Current Path : /sys/dev/fatm/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/dev/fatm/if_fatmreg.h |
/*- * Copyright (c) 2001-2003 * Fraunhofer Institute for Open Communication Systems (FhG Fokus). * 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. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR 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 THE AUTHOR OR CONTRIBUTORS 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. * * Author: Hartmut Brandt <harti@freebsd.org> * * $FreeBSD: release/9.1.0/sys/dev/fatm/if_fatmreg.h 139749 2005-01-06 01:43:34Z imp $ * * Fore PCA200E hardware definitions. */ /* * Fore implements some additional PCI registers. One of them is the * master control register. One of the bits allow to automatically byte * swap accesses to the on-board RAM. */ #define FATM_PCIR_MCTL 0x41 #define FATM_PCIM_SWAB 0x100 /* * Operations codes for commands. */ enum { FATM_OP_INITIALIZE = 0x01, /* Initialize the card */ FATM_OP_ACTIVATE_VCIN = 0x02, /* Start reassembly on a channel */ FATM_OP_ACTIVATE_VCOUT = 0x03, /* (not used) */ FATM_OP_DEACTIVATE_VCIN = 0x04, /* Stop reassembly on a channel */ FATM_OP_DEACTIVATE_VCOUT= 0x05, /* (not used) */ FATM_OP_REQUEST_STATS = 0x06, /* Get statistics */ FATM_OP_OC3_SET_REG = 0x07, /* Set OC3 chip register */ FATM_OP_OC3_GET_REG = 0x08, /* Get OC3 chip registers */ FATM_OP_ZERO_STATS = 0x09, /* Zero out statistics */ FATM_OP_GET_PROM_DATA = 0x0a, /* Return expansion ROM data */ FATM_OP_SETVPI_BITS = 0x0b, /* (not used, not implemented) */ FATM_OP_INTERRUPT_SEL = 0x80, /* Request interrupt on completion */ }; /* * Status word definitions. Before initiating an operation the host sets the * status word to PENDING. The card sets it to COMPLETE upon completion of * the transmit/receive or command. An unused queue entry contains FREE. * The ERROR can be ored into the COMPLETE. Note, that there are circumstances * when ERROR is set without COMPLETE beeing set (when you try to activate * a bad VCI like, for example, VCI 0). */ enum { FATM_STAT_PENDING = 0x01, FATM_STAT_COMPLETE = 0x02, FATM_STAT_FREE = 0x04, FATM_STAT_ERROR = 0x08, }; /* * On board queue offsets. There are two fundamentally different queue types: * the command queue and all other queues. The command queue has 32 byte * entries on the card which contain the operation code, parameters and the * DMA pointer to the status word. All other queues have 8 byte entries, which * contain a DMA pointer to the i/o block, that contains the parameters, and * a DMA pointer to the status word. */ #define FATMOC_OP 0 /* cmd queue: offset to op code */ #define FATMOC_PARAM 4 /* cmd queue: offset to parameters */ #define FATMOC_STATP 16 /* cmd queue: offset to status ptr */ #define FATMOC_END 32 /* cmd queue: element size */ #define FATMOC_ACTIN_VPVC (FATMOC_PARAM + 0) #define FATMOC_ACTIN_MTU (FATMOC_PARAM + 4) #define FATMOC_DEACTIN_VPVC (FATMOC_PARAM + 0) #define FATMOC_GETOC3_BUF (FATMOC_PARAM + 0) #define FATMOC_GSTAT_BUF (FATMOC_PARAM + 0) #define FATMOC_GPROM_BUF (FATMOC_PARAM + 0) #define FATMOS_IOBLK 0 /* other queues: offset to ioblk ptr */ #define FATMOS_STATP 4 /* other queues: offset to status ptr */ #define FATM_MAKE_SETOC3(REG,VAL,MASK) \ (FATM_OP_OC3_SET_REG | (((REG) & 0xff) << 8) | \ (((VAL) & 0xff) << 16) | (((MASK) & 0xff) << 24)) #define FATM_NREGS 128 /* * On board memory layout. * * The card contains up to 2MByte memory that is mapped at virtual offset 0. * It is followed by three registers. The memory contains two areas at * fixed addresses: the mon960 area that is used for communication with * the card's operating system and the common block that is used by the * firmware to communicate with the driver. */ #define FATM_RAM_SIZE (256 * 1024) /* normal RAM size */ #define FATMO_RAM (0x0) /* virtual RAM start */ #define FATMO_MON960 (0x400) /* mon960 communication area */ #define FATMO_COMMON_ORIGIN (0x4d40) /* firmware comm. area */ #define FATMO_HCR (0x100000) /* host control registers */ #define FATMO_HIMR (0x100004) /* host interrupt mask */ #define FATMO_PSR (0x100008) /* PCI control register */ #define FATMO_END (0x200000) /* end of mapped area */ /* * The mon960 area contains two cells that are used as a virtual serial * interface, a status word, the base for loading the application (i.e. * firmware) and a version number. */ #define FATMO_UART_TO_960 (FATMO_MON960 + 0) #define FATMO_UART_TO_HOST (FATMO_MON960 + 4) #define FATMO_BOOT_STATUS (FATMO_MON960 + 8) #define FATMO_APP_BASE (FATMO_MON960 + 12) #define FATMO_VERSION (FATMO_MON960 + 16) /* * The host control register allows to hold the i960 or send it interrupts. * The bits have different meaning on read and write. */ #define FATM_HCR_RESET 0x01 /* (W) reset the card */ #define FATM_HCR_LOCK_HOLD 0x02 /* (W) hold the i960 */ #define FATM_HCR_I960FAIL 0x04 /* (R) internal self-test failed */ #define FATM_HCR_INTR2 0x04 /* (W) assert i960 interrupt 2 */ #define FATM_HCR_HOLDA 0x08 /* (R) hold ack from i960 */ #define FATM_HCR_INTR1 0x08 /* (W) assert i960 interrupt 1 */ #define FATM_HCR_OFIFO 0x10 /* (R) DMA request FIFO full */ #define FATM_HCR_CLRIRQ 0x10 /* (W) clear interrupt request */ #define FATM_HCR_ESP_HOLD 0x20 /* (R) SAR chip holds i960 */ #define FATM_HCR_IFIFO 0x40 /* (R) input FIFO full */ #define FATM_HCR_TESTMODE 0x80 /* (R) board is in test mode */ /* * The mon960 area contains a virtual UART and a status word. * The UART uses a simple protocol: a zero means, that there is no * character available from the i960 or that one can write the next * character to the i960. This character has to be ored with 0x1000000 * to signal to the i960 that there is a new character. * The cold_start values must be written to the status word, the others * denote certain stages of initializing. */ #define XMIT_READY 0 #define CHAR_AVAIL 0x1000000 #define COLD_START 0xc01dc01d #define SELF_TEST_OK 0x02201958 #define SELF_TEST_FAIL 0xadbadbad #define CP_RUNNING 0xce11feed #define MON906_TOO_BIG 0x10aded00 /* * The firmware communication area contains a big structure most of which * is used only during initialisation. */ /* * These are the offsets to the onboard queues that are valid after the * initialisation command has completed. */ #define FATMO_COMMAND_QUEUE (FATMO_COMMON_ORIGIN + 0) #define FATMO_TRANSMIT_QUEUE (FATMO_COMMON_ORIGIN + 4) #define FATMO_RECEIVE_QUEUE (FATMO_COMMON_ORIGIN + 8) #define FATMO_SMALL_B1_QUEUE (FATMO_COMMON_ORIGIN + 12) #define FATMO_LARGE_B1_QUEUE (FATMO_COMMON_ORIGIN + 16) #define FATMO_SMALL_B2_QUEUE (FATMO_COMMON_ORIGIN + 20) #define FATMO_LARGE_B2_QUEUE (FATMO_COMMON_ORIGIN + 24) /* * If the interrupt mask is set to 1, interrupts to the host are queued, but * inhbited. The istat variable is set, when this card has posted an interrupt. */ #define FATMO_IMASK (FATMO_COMMON_ORIGIN + 28) #define FATMO_ISTAT (FATMO_COMMON_ORIGIN + 32) /* * This is the offset and the size of the queue area. Could be used to * dynamically compute queue sizes. */ #define FATMO_HEAP_BASE (FATMO_COMMON_ORIGIN + 36) #define FATMO_HEAP_SIZE (FATMO_COMMON_ORIGIN + 40) #define FATMO_HLOGGER (FATMO_COMMON_ORIGIN + 44) /* * The heartbeat variable is incremented in each loop of the normal processing. * If it is stuck this means, that the card had a fatal error. In this case * it may set the word to a number of values of the form 0xdeadXXXX where * XXXX is an error code. */ #define FATMO_HEARTBEAT (FATMO_COMMON_ORIGIN + 48) #define FATMO_FIRMWARE_RELEASE (FATMO_COMMON_ORIGIN + 52) #define FATMO_MON960_RELEASE (FATMO_COMMON_ORIGIN + 56) #define FATMO_TQ_PLEN (FATMO_COMMON_ORIGIN + 60) /* * At this offset the init command block is located. The init command cannot * use the normal queue mechanism because it is used to initialize the * queues. For this reason it is located at this fixed offset. */ #define FATMO_INIT (FATMO_COMMON_ORIGIN + 64) /* * physical media type */ #define FATMO_MEDIA_TYPE (FATMO_COMMON_ORIGIN + 176) #define FATMO_OC3_REVISION (FATMO_COMMON_ORIGIN + 180) /* * End of the common block */ #define FATMO_COMMON_END (FATMO_COMMON_ORIGIN + 184) /* * The INITIALIZE command block. This is embedded into the above common * block. The offsets are from the beginning of the command block. */ #define FATMOI_OP 0 /* operation code */ #define FATMOI_STATUS 4 /* status word */ #define FATMOI_RECEIVE_TRESHOLD 8 /* when to start interrupting */ #define FATMOI_NUM_CONNECT 12 /* max number of VCIs */ #define FATMOI_CQUEUE_LEN 16 /* length of command queue */ #define FATMOI_TQUEUE_LEN 20 /* length of transmit queue */ #define FATMOI_RQUEUE_LEN 24 /* length of receive queue */ #define FATMOI_RPD_EXTENSION 28 /* additional 32 byte blocks */ #define FATMOI_TPD_EXTENSION 32 /* additional 32 byte blocks */ #define FATMOI_CONLESS_VPVC 36 /* (not used) */ #define FATMOI_SMALL_B1 48 /* small buffer 1 pool */ #define FATMOI_LARGE_B1 64 /* small buffer 2 pool */ #define FATMOI_SMALL_B2 80 /* large buffer 1 pool */ #define FATMOI_LARGE_B2 96 /* large buffer 2 pool */ #define FATMOI_END 112 /* size of init block */ /* * Each of the four buffer schemes is initialized with a block that * contains four words: */ #define FATMOB_QUEUE_LENGTH 0 /* supply queue length */ #define FATMOB_BUFFER_SIZE 4 /* size of each buffer */ #define FATMOB_POOL_SIZE 8 /* size of on-board pool */ #define FATMOB_SUPPLY_BLKSIZE 12 /* number of buffers/supply */ /* * The fore firmware is a binary file, that starts with a header. The * header contains the offset to where the file must be loaded and the * entry for execution. The header must also be loaded onto the card! */ struct firmware { uint32_t id; /* "FORE" */ uint32_t version; /* firmware version */ uint32_t offset; /* load offset */ uint32_t entry; /* entry point */ }; #define FATM_FWID 0x65726f66 /* "FORE" */ #define FATM_FWVERSION 0x100 /* supported version */ /* * PDUs to be transmitted are described by Transmit PDU Descriptors. * These descriptors are held in host memory, but referenced from the ioblk * member of the queue structure on the card. The card DMAs the descriptor * and than gather-DMAs the PDU transmitting it on-the-fly. Tpds are variable * length in blocks of 32 byte (8 words). The minimum length is one block, * maximum 15. The number of blocks beyond 1 is configured during the * initialisation command (tpd_extension). * Each gather-DMA segment is described by a segment descriptor. The buffer * address and the length must be a multiple of four. * Tpd must also be 4 byte aligned. * Because of the minimum length of 32 byte, the first blocks contains already * 2 segement descriptors. Each extension block holds four descriptors. */ #define TXD_FIXED 2 #define SEGS_PER_BLOCK 4 /* segment descriptors per extension block */ struct txseg { uint32_t buffer; /* DMA buffer address */ uint32_t length; /* and length */ }; struct tpd { uint32_t atm_header; /* header for the transmitted cells */ uint32_t spec; /* PDU description */ uint32_t stream; /* traffic shaping word */ uint32_t pad[1]; struct txseg segment[TXD_FIXED]; }; #define TDX_MKSPEC(INTR,AAL,NSEG,LEN) \ (((INTR) << 28) | ((AAL) << 24) | ((NSEG) << 16) | (LEN)) #define TDX_MKSTR(DATA,IDLE) \ (((DATA) << 16) | (IDLE)) #define TDX_MKHDR(VPI,VCI,PT,CLP) \ (((VPI) << 20) | ((VCI) << 4) | ((PT) << 1) | (CLP)) #define TDX_SEGS2BLKS(SEGS) \ (1 + ((SEGS)-TXD_FIXED+SEGS_PER_BLOCK-1)/SEGS_PER_BLOCK) /* * We want probably support scatter transmission, so we use the maximum * transmit descriptor extension that is possible. Because the size of the * Tpd is encoded in 32-byte blocks in a 4-bit field, the maximum extension * is 14 such blocks. The value for the init command is the number of * additional descriptor entries NOT the number of 32 byte blocks. */ #define TPD_EXTENSION_BLOCKS 14 #define TPD_EXTENSIONS (TPD_EXTENSION_BLOCKS * 4) #define TPD_SIZE ((size_t)((TPD_EXTENSION_BLOCKS+1) * 32)) /* * Received PDUs are handed from the card to the host by means of Receive * PDU descriptors. Each segment describes on part of the PDU. The buffer * handle is a 32 bit value that is supplied by the host and passed * transparently back to the host by the card. It is used to locate the buffer. * The length field is the number of actual bytes in that buffer. */ #define RXD_FIXED 3 struct rxseg { uint32_t handle; /* buffer handle */ uint32_t length; /* number of bytes */ }; struct rpd { uint32_t atm_header; uint32_t nseg; struct rxseg segment[RXD_FIXED]; }; /* * PDUs received are stored in buffers supplied to the card. We use only * buffer scheme 1: small buffers are normal mbuf's which can hold three * cells in their default size (256 byte) and mbuf clusters which can * hold 42 cells (2 kbyte). * The number of receive segments can be computed from these sizes: */ #define FATM_MAXPDU 65535 #define MAXPDU_CELLS ((FATM_MAXPDU+47)/48) #define SMALL_BUFFER_CELLS (MHLEN/48) #define LARGE_BUFFER_CELLS (MCLBYTES/48) #define SMALL_BUFFER_LEN (SMALL_BUFFER_CELLS * 48) #define LARGE_BUFFER_LEN (LARGE_BUFFER_CELLS * 48) /* * The card first alloctes a small buffer and the switches to large * buffers. So the number of large buffers needed to store the maximum * PDU is: */ #define MAX_LARGE_BUFFERS ((MAXPDU_CELLS - SMALL_BUFFER_CELLS \ + LARGE_BUFFER_CELLS - 1) \ / LARGE_BUFFER_CELLS) \ /* * From this we get the number of extension blocks for the Rpds as: */ #define RPD_EXTENSION_BLOCKS ((MAX_LARGE_BUFFERS + 1 - RXD_FIXED \ + SEGS_PER_BLOCK - 1) \ / SEGS_PER_BLOCK) #define RPD_EXTENSIONS (RPD_EXTENSION_BLOCKS * 4) #define RPD_SIZE ((size_t)((RPD_EXTENSION_BLOCKS+1) * 32)) /* * Buffers are supplied to the card prior receiving by the supply queues. * We use two queues: scheme 1 small buffers and scheme 1 large buffers. * The queues and on-card pools are initialized by the initialize command. * Buffers are supplied in chunks. Each chunk can contain from 4 to 124 * buffers in multiples of four. The chunk sizes are configured by the * initialize command. Each buffer in a chunk is described by a Receive * Buffer Descriptor that is held in host memory and given as the ioblk * to the card. */ #define BSUP_BLK2SIZE(CHUNK) (8 * (CHUNK)) struct rbd { uint32_t handle; uint32_t buffer; /* DMA address for card */ }; /* * The PCA200E has an expansion ROM that contains version information and * the FORE-assigned MAC address. It can be read via the get_prom_data * operation. */ struct prom { uint32_t version; uint32_t serial; uint8_t mac[8]; }; /* * The media type member of the firmware communication block contains a * code that describes the physical medium and physical protocol. */ #define FORE_MT_TAXI_100 0x04 #define FORE_MT_TAXI_140 0x05 #define FORE_MT_UTP_SONET 0x06 #define FORE_MT_MM_OC3_ST 0x16 #define FORE_MT_MM_OC3_SC 0x26 #define FORE_MT_SM_OC3_ST 0x36 #define FORE_MT_SM_OC3_SC 0x46 /* * Assorted constants */ #define FORE_MAX_VCC 1024 /* max. number of VCIs supported */ #define FORE_VCIBITS 10 #define FATM_STATE_TIMEOUT 500 /* msec */ /* * Statistics as delivered by the FORE cards */ struct fatm_stats { struct { uint32_t crc_header_errors; uint32_t framing_errors; uint32_t pad[2]; } phy_4b5b; struct { uint32_t section_bip8_errors; uint32_t path_bip8_errors; uint32_t line_bip24_errors; uint32_t line_febe_errors; uint32_t path_febe_errors; uint32_t corr_hcs_errors; uint32_t ucorr_hcs_errors; uint32_t pad[1]; } phy_oc3; struct { uint32_t cells_transmitted; uint32_t cells_received; uint32_t vpi_bad_range; uint32_t vpi_no_conn; uint32_t vci_bad_range; uint32_t vci_no_conn; uint32_t pad[2]; } atm; struct { uint32_t cells_transmitted; uint32_t cells_received; uint32_t cells_dropped; uint32_t pad[1]; } aal0; struct { uint32_t cells_transmitted; uint32_t cells_received; uint32_t cells_crc_errors; uint32_t cels_protocol_errors; uint32_t cells_dropped; uint32_t cspdus_transmitted; uint32_t cspdus_received; uint32_t cspdus_protocol_errors; uint32_t cspdus_dropped; uint32_t pad[3]; } aal4; struct { uint32_t cells_transmitted; uint32_t cells_received; uint32_t congestion_experienced; uint32_t cells_dropped; uint32_t cspdus_transmitted; uint32_t cspdus_received; uint32_t cspdus_crc_errors; uint32_t cspdus_protocol_errors; uint32_t cspdus_dropped; uint32_t pad[3]; } aal5; struct { uint32_t small_b1_failed; uint32_t large_b1_failed; uint32_t small_b2_failed; uint32_t large_b2_failed; uint32_t rpd_alloc_failed; uint32_t receive_carrier; uint32_t pad[2]; } aux; }; #define FATM_NSTATS 42