for both receive & transmit data. Note that the descriptor * must start on a 4LW boundary. Since the GT accesses the descriptor as * two 64-bit quantities, we must present them 32bit quantities in the right * order based on endianess. */ struct gt_eth_desc { #if defined(BYTE_ORDER) && BYTE_ORDER == BIG_ENDIAN u_int32_t ed_lencnt; /* length is hi 16 bits; count (rx) is lo 16 */ u_int32_t ed_cmdsts; /* command (hi16)/status (lo16) bits */ u_int32_t ed_nxtptr; /* next descriptor (must be 4LW aligned) */ u_int32_t ed_bufptr; /* pointer to packet buffer */ #endif #if defined(BYTE_ORDER) && BYTE_ORDER == LITTLE_ENDIAN u_int32_t ed_cmdsts; /* command (hi16)/status (lo16) bits */ u_int32_t ed_lencnt; /* length is hi 16 bits; count (rx) is lo 16 */ u_int32_t ed_bufptr; /* pointer to packet buffer */ u_int32_t ed_nxtptr; /* next descriptor (must be 4LW aligned) */ #endif }; /* Table 578: Ethernet TX Descriptor - Command/Status word * All bits except F, EI, AM, O are only valid if TX_CMD_L is also set, * otherwise should be 0 (tx). */ #define TX_STS_LC ETH__BIT(5) /* Late Collision */ #define TX_STS_UR ETH__BIT(6) /* Underrun error */ #define TX_STS_RL ETH__BIT(8) /* Retransmit Limit (excession coll) */ #define TX_STS_COL ETH__BIT(9) /* Collision Occurred */ #define TX_STS_RC(v) ETH__GETBITS(v, 10, 4) /* Retransmit Count */ #define TX_STS_ES ETH__BIT(15) /* Error Summary (LC|UR|RL) */ #define TX_CMD_L ETH__BIT(16) /* Last - End Of Packet */ #define TX_CMD_F ETH__BIT(17) /* First - Start Of Packet */ #define TX_CMD_P ETH__BIT(18) /* Pad Packet */ #define TX_CMD_GC ETH__BIT(22) /* Generate CRC */ #define TX_CMD_EI ETH__BIT(23) /* Enable Interrupt */ #define TX_CMD_AM ETH__BIT(30) /* Auto Mode */ #define TX_CMD_O ETH__BIT(31) /* Ownership (1=GT 0=CPU) */ #define TX_CMD_FIRST (TX_CMD_F|TX_CMD_O) #define TX_CMD_LAST (TX_CMD_L|TX_CMD_GC|TX_CMD_P|TX_CMD_O) /* Table 582: Ethernet RX Descriptor - Command/Status Word * All bits except F, EI, AM, O are only valid if RX_CMD_L is also set, * otherwise should be ignored (rx). */ #define RX_STS_CE ETH__BIT(0) /* CRC Error */ #define RX_STS_COL ETH__BIT(1) /* Collision sensed during reception */ #define RX_STS_LC ETH__BIT(5) /* Late Collision (Reserved) */ #define RX_STS_OR ETH__BIT(6) /* Overrun Error */ #define RX_STS_MFL ETH__BIT(7) /* Max Frame Len Error */ #define RX_STS_SF ETH__BIT(8) /* Short Frame Error (< 64 bytes) */ #define RX_STS_FT ETH__BIT(11) /* Frame Type (1 = 802.3) */ #define RX_STS_M ETH__BIT(12) /* Missed Frame */ #define RX_STS_HE ETH__BIT(13) /* Hash Expired (manual match) */ #define RX_STS_IGMP ETH__BIT(14) /* IGMP Packet */ #define RX_STS_ES ETH__BIT(15) /* Error Summary (CE|COL|LC|OR|MFL|SF) */ #define RX_CMD_L ETH__BIT(16) /* Last - End Of Packet */ #define RX_CMD_F ETH__BIT(17) /* First - Start Of Packet */ #define RX_CMD_EI ETH__BIT(23) /* Enable Interrupt */ #define RX_CMD_AM ETH__BIT(30) /* Auto Mode */ #define RX_CMD_O ETH__BIT(31) /* Ownership (1=GT 0=CPU) */ /* Table 586: Hash Table Entry Fields */ #define HSH_V ETH__LLBIT(0) /* Entry is valid */ #define HSH_S ETH__LLBIT(1) /* Skip this entry */ #define HSH_RD ETH__LLBIT(2) /* Receive(1) / Discard (0) */ #define HSH_R ETH__LLBIT(2) /* Receive(1) */ #define HSH_PRIO_GET(v) ETH__LLEXT(v, 51, 2) #define HSH_PRIO_INS(v) ETH__LLINS(v, 51) #define HSH_ADDR_MASK 0x7fffff8LLU #define HSH_LIMIT 12 #define ETH_EPAR 0x2000 /* PHY Address Register */ #define ETH_ESMIR 0x2010 /* SMI Register */ #define ETH_BASE_ETH0 0x2400 /* Ethernet0 Register Base */ #define ETH_BASE_ETH1 0x2800 /* Ethernet1 Register Base */ #define ETH_BASE_ETH2 0x2c00 /* Ethernet2 Register Base */ #define ETH_SIZE 0x0400 /* Register Space */ #define ETH__EBASE 0x0000 /* Base of Registers */ #define ETH__EPCR 0x0000 /* Port Config. Register */ #define ETH__EPCXR 0x0008 /* Port Config. Extend Reg */ #define ETH__EPCMR 0x0010 /* Port Command Register */ #define ETH__EPSR 0x0018 /* Port Status Register */ #define ETH__ESPR 0x0020 /* Port Serial Parameters Reg */ #define ETH__EHTPR 0x0028 /* Port Hash Table Pointer Reg*/ #define ETH__EFCSAL 0x0030 /* Flow Control Src Addr Low */ #define ETH__EFCSAH 0x0038 /* Flow Control Src Addr High */ #define ETH__ESDCR 0x0040 /* SDMA Configuration Reg */ #define ETH__ESDCMR 0x0048 /* SDMA Command Register */ #define ETH__EICR 0x0050 /* Interrupt Cause Register */ #define ETH__EIMR 0x0058 /* Interrupt Mask Register */ #define ETH__EFRDP0 0x0080 /* First Rx Desc Pointer 0 */ #define ETH__EFRDP1 0x0084 /* First Rx Desc Pointer 1 */ #define ETH__EFRDP2 0x0088 /* First Rx Desc Pointer 2 */ #define ETH__EFRDP3 0x008c /* First Rx Desc Pointer 3 */ #define ETH__ECRDP0 0x00a0 /* Current Rx Desc Pointer 0 */ #define ETH__ECRDP1 0x00a4 /* Current Rx Desc Pointer 1 */ #define ETH__ECRDP2 0x00a8 /* Current Rx Desc Pointer 2 */ #define ETH__ECRDP3 0x00ac /* Current Rx Desc Pointer 3 */ #define ETH__ECTDP0 0x00e0 /* Current Tx Desc Pointer 0 */ #define ETH__ECTDP1 0x00e4 /* Current Tx Desc Pointer 1 */ #define ETH__EDSCP2P0L 0x0060 /* IP Differentiated Services CodePoint to Priority0 low */ #define ETH__EDSCP2P0H 0x0064 /* IP Differentiated Services CodePoint to Priority0 high*/ #define ETH__EDSCP2P1L 0x0068 /* IP Differentiated Services CodePoint to Priority1 low */ #define ETH__EDSCP2P1H 0x006c /* IP Differentiated Services CodePoint to Priority1 high*/ #define ETH__EVPT2P 0x0068 /* VLAN Prio. Tag to Priority */ #define ETH__EMIBCTRS 0x0100 /* MIB Counters */ #define ETH_BASE(n) ETH__GEN(n, EBASE) #define ETH_EPCR(n) ETH__GEN(n, EPCR) /* Port Config. Register */ #define ETH_EPCXR(n) ETH__GEN(n, EPCXR) /* Port Config. Extend Reg */ #define ETH_EPCMR(n) ETH__GEN(n, EPCMR) /* Port Command Register */ #define ETH_EPSR(n) ETH__GEN(n, EPSR) /* Port Status Register */ #define ETH_ESPR(n) ETH__GEN(n, ESPR) /* Port Serial Parameters Reg */ #define ETH_EHTPR(n) ETH__GEN(n, EHPTR) /* Port Hash Table Pointer Reg*/ #define ETH_EFCSAL(n) ETH__GEN(n, EFCSAL) /* Flow Control Src Addr Low */ #define ETH_EFCSAH(n) ETH__GEN(n, EFCSAH) /* Flow Control Src Addr High */ #define ETH_ESDCR(n) ETH__GEN(n, ESDCR) /* SDMA Configuration Reg */ #define ETH_ESDCMR(n) ETH__GEN(n, ESDCMR) /* SDMA Command Register */ #define ETH_EICR(n) ETH__GEN(n, EICR) /* Interrupt Cause Register */ #define ETH_EIMR(n) ETH__GEN(n, EIMR) /* Interrupt Mask Register */ #define ETH_EFRDP0(n) ETH__GEN(n, EFRDP0) /* First Rx Desc Pointer 0 */ #define ETH_EFRDP1(n) ETH__GEN(n, EFRDP1) /* First Rx Desc Pointer 1 */ #define ETH_EFRDP2(n) ETH__GEN(n, EFRDP2) /* First Rx Desc Pointer 2 */ #define ETH_EFRDP3(n) ETH__GEN(n, EFRDP3) /* First Rx Desc Pointer 3 */ #define ETH_ECRDP0(n) ETH__GEN(n, ECRDP0) /* Current Rx Desc Pointer 0 */ #define ETH_ECRDP1(n) ETH__GEN(n, ECRDP1) /* Current Rx Desc Pointer 1 */ #define ETH_ECRDP2(n) ETH__GEN(n, ECRDP2) /* Current Rx Desc Pointer 2 */ #define ETH_ECRDP3(n) ETH__GEN(n, ECRDP3) /* Current Rx Desc Pointer 3 */ #define ETH_ECTDP0(n) ETH__GEN(n, ECTDP0) /* Current Tx Desc Pointer 0 */ #define ETH_ECTDP1(n) ETH__GEN(n, ECTDP1) /* Current Tx Desc Pointer 1 */ #define ETH_EDSCP2P0L(n) ETH__GEN(n, EDSCP2P0L) /* IP Differentiated Services CodePoint to Priority0 low */ #define ETH_EDSCP2P0H(n) ETH__GEN(n, EDSCP2P0H) /* IP Differentiated Services CodePoint to Priority0 high*/ #define ETH_EDSCP2P1L(n) ETH__GEN(n, EDSCP2P1L) /* IP Differentiated Services CodePoint to Priority1 low */ #define ETH_EDSCP2P1H(n) ETH__GEN(n, EDSCP1P1H) /* IP Differentiated Services CodePoint to Priority1 high*/ #define ETH_EVPT2P(n) ETH__GEN(n, EVPT2P) /* VLAN Prio. Tag to Priority */ #define ETH_EMIBCTRS(n) ETH__GEN(n, EMIBCTRS) /* MIB Counters */ #define ETH_EPAR_PhyAD_GET(v, n) (((v) >> ((n) * 5)) & 0x1f) #define ETH_ESMIR_READ(phy, reg) (ETH__INS(phy, 16)|\ ETH__INS(reg, 21)|\ ETH_ESMIR_ReadOpcode) #define ETH_ESMIR_WRITE(phy, reg, val) (ETH__INS(phy, 16)|\ ETH__INS(reg, 21)|\ ETH__INS(val, 0)|\ ETH_ESMIR_WriteOpcode) #define ETH_ESMIR_Value_GET(v) ETH__EXT(v, 0, 16) #define ETH_ESMIR_WriteOpcode 0 #define ETH_ESMIR_ReadOpcode ETH__BIT(26) #define ETH_ESMIR_ReadValid ETH__BIT(27) #define ETH_ESMIR_Busy ETH__BIT(28) /* * Table 597: Port Configuration Register (PCR) * 00:00 PM Promiscuous mode * 0: Normal mode (Frames are only received if the * destination address is found in the hash * table) * 1: Promiscuous mode (Frames are received * regardless of their destination address. * Errored frames are discarded unless the Port * Configuration register's PBF bit is set) * 01:01 RBM Reject Broadcast Mode * 0: Receive broadcast address * 1: Reject frames with broadcast address * Overridden by the promiscuous mode. * 02:02 PBF Pass Bad Frames * (0: Normal mode, 1: Pass bad Frames) * The Ethernet receiver passes to the CPU errored * frames (like fragments and collided packets) * that are normally rejected. * NOTE: Frames are only passed if they * successfully pass address filtering. * 06:03 Reserved * 07:07 EN Enable (0: Disabled, 1: Enable) * When enabled, the ethernet port is ready to * transmit/receive. * 09:08 LPBK Loop Back Mode * 00: Normal mode * 01: Internal loop back mode (TX data is looped * back to the RX lines. No transition is seen * on the interface pins) * 10: External loop back mode (TX data is looped * back to the RX lines and also transmitted * out to the MII interface pins) * 11: Reserved * 10:10 FC Force Collision * 0: Normal mode. * 1: Force Collision on any TX frame. * For RXM test (in Loopback mode). * 11:11 Reserved. * 12:12 HS Hash Size * 0: 8K address filtering * (256KB of memory space required). * 1: 512 address filtering * ( 16KB of memory space required). * 13:13 HM Hash Mode (0: Hash Func. 0; 1: Hash Func. 1) * 14:14 HDM Hash Default Mode * 0: Discard addresses not found in address table * 1: Pass addresses not found in address table * 15:15 HD Duplex Mode (0: Half Duplex, 1: Full Duplex) * NOTE: Valid only when auto-negotiation for * duplex mode is disabled. * 30:16 Reserved * 31:31 ACCS Accelerate Slot Time * (0: Normal mode, 1: Reserved) */ #define ETH_EPCR_PM ETH__BIT(0) #define ETH_EPCR_RBM ETH__BIT(1) #define ETH_EPCR_PBF ETH__BIT(2) #define ETH_EPCR_EN ETH__BIT(7) #define ETH_EPCR_LPBK_GET(v) ETH__BIT(v, 8, 2) #define ETH_EPCR_LPBK_Normal 0 #define ETH_EPCR_LPBK_Internal 1 #define ETH_EPCR_LPBK_External 2 #define ETH_EPCR_FC ETH__BIT(10) #define ETH_EPCR_HS ETH__BIT(12) #define ETH_EPCR_HS_8K 0 #define ETH_EPCR_HS_512 ETH_EPCR_HS #define ETH_EPCR_HM ETH__BIT(13) #define ETH_EPCR_HM_0 0 #define ETH_EPCR_HM_1 ETH_EPCR_HM #define ETH_EPCR_HDM ETH__BIT(14) #define ETH_EPCR_HDM_Discard 0 #define ETH_EPCR_HDM_Pass ETH_EPCR_HDM #define ETH_EPCR_HD_Half 0 #define ETH_EPCR_HD_Full ETH_EPCR_HD_Full #define ETH_EPCR_ACCS ETH__BIT(31) /* * Table 598: Port Configuration Extend Register (PCXR) * 00:00 IGMP IGMP Packets Capture Enable * 0: IGMP packets are treated as normal Multicast * packets. * 1: IGMP packets on IPv4/Ipv6 over Ethernet/802.3 * are trapped and sent to high priority RX * queue. * 01:01 SPAN Spanning Tree Packets Capture Enable * 0: BPDU (Bridge Protocol Data Unit) packets are * treated as normal Multicast packets. * 1: BPDU packets are trapped and sent to high * priority RX queue. * 02:02 PAR Partition Enable (0: Normal, 1: Partition) * When more than 61 collisions occur while * transmitting, the port enters Partition mode. * It waits for the first good packet from the * wire and then goes back to Normal mode. Under * Partition mode it continues transmitting, but * it does not receive. * 05:03 PRIOtx Priority weight in the round-robin between high * and low priority TX queues. * 000: 1 pkt from HIGH, 1 pkt from LOW. * 001: 2 pkt from HIGH, 1 pkt from LOW. * 010: 4 pkt from HIGH, 1 pkt from LOW. * 011: 6 pkt from HIGH, 1 pkt from LOW. * 100: 8 pkt from HIGH, 1 pkt from LOW. * 101: 10 pkt from HIGH, 1 pkt from LOW. * 110: 12 pkt from HIGH, 1 pkt from LOW. * 111: All pkt from HIGH, 0 pkt from LOW. LOW is * served only if HIGH is empty. * NOTE: If the HIGH queue is emptied before * finishing the count, the count is reset * until the next first HIGH comes in. * 07:06 PRIOrx Default Priority for Packets Received on this * Port (00: Lowest priority, 11: Highest priority) * 08:08 PRIOrx_Override Override Priority for Packets Received on this * Port (0: Do not override, 1: Override with * field) * 09:09 DPLXen Enable Auto-negotiation for Duplex Mode * (0: Enable, 1: Disable) * 11:10 FCTLen Enable Auto-negotiation for 802.3x Flow-control * 0: Enable; When enabled, 1 is written (through * SMI access) to the PHY's register 4 bit 10 * to advertise flow-control capability. * 1: Disable; Only enables flow control after the * PHY address is set by the CPU. When changing * the PHY address the flow control * auto-negotiation must be disabled. * 11:11 FLP Force Link Pass * (0: Force Link Pass, 1: Do NOT Force Link pass) * 12:12 FCTL 802.3x Flow-Control Mode (0: Enable, 1: Disable) * NOTE: Only valid when auto negotiation for flow * control is disabled. * 13:13 Reserved * 15:14 MFL Max Frame Length * Maximum packet allowed for reception (including * CRC): 00: 1518 bytes, 01: 1536 bytes, * 10: 2048 bytes, 11: 64K bytes * 16:16 MIBclrMode MIB Counters Clear Mode (0: Clear, 1: No effect) * 17:17 MIBctrMode Reserved. (MBZ) * 18:18 Speed Port Speed (0: 10Mbit/Sec, 1: 100Mbit/Sec) * NOTE: Only valid if SpeedEn bit is set. * 19:19 SpeedEn Enable Auto-negotiation for Speed * (0: Enable, 1: Disable) * 20:20 RMIIen RMII enable * 0: Port functions as MII port * 1: Port functions as RMII port * 21:21 DSCPen DSCP enable * 0: IP DSCP field decoding is disabled. * 1: IP DSCP field decoding is enabled. * 31:22 Reserved */ #define ETH_EPCXR_IGMP ETH__BIT(0) #define ETH_EPCXR_SPAN ETH__BIT(1) #define ETH_EPCXR_PAR ETH__BIT(2) #define ETH_EPCXR_PRIOtx_GET(v) ETH__EXT(v, 3, 3) #define ETH_EPCXR_PRIOrx_GET(v) ETH__EXT(v, 3, 3) #define ETH_EPCXR_PRIOrx_Override ETH__BIT(8) #define ETH_EPCXR_DLPXen ETH__BIT(9) #define ETH_EPCXR_FCTLen ETH__BIT(10) #define ETH_EPCXR_FLP ETH__BIT(11) #define ETH_EPCXR_FCTL ETH__BIT(12) #define ETH_EPCXR_MFL_GET(v) ETH__EXT(v, 14, 2) #define ETH_EPCXR_MFL_1518 0 #define ETH_EPCXR_MFL_1536 1 #define ETH_EPCXR_MFL_2084 2 #define ETH_EPCXR_MFL_64K 3 #define ETH_EPCXR_MIBclrMode ETH__BIT(16) #define ETH_EPCXR_MIBctrMode ETH__BIT(17) #define ETH_EPCXR_Speed ETH__BIT(18) #define ETH_EPCXR_SpeedEn ETH__BIT(19) #define ETH_EPCXR_RMIIEn ETH__BIT(20) #define ETH_EPCXR_DSCPEn ETH__BIT(21) /* * Table 599: Port Command Register (PCMR) * 14:00 Reserved * 15:15 FJ Force Jam / Flow Control * When in half-duplex mode, the CPU uses this bit * to force collisions on the Ethernet segment. * When the CPU recognizes that it is going to run * out of receive buffers, it can force the * transmitter to send jam frames, forcing * collisions on the wire. To allow transmission * on the Ethernet segment, the CPU must clear the * FJ bit when more resources are available. When * in full-duplex and flow-control is enabled, this * bit causes the port's transmitter to send * flow-control PAUSE packets. The CPU must reset * this bit when more resources are available. * 31:16 Reserved */ #define ETH_EPCMR_FJ ETH__BIT(15) /* * Table 600: Port Status Register (PSR) -- Read Only * 00:00 Speed Indicates Port Speed (0: 10Mbs, 1: 100Mbs) * 01:01 Duplex Indicates Port Duplex Mode (0: Half, 1: Full) * 02:02 Fctl Indicates Flow-control Mode * (0: enabled, 1: disabled) * 03:03 Link Indicates Link Status (0: down, 1: up) * 04:04 Pause Indicates that the port is in flow-control * disabled state. This bit is set when an IEEE * 802.3x flow-control PAUSE (XOFF) packet is * received (assuming that flow-control is * enabled and the port is in full-duplex mode). * Reset when XON is received, or when the XOFF * timer has expired. * 05:05 TxLow Tx Low Priority Status * Indicates the status of the low priority * transmit queue: (0: Stopped, 1: Running) * 06:06 TxHigh Tx High Priority Status * Indicates the status of the high priority * transmit queue: (0: Stopped, 1: Running) * 07:07 TXinProg TX in Progress * Indicates that the port's transmitter is in an * active transmission state. * 31:08 Reserved */ #define ETH_EPSR_Speed ETH__BIT(0) #define ETH_EPSR_Duplex ETH__BIT(1) #define ETH_EPSR_Fctl ETH__BIT(2) #define ETH_EPSR_Link ETH__BIT(3) #define ETH_EPSR_Pause ETH__BIT(4) #define ETH_EPSR_TxLow ETH__BIT(5) #define ETH_EPSR_TxHigh ETH__BIT(6) #define ETH_EPSR_TXinProg ETH__BIT(7) /* * Table 601: Serial Parameters Register (SPR) * 01:00 JAM_LENGTH Two bits to determine the JAM Length * (in Backpressure) as follows: * 00 = 12K bit-times * 01 = 24K bit-times * 10 = 32K bit-times * 11 = 48K bit-times * 06:02 JAM_IPG Five bits to determine the JAM IPG. * The step is four bit-times. The value may vary * between 4 bit time to 124. * 11:07 IPG_JAM_TO_DATA Five bits to determine the IPG JAM to DATA. * The step is four bit-times. The value may vary * between 4 bit time to 124. * 16:12 IPG_DATA Inter-Packet Gap (IPG) * The step is four bit-times. The value may vary * between 12 bit time to 124. * NOTE: These bits may be changed only when the * Ethernet ports is disabled. * 21:17 Data_Blind Data Blinder * The number of nibbles from the beginning of the * IPG, in which the IPG counter is restarted when * detecting a carrier activity. Following this * value, the port enters the Data Blinder zone and * does not reset the IPG counter. This ensures * fair access to the medium. * The default is 10 hex (64 bit times - 2/3 of the * default IPG). The step is 4 bit-times. Valid * range is 3 to 1F hex nibbles. * NOTE: These bits may be only changed when the * Ethernet port is disabled. * 22:22 Limit4 The number of consecutive packet collisions that * occur before the collision counter is reset. * 0: The port resets its collision counter after * 16 consecutive retransmit trials and * restarts the Backoff algorithm. * 1: The port resets its collision counter and * restarts the Backoff algorithm after 4 * consecutive transmit trials. * 31:23 Reserved */ #define ETH_ESPR_JAM_LENGTH_GET(v) ETH__EXT(v, 0, 2) #define ETH_ESPR_JAM_IPG_GET(v) ETH__EXT(v, 2, 5) #define ETH_ESPR_IPG_JAM_TO_DATA_GET(v) ETH__EXT(v, 7, 5) #define ETH_ESPR_IPG_DATA_GET(v) ETH__EXT(v, 12, 5) #define ETH_ESPR_Data_Bilnd_GET(v) ETH__EXT(v, 17, 5) #define ETH_ESPR_Limit4(v) ETH__BIT(22) /* * Table 602: Hash Table Pointer Register (HTPR) * 31:00 HTP 32-bit pointer to the address table. * Bits [2:0] must be set to zero. */ /* * Table 603: Flow Control Source Address Low (FCSAL) * 15:0 SA[15:0] Source Address * The least significant bits of the source * address for the port. This address is used for * Flow Control. * 31:16 Reserved */ /* * Table 604: Flow Control Source Address High (FCSAH) * 31:0 SA[47:16] Source Address * The most significant bits of the source address * for the port. This address is used for Flow * Control. */ /* * Table 605: SDMA Configuration Register (SDCR) * 01:00 Reserved * 05:02 RC Retransmit Count * Sets the maximum number of retransmits per * packet. After executing retransmit for RC * times, the TX SDMA closes the descriptor with a * Retransmit Limit error indication and processes * the next packet. When RC is set to 0, the * number of retransmits is unlimited. In this * case, the retransmit process is only terminated * if CPU issues an Abort command. * 06:06 BLMR Big/Little Endian Receive Mode * The DMA supports Big or Little Endian * configurations on a per channel basis. The BLMR * bit only affects data transfer to memory. * 0: Big Endian * 1: Little Endian * 07:07 BLMT Big/Little Endian Transmit Mode * The DMA supports Big or Little Endian * configurations on a per channel basis. The BLMT * bit only affects data transfer from memory. * 0: Big Endian * 1: Little Endian * 08:08 POVR PCI Override * When set, causes the SDMA to direct all its * accesses in PCI_0 direction and overrides * normal address decoding process. * 09:09 RIFB Receive Interrupt on Frame Boundaries * When set, the SDMA Rx generates interrupts only * on frame boundaries (i.e. after writing the * frame status to the descriptor). * 11:10 Reserved * 13:12 BSZ Burst Size * Sets the maximum burst size for SDMA * transactions: * 00: Burst is limited to 1 64bit words. * 01: Burst is limited to 2 64bit words. * 10: Burst is limited to 4 64bit words. * 11: Burst is limited to 8 64bit words. * 31:14 Reserved */ #define ETH_ESDCR_RC_GET(v) ETH__EXT(v, 2, 4) #define ETH_ESDCR_BLMR ETH__BIT(6) #define ETH_ESDCR_BLMT ETH__BIT(7) #define ETH_ESDCR_POVR ETH__BIT(8) #define ETH_ESDCR_RIFB ETH__BIT(9) #define ETH_ESDCR_BSZ_GET(v) ETH__EXT(v, 12, 2) #define ETH_ESDCR_BSZ_SET(v, n) (ETH__CLR(v, 12, 2),\ (v) |= ETH__INS(n, 12)) #define ETH_ESDCR_BSZ_1 0 #define ETH_ESDCR_BSZ_2 1 #define ETH_ESDCR_BSZ_4 2 #define ETH_ESDCR_BSZ_8 3 #define ETH_ESDCR_BSZ_Strings { "1 64-bit word", "2 64-bit words", \ "4 64-bit words", "8 64-bit words" } /* * Table 606: SDMA Command Register (SDCMR) * 06:00 Reserved * 07:07 ERD Enable RX DMA. * Set to 1 by the CPU to cause the SDMA to start * a receive process. Cleared when the CPU issues * an Abort Receive command. * 14:08 Reserved * 15:15 AR Abort Receive * Set to 1 by the CPU to abort a receive SDMA * operation. When the AR bit is set, the SDMA * aborts its current operation and moves to IDLE. * No descriptor is closed. The AR bit is cleared * upon entering IDLE. After setting the AR bit, * the CPU must poll the bit to verify that the * abort sequence is completed. * 16:16 STDH Stop TX High * Set to 1 by the CPU to stop the transmission * process from the high priority queue at the end * of the current frame. An interrupt is generated * when the stop command has been executed. * Writing 1 to STDH resets TXDH bit. * Writing 0 to this bit has no effect. * 17:17 STDL Stop TX Low * Set to 1 by the CPU to stop the transmission * process from the low priority queue at the end * of the current frame. An interrupt is generated * when the stop command has been executed. * Writing 1 to STDL resets TXDL bit. * Writing 0 to this bit has no effect. * 22:18 Reserved * 23:23 TXDH Start Tx High * Set to 1 by the CPU to cause the SDMA to fetch * the first descriptor and start a transmit * process from the high priority Tx queue. * Writing 1 to TXDH resets STDH bit. * Writing 0 to this bit has no effect. * 24:24 TXDL Start Tx Low * Set to 1 by the CPU to cause the SDMA to fetch * the first descriptor and start a transmit * process from the low priority Tx queue. * Writing 1 to TXDL resets STDL bit. * Writing 0 to this bit has no effect. * 30:25 Reserved * 31:31 AT Abort Transmit * Set to 1 by the CPU to abort a transmit DMA * operation. When the AT bit is set, the SDMA * aborts its current operation and moves to IDLE. * No descriptor is closed. Cleared upon entering * IDLE. After setting AT bit, the CPU must poll * it in order to verify that the abort sequence * is completed. */ #define ETH_ESDCMR_ERD ETH__BIT(7) #define ETH_ESDCMR_AR ETH__BIT(15) #define ETH_ESDCMR_STDH ETH__BIT(16) #define ETH_ESDCMR_STDL ETH__BIT(17) #define ETH_ESDCMR_TXDH ETH__BIT(23) #define ETH_ESDCMR_TXDL ETH__BIT(24) #define ETH_ESDCMR_AT ETH__BIT(31) /* * Table 607: Interrupt Cause Register (ICR) * 00:00 RxBuffer Rx Buffer Return * Indicates an Rx buffer returned to CPU ownership * or that the port finished reception of a Rx * frame in either priority queues. * NOTE: In order to get a Rx Buffer return per * priority queue, use bit 19:16. This bit is * set upon closing any Rx descriptor which * has its EI bit set. To limit the * interrupts to frame (rather than buffer) * boundaries, the user must set SDMA * Configuration register's RIFB bit. When * the RIFB bit is set, an interrupt * generates only upon closing the first * descriptor of a received packet, if this * descriptor has it EI bit set. * 01:01 Reserved * 02:02 TxBufferHigh Tx Buffer for High priority Queue * Indicates a Tx buffer returned to CPU ownership * or that the port finished transmission of a Tx * frame. * NOTE: This bit is set upon closing any Tx * descriptor which has its EI bit set. To * limit the interrupts to frame (rather than * buffer) boundaries, the user must set EI * only in the last descriptor. * 03:03 TxBufferLow Tx Buffer for Low Priority Queue * Indicates a Tx buffer returned to CPU ownership * or that the port finished transmission of a Tx * frame. * NOTE: This bit is set upon closing any Tx * descriptor which has its EI bit set. To * limit the interrupts to frame (rather than * buffer) boundaries, the user must set EI * only in the last descriptor. * 05:04 Reserved * 06:06 TxEndHigh Tx End for High Priority Queue * Indicates that the Tx DMA stopped processing the * high priority queue after stop command, or that * it reached the end of the high priority * descriptor chain. * 07:07 TxEndLow Tx End for Low Priority Queue * Indicates that the Tx DMA stopped processing the * low priority queue after stop command, or that * it reached the end of the low priority * descriptor chain. * 08:08 RxError Rx Resource Error * Indicates a Rx resource error event in one of * the priority queues. * NOTE: To get a Rx Resource Error Indication per * priority queue, use bit 23:20. * 09:09 Reserved * 10:10 TxErrorHigh Tx Resource Error for High Priority Queue * Indicates a Tx resource error event during * packet transmission from the high priority queue * 11:11 TxErrorLow Tx Resource Error for Low Priority Queue * Indicates a Tx resource error event during * packet transmission from the low priority queue * 12:12 RxOVR Rx Overrun * Indicates an overrun event that occurred during * reception of a packet. * 13:13 TxUdr Tx Underrun * Indicates an underrun event that occurred during * transmission of packet from either queue. * 15:14 Reserved * 16:16 RxBuffer-Queue[0] Rx Buffer Return in Priority Queue[0] * Indicates a Rx buffer returned to CPU ownership * or that the port completed reception of a Rx * frame in a receive priority queue[0] * 17:17 RxBuffer-Queue[1] Rx Buffer Return in Priority Queue[1] * Indicates a Rx buffer returned to CPU ownership * or that the port completed reception of a Rx * frame in a receive priority queue[1]. * 18:18 RxBuffer-Queue[2] Rx Buffer Return in Priority Queue[2] * Indicates a Rx buffer returned to CPU ownership * or that the port completed reception of a Rx * frame in a receive priority queue[2]. * 19:19 RxBuffer-Queue[3] Rx Buffer Return in Priority Queue[3] * Indicates a Rx buffer returned to CPU ownership * or that the port completed reception of a Rx * frame in a receive priority queue[3]. * 20:20 RxError-Queue[0] Rx Resource Error in Priority Queue[0] * Indicates a Rx resource error event in receive * priority queue[0]. * 21:21 RxError-Queue[1] Rx Resource Error in Priority Queue[1] * Indicates a Rx resource error event in receive * priority queue[1]. * 22:22 RxError-Queue[2] Rx Resource Error in Priority Queue[2] * Indicates a Rx resource error event in receive * priority queue[2]. * 23:23 RxError-Queue[3] Rx Resource Error in Priority Queue[3] * Indicates a Rx resource error event in receive * priority queue[3]. * 27:24 Reserved * 28:29 MIIPhySTC MII PHY Status Change * Indicates a status change reported by the PHY * connected to this port. Set when the MII * management interface block identifies a change * in PHY's register 1. * 29:29 SMIdone SMI Command Done * Indicates that the SMI completed a MII * management command (either read or write) that * was initiated by the CPU writing to the SMI * register. * 30:30 Reserved * 31:31 EtherIntSum Ethernet Interrupt Summary * This bit is a logical OR of the (unmasked) bits * [30:04] in the Interrupt Cause register. */ #define ETH_IR_RxBuffer ETH__BIT(0) #define ETH_IR_TxBufferHigh ETH__BIT(2) #define ETH_IR_TxBufferLow ETH__BIT(3) #define ETH_IR_TxEndHigh ETH__BIT(6) #define ETH_IR_TxEndLow ETH__BIT(7) #define ETH_IR_RxError ETH__BIT(8) #define ETH_IR_TxErrorHigh ETH__BIT(10) #define ETH_IR_TxErrorLow ETH__BIT(11) #define ETH_IR_RxOVR ETH__BIT(12) #define ETH_IR_TxUdr ETH__BIT(13) #define ETH_IR_RxBuffer_0 ETH__BIT(16) #define ETH_IR_RxBuffer_1 ETH__BIT(17) #define ETH_IR_RxBuffer_2 ETH__BIT(18) #define ETH_IR_RxBuffer_3 ETH__BIT(19) #define ETH_IR_RxBuffer_GET(v) ETH__EXT(v, 16, 4) #define ETH_IR_RxError_0 ETH__BIT(20) #define ETH_IR_RxError_1 ETH__BIT(21) #define ETH_IR_RxError_2 ETH__BIT(22) #define ETH_IR_RxError_3 ETH__BIT(23) #define ETH_IR_RxError_GET(v) ETH__EXT(v, 20, 4) #define ETH_IR_RxBits (ETH_IR_RxBuffer_0|\ ETH_IR_RxBuffer_1|\ ETH_IR_RxBuffer_2|\ ETH_IR_RxBuffer_3|\ ETH_IR_RxError_0|\ ETH_IR_RxError_1|\ ETH_IR_RxError_2|\ ETH_IR_RxError_3) #define ETH_IR_MIIPhySTC ETH__BIT(28) #define ETH_IR_SMIdone ETH__BIT(29) #define ETH_IR_EtherIntSum ETH__BIT(31) #define ETH_IR_Summary ETH__BIT(31) /* * Table 608: Interrupt Mask Register (IMR) * 31:00 Various Mask bits for the Interrupt Cause register. */ /* * Table 609: IP Differentiated Services CodePoint to Priority0 low (DSCP2P0L), * 31:00 Priority0_low The LSB priority bits for DSCP[31:0] entries. */ /* * Table 610: IP Differentiated Services CodePoint to Priority0 high (DSCP2P0H) * 31:00 Priority0_high The LSB priority bits for DSCP[63:32] entries. */ /* * Table 611: IP Differentiated Services CodePoint to Priority1 low (DSCP2P1L) * 31:00 Priority1_low The MSB priority bits for DSCP[31:0] entries. */ /* * Table 612: IP Differentiated Services CodePoint to Priority1 high (DSCP2P1H) * 31:00 Priority1_high The MSB priority bit for DSCP[63:32] entries. */ /* * Table 613: VLAN Priority Tag to Priority (VPT2P) * 07:00 Priority0 The LSB priority bits for VLAN Priority[7:0] * entries. * 15:08 Priority1 The MSB priority bits for VLAN Priority[7:0] * entries. * 31:16 Reserved */ #endif /* _DEV_GTETHREG_H_ */