freebsd-nq/sys/pci/if_skreg.h

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This commit adds driver support for the SysKonnect SK-984x series gigabit ethernet adapters. This includes two single port cards (single mode and multimode fiber) and two dual port cards (also single mode and multimode fiber). SysKonnect is currently the only vendor with a dual port gigabit ethernet NIC. The ports on dual port adapters are treated as separate network interfaces. Thus, if you have an SK-9844 dual port SX card, you should have both sk0 and sk1 interfaces attached. Dual port cards are implemented using two XMAC II chips connected to a single SysKonnect GEnesis controller. Hence, dual port cards are really one PCI device, as opposed to two separate PCI devices connected through a PCI to PCI bridge. Note that SysKonnect's drivers use the two ports for failover purposes rather that as two separate interfaces, plus they don't support jumbo frames. This applies to their Linux driver too. :) Support is provided for hardware multicast filtering, BPF and jumbo frames. The SysKonnect cards support TCP checksum offload however this feature is not currently enabled (hopefully it will be once we get checksum offload support). There are still a few things that need to be implemeted, like the ability to communicate with the on-board LM80 voltage/temperature monitor, but I wanted to get the driver under CVS control and into -current so people could bang on it. A big thanks for SysKonnect for making all their programming info for these cards (and for their FDDI and token ring cards) available without NDA (see www.syskonnect.com).
1999-07-09 04:30:09 +00:00
/*
* Copyright (c) 1997, 1998, 1999
* Bill Paul <wpaul@ctr.columbia.edu>. 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 by Bill Paul.
* 4. Neither the name of the author nor the names of any co-contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY Bill Paul AND CONTRIBUTORS ``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 Bill Paul OR THE VOICES IN HIS HEAD
* 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.
*
1999-08-28 01:08:13 +00:00
* $FreeBSD$
This commit adds driver support for the SysKonnect SK-984x series gigabit ethernet adapters. This includes two single port cards (single mode and multimode fiber) and two dual port cards (also single mode and multimode fiber). SysKonnect is currently the only vendor with a dual port gigabit ethernet NIC. The ports on dual port adapters are treated as separate network interfaces. Thus, if you have an SK-9844 dual port SX card, you should have both sk0 and sk1 interfaces attached. Dual port cards are implemented using two XMAC II chips connected to a single SysKonnect GEnesis controller. Hence, dual port cards are really one PCI device, as opposed to two separate PCI devices connected through a PCI to PCI bridge. Note that SysKonnect's drivers use the two ports for failover purposes rather that as two separate interfaces, plus they don't support jumbo frames. This applies to their Linux driver too. :) Support is provided for hardware multicast filtering, BPF and jumbo frames. The SysKonnect cards support TCP checksum offload however this feature is not currently enabled (hopefully it will be once we get checksum offload support). There are still a few things that need to be implemeted, like the ability to communicate with the on-board LM80 voltage/temperature monitor, but I wanted to get the driver under CVS control and into -current so people could bang on it. A big thanks for SysKonnect for making all their programming info for these cards (and for their FDDI and token ring cards) available without NDA (see www.syskonnect.com).
1999-07-09 04:30:09 +00:00
*/
/*
* SysKonnect PCI vendor ID
*/
#define SK_VENDORID 0x1148
/*
* SK-NET gigabit ethernet device ID
*/
#define SK_DEVICEID_GE 0x4300
/*
* GEnesis registers. The GEnesis chip has a 256-byte I/O window
* but internally it has a 16K register space. This 16K space is
* divided into 128-byte blocks. The first 128 bytes of the I/O
* window represent the first block, which is permanently mapped
* at the start of the window. The other 127 blocks can be mapped
* to the second 128 bytes of the I/O window by setting the desired
* block value in the RAP register in block 0. Not all of the 127
* blocks are actually used. Most registers are 32 bits wide, but
* there are a few 16-bit and 8-bit ones as well.
*/
/* Start of remappable register window. */
#define SK_WIN_BASE 0x0080
/* Size of a window */
#define SK_WIN_LEN 0x80
#define SK_WIN_MASK 0x3F80
#define SK_REG_MASK 0x7F
/* Compute the window of a given register (for the RAP register) */
#define SK_WIN(reg) (((reg) & SK_WIN_MASK) / SK_WIN_LEN)
/* Compute the relative offset of a register within the window */
#define SK_REG(reg) ((reg) & SK_REG_MASK)
#define SK_PORT_A 0
#define SK_PORT_B 1
/*
* Compute offset of port-specific register. Since there are two
* ports, there are two of some GEnesis modules (e.g. two sets of
* DMA queues, two sets of FIFO control registers, etc...). Normally,
* the block for port 0 is at offset 0x0 and the block for port 1 is
* at offset 0x80 (i.e. the next page over). However for the transmit
* BMUs and RAMbuffers, there are two blocks for each port: one for
* the sync transmit queue and one for the async queue (which we don't
* use). However instead of ordering them like this:
* TX sync 1 / TX sync 2 / TX async 1 / TX async 2
* SysKonnect has instead ordered them like this:
* TX sync 1 / TX async 1 / TX sync 2 / TX async 2
* This means that when referencing the TX BMU and RAMbuffer registers,
* we have to double the block offset (0x80 * 2) in order to reach the
* second queue. This prevents us from using the same formula
* (sk_port * 0x80) to compute the offsets for all of the port-specific
* blocks: we need an extra offset for the BMU and RAMbuffer registers.
* The simplest thing is to provide an extra argument to these macros:
* the 'skip' parameter. The 'skip' value is the number of extra pages
* for skip when computing the port0/port1 offsets. For most registers,
* the skip value is 0; for the BMU and RAMbuffer registers, it's 1.
*/
#define SK_IF_READ_4(sc_if, skip, reg) \
sk_win_read_4(sc_if->sk_softc, reg + \
((sc_if->sk_port * (skip + 1)) * SK_WIN_LEN))
#define SK_IF_READ_2(sc_if, skip, reg) \
sk_win_read_2(sc_if->sk_softc, reg + \
((sc_if->sk_port * (skip + 1)) * SK_WIN_LEN))
#define SK_IF_READ_1(sc_if, skip, reg) \
sk_win_read_1(sc_if->sk_softc, reg + \
((sc_if->sk_port * (skip + 1)) * SK_WIN_LEN))
#define SK_IF_WRITE_4(sc_if, skip, reg, val) \
sk_win_write_4(sc_if->sk_softc, \
reg + ((sc_if->sk_port * (skip + 1)) * SK_WIN_LEN), val)
#define SK_IF_WRITE_2(sc_if, skip, reg, val) \
sk_win_write_2(sc_if->sk_softc, \
reg + ((sc_if->sk_port * (skip + 1)) * SK_WIN_LEN), val)
#define SK_IF_WRITE_1(sc_if, skip, reg, val) \
sk_win_write_1(sc_if->sk_softc, \
reg + ((sc_if->sk_port * (skip + 1)) * SK_WIN_LEN), val)
/* Block 0 registers, permanently mapped at iobase. */
#define SK_RAP 0x0000
#define SK_CSR 0x0004
#define SK_LED 0x0006
#define SK_ISR 0x0008 /* interrupt source */
#define SK_IMR 0x000C /* interrupt mask */
#define SK_IESR 0x0010 /* interrupt hardware error source */
#define SK_IEMR 0x0014 /* interrupt hardware error mask */
#define SK_ISSR 0x0018 /* special interrupt source */
#define SK_XM_IMR0 0x0020
#define SK_XM_ISR0 0x0028
#define SK_XM_PHYADDR0 0x0030
#define SK_XM_PHYDATA0 0x0034
#define SK_XM_IMR1 0x0040
#define SK_XM_ISR1 0x0048
#define SK_XM_PHYADDR1 0x0050
#define SK_XM_PHYDATA1 0x0054
#define SK_BMU_RX_CSR0 0x0060
#define SK_BMU_RX_CSR1 0x0064
#define SK_BMU_TXS_CSR0 0x0068
#define SK_BMU_TXA_CSR0 0x006C
#define SK_BMU_TXS_CSR1 0x0070
#define SK_BMU_TXA_CSR1 0x0074
/* SK_CSR register */
#define SK_CSR_SW_RESET 0x0001
#define SK_CSR_SW_UNRESET 0x0002
#define SK_CSR_MASTER_RESET 0x0004
#define SK_CSR_MASTER_UNRESET 0x0008
#define SK_CSR_MASTER_STOP 0x0010
#define SK_CSR_MASTER_DONE 0x0020
#define SK_CSR_SW_IRQ_CLEAR 0x0040
#define SK_CSR_SW_IRQ_SET 0x0080
#define SK_CSR_SLOTSIZE 0x0100 /* 1 == 64 bits, 0 == 32 */
#define SK_CSR_BUSCLOCK 0x0200 /* 1 == 33/66 Mhz, = 33 */
/* SK_LED register */
#define SK_LED_GREEN_OFF 0x01
#define SK_LED_GREEN_ON 0x02
/* SK_ISR register */
#define SK_ISR_TX2_AS_CHECK 0x00000001
#define SK_ISR_TX2_AS_EOF 0x00000002
#define SK_ISR_TX2_AS_EOB 0x00000004
#define SK_ISR_TX2_S_CHECK 0x00000008
#define SK_ISR_TX2_S_EOF 0x00000010
#define SK_ISR_TX2_S_EOB 0x00000020
#define SK_ISR_TX1_AS_CHECK 0x00000040
#define SK_ISR_TX1_AS_EOF 0x00000080
#define SK_ISR_TX1_AS_EOB 0x00000100
#define SK_ISR_TX1_S_CHECK 0x00000200
#define SK_ISR_TX1_S_EOF 0x00000400
#define SK_ISR_TX1_S_EOB 0x00000800
#define SK_ISR_RX2_CHECK 0x00001000
#define SK_ISR_RX2_EOF 0x00002000
#define SK_ISR_RX2_EOB 0x00004000
#define SK_ISR_RX1_CHECK 0x00008000
#define SK_ISR_RX1_EOF 0x00010000
#define SK_ISR_RX1_EOB 0x00020000
#define SK_ISR_LINK2_OFLOW 0x00040000
#define SK_ISR_MAC2 0x00080000
#define SK_ISR_LINK1_OFLOW 0x00100000
#define SK_ISR_MAC1 0x00200000
#define SK_ISR_TIMER 0x00400000
#define SK_ISR_EXTERNAL_REG 0x00800000
#define SK_ISR_SW 0x01000000
#define SK_ISR_I2C_RDY 0x02000000
#define SK_ISR_TX2_TIMEO 0x04000000
#define SK_ISR_TX1_TIMEO 0x08000000
#define SK_ISR_RX2_TIMEO 0x10000000
#define SK_ISR_RX1_TIMEO 0x20000000
#define SK_ISR_RSVD 0x40000000
#define SK_ISR_HWERR 0x80000000
/* SK_IMR register */
#define SK_IMR_TX2_AS_CHECK 0x00000001
#define SK_IMR_TX2_AS_EOF 0x00000002
#define SK_IMR_TX2_AS_EOB 0x00000004
#define SK_IMR_TX2_S_CHECK 0x00000008
#define SK_IMR_TX2_S_EOF 0x00000010
#define SK_IMR_TX2_S_EOB 0x00000020
#define SK_IMR_TX1_AS_CHECK 0x00000040
#define SK_IMR_TX1_AS_EOF 0x00000080
#define SK_IMR_TX1_AS_EOB 0x00000100
#define SK_IMR_TX1_S_CHECK 0x00000200
#define SK_IMR_TX1_S_EOF 0x00000400
#define SK_IMR_TX1_S_EOB 0x00000800
#define SK_IMR_RX2_CHECK 0x00001000
#define SK_IMR_RX2_EOF 0x00002000
#define SK_IMR_RX2_EOB 0x00004000
#define SK_IMR_RX1_CHECK 0x00008000
#define SK_IMR_RX1_EOF 0x00010000
#define SK_IMR_RX1_EOB 0x00020000
#define SK_IMR_LINK2_OFLOW 0x00040000
#define SK_IMR_MAC2 0x00080000
#define SK_IMR_LINK1_OFLOW 0x00100000
#define SK_IMR_MAC1 0x00200000
#define SK_IMR_TIMER 0x00400000
#define SK_IMR_EXTERNAL_REG 0x00800000
#define SK_IMR_SW 0x01000000
#define SK_IMR_I2C_RDY 0x02000000
#define SK_IMR_TX2_TIMEO 0x04000000
#define SK_IMR_TX1_TIMEO 0x08000000
#define SK_IMR_RX2_TIMEO 0x10000000
#define SK_IMR_RX1_TIMEO 0x20000000
#define SK_IMR_RSVD 0x40000000
#define SK_IMR_HWERR 0x80000000
#define SK_INTRS1 \
(SK_IMR_RX1_EOF|SK_IMR_TX1_S_EOF|SK_IMR_MAC1)
#define SK_INTRS2 \
(SK_IMR_RX2_EOF|SK_IMR_TX2_S_EOF|SK_IMR_MAC2)
/* SK_IESR register */
#define SK_IESR_PAR_RX2 0x00000001
#define SK_IESR_PAR_RX1 0x00000002
#define SK_IESR_PAR_MAC2 0x00000004
#define SK_IESR_PAR_MAC1 0x00000008
#define SK_IESR_PAR_WR_RAM 0x00000010
#define SK_IESR_PAR_RD_RAM 0x00000020
#define SK_IESR_NO_TSTAMP_MAC2 0x00000040
#define SK_IESR_NO_TSTAMO_MAC1 0x00000080
#define SK_IESR_NO_STS_MAC2 0x00000100
#define SK_IESR_NO_STS_MAC1 0x00000200
#define SK_IESR_IRQ_STS 0x00000400
#define SK_IESR_MASTERERR 0x00000800
/* SK_IEMR register */
#define SK_IEMR_PAR_RX2 0x00000001
#define SK_IEMR_PAR_RX1 0x00000002
#define SK_IEMR_PAR_MAC2 0x00000004
#define SK_IEMR_PAR_MAC1 0x00000008
#define SK_IEMR_PAR_WR_RAM 0x00000010
#define SK_IEMR_PAR_RD_RAM 0x00000020
#define SK_IEMR_NO_TSTAMP_MAC2 0x00000040
#define SK_IEMR_NO_TSTAMO_MAC1 0x00000080
#define SK_IEMR_NO_STS_MAC2 0x00000100
#define SK_IEMR_NO_STS_MAC1 0x00000200
#define SK_IEMR_IRQ_STS 0x00000400
#define SK_IEMR_MASTERERR 0x00000800
/* Block 2 */
#define SK_MAC0_0 0x0100
#define SK_MAC0_1 0x0104
#define SK_MAC1_0 0x0108
#define SK_MAC1_1 0x010C
#define SK_MAC2_0 0x0110
#define SK_MAC2_1 0x0114
#define SK_CONNTYPE 0x0118
#define SK_PMDTYPE 0x0119
#define SK_CONFIG 0x011A
#define SK_CHIPVER 0x011B
#define SK_EPROM0 0x011C
#define SK_EPROM1 0x011D
#define SK_EPROM2 0x011E
#define SK_EPROM3 0x011F
#define SK_EP_ADDR 0x0120
#define SK_EP_DATA 0x0124
#define SK_EP_LOADCTL 0x0128
#define SK_EP_LOADTST 0x0129
#define SK_TIMERINIT 0x0130
#define SK_TIMER 0x0134
#define SK_TIMERCTL 0x0138
#define SK_TIMERTST 0x0139
#define SK_IMTIMERINIT 0x0140
#define SK_IMTIMER 0x0144
#define SK_IMTIMERCTL 0x0148
#define SK_IMTIMERTST 0x0149
#define SK_IMMR 0x014C
#define SK_IHWEMR 0x0150
#define SK_TESTCTL1 0x0158
#define SK_TESTCTL2 0x0159
#define SK_GPIO 0x015C
#define SK_I2CHWCTL 0x0160
#define SK_I2CHWDATA 0x0164
#define SK_I2CHWIRQ 0x0168
#define SK_I2CSW 0x016C
#define SK_BLNKINIT 0x0170
#define SK_BLNKCOUNT 0x0174
#define SK_BLNKCTL 0x0178
#define SK_BLNKSTS 0x0179
#define SK_BLNKTST 0x017A
#define SK_IMCTL_STOP 0x02
#define SK_IMCTL_START 0x04
#define SK_IMTIMER_TICKS 54
#define SK_IM_USECS(x) ((x) * SK_IMTIMER_TICKS)
/*
* The SK_EPROM0 register contains a byte that describes the
* amount of SRAM mounted on the NIC. The value also tells if
* the chips are 64K or 128K. This affects the RAMbuffer address
* offset that we need to use.
*/
#define SK_RAMSIZE_512K_64 0x1
#define SK_RAMSIZE_1024K_128 0x2
#define SK_RAMSIZE_1024K_64 0x3
#define SK_RAMSIZE_2048K_128 0x4
#define SK_RBOFF_0 0x0
#define SK_RBOFF_80000 0x80000
#define SK_CONFIG_SINGLEMAC 0x01
#define SK_CONFIG_DIS_DSL_CLK 0x02
#define SK_PMD_1000BASELX 0x4C
#define SK_PMD_1000BASESX 0x53
#define SK_PMD_1000BASECX 0x43
#define SK_PMD_1000BASETX 0x54
/* Block 3 Ram interface and MAC arbiter registers */
#define SK_RAMADDR 0x0180
#define SK_RAMDATA0 0x0184
#define SK_RAMDATA1 0x0188
#define SK_TO0 0x0190
#define SK_TO1 0x0191
#define SK_TO2 0x0192
#define SK_TO3 0x0193
#define SK_TO4 0x0194
#define SK_TO5 0x0195
#define SK_TO6 0x0196
#define SK_TO7 0x0197
#define SK_TO8 0x0198
#define SK_TO9 0x0199
#define SK_TO10 0x019A
#define SK_TO11 0x019B
#define SK_RITIMEO_TMR 0x019C
#define SK_RAMCTL 0x01A0
#define SK_RITIMER_TST 0x01A2
#define SK_RAMCTL_RESET 0x0001
#define SK_RAMCTL_UNRESET 0x0002
#define SK_RAMCTL_CLR_IRQ_WPAR 0x0100
#define SK_RAMCTL_CLR_IRQ_RPAR 0x0200
/* Mac arbiter registers */
#define SK_MINIT_RX1 0x01B0
#define SK_MINIT_RX2 0x01B1
#define SK_MINIT_TX1 0x01B2
#define SK_MINIT_TX2 0x01B3
#define SK_MTIMEO_RX1 0x01B4
#define SK_MTIMEO_RX2 0x01B5
#define SK_MTIMEO_TX1 0x01B6
#define SK_MTIEMO_TX2 0x01B7
#define SK_MACARB_CTL 0x01B8
#define SK_MTIMER_TST 0x01BA
#define SK_RCINIT_RX1 0x01C0
#define SK_RCINIT_RX2 0x01C1
#define SK_RCINIT_TX1 0x01C2
#define SK_RCINIT_TX2 0x01C3
#define SK_RCTIMEO_RX1 0x01C4
#define SK_RCTIMEO_RX2 0x01C5
#define SK_RCTIMEO_TX1 0x01C6
#define SK_RCTIMEO_TX2 0x01C7
#define SK_RECOVERY_CTL 0x01C8
#define SK_RCTIMER_TST 0x01CA
/* Packet arbiter registers */
#define SK_RXPA1_TINIT 0x01D0
#define SK_RXPA2_TINIT 0x01D4
#define SK_TXPA1_TINIT 0x01D8
#define SK_TXPA2_TINIT 0x01DC
#define SK_RXPA1_TIMEO 0x01E0
#define SK_RXPA2_TIMEO 0x01E4
#define SK_TXPA1_TIMEO 0x01E8
#define SK_TXPA2_TIMEO 0x01EC
#define SK_PKTARB_CTL 0x01F0
#define SK_PKTATB_TST 0x01F2
#define SK_PKTARB_TIMEOUT 0x2000
#define SK_PKTARBCTL_RESET 0x0001
#define SK_PKTARBCTL_UNRESET 0x0002
#define SK_PKTARBCTL_RXTO1_OFF 0x0004
#define SK_PKTARBCTL_RXTO1_ON 0x0008
#define SK_PKTARBCTL_RXTO2_OFF 0x0010
#define SK_PKTARBCTL_RXTO2_ON 0x0020
#define SK_PKTARBCTL_TXTO1_OFF 0x0040
#define SK_PKTARBCTL_TXTO1_ON 0x0080
#define SK_PKTARBCTL_TXTO2_OFF 0x0100
#define SK_PKTARBCTL_TXTO2_ON 0x0200
#define SK_PKTARBCTL_CLR_IRQ_RXTO1 0x0400
#define SK_PKTARBCTL_CLR_IRQ_RXTO2 0x0800
#define SK_PKTARBCTL_CLR_IRQ_TXTO1 0x1000
#define SK_PKTARBCTL_CLR_IRQ_TXTO2 0x2000
#define SK_MINIT_XMAC_B2 54
#define SK_MINIT_XMAC_C1 63
#define SK_MACARBCTL_RESET 0x0001
#define SK_MACARBCTL_UNRESET 0x0002
#define SK_MACARBCTL_FASTOE_OFF 0x0004
#define SK_MACARBCRL_FASTOE_ON 0x0008
#define SK_RCINIT_XMAC_B2 54
#define SK_RCINIT_XMAC_C1 0
#define SK_RECOVERYCTL_RX1_OFF 0x0001
#define SK_RECOVERYCTL_RX1_ON 0x0002
#define SK_RECOVERYCTL_RX2_OFF 0x0004
#define SK_RECOVERYCTL_RX2_ON 0x0008
#define SK_RECOVERYCTL_TX1_OFF 0x0010
#define SK_RECOVERYCTL_TX1_ON 0x0020
#define SK_RECOVERYCTL_TX2_OFF 0x0040
#define SK_RECOVERYCTL_TX2_ON 0x0080
#define SK_RECOVERY_XMAC_B2 \
(SK_RECOVERYCTL_RX1_ON|SK_RECOVERYCTL_RX2_ON| \
SK_RECOVERYCTL_TX1_ON|SK_RECOVERYCTL_TX2_ON)
#define SK_RECOVERY_XMAC_C1 \
(SK_RECOVERYCTL_RX1_OFF|SK_RECOVERYCTL_RX2_OFF| \
SK_RECOVERYCTL_TX1_OFF|SK_RECOVERYCTL_TX2_OFF)
/* Block 4 -- TX Arbiter MAC 1 */
#define SK_TXAR1_TIMERINIT 0x0200
#define SK_TXAR1_TIMERVAL 0x0204
#define SK_TXAR1_LIMITINIT 0x0208
#define SK_TXAR1_LIMITCNT 0x020C
#define SK_TXAR1_COUNTERCTL 0x0210
#define SK_TXAR1_COUNTERTST 0x0212
#define SK_TXAR1_COUNTERSTS 0x0212
/* Block 5 -- TX Arbiter MAC 2 */
#define SK_TXAR2_TIMERINIT 0x0280
#define SK_TXAR2_TIMERVAL 0x0284
#define SK_TXAR2_LIMITINIT 0x0288
#define SK_TXAR2_LIMITCNT 0x028C
#define SK_TXAR2_COUNTERCTL 0x0290
#define SK_TXAR2_COUNTERTST 0x0291
#define SK_TXAR2_COUNTERSTS 0x0292
#define SK_TXARCTL_OFF 0x01
#define SK_TXARCTL_ON 0x02
#define SK_TXARCTL_RATECTL_OFF 0x04
#define SK_TXARCTL_RATECTL_ON 0x08
#define SK_TXARCTL_ALLOC_OFF 0x10
#define SK_TXARCTL_ALLOC_ON 0x20
#define SK_TXARCTL_FSYNC_OFF 0x40
#define SK_TXARCTL_FSYNC_ON 0x80
/* Block 6 -- External registers */
#define SK_EXTREG_BASE 0x300
#define SK_EXTREG_END 0x37C
/* Block 7 -- PCI config registers */
#define SK_PCI_BASE 0x0380
#define SK_PCI_END 0x03FC
/* Compute offset of mirrored PCI register */
#define SK_PCI_REG(reg) ((reg) + SK_PCI_BASE)
/* Block 8 -- RX queue 1 */
#define SK_RXQ1_BUFCNT 0x0400
#define SK_RXQ1_BUFCTL 0x0402
#define SK_RXQ1_NEXTDESC 0x0404
#define SK_RXQ1_RXBUF_LO 0x0408
#define SK_RXQ1_RXBUF_HI 0x040C
#define SK_RXQ1_RXSTAT 0x0410
#define SK_RXQ1_TIMESTAMP 0x0414
#define SK_RXQ1_CSUM1 0x0418
#define SK_RXQ1_CSUM2 0x041A
#define SK_RXQ1_CSUM1_START 0x041C
#define SK_RXQ1_CSUM2_START 0x041E
#define SK_RXQ1_CURADDR_LO 0x0420
#define SK_RXQ1_CURADDR_HI 0x0424
#define SK_RXQ1_CURCNT_LO 0x0428
#define SK_RXQ1_CURCNT_HI 0x042C
#define SK_RXQ1_CURBYTES 0x0430
#define SK_RXQ1_BMU_CSR 0x0434
#define SK_RXQ1_WATERMARK 0x0438
#define SK_RXQ1_FLAG 0x043A
#define SK_RXQ1_TEST1 0x043C
#define SK_RXQ1_TEST2 0x0440
#define SK_RXQ1_TEST3 0x0444
/* Block 9 -- RX queue 2 */
#define SK_RXQ2_BUFCNT 0x0480
#define SK_RXQ2_BUFCTL 0x0482
#define SK_RXQ2_NEXTDESC 0x0484
#define SK_RXQ2_RXBUF_LO 0x0488
#define SK_RXQ2_RXBUF_HI 0x048C
#define SK_RXQ2_RXSTAT 0x0490
#define SK_RXQ2_TIMESTAMP 0x0494
#define SK_RXQ2_CSUM1 0x0498
#define SK_RXQ2_CSUM2 0x049A
#define SK_RXQ2_CSUM1_START 0x049C
#define SK_RXQ2_CSUM2_START 0x049E
#define SK_RXQ2_CURADDR_LO 0x04A0
#define SK_RXQ2_CURADDR_HI 0x04A4
#define SK_RXQ2_CURCNT_LO 0x04A8
#define SK_RXQ2_CURCNT_HI 0x04AC
#define SK_RXQ2_CURBYTES 0x04B0
#define SK_RXQ2_BMU_CSR 0x04B4
#define SK_RXQ2_WATERMARK 0x04B8
#define SK_RXQ2_FLAG 0x04BA
#define SK_RXQ2_TEST1 0x04BC
#define SK_RXQ2_TEST2 0x04C0
#define SK_RXQ2_TEST3 0x04C4
#define SK_RXBMU_CLR_IRQ_ERR 0x00000001
#define SK_RXBMU_CLR_IRQ_EOF 0x00000002
#define SK_RXBMU_CLR_IRQ_EOB 0x00000004
#define SK_RXBMU_CLR_IRQ_PAR 0x00000008
#define SK_RXBMU_RX_START 0x00000010
#define SK_RXBMU_RX_STOP 0x00000020
#define SK_RXBMU_POLL_OFF 0x00000040
#define SK_RXBMU_POLL_ON 0x00000080
#define SK_RXBMU_TRANSFER_SM_RESET 0x00000100
#define SK_RXBMU_TRANSFER_SM_UNRESET 0x00000200
#define SK_RXBMU_DESCWR_SM_RESET 0x00000400
#define SK_RXBMU_DESCWR_SM_UNRESET 0x00000800
#define SK_RXBMU_DESCRD_SM_RESET 0x00001000
#define SK_RXBMU_DESCRD_SM_UNRESET 0x00002000
#define SK_RXBMU_SUPERVISOR_SM_RESET 0x00004000
#define SK_RXBMU_SUPERVISOR_SM_UNRESET 0x00008000
#define SK_RXBMU_PFI_SM_RESET 0x00010000
#define SK_RXBMU_PFI_SM_UNRESET 0x00020000
#define SK_RXBMU_FIFO_RESET 0x00040000
#define SK_RXBMU_FIFO_UNRESET 0x00080000
#define SK_RXBMU_DESC_RESET 0x00100000
#define SK_RXBMU_DESC_UNRESET 0x00200000
#define SK_RXBMU_SUPERVISOR_IDLE 0x01000000
#define SK_RXBMU_ONLINE \
(SK_RXBMU_TRANSFER_SM_UNRESET|SK_RXBMU_DESCWR_SM_UNRESET| \
SK_RXBMU_DESCRD_SM_UNRESET|SK_RXBMU_SUPERVISOR_SM_UNRESET| \
SK_RXBMU_PFI_SM_UNRESET|SK_RXBMU_FIFO_UNRESET| \
SK_RXBMU_DESC_UNRESET)
#define SK_RXBMU_OFFLINE \
(SK_RXBMU_TRANSFER_SM_RESET|SK_RXBMU_DESCWR_SM_RESET| \
SK_RXBMU_DESCRD_SM_RESET|SK_RXBMU_SUPERVISOR_SM_RESET| \
SK_RXBMU_PFI_SM_RESET|SK_RXBMU_FIFO_RESET| \
SK_RXBMU_DESC_RESET)
/* Block 12 -- TX sync queue 1 */
#define SK_TXQS1_BUFCNT 0x0600
#define SK_TXQS1_BUFCTL 0x0602
#define SK_TXQS1_NEXTDESC 0x0604
#define SK_TXQS1_RXBUF_LO 0x0608
#define SK_TXQS1_RXBUF_HI 0x060C
#define SK_TXQS1_RXSTAT 0x0610
#define SK_TXQS1_CSUM_STARTVAL 0x0614
#define SK_TXQS1_CSUM_STARTPOS 0x0618
#define SK_TXQS1_CSUM_WRITEPOS 0x061A
#define SK_TXQS1_CURADDR_LO 0x0620
#define SK_TXQS1_CURADDR_HI 0x0624
#define SK_TXQS1_CURCNT_LO 0x0628
#define SK_TXQS1_CURCNT_HI 0x062C
#define SK_TXQS1_CURBYTES 0x0630
#define SK_TXQS1_BMU_CSR 0x0634
#define SK_TXQS1_WATERMARK 0x0638
#define SK_TXQS1_FLAG 0x063A
#define SK_TXQS1_TEST1 0x063C
#define SK_TXQS1_TEST2 0x0640
#define SK_TXQS1_TEST3 0x0644
/* Block 13 -- TX async queue 1 */
#define SK_TXQA1_BUFCNT 0x0680
#define SK_TXQA1_BUFCTL 0x0682
#define SK_TXQA1_NEXTDESC 0x0684
#define SK_TXQA1_RXBUF_LO 0x0688
#define SK_TXQA1_RXBUF_HI 0x068C
#define SK_TXQA1_RXSTAT 0x0690
#define SK_TXQA1_CSUM_STARTVAL 0x0694
#define SK_TXQA1_CSUM_STARTPOS 0x0698
#define SK_TXQA1_CSUM_WRITEPOS 0x069A
#define SK_TXQA1_CURADDR_LO 0x06A0
#define SK_TXQA1_CURADDR_HI 0x06A4
#define SK_TXQA1_CURCNT_LO 0x06A8
#define SK_TXQA1_CURCNT_HI 0x06AC
#define SK_TXQA1_CURBYTES 0x06B0
#define SK_TXQA1_BMU_CSR 0x06B4
#define SK_TXQA1_WATERMARK 0x06B8
#define SK_TXQA1_FLAG 0x06BA
#define SK_TXQA1_TEST1 0x06BC
#define SK_TXQA1_TEST2 0x06C0
#define SK_TXQA1_TEST3 0x06C4
/* Block 14 -- TX sync queue 2 */
#define SK_TXQS2_BUFCNT 0x0700
#define SK_TXQS2_BUFCTL 0x0702
#define SK_TXQS2_NEXTDESC 0x0704
#define SK_TXQS2_RXBUF_LO 0x0708
#define SK_TXQS2_RXBUF_HI 0x070C
#define SK_TXQS2_RXSTAT 0x0710
#define SK_TXQS2_CSUM_STARTVAL 0x0714
#define SK_TXQS2_CSUM_STARTPOS 0x0718
#define SK_TXQS2_CSUM_WRITEPOS 0x071A
#define SK_TXQS2_CURADDR_LO 0x0720
#define SK_TXQS2_CURADDR_HI 0x0724
#define SK_TXQS2_CURCNT_LO 0x0728
#define SK_TXQS2_CURCNT_HI 0x072C
#define SK_TXQS2_CURBYTES 0x0730
#define SK_TXQS2_BMU_CSR 0x0734
#define SK_TXQS2_WATERMARK 0x0738
#define SK_TXQS2_FLAG 0x073A
#define SK_TXQS2_TEST1 0x073C
#define SK_TXQS2_TEST2 0x0740
#define SK_TXQS2_TEST3 0x0744
/* Block 15 -- TX async queue 2 */
#define SK_TXQA2_BUFCNT 0x0780
#define SK_TXQA2_BUFCTL 0x0782
#define SK_TXQA2_NEXTDESC 0x0784
#define SK_TXQA2_RXBUF_LO 0x0788
#define SK_TXQA2_RXBUF_HI 0x078C
#define SK_TXQA2_RXSTAT 0x0790
#define SK_TXQA2_CSUM_STARTVAL 0x0794
#define SK_TXQA2_CSUM_STARTPOS 0x0798
#define SK_TXQA2_CSUM_WRITEPOS 0x079A
#define SK_TXQA2_CURADDR_LO 0x07A0
#define SK_TXQA2_CURADDR_HI 0x07A4
#define SK_TXQA2_CURCNT_LO 0x07A8
#define SK_TXQA2_CURCNT_HI 0x07AC
#define SK_TXQA2_CURBYTES 0x07B0
#define SK_TXQA2_BMU_CSR 0x07B4
#define SK_TXQA2_WATERMARK 0x07B8
#define SK_TXQA2_FLAG 0x07BA
#define SK_TXQA2_TEST1 0x07BC
#define SK_TXQA2_TEST2 0x07C0
#define SK_TXQA2_TEST3 0x07C4
#define SK_TXBMU_CLR_IRQ_ERR 0x00000001
#define SK_TXBMU_CLR_IRQ_EOF 0x00000002
#define SK_TXBMU_CLR_IRQ_EOB 0x00000004
#define SK_TXBMU_TX_START 0x00000010
#define SK_TXBMU_TX_STOP 0x00000020
#define SK_TXBMU_POLL_OFF 0x00000040
#define SK_TXBMU_POLL_ON 0x00000080
#define SK_TXBMU_TRANSFER_SM_RESET 0x00000100
#define SK_TXBMU_TRANSFER_SM_UNRESET 0x00000200
#define SK_TXBMU_DESCWR_SM_RESET 0x00000400
#define SK_TXBMU_DESCWR_SM_UNRESET 0x00000800
#define SK_TXBMU_DESCRD_SM_RESET 0x00001000
#define SK_TXBMU_DESCRD_SM_UNRESET 0x00002000
#define SK_TXBMU_SUPERVISOR_SM_RESET 0x00004000
#define SK_TXBMU_SUPERVISOR_SM_UNRESET 0x00008000
#define SK_TXBMU_PFI_SM_RESET 0x00010000
#define SK_TXBMU_PFI_SM_UNRESET 0x00020000
#define SK_TXBMU_FIFO_RESET 0x00040000
#define SK_TXBMU_FIFO_UNRESET 0x00080000
#define SK_TXBMU_DESC_RESET 0x00100000
#define SK_TXBMU_DESC_UNRESET 0x00200000
#define SK_TXBMU_SUPERVISOR_IDLE 0x01000000
#define SK_TXBMU_ONLINE \
(SK_TXBMU_TRANSFER_SM_UNRESET|SK_TXBMU_DESCWR_SM_UNRESET| \
SK_TXBMU_DESCRD_SM_UNRESET|SK_TXBMU_SUPERVISOR_SM_UNRESET| \
SK_TXBMU_PFI_SM_UNRESET|SK_TXBMU_FIFO_UNRESET| \
SK_TXBMU_DESC_UNRESET)
#define SK_TXBMU_OFFLINE \
(SK_TXBMU_TRANSFER_SM_RESET|SK_TXBMU_DESCWR_SM_RESET| \
SK_TXBMU_DESCRD_SM_RESET|SK_TXBMU_SUPERVISOR_SM_RESET| \
SK_TXBMU_PFI_SM_RESET|SK_TXBMU_FIFO_RESET| \
SK_TXBMU_DESC_RESET)
/* Block 16 -- Receive RAMbuffer 1 */
#define SK_RXRB1_START 0x0800
#define SK_RXRB1_END 0x0804
#define SK_RXRB1_WR_PTR 0x0808
#define SK_RXRB1_RD_PTR 0x080C
#define SK_RXRB1_UTHR_PAUSE 0x0810
#define SK_RXRB1_LTHR_PAUSE 0x0814
#define SK_RXRB1_UTHR_HIPRIO 0x0818
#define SK_RXRB1_UTHR_LOPRIO 0x081C
#define SK_RXRB1_PKTCNT 0x0820
#define SK_RXRB1_LVL 0x0824
#define SK_RXRB1_CTLTST 0x0828
/* Block 17 -- Receive RAMbuffer 2 */
#define SK_RXRB2_START 0x0880
#define SK_RXRB2_END 0x0884
#define SK_RXRB2_WR_PTR 0x0888
#define SK_RXRB2_RD_PTR 0x088C
#define SK_RXRB2_UTHR_PAUSE 0x0890
#define SK_RXRB2_LTHR_PAUSE 0x0894
#define SK_RXRB2_UTHR_HIPRIO 0x0898
#define SK_RXRB2_UTHR_LOPRIO 0x089C
#define SK_RXRB2_PKTCNT 0x08A0
#define SK_RXRB2_LVL 0x08A4
#define SK_RXRB2_CTLTST 0x08A8
/* Block 20 -- Sync. Transmit RAMbuffer 1 */
#define SK_TXRBS1_START 0x0A00
#define SK_TXRBS1_END 0x0A04
#define SK_TXRBS1_WR_PTR 0x0A08
#define SK_TXRBS1_RD_PTR 0x0A0C
#define SK_TXRBS1_PKTCNT 0x0A20
#define SK_TXRBS1_LVL 0x0A24
#define SK_TXRBS1_CTLTST 0x0A28
/* Block 21 -- Async. Transmit RAMbuffer 1 */
#define SK_TXRBA1_START 0x0A80
#define SK_TXRBA1_END 0x0A84
#define SK_TXRBA1_WR_PTR 0x0A88
#define SK_TXRBA1_RD_PTR 0x0A8C
#define SK_TXRBA1_PKTCNT 0x0AA0
#define SK_TXRBA1_LVL 0x0AA4
#define SK_TXRBA1_CTLTST 0x0AA8
/* Block 22 -- Sync. Transmit RAMbuffer 2 */
#define SK_TXRBS2_START 0x0B00
#define SK_TXRBS2_END 0x0B04
#define SK_TXRBS2_WR_PTR 0x0B08
#define SK_TXRBS2_RD_PTR 0x0B0C
#define SK_TXRBS2_PKTCNT 0x0B20
#define SK_TXRBS2_LVL 0x0B24
#define SK_TXRBS2_CTLTST 0x0B28
/* Block 23 -- Async. Transmit RAMbuffer 2 */
#define SK_TXRBA2_START 0x0B80
#define SK_TXRBA2_END 0x0B84
#define SK_TXRBA2_WR_PTR 0x0B88
#define SK_TXRBA2_RD_PTR 0x0B8C
#define SK_TXRBA2_PKTCNT 0x0BA0
#define SK_TXRBA2_LVL 0x0BA4
#define SK_TXRBA2_CTLTST 0x0BA8
#define SK_RBCTL_RESET 0x00000001
#define SK_RBCTL_UNRESET 0x00000002
#define SK_RBCTL_OFF 0x00000004
#define SK_RBCTL_ON 0x00000008
#define SK_RBCTL_STORENFWD_OFF 0x00000010
#define SK_RBCTL_STORENFWD_ON 0x00000020
/* Block 24 -- RX MAC FIFO 1 regisrers and LINK_SYNC counter */
#define SK_RXF1_END 0x0C00
#define SK_RXF1_WPTR 0x0C04
#define SK_RXF1_RPTR 0x0C0C
#define SK_RXF1_PKTCNT 0x0C10
#define SK_RXF1_LVL 0x0C14
#define SK_RXF1_MACCTL 0x0C18
#define SK_RXF1_CTL 0x0C1C
#define SK_RXLED1_CNTINIT 0x0C20
#define SK_RXLED1_COUNTER 0x0C24
#define SK_RXLED1_CTL 0x0C28
#define SK_RXLED1_TST 0x0C29
#define SK_LINK_SYNC1_CINIT 0x0C30
#define SK_LINK_SYNC1_COUNTER 0x0C34
#define SK_LINK_SYNC1_CTL 0x0C38
#define SK_LINK_SYNC1_TST 0x0C39
#define SK_LINKLED1_CTL 0x0C3C
#define SK_FIFO_END 0x3F
/* Block 25 -- RX MAC FIFO 2 regisrers and LINK_SYNC counter */
#define SK_RXF2_END 0x0C80
#define SK_RXF2_WPTR 0x0C84
#define SK_RXF2_RPTR 0x0C8C
#define SK_RXF2_PKTCNT 0x0C90
#define SK_RXF2_LVL 0x0C94
#define SK_RXF2_MACCTL 0x0C98
#define SK_RXF2_CTL 0x0C9C
#define SK_RXLED2_CNTINIT 0x0CA0
#define SK_RXLED2_COUNTER 0x0CA4
#define SK_RXLED2_CTL 0x0CA8
#define SK_RXLED2_TST 0x0CA9
#define SK_LINK_SYNC2_CINIT 0x0CB0
#define SK_LINK_SYNC2_COUNTER 0x0CB4
#define SK_LINK_SYNC2_CTL 0x0CB8
#define SK_LINK_SYNC2_TST 0x0CB9
#define SK_LINKLED2_CTL 0x0CBC
#define SK_RXMACCTL_CLR_IRQ_NOSTS 0x00000001
#define SK_RXMACCTL_CLR_IRQ_NOTSTAMP 0x00000002
#define SK_RXMACCTL_TSTAMP_OFF 0x00000004
#define SK_RXMACCTL_RSTAMP_ON 0x00000008
#define SK_RXMACCTL_FLUSH_OFF 0x00000010
#define SK_RXMACCTL_FLUSH_ON 0x00000020
#define SK_RXMACCTL_PAUSE_OFF 0x00000040
#define SK_RXMACCTL_PAUSE_ON 0x00000080
#define SK_RXMACCTL_AFULL_OFF 0x00000100
#define SK_RXMACCTL_AFULL_ON 0x00000200
#define SK_RXMACCTL_VALIDTIME_PATCH_OFF 0x00000400
#define SK_RXMACCTL_VALIDTIME_PATCH_ON 0x00000800
#define SK_RXMACCTL_RXRDY_PATCH_OFF 0x00001000
#define SK_RXMACCTL_RXRDY_PATCH_ON 0x00002000
#define SK_RXMACCTL_STS_TIMEO 0x00FF0000
#define SK_RXMACCTL_TSTAMP_TIMEO 0xFF000000
#define SK_RXLEDCTL_ENABLE 0x0001
#define SK_RXLEDCTL_COUNTER_STOP 0x0002
#define SK_RXLEDCTL_COUNTER_START 0x0004
#define SK_LINKLED_OFF 0x0001
#define SK_LINKLED_ON 0x0002
#define SK_LINKLED_LINKSYNC_OFF 0x0004
#define SK_LINKLED_LINKSYNC_ON 0x0008
#define SK_LINKLED_BLINK_OFF 0x0010
#define SK_LINKLED_BLINK_ON 0x0020
/* Block 26 -- TX MAC FIFO 1 regisrers */
#define SK_TXF1_END 0x0D00
#define SK_TXF1_WPTR 0x0D04
#define SK_TXF1_RPTR 0x0D0C
#define SK_TXF1_PKTCNT 0x0D10
#define SK_TXF1_LVL 0x0D14
#define SK_TXF1_MACCTL 0x0D18
#define SK_TXF1_CTL 0x0D1C
#define SK_TXLED1_CNTINIT 0x0D20
#define SK_TXLED1_COUNTER 0x0D24
#define SK_TXLED1_CTL 0x0D28
#define SK_TXLED1_TST 0x0D29
/* Block 27 -- TX MAC FIFO 2 regisrers */
#define SK_TXF2_END 0x0D80
#define SK_TXF2_WPTR 0x0D84
#define SK_TXF2_RPTR 0x0D8C
#define SK_TXF2_PKTCNT 0x0D90
#define SK_TXF2_LVL 0x0D94
#define SK_TXF2_MACCTL 0x0D98
#define SK_TXF2_CTL 0x0D9C
#define SK_TXLED2_CNTINIT 0x0DA0
#define SK_TXLED2_COUNTER 0x0DA4
#define SK_TXLED2_CTL 0x0DA8
#define SK_TXLED2_TST 0x0DA9
#define SK_TXMACCTL_XMAC_RESET 0x00000001
#define SK_TXMACCTL_XMAC_UNRESET 0x00000002
#define SK_TXMACCTL_LOOP_OFF 0x00000004
#define SK_TXMACCTL_LOOP_ON 0x00000008
#define SK_TXMACCTL_FLUSH_OFF 0x00000010
#define SK_TXMACCTL_FLUSH_ON 0x00000020
#define SK_TXMACCTL_WAITEMPTY_OFF 0x00000040
#define SK_TXMACCTL_WAITEMPTY_ON 0x00000080
#define SK_TXMACCTL_AFULL_OFF 0x00000100
#define SK_TXMACCTL_AFULL_ON 0x00000200
#define SK_TXMACCTL_TXRDY_PATCH_OFF 0x00000400
#define SK_TXMACCTL_RXRDY_PATCH_ON 0x00000800
#define SK_TXMACCTL_PKT_RECOVERY_OFF 0x00001000
#define SK_TXMACCTL_PKT_RECOVERY_ON 0x00002000
#define SK_TXMACCTL_CLR_IRQ_PERR 0x00008000
#define SK_TXMACCTL_WAITAFTERFLUSH 0x00010000
#define SK_TXLEDCTL_ENABLE 0x0001
#define SK_TXLEDCTL_COUNTER_STOP 0x0002
#define SK_TXLEDCTL_COUNTER_START 0x0004
#define SK_FIFO_RESET 0x00000001
#define SK_FIFO_UNRESET 0x00000002
#define SK_FIFO_OFF 0x00000004
#define SK_FIFO_ON 0x00000008
/* Block 0x40 to 0x4F -- XMAC 1 registers */
#define SK_XMAC1_BASE 0x2000
#define SK_XMAC1_END 0x23FF
/* Block 0x60 to 0x6F -- XMAC 2 registers */
#define SK_XMAC2_BASE 0x3000
#define SK_XMAC2_END 0x33FF
/* Compute relative offset of an XMAC register in the XMAC window(s). */
#define SK_XMAC_REG(reg, mac) (((reg) * 2) + SK_XMAC1_BASE + \
(mac * (SK_XMAC2_BASE - SK_XMAC1_BASE)))
#define SK_XM_READ_4(sc, reg) \
(sk_win_read_2(sc->sk_softc, \
SK_XMAC_REG(reg, sc->sk_port)) & 0xFFFF) | \
((sk_win_read_2(sc->sk_softc, \
SK_XMAC_REG(reg + 2, sc->sk_port)) << 16) & 0xFFFF0000)
#define SK_XM_WRITE_4(sc, reg, val) \
sk_win_write_2(sc->sk_softc, \
SK_XMAC_REG(reg, sc->sk_port), ((val) & 0xFFFF)); \
sk_win_write_2(sc->sk_softc, \
SK_XMAC_REG(reg + 2, sc->sk_port), ((val) >> 16) & 0xFFFF);
#define SK_XM_READ_2(sc, reg) \
sk_win_read_2(sc->sk_softc, SK_XMAC_REG(reg, sc->sk_port))
#define SK_XM_WRITE_2(sc, reg, val) \
sk_win_write_2(sc->sk_softc, SK_XMAC_REG(reg, sc->sk_port), val)
#define SK_XM_SETBIT_4(sc, reg, x) \
SK_XM_WRITE_4(sc, reg, (SK_XM_READ_4(sc, reg)) | (x))
#define SK_XM_CLRBIT_4(sc, reg, x) \
SK_XM_WRITE_4(sc, reg, (SK_XM_READ_4(sc, reg)) & ~(x))
#define SK_XM_SETBIT_2(sc, reg, x) \
SK_XM_WRITE_2(sc, reg, (SK_XM_READ_2(sc, reg)) | (x))
#define SK_XM_CLRBIT_2(sc, reg, x) \
SK_XM_WRITE_2(sc, reg, (SK_XM_READ_2(sc, reg)) & ~(x))
/*
* The default FIFO threshold on the XMAC II is 4 bytes. On
* dual port NICs, this often leads to transmit underruns, so we
This commit adds driver support for the SysKonnect SK-984x series gigabit ethernet adapters. This includes two single port cards (single mode and multimode fiber) and two dual port cards (also single mode and multimode fiber). SysKonnect is currently the only vendor with a dual port gigabit ethernet NIC. The ports on dual port adapters are treated as separate network interfaces. Thus, if you have an SK-9844 dual port SX card, you should have both sk0 and sk1 interfaces attached. Dual port cards are implemented using two XMAC II chips connected to a single SysKonnect GEnesis controller. Hence, dual port cards are really one PCI device, as opposed to two separate PCI devices connected through a PCI to PCI bridge. Note that SysKonnect's drivers use the two ports for failover purposes rather that as two separate interfaces, plus they don't support jumbo frames. This applies to their Linux driver too. :) Support is provided for hardware multicast filtering, BPF and jumbo frames. The SysKonnect cards support TCP checksum offload however this feature is not currently enabled (hopefully it will be once we get checksum offload support). There are still a few things that need to be implemeted, like the ability to communicate with the on-board LM80 voltage/temperature monitor, but I wanted to get the driver under CVS control and into -current so people could bang on it. A big thanks for SysKonnect for making all their programming info for these cards (and for their FDDI and token ring cards) available without NDA (see www.syskonnect.com).
1999-07-09 04:30:09 +00:00
* bump the threshold a little.
*/
#define SK_XM_TX_FIFOTHRESH 512
#define SK_PCI_VENDOR_ID 0x0000
#define SK_PCI_DEVICE_ID 0x0002
#define SK_PCI_COMMAND 0x0004
#define SK_PCI_STATUS 0x0006
#define SK_PCI_REVID 0x0008
#define SK_PCI_CLASSCODE 0x0009
#define SK_PCI_CACHELEN 0x000C
#define SK_PCI_LATENCY_TIMER 0x000D
#define SK_PCI_HEADER_TYPE 0x000E
#define SK_PCI_LOMEM 0x0010
#define SK_PCI_LOIO 0x0014
#define SK_PCI_SUBVEN_ID 0x002C
#define SK_PCI_SYBSYS_ID 0x002E
#define SK_PCI_BIOSROM 0x0030
#define SK_PCI_INTLINE 0x003C
#define SK_PCI_INTPIN 0x003D
#define SK_PCI_MINGNT 0x003E
#define SK_PCI_MINLAT 0x003F
/* device specific PCI registers */
#define SK_PCI_OURREG1 0x0040
#define SK_PCI_OURREG2 0x0044
#define SK_PCI_CAPID 0x0048 /* 8 bits */
#define SK_PCI_NEXTPTR 0x0049 /* 8 bits */
#define SK_PCI_PWRMGMTCAP 0x004A /* 16 bits */
#define SK_PCI_PWRMGMTCTRL 0x004C /* 16 bits */
#define SK_PCI_PME_EVENT 0x004F
#define SK_PCI_VPD_CAPID 0x0050
#define SK_PCI_VPD_NEXTPTR 0x0051
#define SK_PCI_VPD_ADDR 0x0052
#define SK_PCI_VPD_DATA 0x0054
#define SK_PSTATE_MASK 0x0003
#define SK_PSTATE_D0 0x0000
#define SK_PSTATE_D1 0x0001
#define SK_PSTATE_D2 0x0002
#define SK_PSTATE_D3 0x0003
#define SK_PME_EN 0x0010
#define SK_PME_STATUS 0x8000
/*
* VPD flag bit. Set to 0 to initiate a read, will become 1 when
* read is complete. Set to 1 to initiate a write, will become 0
* when write is finished.
*/
#define SK_VPD_FLAG 0x8000
/* VPD structures */
struct vpd_res {
u_int8_t vr_id;
u_int8_t vr_len;
u_int8_t vr_pad;
};
struct vpd_key {
char vk_key[2];
u_int8_t vk_len;
};
#define VPD_RES_ID 0x82 /* ID string */
#define VPD_RES_READ 0x90 /* start of read only area */
#define VPD_RES_WRITE 0x81 /* start of read/write area */
#define VPD_RES_END 0x78 /* end tag */
#define CSR_WRITE_4(sc, reg, val) \
bus_space_write_4(sc->sk_btag, sc->sk_bhandle, reg, val)
#define CSR_WRITE_2(sc, reg, val) \
bus_space_write_2(sc->sk_btag, sc->sk_bhandle, reg, val)
#define CSR_WRITE_1(sc, reg, val) \
bus_space_write_1(sc->sk_btag, sc->sk_bhandle, reg, val)
#define CSR_READ_4(sc, reg) \
bus_space_read_4(sc->sk_btag, sc->sk_bhandle, reg)
#define CSR_READ_2(sc, reg) \
bus_space_read_2(sc->sk_btag, sc->sk_bhandle, reg)
#define CSR_READ_1(sc, reg) \
bus_space_read_1(sc->sk_btag, sc->sk_bhandle, reg)
struct sk_type {
u_int16_t sk_vid;
u_int16_t sk_did;
char *sk_name;
};
/* RX queue descriptor data structure */
struct sk_rx_desc {
u_int32_t sk_ctl;
u_int32_t sk_next;
u_int32_t sk_data_lo;
u_int32_t sk_data_hi;
u_int32_t sk_xmac_rxstat;
u_int32_t sk_timestamp;
u_int16_t sk_csum2;
u_int16_t sk_csum1;
u_int16_t sk_csum2_start;
u_int16_t sk_csum1_start;
};
#define SK_OPCODE_DEFAULT 0x00550000
#define SK_OPCODE_CSUM 0x00560000
#define SK_RXCTL_LEN 0x0000FFFF
#define SK_RXCTL_OPCODE 0x00FF0000
#define SK_RXCTL_TSTAMP_VALID 0x01000000
#define SK_RXCTL_STATUS_VALID 0x02000000
#define SK_RXCTL_DEV0 0x04000000
#define SK_RXCTL_EOF_INTR 0x08000000
#define SK_RXCTL_EOB_INTR 0x10000000
#define SK_RXCTL_LASTFRAG 0x20000000
#define SK_RXCTL_FIRSTFRAG 0x40000000
#define SK_RXCTL_OWN 0x80000000
#define SK_RXSTAT \
(SK_OPCODE_DEFAULT|SK_RXCTL_EOF_INTR|SK_RXCTL_LASTFRAG| \
SK_RXCTL_FIRSTFRAG|SK_RXCTL_OWN)
struct sk_tx_desc {
u_int32_t sk_ctl;
u_int32_t sk_next;
u_int32_t sk_data_lo;
u_int32_t sk_data_hi;
u_int32_t sk_xmac_txstat;
u_int16_t sk_rsvd0;
u_int16_t sk_csum_startval;
u_int16_t sk_csum_startpos;
u_int16_t sk_csum_writepos;
u_int32_t sk_rsvd1;
};
#define SK_TXCTL_LEN 0x0000FFFF
#define SK_TXCTL_OPCODE 0x00FF0000
#define SK_TXCTL_SW 0x01000000
#define SK_TXCTL_NOCRC 0x02000000
#define SK_TXCTL_STORENFWD 0x04000000
#define SK_TXCTL_EOF_INTR 0x08000000
#define SK_TXCTL_EOB_INTR 0x10000000
#define SK_TXCTL_LASTFRAG 0x20000000
#define SK_TXCTL_FIRSTFRAG 0x40000000
#define SK_TXCTL_OWN 0x80000000
#define SK_TXSTAT \
(SK_OPCODE_DEFAULT|SK_TXCTL_EOF_INTR|SK_TXCTL_LASTFRAG|SK_TXCTL_OWN)
#define SK_RXBYTES(x) (x) & 0x0000FFFF;
#define SK_TXBYTES SK_RXBYTES
#define SK_TX_RING_CNT 512
#define SK_RX_RING_CNT 256
/*
* Jumbo buffer stuff. Note that we must allocate more jumbo
* buffers than there are descriptors in the receive ring. This
* is because we don't know how long it will take for a packet
* to be released after we hand it off to the upper protocol
* layers. To be safe, we allocate 1.5 times the number of
* receive descriptors.
*/
#define SK_JUMBO_FRAMELEN 9018
#define SK_JUMBO_MTU (SK_JUMBO_FRAMELEN-ETHER_HDR_LEN-ETHER_CRC_LEN)
#define SK_JSLOTS 384
#define SK_JRAWLEN (SK_JUMBO_FRAMELEN + ETHER_ALIGN + sizeof(u_int64_t))
#define SK_JLEN (SK_JRAWLEN + (sizeof(u_int64_t) - \
(SK_JRAWLEN % sizeof(u_int64_t))))
#define SK_MCLBYTES (SK_JLEN - sizeof(u_int64_t))
#define SK_JPAGESZ PAGE_SIZE
#define SK_RESID (SK_JPAGESZ - (SK_JLEN * SK_JSLOTS) % SK_JPAGESZ)
#define SK_JMEM ((SK_JLEN * SK_JSLOTS) + SK_RESID)
struct sk_jslot {
caddr_t sk_buf;
int sk_inuse;
};
struct sk_jpool_entry {
int slot;
SLIST_ENTRY(sk_jpool_entry) jpool_entries;
};
struct sk_chain {
void *sk_desc;
struct mbuf *sk_mbuf;
struct sk_chain *sk_next;
};
struct sk_chain_data {
struct sk_chain sk_tx_chain[SK_TX_RING_CNT];
struct sk_chain sk_rx_chain[SK_RX_RING_CNT];
int sk_tx_prod;
int sk_tx_cons;
int sk_tx_cnt;
int sk_rx_prod;
int sk_rx_cons;
int sk_rx_cnt;
/* Stick the jumbo mem management stuff here too. */
struct sk_jslot sk_jslots[SK_JSLOTS];
void *sk_jumbo_buf;
};
struct sk_ring_data {
struct sk_tx_desc sk_tx_ring[SK_TX_RING_CNT];
struct sk_rx_desc sk_rx_ring[SK_RX_RING_CNT];
};
#define SK_INC(x, y) (x) = (x + 1) % y
/* Forward decl. */
struct sk_if_softc;
/* Softc for the GEnesis controller. */
struct sk_softc {
bus_space_handle_t sk_bhandle; /* bus space handle */
bus_space_tag_t sk_btag; /* bus space tag */
void *sk_intrhand; /* irq handler handle */
struct resource *sk_irq; /* IRQ resource handle */
struct resource *sk_res; /* I/O or shared mem handle */
This commit adds driver support for the SysKonnect SK-984x series gigabit ethernet adapters. This includes two single port cards (single mode and multimode fiber) and two dual port cards (also single mode and multimode fiber). SysKonnect is currently the only vendor with a dual port gigabit ethernet NIC. The ports on dual port adapters are treated as separate network interfaces. Thus, if you have an SK-9844 dual port SX card, you should have both sk0 and sk1 interfaces attached. Dual port cards are implemented using two XMAC II chips connected to a single SysKonnect GEnesis controller. Hence, dual port cards are really one PCI device, as opposed to two separate PCI devices connected through a PCI to PCI bridge. Note that SysKonnect's drivers use the two ports for failover purposes rather that as two separate interfaces, plus they don't support jumbo frames. This applies to their Linux driver too. :) Support is provided for hardware multicast filtering, BPF and jumbo frames. The SysKonnect cards support TCP checksum offload however this feature is not currently enabled (hopefully it will be once we get checksum offload support). There are still a few things that need to be implemeted, like the ability to communicate with the on-board LM80 voltage/temperature monitor, but I wanted to get the driver under CVS control and into -current so people could bang on it. A big thanks for SysKonnect for making all their programming info for these cards (and for their FDDI and token ring cards) available without NDA (see www.syskonnect.com).
1999-07-09 04:30:09 +00:00
u_int8_t sk_unit; /* controller number */
u_int8_t sk_type;
char *sk_vpd_prodname;
char *sk_vpd_readonly;
u_int32_t sk_rboff; /* RAMbuffer offset */
u_int32_t sk_ramsize; /* amount of RAM on NIC */
u_int32_t sk_pmd; /* physical media type */
u_int32_t sk_intrmask;
struct sk_if_softc *sk_if[2];
};
/* Softc for each logical interface */
struct sk_if_softc {
struct arpcom arpcom; /* interface info */
struct ifmedia ifmedia; /* media info */
u_int8_t sk_unit; /* interface number */
u_int8_t sk_port; /* port # on controller */
u_int8_t sk_xmac_rev; /* XMAC chip rev (B2 or C1) */
u_int8_t sk_link;
u_int32_t sk_rx_ramstart;
u_int32_t sk_rx_ramend;
u_int32_t sk_tx_ramstart;
u_int32_t sk_tx_ramend;
struct sk_chain_data sk_cdata;
struct sk_ring_data *sk_rdata;
struct sk_softc *sk_softc; /* parent controller */
int sk_tx_bmu; /* TX BMU register */
int sk_if_flags;
SLIST_HEAD(__sk_jfreehead, sk_jpool_entry) sk_jfree_listhead;
SLIST_HEAD(__sk_jinusehead, sk_jpool_entry) sk_jinuse_listhead;
};
#define SK_MAXUNIT 256
This commit adds driver support for the SysKonnect SK-984x series gigabit ethernet adapters. This includes two single port cards (single mode and multimode fiber) and two dual port cards (also single mode and multimode fiber). SysKonnect is currently the only vendor with a dual port gigabit ethernet NIC. The ports on dual port adapters are treated as separate network interfaces. Thus, if you have an SK-9844 dual port SX card, you should have both sk0 and sk1 interfaces attached. Dual port cards are implemented using two XMAC II chips connected to a single SysKonnect GEnesis controller. Hence, dual port cards are really one PCI device, as opposed to two separate PCI devices connected through a PCI to PCI bridge. Note that SysKonnect's drivers use the two ports for failover purposes rather that as two separate interfaces, plus they don't support jumbo frames. This applies to their Linux driver too. :) Support is provided for hardware multicast filtering, BPF and jumbo frames. The SysKonnect cards support TCP checksum offload however this feature is not currently enabled (hopefully it will be once we get checksum offload support). There are still a few things that need to be implemeted, like the ability to communicate with the on-board LM80 voltage/temperature monitor, but I wanted to get the driver under CVS control and into -current so people could bang on it. A big thanks for SysKonnect for making all their programming info for these cards (and for their FDDI and token ring cards) available without NDA (see www.syskonnect.com).
1999-07-09 04:30:09 +00:00
#define SK_TIMEOUT 1000
#define ETHER_ALIGN 2
#ifdef __alpha__
#undef vtophys
#define vtophys(va) alpha_XXX_dmamap((vm_offset_t)va)
This commit adds driver support for the SysKonnect SK-984x series gigabit ethernet adapters. This includes two single port cards (single mode and multimode fiber) and two dual port cards (also single mode and multimode fiber). SysKonnect is currently the only vendor with a dual port gigabit ethernet NIC. The ports on dual port adapters are treated as separate network interfaces. Thus, if you have an SK-9844 dual port SX card, you should have both sk0 and sk1 interfaces attached. Dual port cards are implemented using two XMAC II chips connected to a single SysKonnect GEnesis controller. Hence, dual port cards are really one PCI device, as opposed to two separate PCI devices connected through a PCI to PCI bridge. Note that SysKonnect's drivers use the two ports for failover purposes rather that as two separate interfaces, plus they don't support jumbo frames. This applies to their Linux driver too. :) Support is provided for hardware multicast filtering, BPF and jumbo frames. The SysKonnect cards support TCP checksum offload however this feature is not currently enabled (hopefully it will be once we get checksum offload support). There are still a few things that need to be implemeted, like the ability to communicate with the on-board LM80 voltage/temperature monitor, but I wanted to get the driver under CVS control and into -current so people could bang on it. A big thanks for SysKonnect for making all their programming info for these cards (and for their FDDI and token ring cards) available without NDA (see www.syskonnect.com).
1999-07-09 04:30:09 +00:00
#endif