1
0
mirror of https://git.FreeBSD.org/src.git synced 2024-12-22 11:17:19 +00:00
freebsd/sys/pci/if_sfreg.h
Bill Paul d1ce910572 First round of converting network drivers from spls to mutexes. This
takes care of all the 10/100 and gigE PCI drivers that I've done.
Next will be the wireless drivers, then the USB ones. I may pick up
some stragglers along the way. I'm sort of playing this by ear: if
anyone spots any places where I've screwed up horribly, please let me
know.
2000-10-13 17:54:19 +00:00

1060 lines
32 KiB
C

/*
* 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.
*
* $FreeBSD$
*/
/*
* Registers for the Adaptec AIC-6915 Starfire. The Starfire has a 512K
* register space. These registers can be accessed in the following way:
* - PCI config registers are always accessible through PCI config space
* - Full 512K space mapped into memory using PCI memory mapped access
* - 256-byte I/O space mapped through PCI I/O access
* - Full 512K space mapped through indirect I/O using PCI I/O access
* It's possible to use either memory mapped mode or I/O mode to access
* the registers, but memory mapped is usually the easiest. All registers
* are 32 bits wide and must be accessed using 32-bit operations.
*/
/*
* Adaptec PCI vendor ID.
*/
#define AD_VENDORID 0x9004
/*
* AIC-6915 PCI device ID.
*/
#define AD_DEVICEID_STARFIRE 0x6915
/*
* AIC-6915 subsystem IDs. Adaptec uses the subsystem ID to identify
* the exact kind of NIC on which the ASIC is mounted. Currently there
* are six different variations. Note: the Adaptec manual lists code 0x28
* for two different NICs: the 62044 and the 69011/TX. This is a typo:
* the code for the 62044 is really 0x18.
*
* Note that there also appears to be an 0x19 code for a newer rev
* 62044 card.
*/
#define AD_SUBSYSID_62011_REV0 0x0008 /* single port 10/100baseTX 64-bit */
#define AD_SUBSYSID_62011_REV1 0x0009 /* single port 10/100baseTX 64-bit */
#define AD_SUBSYSID_62022 0x0010 /* dual port 10/100baseTX 64-bit */
#define AD_SUBSYSID_62044_REV0 0x0018 /* quad port 10/100baseTX 64-bit */
#define AD_SUBSYSID_62044_REV1 0x0019 /* quad port 10/100baseTX 64-bit */
#define AD_SUBSYSID_62020 0x0020 /* single port 10/100baseFX 64-bit */
#define AD_SUBSYSID_69011 0x0028 /* single port 10/100baseTX 32-bit */
/*
* Starfire internal register space map. The entire register space
* is available using PCI memory mapped mode. The SF_RMAP_INTREG
* space is available using PCI I/O mode. The entire space can be
* accessed using indirect I/O using the indirect I/O addr and
* indirect I/O data registers located within the SF_RMAP_INTREG space.
*/
#define SF_RMAP_ROMADDR_BASE 0x00000 /* Expansion ROM space */
#define SF_RMAP_ROMADDR_MAX 0x3FFFF
#define SF_RMAP_EXGPIO_BASE 0x40000 /* External general purpose regs */
#define SF_RMAP_EXGPIO_MAX 0x3FFFF
#define SF_RMAP_INTREG_BASE 0x50000 /* Internal functional registers */
#define SF_RMAP_INTREG_MAX 0x500FF
#define SF_RMAP_GENREG_BASE 0x50100 /* General purpose registers */
#define SF_RMAP_GENREG_MAX 0x5FFFF
#define SF_RMAP_FIFO_BASE 0x60000
#define SF_RMAP_FIFO_MAX 0x6FFFF
#define SF_RMAP_STS_BASE 0x70000
#define SF_RMAP_STS_MAX 0x70083
#define SF_RMAP_RSVD_BASE 0x70084
#define SF_RMAP_RSVD_MAX 0x7FFFF
/*
* PCI config header registers, 0x0000 to 0x003F
*/
#define SF_PCI_VENDOR_ID 0x0000
#define SF_PCI_DEVICE_ID 0x0002
#define SF_PCI_COMMAND 0x0004
#define SF_PCI_STATUS 0x0006
#define SF_PCI_REVID 0x0008
#define SF_PCI_CLASSCODE 0x0009
#define SF_PCI_CACHELEN 0x000C
#define SF_PCI_LATENCY_TIMER 0x000D
#define SF_PCI_HEADER_TYPE 0x000E
#define SF_PCI_LOMEM 0x0010
#define SF_PCI_LOIO 0x0014
#define SF_PCI_SUBVEN_ID 0x002C
#define SF_PCI_SYBSYS_ID 0x002E
#define SF_PCI_BIOSROM 0x0030
#define SF_PCI_INTLINE 0x003C
#define SF_PCI_INTPIN 0x003D
#define SF_PCI_MINGNT 0x003E
#define SF_PCI_MINLAT 0x003F
/*
* PCI registers, 0x0040 to 0x006F
*/
#define SF_PCI_DEVCFG 0x0040
#define SF_BACCTL 0x0044
#define SF_PCI_MON1 0x0048
#define SF_PCI_MON2 0x004C
#define SF_PCI_CAPID 0x0050 /* 8 bits */
#define SF_PCI_NEXTPTR 0x0051 /* 8 bits */
#define SF_PCI_PWRMGMTCAP 0x0052 /* 16 bits */
#define SF_PCI_PWRMGMTCTRL 0x0054 /* 16 bits */
#define SF_PCI_PME_EVENT 0x0058
#define SF_PCI_EECTL 0x0060
#define SF_PCI_COMPLIANCE 0x0064
#define SF_INDIRECTIO_ADDR 0x0068
#define SF_INDIRECTIO_DATA 0x006C
#define SF_PCIDEVCFG_RESET 0x00000001
#define SF_PCIDEVCFG_FORCE64 0x00000002
#define SF_PCIDEVCFG_SYSTEM64 0x00000004
#define SF_PCIDEVCFG_RSVD0 0x00000008
#define SF_PCIDEVCFG_INCR_INB 0x00000010
#define SF_PCIDEVCFG_ABTONPERR 0x00000020
#define SF_PCIDEVCFG_STPONPERR 0x00000040
#define SF_PCIDEVCFG_MR_ENB 0x00000080
#define SF_PCIDEVCFG_FIFOTHR 0x00000F00
#define SF_PCIDEVCFG_STPONCA 0x00001000
#define SF_PCIDEVCFG_PCIMEN 0x00002000 /* enable PCI bus master */
#define SF_PCIDEVCFG_LATSTP 0x00004000
#define SF_PCIDEVCFG_BYTE_ENB 0x00008000
#define SF_PCIDEVCFG_EECSWIDTH 0x00070000
#define SF_PCIDEVCFG_STPMWCA 0x00080000
#define SF_PCIDEVCFG_REGCSWIDTH 0x00700000
#define SF_PCIDEVCFG_INTR_ENB 0x00800000
#define SF_PCIDEVCFG_DPR_ENB 0x01000000
#define SF_PCIDEVCFG_RSVD1 0x02000000
#define SF_PCIDEVCFG_RSVD2 0x04000000
#define SF_PCIDEVCFG_STA_ENB 0x08000000
#define SF_PCIDEVCFG_RTA_ENB 0x10000000
#define SF_PCIDEVCFG_RMA_ENB 0x20000000
#define SF_PCIDEVCFG_SSE_ENB 0x40000000
#define SF_PCIDEVCFG_DPE_ENB 0x80000000
#define SF_BACCTL_BACDMA_ENB 0x00000001
#define SF_BACCTL_PREFER_RXDMA 0x00000002
#define SF_BACCTL_PREFER_TXDMA 0x00000004
#define SF_BACCTL_SINGLE_DMA 0x00000008
#define SF_BACCTL_SWAPMODE_DATA 0x00000030
#define SF_BACCTL_SWAPMODE_DESC 0x000000C0
#define SF_SWAPMODE_LE 0x00000000
#define SF_SWAPMODE_BE 0x00000010
#define SF_PSTATE_MASK 0x0003
#define SF_PSTATE_D0 0x0000
#define SF_PSTATE_D1 0x0001
#define SF_PSTATE_D2 0x0002
#define SF_PSTATE_D3 0x0003
#define SF_PME_EN 0x0010
#define SF_PME_STATUS 0x8000
/*
* Ethernet registers 0x0070 to 0x00FF
*/
#define SF_GEN_ETH_CTL 0x0070
#define SF_TIMER_CTL 0x0074
#define SF_CURTIME 0x0078
#define SF_ISR 0x0080
#define SF_ISR_SHADOW 0x0084
#define SF_IMR 0x0088
#define SF_GPIO 0x008C
#define SF_TXDQ_CTL 0x0090
#define SF_TXDQ_ADDR_HIPRIO 0x0094
#define SF_TXDQ_ADDR_LOPRIO 0x0098
#define SF_TXDQ_ADDR_HIADDR 0x009C
#define SF_TXDQ_PRODIDX 0x00A0
#define SF_TXDQ_CONSIDX 0x00A4
#define SF_TXDMA_STS1 0x00A8
#define SF_TXDMA_STS2 0x00AC
#define SF_TX_FRAMCTL 0x00B0
#define SF_TXCQ_ADDR_HI 0x00B4
#define SF_TXCQ_CTL 0x00B8
#define SF_RXCQ_CTL_1 0x00BC
#define SF_RXCQ_CTL_2 0x00C0
#define SF_CQ_CONSIDX 0x00C4
#define SF_CQ_PRODIDX 0x00C8
#define SF_CQ_RXQ2 0x00CC
#define SF_RXDMA_CTL 0x00D0
#define SF_RXDQ_CTL_1 0x00D4
#define SF_RXDQ_CTL_2 0x00D8
#define SF_RXDQ_ADDR_HIADDR 0x00DC
#define SF_RXDQ_ADDR_Q1 0x00E0
#define SF_RXDQ_ADDR_Q2 0x00E4
#define SF_RXDQ_PTR_Q1 0x00E8
#define SF_RXDQ_PTR_Q2 0x00EC
#define SF_RXDMA_STS 0x00F0
#define SF_RXFILT 0x00F4
#define SF_RX_FRAMETEST_OUT 0x00F8
/* Ethernet control register */
#define SF_ETHCTL_RX_ENB 0x00000001
#define SF_ETHCTL_TX_ENB 0x00000002
#define SF_ETHCTL_RXDMA_ENB 0x00000004
#define SF_ETHCTL_TXDMA_ENB 0x00000008
#define SF_ETHCTL_RXGFP_ENB 0x00000010
#define SF_ETHCTL_TXGFP_ENB 0x00000020
#define SF_ETHCTL_SOFTINTR 0x00000800
/* Timer control register */
#define SF_TIMER_IMASK_INTERVAL 0x0000001F
#define SF_TIMER_IMASK_MODE 0x00000060
#define SF_TIMER_SMALLFRAME_BYP 0x00000100
#define SF_TIMER_SMALLRX_FRAME 0x00000600
#define SF_TIMER_TIMES_TEN 0x00000800
#define SF_TIMER_RXHIPRIO_BYP 0x00001000
#define SF_TIMER_TX_DMADONE_DLY 0x00002000
#define SF_TIMER_TX_QDONE_DLY 0x00004000
#define SF_TIMER_TX_FRDONE_DLY 0x00008000
#define SF_TIMER_GENTIMER 0x00FF0000
#define SF_TIMER_ONESHOT 0x01000000
#define SF_TIMER_GENTIMER_RES 0x02000000
#define SF_TIMER_TIMEST_RES 0x04000000
#define SF_TIMER_RXQ2DONE_DLY 0x10000000
#define SF_TIMER_EARLYRX2_DLY 0x20000000
#define SF_TIMER_RXQ1DONE_DLY 0x40000000
#define SF_TIMER_EARLYRX1_DLY 0x80000000
/* Interrupt status register */
#define SF_ISR_PCIINT_ASSERTED 0x00000001
#define SF_ISR_GFP_TX 0x00000002
#define SF_ISR_GFP_RX 0x00000004
#define SF_ISR_TX_BADID_HIPRIO 0x00000008
#define SF_ISR_TX_BADID_LOPRIO 0x00000010
#define SF_ISR_NO_TX_CSUM 0x00000020
#define SF_ISR_RXDQ2_NOBUFS 0x00000040
#define SF_ISR_RXGFP_NORESP 0x00000080
#define SF_ISR_RXDQ1_DMADONE 0x00000100
#define SF_ISR_RXDQ2_DMADONE 0x00000200
#define SF_ISR_RXDQ1_EARLY 0x00000400
#define SF_ISR_RXDQ2_EARLY 0x00000800
#define SF_ISR_TX_QUEUEDONE 0x00001000
#define SF_ISR_TX_DMADONE 0x00002000
#define SF_ISR_TX_TXDONE 0x00004000
#define SF_ISR_NORMALINTR 0x00008000
#define SF_ISR_RXDQ1_NOBUFS 0x00010000
#define SF_ISR_RXCQ2_NOBUFS 0x00020000
#define SF_ISR_TX_LOFIFO 0x00040000
#define SF_ISR_DMAERR 0x00080000
#define SF_ISR_PCIINT 0x00100000
#define SF_ISR_TXCQ_NOBUFS 0x00200000
#define SF_ISR_RXCQ1_NOBUFS 0x00400000
#define SF_ISR_SOFTINTR 0x00800000
#define SF_ISR_GENTIMER 0x01000000
#define SF_ISR_ABNORMALINTR 0x02000000
#define SF_ISR_RSVD0 0x04000000
#define SF_ISR_STATSOFLOW 0x08000000
#define SF_ISR_GPIO 0xF0000000
/*
* Shadow interrupt status register. Unlike the normal IRQ register,
* reading bits here does not automatically cause them to reset.
*/
#define SF_SISR_PCIINT_ASSERTED 0x00000001
#define SF_SISR_GFP_TX 0x00000002
#define SF_SISR_GFP_RX 0x00000004
#define SF_SISR_TX_BADID_HIPRIO 0x00000008
#define SF_SISR_TX_BADID_LOPRIO 0x00000010
#define SF_SISR_NO_TX_CSUM 0x00000020
#define SF_SISR_RXDQ2_NOBUFS 0x00000040
#define SF_SISR_RXGFP_NORESP 0x00000080
#define SF_SISR_RXDQ1_DMADONE 0x00000100
#define SF_SISR_RXDQ2_DMADONE 0x00000200
#define SF_SISR_RXDQ1_EARLY 0x00000400
#define SF_SISR_RXDQ2_EARLY 0x00000800
#define SF_SISR_TX_QUEUEDONE 0x00001000
#define SF_SISR_TX_DMADONE 0x00002000
#define SF_SISR_TX_TXDONE 0x00004000
#define SF_SISR_NORMALINTR 0x00008000
#define SF_SISR_RXDQ1_NOBUFS 0x00010000
#define SF_SISR_RXCQ2_NOBUFS 0x00020000
#define SF_SISR_TX_LOFIFO 0x00040000
#define SF_SISR_DMAERR 0x00080000
#define SF_SISR_PCIINT 0x00100000
#define SF_SISR_TXCQ_NOBUFS 0x00200000
#define SF_SISR_RXCQ1_NOBUFS 0x00400000
#define SF_SISR_SOFTINTR 0x00800000
#define SF_SISR_GENTIMER 0x01000000
#define SF_SISR_ABNORMALINTR 0x02000000
#define SF_SISR_RSVD0 0x04000000
#define SF_SISR_STATSOFLOW 0x08000000
#define SF_SISR_GPIO 0xF0000000
/* Interrupt mask register */
#define SF_IMR_PCIINT_ASSERTED 0x00000001
#define SF_IMR_GFP_TX 0x00000002
#define SF_IMR_GFP_RX 0x00000004
#define SF_IMR_TX_BADID_HIPRIO 0x00000008
#define SF_IMR_TX_BADID_LOPRIO 0x00000010
#define SF_IMR_NO_TX_CSUM 0x00000020
#define SF_IMR_RXDQ2_NOBUFS 0x00000040
#define SF_IMR_RXGFP_NORESP 0x00000080
#define SF_IMR_RXDQ1_DMADONE 0x00000100
#define SF_IMR_RXDQ2_DMADONE 0x00000200
#define SF_IMR_RXDQ1_EARLY 0x00000400
#define SF_IMR_RXDQ2_EARLY 0x00000800
#define SF_IMR_TX_QUEUEDONE 0x00001000
#define SF_IMR_TX_DMADONE 0x00002000
#define SF_IMR_TX_TXDONE 0x00004000
#define SF_IMR_NORMALINTR 0x00008000
#define SF_IMR_RXDQ1_NOBUFS 0x00010000
#define SF_IMR_RXCQ2_NOBUFS 0x00020000
#define SF_IMR_TX_LOFIFO 0x00040000
#define SF_IMR_DMAERR 0x00080000
#define SF_IMR_PCIINT 0x00100000
#define SF_IMR_TXCQ_NOBUFS 0x00200000
#define SF_IMR_RXCQ1_NOBUFS 0x00400000
#define SF_IMR_SOFTINTR 0x00800000
#define SF_IMR_GENTIMER 0x01000000
#define SF_IMR_ABNORMALINTR 0x02000000
#define SF_IMR_RSVD0 0x04000000
#define SF_IMR_STATSOFLOW 0x08000000
#define SF_IMR_GPIO 0xF0000000
#define SF_INTRS \
(SF_IMR_RXDQ2_NOBUFS|SF_IMR_RXDQ1_DMADONE|SF_IMR_RXDQ2_DMADONE| \
SF_IMR_TX_TXDONE|SF_IMR_RXDQ1_NOBUFS|SF_IMR_RXDQ2_DMADONE| \
SF_IMR_NORMALINTR|SF_IMR_ABNORMALINTR|SF_IMR_TXCQ_NOBUFS| \
SF_IMR_RXCQ1_NOBUFS|SF_IMR_RXCQ2_NOBUFS|SF_IMR_STATSOFLOW)
/* TX descriptor queue control registers */
#define SF_TXDQCTL_DESCTYPE 0x00000007
#define SF_TXDQCTL_NODMACMP 0x00000008
#define SF_TXDQCTL_MINSPACE 0x00000070
#define SF_TXDQCTL_64BITADDR 0x00000080
#define SF_TXDQCTL_BURSTLEN 0x00003F00
#define SF_TXDQCTL_SKIPLEN 0x001F0000
#define SF_TXDQCTL_HIPRIOTHRESH 0xFF000000
#define SF_TXBUFDESC_TYPE0 0x00000000
#define SF_TXBUFDESC_TYPE1 0x00000001
#define SF_TXBUFDESC_TYPE2 0x00000002
#define SF_TXBUFDESC_TYPE3 0x00000003
#define SF_TXBUFDESC_TYPE4 0x00000004
#define SF_TXMINSPACE_UNLIMIT 0x00000000
#define SF_TXMINSPACE_32BYTES 0x00000010
#define SF_TXMINSPACE_64BYTES 0x00000020
#define SF_TXMINSPACE_128BYTES 0x00000030
#define SF_TXMINSPACE_256BYTES 0x00000040
#define SF_TXSKIPLEN_0BYTES 0x00000000
#define SF_TXSKIPLEN_8BYTES 0x00010000
#define SF_TXSKIPLEN_16BYTES 0x00020000
#define SF_TXSKIPLEN_24BYTES 0x00030000
#define SF_TXSKIPLEN_32BYTES 0x00040000
/* TX frame control register */
#define SF_TXFRMCTL_TXTHRESH 0x000000FF
#define SF_TXFRMCTL_CPLAFTERTX 0x00000100
#define SF_TXFRMCRL_DEBUG 0x0000FE00
#define SF_TXFRMCTL_STATUS 0x01FF0000
#define SF_TXFRMCTL_MAC_TXIF 0xFE000000
/* TX completion queue control register */
#define SF_TXCQ_THRESH 0x0000000F
#define SF_TXCQ_COMMON 0x00000010
#define SF_TXCQ_SIZE 0x00000020
#define SF_TXCQ_WRITEENB 0x00000040
#define SF_TXCQ_USE_64BIT 0x00000080
#define SF_TXCQ_ADDR 0xFFFFFF00
/* RX completion queue control register */
#define SF_RXCQ_THRESH 0x0000000F
#define SF_RXCQ_TYPE 0x00000030
#define SF_RXCQ_WRITEENB 0x00000040
#define SF_RXCQ_USE_64BIT 0x00000080
#define SF_RXCQ_ADDR 0xFFFFFF00
#define SF_RXCQTYPE_0 0x00000000
#define SF_RXCQTYPE_1 0x00000010
#define SF_RXCQTYPE_2 0x00000020
#define SF_RXCQTYPE_3 0x00000030
/* TX descriptor queue producer index register */
#define SF_TXDQ_PRODIDX_LOPRIO 0x000007FF
#define SF_TXDQ_PRODIDX_HIPRIO 0x07FF0000
/* TX descriptor queue consumer index register */
#define SF_TXDQ_CONSIDX_LOPRIO 0x000007FF
#define SF_TXDQ_CONSIDX_HIPRIO 0x07FF0000
/* Completion queue consumer index register */
#define SF_CQ_CONSIDX_RXQ1 0x000003FF
#define SF_CQ_CONSIDX_RXTHRMODE 0x00008000
#define SF_CQ_CONSIDX_TXQ 0x03FF0000
#define SF_CQ_CONSIDX_TXTHRMODE 0x80000000
/* Completion queue producer index register */
#define SF_CQ_PRODIDX_RXQ1 0x000003FF
#define SF_CQ_PRODIDX_TXQ 0x03FF0000
/* RX completion queue 2 consumer/producer index register */
#define SF_CQ_RXQ2_CONSIDX 0x000003FF
#define SF_CQ_RXQ2_RXTHRMODE 0x00008000
#define SF_CQ_RXQ2_PRODIDX 0x03FF0000
#define SF_CQ_RXTHRMODE_INT_ON 0x00008000
#define SF_CQ_RXTHRMODE_INT_OFF 0x00000000
#define SF_CQ_TXTHRMODE_INT_ON 0x80000000
#define SF_CQ_TXTHRMODE_INT_OFF 0x00000000
#define SF_IDX_LO(x) ((x) & 0x000007FF)
#define SF_IDX_HI(x) (((x) >> 16) & 0x000007FF)
/* RX DMA control register */
#define SF_RXDMA_BURSTSIZE 0x0000007F
#define SF_RXDMA_FPTESTMODE 0x00000080
#define SF_RXDMA_HIPRIOTHRESH 0x00000F00
#define SF_RXDMA_RXEARLYTHRESH 0x0001F000
#define SF_RXDMA_DMACRC 0x00040000
#define SF_RXDMA_USEBKUPQUEUE 0x00080000
#define SF_RXDMA_QUEUEMODE 0x00700000
#define SF_RXDMA_RXCQ2_ON 0x00800000
#define SF_RXDMA_CSUMMODE 0x03000000
#define SF_RXDMA_DMAPAUSEPKTS 0x04000000
#define SF_RXDMA_DMACTLPKTS 0x08000000
#define SF_RXDMA_DMACRXERRPKTS 0x10000000
#define SF_RXDMA_DMABADPKTS 0x20000000
#define SF_RXDMA_DMARUNTS 0x40000000
#define SF_RXDMA_REPORTBADPKTS 0x80000000
#define SF_RXDQMODE_Q1ONLY 0x00100000
#define SF_RXDQMODE_Q2_ON_FP 0x00200000
#define SF_RXDQMODE_Q2_ON_SHORT 0x00300000
#define SF_RXDQMODE_Q2_ON_PRIO 0x00400000
#define SF_RXDQMODE_SPLITHDR 0x00500000
#define SF_RXCSUMMODE_IGNORE 0x00000000
#define SF_RXCSUMMODE_REJECT_BAD_TCP 0x01000000
#define SF_RXCSUMMODE_REJECT_BAD_TCPUDP 0x02000000
#define SF_RXCSUMMODE_RSVD 0x03000000
/* RX descriptor queue control registers */
#define SF_RXDQCTL_MINDESCTHR 0x0000007F
#define SF_RXDQCTL_Q1_WE 0x00000080
#define SF_RXDQCTL_DESCSPACE 0x00000700
#define SF_RXDQCTL_64BITDADDR 0x00000800
#define SF_RXDQCTL_64BITBADDR 0x00001000
#define SF_RXDQCTL_VARIABLE 0x00002000
#define SF_RXDQCTL_ENTRIES 0x00004000
#define SF_RXDQCTL_PREFETCH 0x00008000
#define SF_RXDQCTL_BUFLEN 0xFFFF0000
#define SF_DESCSPACE_4BYTES 0x00000000
#define SF_DESCSPACE_8BYTES 0x00000100
#define SF_DESCSPACE_16BYTES 0x00000200
#define SF_DESCSPACE_32BYTES 0x00000300
#define SF_DESCSPACE_64BYTES 0x00000400
#define SF_DESCSPACE_128_BYTES 0x00000500
/* RX buffer consumer/producer index registers */
#define SF_RXDQ_PRODIDX 0x000007FF
#define SF_RXDQ_CONSIDX 0x07FF0000
/* RX filter control register */
#define SF_RXFILT_PROMISC 0x00000001
#define SF_RXFILT_ALLMULTI 0x00000002
#define SF_RXFILT_BROAD 0x00000004
#define SF_RXFILT_HASHPRIO 0x00000008
#define SF_RXFILT_HASHMODE 0x00000030
#define SF_RXFILT_PERFMODE 0x000000C0
#define SF_RXFILT_VLANMODE 0x00000300
#define SF_RXFILT_WAKEMODE 0x00000C00
#define SF_RXFILT_MULTI_NOBROAD 0x00001000
#define SF_RXFILT_MIN_VLANPRIO 0x0000E000
#define SF_RXFILT_PEFECTPRIO 0xFFFF0000
/* Hash filtering mode */
#define SF_HASHMODE_OFF 0x00000000
#define SF_HASHMODE_WITHVLAN 0x00000010
#define SF_HASHMODE_ANYVLAN 0x00000020
#define SF_HASHMODE_ANY 0x00000030
/* Perfect filtering mode */
#define SF_PERFMODE_OFF 0x00000000
#define SF_PERFMODE_NORMAL 0x00000040
#define SF_PERFMODE_INVERSE 0x00000080
#define SF_PERFMODE_VLAN 0x000000C0
/* VLAN mode */
#define SF_VLANMODE_OFF 0x00000000
#define SF_VLANMODE_NOSTRIP 0x00000100
#define SF_VLANMODE_STRIP 0x00000200
#define SF_VLANMODE_RSVD 0x00000300
/* Wakeup mode */
#define SF_WAKEMODE_OFF 0x00000000
#define SF_WAKEMODE_FILTER 0x00000400
#define SF_WAKEMODE_FP 0x00000800
#define SF_WAKEMODE_HIPRIO 0x00000C00
/*
* Extra PCI registers 0x0100 to 0x0FFF
*/
#define SF_PCI_TARGSTAT 0x0100
#define SF_PCI_MASTSTAT1 0x0104
#define SF_PCI_MASTSTAT2 0x0108
#define SF_PCI_DMAHOSTADDR_LO 0x010C
#define SF_BAC_DMADIAG0 0x0110
#define SF_BAC_DMADIAG1 0x0114
#define SF_BAC_DMADIAG2 0x0118
#define SF_BAC_DMADIAG3 0x011C
#define SF_PAR0 0x0120
#define SF_PAR1 0x0124
#define SF_PCICB_FUNCEVENT 0x0130
#define SF_PCICB_FUNCEVENT_MASK 0x0134
#define SF_PCICB_FUNCSTATE 0x0138
#define SF_PCICB_FUNCFORCE 0x013C
/*
* Serial EEPROM registers 0x1000 to 0x1FFF
* Presumeably the EEPROM is mapped into this 8K window.
*/
#define SF_EEADDR_BASE 0x1000
#define SF_EEADDR_MAX 0x1FFF
#define SF_EE_NODEADDR 14
/*
* MII registers registers 0x2000 to 0x3FFF
* There are 32 sets of 32 registers, one set for each possible
* PHY address. Each 32 bit register is split into a 16-bit data
* port and a couple of status bits.
*/
#define SF_MIIADDR_BASE 0x2000
#define SF_MIIADDR_MAX 0x3FFF
#define SF_MII_BLOCKS 32
#define SF_MII_DATAVALID 0x80000000
#define SF_MII_BUSY 0x40000000
#define SF_MII_DATAPORT 0x0000FFFF
#define SF_PHY_REG(phy, reg) \
(SF_MIIADDR_BASE + (phy * SF_MII_BLOCKS * sizeof(u_int32_t)) + \
(reg * sizeof(u_int32_t)))
/*
* Ethernet extra registers 0x4000 to 0x4FFF
*/
#define SF_TESTMODE 0x4000
#define SF_RX_FRAMEPROC_CTL 0x4004
#define SF_TX_FRAMEPROC_CTL 0x4008
/*
* MAC registers 0x5000 to 0x5FFF
*/
#define SF_MACCFG_1 0x5000
#define SF_MACCFG_2 0x5004
#define SF_BKTOBKIPG 0x5008
#define SF_NONBKTOBKIPG 0x500C
#define SF_COLRETRY 0x5010
#define SF_MAXLEN 0x5014
#define SF_TXNIBBLECNT 0x5018
#define SF_TXBYTECNT 0x501C
#define SF_RETXCNT 0x5020
#define SF_RANDNUM 0x5024
#define SF_RANDNUM_MASK 0x5028
#define SF_TOTALTXCNT 0x5034
#define SF_RXBYTECNT 0x5040
#define SF_TXPAUSETIMER 0x5060
#define SF_VLANTYPE 0x5064
#define SF_MIISTATUS 0x5070
#define SF_MACCFG1_HUGEFRAMES 0x00000001
#define SF_MACCFG1_FULLDUPLEX 0x00000002
#define SF_MACCFG1_AUTOPAD 0x00000004
#define SF_MACCFG1_HDJAM 0x00000008
#define SF_MACCFG1_DELAYCRC 0x00000010
#define SF_MACCFG1_NOBACKOFF 0x00000020
#define SF_MACCFG1_LENGTHCHECK 0x00000040
#define SF_MACCFG1_PUREPREAMBLE 0x00000080
#define SF_MACCFG1_PASSALLRX 0x00000100
#define SF_MACCFG1_PREAM_DETCNT 0x00000200
#define SF_MACCFG1_RX_FLOWENB 0x00000400
#define SF_MACCFG1_TX_FLOWENB 0x00000800
#define SF_MACCFG1_TESTMODE 0x00003000
#define SF_MACCFG1_MIILOOPBK 0x00004000
#define SF_MACCFG1_SOFTRESET 0x00008000
/*
* There are the recommended IPG nibble counter settings
* specified in the Adaptec manual for full duplex and
* half duplex operation.
*/
#define SF_IPGT_FDX 0x15
#define SF_IPGT_HDX 0x11
/*
* RX filter registers 0x6000 to 0x6FFF
*/
#define SF_RXFILT_PERFECT_BASE 0x6000
#define SF_RXFILT_PERFECT_MAX 0x60FF
#define SF_RXFILT_PERFECT_SKIP 0x0010
#define SF_RXFILT_PERFECT_CNT 0x0010
#define SF_RXFILT_HASH_BASE 0x6100
#define SF_RXFILT_HASH_MAX 0x62FF
#define SF_RXFILT_HASH_SKIP 0x0010
#define SF_RXFILT_HASH_CNT 0x001F
#define SF_RXFILT_HASH_ADDROFF 0x0000
#define SF_RXFILT_HASH_PRIOOFF 0x0004
#define SF_RXFILT_HASH_VLANOFF 0x0008
/*
* Statistics registers 0x7000 to 0x7FFF
*/
#define SF_STATS_BASE 0x7000
#define SF_STATS_END 0x7FFF
/*
* TX frame processor instruction space 0x8000 to 0x9FFF
*/
/*
* RX frame processor instruction space 0xA000 to 0xBFFF
*/
/*
* Ethernet FIFO access space 0xC000 to 0xDFFF
*/
/*
* Reserved 0xE000 to 0xFFFF
*/
/*
* Descriptor data structures.
*/
/* Receive descriptor formats. */
#define SF_RX_MINSPACING 8
#define SF_RX_DLIST_CNT 256
#define SF_RX_CLIST_CNT 1024
#define SF_RX_HOSTADDR(x) (((x) >> 2) & 0x3FFFFFFF)
/*
* RX buffer descriptor type 0, 32-bit addressing. Note that we
* program the RX buffer queue control register(s) to allow a
* descriptor spacing of 16 bytes, which leaves room after each
* descriptor to store a pointer to the mbuf for each buffer.
*/
struct sf_rx_bufdesc_type0 {
u_int32_t sf_valid:1,
sf_end:1,
sf_addrlo:30;
u_int32_t sf_pad0;
#ifdef __i386__
u_int32_t sf_pad1;
#endif
struct mbuf *sf_mbuf;
};
/*
* RX buffer descriptor type 0, 64-bit addressing.
*/
struct sf_rx_bufdesc_type1 {
u_int32_t sf_valid:1,
sf_end:1,
sf_addrlo:30;
u_int32_t sf_addrhi;
#ifdef __i386__
u_int32_t sf_pad;
#endif
struct mbuf *sf_mbuf;
};
/*
* RX completion descriptor, type 0 (short).
*/
struct sf_rx_cmpdesc_type0 {
u_int32_t sf_len:16,
sf_endidx:11,
sf_status1:3,
sf_id:2;
};
/*
* RX completion descriptor, type 1 (basic). Includes vlan ID
* if this is a vlan-addressed packet, plus extended status.
*/
struct sf_rx_cmpdesc_type1 {
u_int32_t sf_len:16,
sf_endidx:11,
sf_status1:3,
sf_id:2;
u_int16_t sf_status2;
u_int16_t sf_vlanid;
};
/*
* RX completion descriptor, type 2 (checksum). Includes partial TCP/IP
* checksum instead of vlan tag, plus extended status.
*/
struct sf_rx_cmpdesc_type2 {
u_int32_t sf_len:16,
sf_endidx:11,
sf_status1:3,
sf_id:2;
u_int16_t sf_status2;
u_int16_t sf_cksum;
};
/*
* RX completion descriptor type 3 (full). Includes timestamp, partial
* TCP/IP checksum, vlan tag plus priority, two extended status fields.
*/
struct sf_rx_cmpdesc_type3 {
u_int32_t sf_len:16,
sf_endidx:11,
sf_status1:3,
sf_id:2;
u_int32_t sf_startidx:10,
sf_status3:6,
sf_status2:16;
u_int16_t sf_cksum;
u_int16_t sf_vlanid_prio;
u_int32_t sf_timestamp;
};
#define SF_RXSTAT1_QUEUE 0x1
#define SF_RXSTAT1_FIFOFULL 0x2
#define SF_RXSTAT1_OK 0x4
/* 0=unknown,5=unsupported */
#define SF_RXSTAT2_FRAMETYPE 0x0007 /* 1=IPv4,2=IPv2,3=IPX,4=ICMP */
#define SF_RXSTAT2_UDP 0x0008
#define SF_RXSTAT2_TCP 0x0010
#define SF_RXSTAT2_FRAG 0x0020
#define SF_RXSTAT2_PCSUM_OK 0x0040 /* partial checksum ok */
#define SF_RXSTAT2_CSUM_BAD 0x0080 /* TCP/IP checksum bad */
#define SF_RXSTAT2_CSUM_OK 0x0100 /* TCP/IP checksum ok */
#define SF_RXSTAT2_VLAN 0x0200
#define SF_RXSTAT2_BADRXCODE 0x0400
#define SF_RXSTAT2_DRIBBLE 0x0800
#define SF_RXSTAT2_ISL_CRCERR 0x1000
#define SF_RXSTAT2_CRCERR 0x2000
#define SF_RXSTAT2_HASH 0x4000
#define SF_RXSTAT2_PERFECT 0x8000
#define SF_RXSTAT3_TRAILER 0x01
#define SF_RXSTAT3_HEADER 0x02
#define SF_RXSTAT3_CONTROL 0x04
#define SF_RXSTAT3_PAUSE 0x08
#define SF_RXSTAT3_ISL 0x10
/*
* Transmit descriptor formats.
* Each transmit descriptor type allows for a skip field at the
* start of each structure. The size of the skip field can vary,
* however we always set it for 8 bytes, which is enough to hold
* a pointer (32 bits on x86, 64-bits on alpha) that we can use
* to hold the address of the head of the mbuf chain for the
* frame or fragment associated with the descriptor. This saves
* us from having to create a separate pointer array to hold
* the mbuf addresses.
*/
#define SF_TX_BUFDESC_ID 0xB
#define SF_MAXFRAGS 14
#define SF_TX_MINSPACING 128
#define SF_TX_DLIST_CNT 128
#define SF_TX_DLIST_SIZE 16384
#define SF_TX_SKIPLEN 1
#define SF_TX_CLIST_CNT 1024
struct sf_frag {
u_int32_t sf_addr;
u_int16_t sf_fraglen;
u_int16_t sf_pktlen;
};
struct sf_frag_msdos {
u_int16_t sf_pktlen;
u_int16_t sf_fraglen;
u_int32_t sf_addr;
};
/*
* TX frame descriptor type 0, 32-bit addressing. One descriptor can
* be used to map multiple packet fragments. We use this format since
* BSD networking fragments packet data across mbuf chains. Note that
* the number of fragments can be variable depending on how the descriptor
* spacing is specified in the TX descriptor queue control register.
* We always use a spacing of 128 bytes, and a skipfield length of 8
* bytes: this means 16 bytes for the descriptor, including the skipfield,
* with 121 bytes left for fragment maps. Each fragment requires 8 bytes,
* which allows for 14 fragments per descriptor. The total size of the
* transmit buffer queue is limited to 16384 bytes, so with a spacing of
* 128 bytes per descriptor, we have room for 128 descriptors in the queue.
*/
struct sf_tx_bufdesc_type0 {
#ifdef __i386__
u_int32_t sf_pad;
#endif
struct mbuf *sf_mbuf;
u_int32_t sf_rsvd0:24,
sf_crcen:1,
sf_caltcp:1,
sf_end:1,
sf_intr:1,
sf_id:4;
u_int8_t sf_fragcnt;
u_int8_t sf_rsvd2;
u_int16_t sf_rsvd1;
struct sf_frag sf_frags[14];
};
/*
* TX buffer descriptor type 1, 32-bit addressing. Each descriptor
* maps a single fragment.
*/
struct sf_tx_bufdesc_type1 {
#ifdef __i386__
u_int32_t sf_pad;
#endif
struct mbuf *sf_mbuf;
u_int32_t sf_fraglen:16,
sf_fragcnt:8,
sf_crcen:1,
sf_caltcp:1,
sf_end:1,
sf_intr:1,
sf_id:4;
u_int32_t sf_addr;
};
/*
* TX buffer descriptor type 2, 64-bit addressing. Each descriptor
* maps a single fragment.
*/
struct sf_tx_bufdesc_type2 {
#ifdef __i386__
u_int32_t sf_pad;
#endif
struct mbuf *sf_mbuf;
u_int32_t sf_fraglen:16,
sf_fragcnt:8,
sf_crcen:1,
sf_caltcp:1,
sf_end:1,
sf_intr:1,
sf_id:4;
u_int32_t sf_addrlo;
u_int32_t sf_addrhi;
};
/* TX buffer descriptor type 3 is not defined. */
/*
* TX frame descriptor type 4, 32-bit addressing. This is a special
* case of the type 0 descriptor, identical except that the fragment
* address and length fields are ordered differently. This is done
* to optimize copies in MS-DOS and OS/2 drivers.
*/
struct sf_tx_bufdesc_type4 {
#ifdef __i386__
u_int32_t sf_pad;
#endif
struct mbuf *sf_mbuf;
u_int32_t sf_rsvd0:24,
sf_crcen:1,
sf_caltcp:1,
sf_end:1,
sf_intr:1,
sf_id:4;
u_int8_t sf_fragcnt;
u_int8_t sf_rsvd2;
u_int16_t sf_rsvd1;
struct sf_frag_msdos sf_frags[14];
};
/*
* Transmit completion queue descriptor formats.
*/
/*
* Transmit DMA completion descriptor, type 0.
*/
#define SF_TXCMPTYPE_DMA 0x4
struct sf_tx_cmpdesc_type0 {
u_int32_t sf_index:15,
sf_priority:1,
sf_timestamp:13,
sf_type:3;
};
/*
* Transmit completion descriptor, type 1.
*/
#define SF_TXCMPTYPE_TX 0x5
struct sf_tx_cmpdesc_type1 {
u_int32_t sf_index:15,
sf_priority:1,
sf_txstat:13,
sf_type:3;
};
#define SF_TXSTAT_CRCERR 0x0001
#define SF_TXSTAT_LENCHECKERR 0x0002
#define SF_TXSTAT_LENRANGEERR 0x0004
#define SF_TXSTAT_TX_OK 0x0008
#define SF_TXSTAT_TX_DEFERED 0x0010
#define SF_TXSTAT_EXCESS_DEFER 0x0020
#define SF_TXSTAT_EXCESS_COLL 0x0040
#define SF_TXSTAT_LATE_COLL 0x0080
#define SF_TXSTAT_TOOBIG 0x0100
#define SF_TXSTAT_TX_UNDERRUN 0x0200
#define SF_TXSTAT_CTLFRAME_OK 0x0400
#define SF_TXSTAT_PAUSEFRAME_OK 0x0800
#define SF_TXSTAT_PAUSED 0x1000
/* Statistics counters. */
struct sf_stats {
u_int32_t sf_tx_frames;
u_int32_t sf_tx_single_colls;
u_int32_t sf_tx_multi_colls;
u_int32_t sf_tx_crcerrs;
u_int32_t sf_tx_bytes;
u_int32_t sf_tx_defered;
u_int32_t sf_tx_late_colls;
u_int32_t sf_tx_pause_frames;
u_int32_t sf_tx_control_frames;
u_int32_t sf_tx_excess_colls;
u_int32_t sf_tx_excess_defer;
u_int32_t sf_tx_mcast_frames;
u_int32_t sf_tx_bcast_frames;
u_int32_t sf_tx_frames_lost;
u_int32_t sf_rx_rx_frames;
u_int32_t sf_rx_crcerrs;
u_int32_t sf_rx_alignerrs;
u_int32_t sf_rx_bytes;
u_int32_t sf_rx_control_frames;
u_int32_t sf_rx_unsup_control_frames;
u_int32_t sf_rx_giants;
u_int32_t sf_rx_runts;
u_int32_t sf_rx_jabbererrs;
u_int32_t sf_rx_pkts_64;
u_int32_t sf_rx_pkts_65_127;
u_int32_t sf_rx_pkts_128_255;
u_int32_t sf_rx_pkts_256_511;
u_int32_t sf_rx_pkts_512_1023;
u_int32_t sf_rx_pkts_1024_1518;
u_int32_t sf_rx_frames_lost;
u_int16_t sf_tx_underruns;
u_int16_t sf_pad;
};
/*
* register space access macros
*/
#define CSR_WRITE_4(sc, reg, val) \
bus_space_write_4(sc->sf_btag, sc->sf_bhandle, reg, val)
#define CSR_READ_4(sc, reg) \
bus_space_read_4(sc->sf_btag, sc->sf_bhandle, reg)
#define CSR_READ_1(sc, reg) \
bus_space_read_1(sc->sf_btag, sc->sf_bhandle, reg)
struct sf_type {
u_int16_t sf_vid;
u_int16_t sf_did;
char *sf_name;
};
#define SF_INC(x, y) (x) = (x + 1) % y
#define ETHER_ALIGN 2
/*
* Note: alignment is important here: each list must be aligned to
* a 256-byte boundary. It turns out that each ring is some multiple
* of 4K in length, so we can stack them all on top of each other
* and just worry about aligning the whole mess. There's one transmit
* buffer ring and two receive buffer rings: one RX ring is for small
* packets and the other is for large packets. Each buffer ring also
* has a companion completion queue.
*/
struct sf_list_data {
struct sf_tx_bufdesc_type0 sf_tx_dlist[SF_TX_DLIST_CNT];
struct sf_tx_cmpdesc_type1 sf_tx_clist[SF_TX_CLIST_CNT];
struct sf_rx_bufdesc_type0 sf_rx_dlist_big[SF_RX_DLIST_CNT];
#ifdef notdef
/*
* Unfortunately, because the Starfire doesn't allow arbitrary
* byte alignment, we have to copy packets in the RX handler in
* order to align the payload correctly. This means that we
* don't gain anything by having separate large and small descriptor
* lists, so for now we don't bother with the small one.
*/
struct sf_rx_bufdesc_type0 sf_rx_dlist_small[SF_RX_DLIST_CNT];
#endif
struct sf_rx_cmpdesc_type3 sf_rx_clist[SF_RX_CLIST_CNT];
};
struct sf_softc {
struct arpcom arpcom; /* interface info */
bus_space_handle_t sf_bhandle; /* bus space handle */
bus_space_tag_t sf_btag; /* bus space tag */
void *sf_intrhand; /* interrupt handler cookie */
struct resource *sf_irq; /* irq resource descriptor */
struct resource *sf_res; /* mem/ioport resource */
struct sf_type *sf_info; /* Starfire adapter info */
device_t sf_miibus;
u_int8_t sf_unit; /* interface number */
struct sf_list_data *sf_ldata;
int sf_tx_cnt;
u_int8_t sf_link;
int sf_if_flags;
struct callout_handle sf_stat_ch;
struct mtx sf_mtx;
};
#define SF_LOCK(_sc) mtx_enter(&(_sc)->sf_mtx, MTX_DEF)
#define SF_UNLOCK(_sc) mtx_exit(&(_sc)->sf_mtx, MTX_DEF)
#define SF_TIMEOUT 1000
#ifdef __alpha__
#undef vtophys
#define vtophys(va) alpha_XXX_dmamap((vm_offset_t)va)
#endif