Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/sound/driver/driver/@/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/amd64/compile/hs32/modules/usr/src/sys/modules/sound/driver/driver/@/dev/fatm/if_fatmvar.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_fatmvar.h 199559 2009-11-19 22:06:40Z jhb $ * * Fore PCA200E driver definitions. */ /* * Debug statistics of the PCA200 driver */ struct istats { uint32_t cmd_queue_full; uint32_t get_stat_errors; uint32_t clr_stat_errors; uint32_t get_prom_errors; uint32_t suni_reg_errors; uint32_t tx_queue_full; uint32_t tx_queue_almost_full; uint32_t tx_pdu2big; uint32_t tx_too_many_segs; uint32_t tx_retry; uint32_t fix_empty; uint32_t fix_addr_copy; uint32_t fix_addr_noext; uint32_t fix_addr_ext; uint32_t fix_len_noext; uint32_t fix_len_copy; uint32_t fix_len; uint32_t rx_badvc; uint32_t rx_closed; }; /* * Addresses on the on-board RAM are expressed as offsets to the * start of that RAM. */ typedef uint32_t cardoff_t; /* * The card uses a number of queues for communication with the host. * Parts of the queue are located on the card (pointers to the status * word and the ioblk and the command blocks), the rest in host memory. * Each of these queues forms a ring, where the head and tail pointers are * managed * either by the card or the host. For the receive queue the * head is managed by the card (and not used altogether by the host) and the * tail by the host - for all other queues its the other way around. * The host resident parts of the queue entries contain pointers to * the host resident status and the host resident ioblk (the latter not for * the command queue) as well as DMA addresses for supply to the card. */ struct fqelem { cardoff_t card; /* corresponding element on card */ bus_addr_t card_ioblk; /* ioblk address to supply to card */ volatile uint32_t *statp; /* host status pointer */ void *ioblk; /* host ioblk (not for commands) */ }; struct fqueue { struct fqelem *chunk; /* pointer to the element array */ int head; /* queue head */ int tail; /* queue tail */ }; /* * Queue manipulation macros */ #define NEXT_QUEUE_ENTRY(HEAD,LEN) ((HEAD) = ((HEAD) + 1) % LEN) #define GET_QUEUE(Q,TYPE,IDX) (&((TYPE *)(Q).chunk)[(IDX)]) /* * Now define structures for the different queues. Each of these structures * must start with a struct fqelem. */ struct txqueue { /* transmit queue element */ struct fqelem q; struct mbuf *m; /* the chain we are transmitting */ bus_dmamap_t map; /* map for the packet */ }; struct rxqueue { /* receive queue element */ struct fqelem q; }; struct supqueue { /* supply queue element */ struct fqelem q; }; struct cmdqueue; struct fatm_softc; typedef void (*completion_cb)(struct fatm_softc *, struct cmdqueue *); struct cmdqueue { /* command queue element */ struct fqelem q; completion_cb cb; /* call on command completion */ int error; /* set if error occured */ }; /* * Card-DMA-able memory is managed by means of the bus_dma* functions. * To allocate a chunk of memory with a specific size and alignment one * has to: * 1. create a DMA tag * 2. allocate the memory * 3. load the memory into a map. * This finally gives the physical address that can be given to the card. * The card can DMA the entire 32-bit space without boundaries. We assume, * that all the allocations can be mapped in one contiguous segment. This * may be wrong in the future if we have more than 32 bit addresses. * Allocation is done at attach time and managed by the following structure. * * This could be done easier with the NetBSD bus_dma* functions. They appear * to be more useful and consistent. */ struct fatm_mem { u_int size; /* size */ u_int align; /* alignment */ bus_dma_tag_t dmat; /* DMA tag */ void *mem; /* memory block */ bus_addr_t paddr; /* pysical address */ bus_dmamap_t map; /* map */ }; /* * Each of these structures describes one receive buffer while the buffer * is on the card or in the receive return queue. These structures are * allocated at initialisation time together with the DMA maps. The handle that * is given to the card is the index into the array of these structures. */ struct rbuf { struct mbuf *m; /* the mbuf while we are on the card */ bus_dmamap_t map; /* the map */ LIST_ENTRY(rbuf) link; /* the free list link */ }; LIST_HEAD(rbuf_list, rbuf); /* * The driver maintains a list of all open VCCs. Because we * use only VPI=0 and a maximum VCI of 1024, the list is rather an array * than a list. We also store the atm pseudoheader flags here and the * rxhand (aka. protocol block). */ struct card_vcc { struct atmio_vcc param; /* traffic parameters */ void *rxhand; u_int vflags; uint32_t ipackets; uint32_t opackets; uint32_t ibytes; uint32_t obytes; }; #define FATM_VCC_OPEN 0x00010000 /* is open */ #define FATM_VCC_TRY_OPEN 0x00020000 /* is currently opening */ #define FATM_VCC_TRY_CLOSE 0x00040000 /* is currently closing */ #define FATM_VCC_BUSY 0x00070000 /* one of the above */ #define FATM_VCC_REOPEN 0x00080000 /* reopening during init */ /* * Finally the softc structure */ struct fatm_softc { struct ifnet *ifp; /* common part */ struct mtx mtx; /* lock this structure */ struct ifmedia media; /* media */ struct callout watchdog_timer; int init_state; /* initialisation step */ int memid; /* resource id for card memory */ struct resource *memres; /* resource for card memory */ bus_space_handle_t memh; /* handle for card memory */ bus_space_tag_t memt; /* tag for card memory */ int irqid; /* resource id for interrupt */ struct resource *irqres; /* resource for interrupt */ void *ih; /* interrupt handler */ bus_dma_tag_t parent_dmat; /* parent DMA tag */ struct fatm_mem stat_mem; /* memory for status blocks */ struct fatm_mem txq_mem; /* TX descriptor queue */ struct fatm_mem rxq_mem; /* RX descriptor queue */ struct fatm_mem s1q_mem; /* Small buffer 1 queue */ struct fatm_mem l1q_mem; /* Large buffer 1 queue */ struct fatm_mem prom_mem; /* PROM memory */ struct fqueue txqueue; /* transmission queue */ struct fqueue rxqueue; /* receive queue */ struct fqueue s1queue; /* SMALL S1 queue */ struct fqueue l1queue; /* LARGE S1 queue */ struct fqueue cmdqueue; /* command queue */ /* fields for access to the SUNI registers */ struct fatm_mem reg_mem; /* DMAable memory for readregs */ struct cv cv_regs; /* to serialize access to reg_mem */ /* fields for access to statistics */ struct fatm_mem sadi_mem; /* sadistics memory */ struct cv cv_stat; /* to serialize access to sadi_mem */ u_int flags; #define FATM_STAT_INUSE 0x0001 #define FATM_REGS_INUSE 0x0002 u_int txcnt; /* number of used transmit desc */ int retry_tx; /* keep mbufs in queue if full */ struct card_vcc **vccs; /* table of vccs */ int open_vccs; /* number of vccs in use */ int small_cnt; /* number of buffers owned by card */ int large_cnt; /* number of buffers owned by card */ uma_zone_t vcc_zone; /* allocator for VCCs */ /* receiving */ struct rbuf *rbufs; /* rbuf array */ struct rbuf_list rbuf_free; /* free rbufs list */ struct rbuf_list rbuf_used; /* used rbufs list */ u_int rbuf_total; /* total number of buffs */ bus_dma_tag_t rbuf_tag; /* tag for rbuf mapping */ /* transmission */ bus_dma_tag_t tx_tag; /* transmission tag */ uint32_t heartbeat; /* last heartbeat */ u_int stop_cnt; /* how many times checked */ struct istats istats; /* internal statistics */ /* SUNI state */ struct utopia utopia; /* sysctl support */ struct sysctl_ctx_list sysctl_ctx; struct sysctl_oid *sysctl_tree; #ifdef FATM_DEBUG /* debugging */ u_int debug; #endif }; #ifndef FATM_DEBUG #define FATM_LOCK(SC) mtx_lock(&(SC)->mtx) #define FATM_UNLOCK(SC) mtx_unlock(&(SC)->mtx) #else #define FATM_LOCK(SC) do { \ DBG(SC, LOCK, ("locking in line %d", __LINE__)); \ mtx_lock(&(SC)->mtx); \ } while (0) #define FATM_UNLOCK(SC) do { \ DBG(SC, LOCK, ("unlocking in line %d", __LINE__)); \ mtx_unlock(&(SC)->mtx); \ } while (0) #endif #define FATM_CHECKLOCK(SC) mtx_assert(&sc->mtx, MA_OWNED) /* * Macros to access host memory fields that are also access by the card. * These fields need to little-endian always. */ #define H_GETSTAT(STATP) (le32toh(*(STATP))) #define H_SETSTAT(STATP, S) do { *(STATP) = htole32(S); } while (0) #define H_SETDESC(DESC, D) do { (DESC) = htole32(D); } while (0) #ifdef notyet #define H_SYNCSTAT_POSTREAD(SC, P) \ bus_dmamap_sync_size((SC)->stat_mem.dmat, \ (SC)->stat_mem.map, \ (volatile char *)(P) - (volatile char *)(SC)->stat_mem.mem, \ sizeof(volatile uint32_t), BUS_DMASYNC_POSTREAD) #define H_SYNCSTAT_PREWRITE(SC, P) \ bus_dmamap_sync_size((SC)->stat_mem.dmat, \ (SC)->stat_mem.map, \ (volatile char *)(P) - (volatile char *)(SC)->stat_mem.mem, \ sizeof(volatile uint32_t), BUS_DMASYNC_PREWRITE) #define H_SYNCQ_PREWRITE(M, P, SZ) \ bus_dmamap_sync_size((M)->dmat, (M)->map, \ (volatile char *)(P) - (volatile char *)(M)->mem, (SZ), \ BUS_DMASYNC_PREWRITE) #define H_SYNCQ_POSTREAD(M, P, SZ) \ bus_dmamap_sync_size((M)->dmat, (M)->map, \ (volatile char *)(P) - (volatile char *)(M)->mem, (SZ), \ BUS_DMASYNC_POSTREAD) #else #define H_SYNCSTAT_POSTREAD(SC, P) do { } while (0) #define H_SYNCSTAT_PREWRITE(SC, P) do { } while (0) #define H_SYNCQ_PREWRITE(M, P, SZ) do { } while (0) #define H_SYNCQ_POSTREAD(M, P, SZ) do { } while (0) #endif /* * Macros to manipulate VPVCs */ #define MKVPVC(VPI,VCI) (((VPI) << 16) | (VCI)) #define GETVPI(VPVC) (((VPVC) >> 16) & 0xff) #define GETVCI(VPVC) ((VPVC) & 0xffff) /* * These macros encapsulate the bus_space functions for better readabiliy. */ #define WRITE4(SC, OFF, VAL) bus_space_write_4(SC->memt, SC->memh, OFF, VAL) #define WRITE1(SC, OFF, VAL) bus_space_write_1(SC->memt, SC->memh, OFF, VAL) #define READ4(SC, OFF) bus_space_read_4(SC->memt, SC->memh, OFF) #define READ1(SC, OFF) bus_space_read_1(SC->memt, SC->memh, OFF) #define BARRIER_R(SC) \ bus_space_barrier(SC->memt, SC->memh, 0, FATMO_END, \ BUS_SPACE_BARRIER_READ) #define BARRIER_W(SC) \ bus_space_barrier(SC->memt, SC->memh, 0, FATMO_END, \ BUS_SPACE_BARRIER_WRITE) #define BARRIER_RW(SC) \ bus_space_barrier(SC->memt, SC->memh, 0, FATMO_END, \ BUS_SPACE_BARRIER_WRITE|BUS_SPACE_BARRIER_READ) #ifdef FATM_DEBUG #define DBG(SC, FL, PRINT) do { \ if ((SC)->debug & DBG_##FL) { \ if_printf(&(SC)->ifatm.ifnet, "%s: ", __func__); \ printf PRINT; \ printf("\n"); \ } \ } while (0) #define DBGC(SC, FL, PRINT) do { \ if ((SC)->debug & DBG_##FL) \ printf PRINT; \ } while (0) enum { DBG_RCV = 0x0001, DBG_XMIT = 0x0002, DBG_VCC = 0x0004, DBG_IOCTL = 0x0008, DBG_ATTACH = 0x0010, DBG_INIT = 0x0020, DBG_DMA = 0x0040, DBG_BEAT = 0x0080, DBG_UART = 0x0100, DBG_LOCK = 0x0200, DBG_ALL = 0xffff }; #else #define DBG(SC, FL, PRINT) #define DBGC(SC, FL, PRINT) #endif /* * Configuration. * * This section contains tunable parameters and dependend defines. */ #define FATM_CMD_QLEN 16 /* command queue length */ #ifndef TEST_DMA_SYNC #define FATM_TX_QLEN 128 /* transmit queue length */ #define FATM_RX_QLEN 64 /* receive queue length */ #else #define FATM_TX_QLEN 8 /* transmit queue length */ #define FATM_RX_QLEN 8 /* receive queue length */ #endif #define SMALL_SUPPLY_QLEN 16 #define SMALL_POOL_SIZE 256 #define SMALL_SUPPLY_BLKSIZE 8 #define LARGE_SUPPLY_QLEN 16 #define LARGE_POOL_SIZE 128 #define LARGE_SUPPLY_BLKSIZE 8