freebsd-skq/sys/dev/fatm/if_fatmreg.h
harti c1fe1ae28e This is a driver for Fore PCA200E cards that uses busdma and works on
little endian and big endian and with 32 and 64 bit pointers. It already
has the hooks to be used for HARP, NATM and ngATM.
2003-06-23 14:46:12 +00:00

500 lines
17 KiB
C

/*
* 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>
*
* $FreeBSD$
*
* 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