Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/pccard/@/dev/hatm/ |
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/pccard/@/dev/hatm/if_hatmvar.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/hatm/if_hatmvar.h 147524 2005-06-22 06:42:03Z harti $ * * Fore HE driver for NATM */ /* * Debug statistics of the HE driver */ struct istats { uint32_t tdprq_full; uint32_t hbuf_error; uint32_t crc_error; uint32_t len_error; uint32_t flow_closed; uint32_t flow_drop; uint32_t tpd_no_mem; uint32_t rx_seg; uint32_t empty_hbuf; uint32_t short_aal5; uint32_t badlen_aal5; uint32_t bug_bad_isw; uint32_t bug_no_irq_upd; uint32_t itype_tbrq; uint32_t itype_tpd; uint32_t itype_rbps; uint32_t itype_rbpl; uint32_t itype_rbrq; uint32_t itype_rbrqt; uint32_t itype_unknown; uint32_t itype_phys; uint32_t itype_err; uint32_t defrag; uint32_t mcc; uint32_t oec; uint32_t dcc; uint32_t cec; uint32_t no_rcv_mbuf; }; /* Card memory layout parameters */ #define HE_CONFIG_MEM_LAYOUT { \ { /* 155 */ \ 20, /* cells_per_row */ \ 1024, /* bytes_per_row */ \ 512, /* r0_numrows */ \ 1018, /* tx_numrows */ \ 512, /* r1_numrows */ \ 6, /* r0_startrow */ \ 2 /* cells_per_lbuf */ \ }, { /* 622 */ \ 40, /* cells_per_row */ \ 2048, /* bytes_per_row */ \ 256, /* r0_numrows */ \ 512, /* tx_numrows */ \ 256, /* r1_numrows */ \ 0, /* r0_startrow */ \ 4 /* cells_per_lbuf */ \ } \ } /*********************************************************************/ struct hatm_softc; /* * A chunk of DMA-able memory */ struct dmamem { u_int size; /* in bytes */ u_int align; /* alignement */ bus_dma_tag_t tag; /* DMA tag */ void *base; /* the memory */ bus_addr_t paddr; /* physical address */ bus_dmamap_t map; /* the MAP */ }; /* * RBP (Receive Buffer Pool) queue entry and queue. */ struct herbp { u_int size; /* RBP number of entries (power of two) */ u_int thresh; /* interrupt treshold */ uint32_t bsize; /* buffer size in bytes */ u_int offset; /* free space at start for small bufs */ uint32_t mask; /* mask for index */ struct dmamem mem; /* the queue area */ struct he_rbpen *rbp; uint32_t head, tail; /* head and tail */ }; /* * RBRQ (Receive Buffer Return Queue) entry and queue. */ struct herbrq { u_int size; /* number of entries */ u_int thresh; /* interrupt threshold */ u_int tout; /* timeout value */ u_int pcnt; /* packet count threshold */ struct dmamem mem; /* memory */ struct he_rbrqen *rbrq; uint32_t head; /* driver end */ }; /* * TPDRQ (Transmit Packet Descriptor Ready Queue) entry and queue */ struct hetpdrq { u_int size; /* number of entries */ struct dmamem mem; /* memory */ struct he_tpdrqen *tpdrq; u_int head; /* head (copy of adapter) */ u_int tail; /* written back to adapter */ }; /* * TBRQ (Transmit Buffer Return Queue) entry and queue */ struct hetbrq { u_int size; /* number of entries */ u_int thresh; /* interrupt threshold */ struct dmamem mem; /* memory */ struct he_tbrqen *tbrq; u_int head; /* adapter end */ }; /*==================================================================*/ /* * TPDs are 32 byte and must be aligned on 64 byte boundaries. That means, * that half of the space is free. We use this space to plug in a link for * the list of free TPDs. Note, that the m_act member of the mbufs contain * a pointer to the dmamap. * * The maximum number of TDPs is the size of the common transmit packet * descriptor ready queue plus the sizes of the transmit buffer return queues * (currently only queue 0). We allocate and map these TPD when initializing * the card. We also allocate on DMA map for each TPD. Only the map in the * last TPD of a packets is used when a packet is transmitted. * This is signalled by having the mbuf member of this TPD non-zero and * pointing to the mbuf. */ #define HE_TPD_SIZE 64 struct tpd { struct he_tpd tpd; /* at beginning */ SLIST_ENTRY(tpd) link; /* free cid list link */ struct mbuf *mbuf; /* the buf chain */ bus_dmamap_t map; /* map */ uint32_t cid; /* CID */ uint16_t no; /* number of this tpd */ }; SLIST_HEAD(tpd_list, tpd); #define TPD_SET_USED(SC, I) do { \ (SC)->tpd_used[(I) / 8] |= (1 << ((I) % 8)); \ } while (0) #define TPD_CLR_USED(SC, I) do { \ (SC)->tpd_used[(I) / 8] &= ~(1 << ((I) % 8)); \ } while (0) #define TPD_TST_USED(SC, I) ((SC)->tpd_used[(I) / 8] & (1 << ((I) % 8))) #define TPD_ADDR(SC, I) ((struct tpd *)((char *)sc->tpds.base + \ (I) * HE_TPD_SIZE)) /*==================================================================*/ /* * External MBUFs. The card needs a lot of mbufs in the pools for high * performance. The problem with using mbufs directly is that we would need * a dmamap for each of the mbufs. This can exhaust iommu space on the sparc * and it eats also a lot of processing time. So we use external mbufs * for the small buffers and clusters for the large buffers. * For receive group 0 we use 5 ATM cells, for group 1 one (52 byte) ATM * cell. The mbuf storage is allocated pagewise and one dmamap is used per * page. * * The handle we give to the card for the small buffers is a word combined * of the page number and the number of the chunk in the page. This restricts * the number of chunks per page to 256 (8 bit) and the number of pages to * 65536 (16 bits). * * A chunk may be in one of three states: free, on the card and floating around * in the system. If it is free, it is on one of the two free lists and * start with a struct mbufx_free. Each page has a bitmap that tracks where * its chunks are. * * For large buffers we use mbuf clusters. Here we have two problems: we need * to track the buffers on the card (in the case we want to stop it) and * we need to map the 64bit mbuf address to a 26bit handle for 64-bit machines. * The card uses the buffers in the order we give it to the card. Therefor * we can use a private array holding pointers to the mbufs as a circular * queue for both tasks. This is done with the lbufs member of softc. The * handle for these buffer is the lbufs index ored with a flag. */ /* data space in each external mbuf */ #define MBUF0_SIZE (5 * 48) /* 240 */ #define MBUF1_SIZE (52) /* 1 raw cell */ /* size of the buffer. Must fit data, offset and header */ #define MBUF0_CHUNK 256 /* 16 free bytes */ #define MBUF1_CHUNK 96 /* 44 free bytes */ /* start of actual data in buffer */ #define MBUF0_OFFSET 0 #define MBUF1_OFFSET 16 #define MBUFL_OFFSET 16 /* two pointers for HARP */ #if PAGE_SIZE > 8192 #define MBUF_ALLOC_SIZE (8192) #else #define MBUF_ALLOC_SIZE (PAGE_SIZE) #endif /* each allocated page has one of these structures at its very end. */ struct mbuf_page_hdr { uint16_t nchunks; /* chunks on this page */ bus_dmamap_t map; /* the DMA MAP */ uint32_t phys; /* physical base address */ uint32_t hdroff; /* chunk header offset */ uint32_t chunksize; /* chunk size */ u_int pool; /* pool number */ }; struct mbuf_page { char storage[MBUF_ALLOC_SIZE - sizeof(struct mbuf_page_hdr)]; struct mbuf_page_hdr hdr; }; /* numbers per page */ #define MBUF0_PER_PAGE ((MBUF_ALLOC_SIZE - sizeof(struct mbuf_page_hdr)) / \ MBUF0_CHUNK) #define MBUF1_PER_PAGE ((MBUF_ALLOC_SIZE - sizeof(struct mbuf_page_hdr)) / \ MBUF1_CHUNK) /* * Convert to/from handles */ /* small buffers */ #define MBUF_MAKE_HANDLE(PAGENO, CHUNKNO) \ ((((PAGENO) << 10) | (CHUNKNO)) << HE_REGS_RBRQ_ADDR) #define MBUF_MAKE_LHANDLE(INDEX) \ (MBUF_LARGE_FLAG | ((INDEX) << HE_REGS_RBRQ_ADDR)) /* large buffers */ #define MBUF_PARSE_HANDLE(HANDLE, PAGENO, CHUNKNO) do { \ (CHUNKNO) = ((HANDLE) >> HE_REGS_RBRQ_ADDR) & 0x3ff; \ (PAGENO) = (((HANDLE) >> 10) >> HE_REGS_RBRQ_ADDR) & 0x3fff; \ } while (0) #define MBUF_PARSE_LHANDLE(HANDLE, INDEX) do { \ (INDEX) = ((HANDLE) >> HE_REGS_RBRQ_ADDR) & 0xffffff; \ } while (0) #define MBUF_LARGE_FLAG 0x80000000 /* chunks have the following structure at the end (8 byte) */ struct mbuf_chunk_hdr { uint16_t pageno; uint8_t chunkno; uint8_t flags; u_int ref_cnt; }; #define MBUF_CARD 0x01 /* buffer is on card */ #define MBUF_USED 0x02 /* buffer is somewhere in the system */ #define MBUFX_STORAGE_SIZE(X) (MBUF##X##_CHUNK \ - sizeof(struct mbuf_chunk_hdr)) struct mbuf0_chunk { char storage[MBUFX_STORAGE_SIZE(0)]; struct mbuf_chunk_hdr hdr; }; struct mbuf1_chunk { char storage[MBUFX_STORAGE_SIZE(1)]; struct mbuf_chunk_hdr hdr; }; struct mbufx_free { struct mbufx_free *link; }; /*==================================================================*/ /* * Interrupt queue */ struct heirq { u_int size; /* number of entries */ u_int thresh; /* re-interrupt threshold */ u_int line; /* interrupt line to use */ struct dmamem mem; /* interrupt queues */ uint32_t * irq; /* interrupt queue */ uint32_t head; /* head index */ uint32_t * tailp; /* pointer to tail */ struct hatm_softc *sc; /* back pointer */ u_int group; /* interrupt group */ }; /* * This structure describes all information for a VCC open on the card. * The array of these structures is indexed by the compressed connection ID * (CID). This structure must begin with the atmio_vcc. */ struct hevcc { struct atmio_vcc param; /* traffic parameters */ void * rxhand; /* NATM protocol block */ u_int vflags; /* private flags */ uint32_t ipackets; uint32_t opackets; uint32_t ibytes; uint32_t obytes; u_int rc; /* rate control group for CBR */ struct mbuf * chain; /* partial received PDU */ struct mbuf * last; /* last mbuf in chain */ u_int ntpds; /* number of active TPDs */ }; #define HE_VCC_OPEN 0x000f0000 #define HE_VCC_RX_OPEN 0x00010000 #define HE_VCC_RX_CLOSING 0x00020000 #define HE_VCC_TX_OPEN 0x00040000 #define HE_VCC_TX_CLOSING 0x00080000 #define HE_VCC_FLOW_CTRL 0x00100000 /* * CBR rate groups */ struct herg { u_int refcnt; /* how many connections reference this group */ u_int rate; /* the value */ }; /* * Softc */ struct hatm_softc { struct ifnet *ifp; struct mtx mtx; /* lock */ struct ifmedia media; /* media */ device_t dev; /* device */ int memid; /* resoure id for memory */ struct resource * memres; /* memory resource */ bus_space_handle_t memh; /* handle */ bus_space_tag_t memt; /* ... and tag */ bus_dma_tag_t parent_tag; /* global restriction */ struct cv vcc_cv; /* condition variable */ int irqid; /* resource id */ struct resource * irqres; /* resource */ void * ih; /* interrupt handle */ struct utopia utopia; /* utopia state */ /* rest has to be reset by stop */ int he622; /* this is a HE622 */ int pci64; /* 64bit bus */ char prod_id[HE_EEPROM_PROD_ID_LEN + 1]; char rev[HE_EEPROM_REV_LEN + 1]; struct heirq irq_0; /* interrupt queues 0 */ /* generic network controller state */ u_int cells_per_row; u_int bytes_per_row; u_int r0_numrows; u_int tx_numrows; u_int r1_numrows; u_int r0_startrow; u_int tx_startrow; u_int r1_startrow; u_int cells_per_lbuf; u_int r0_numbuffs; u_int r1_numbuffs; u_int tx_numbuffs; /* HSP */ struct he_hsp *hsp; struct dmamem hsp_mem; /*** TX ***/ struct hetbrq tbrq; /* TBRQ 0 */ struct hetpdrq tpdrq; /* TPDRQ */ struct tpd_list tpd_free; /* Free TPDs */ u_int tpd_nfree; /* number of free TPDs */ u_int tpd_total; /* total TPDs */ uint8_t *tpd_used; /* bitmap of used TPDs */ struct dmamem tpds; /* TPD memory */ bus_dma_tag_t tx_tag; /* DMA tag for all tx mbufs */ /*** RX ***/ /* receive/transmit groups */ struct herbp rbp_s0; /* RBPS0 */ struct herbp rbp_l0; /* RBPL0 */ struct herbp rbp_s1; /* RBPS1 */ struct herbrq rbrq_0; /* RBRQ0 */ struct herbrq rbrq_1; /* RBRQ1 */ /* list of external mbuf storage */ bus_dma_tag_t mbuf_tag; struct mbuf_page **mbuf_pages; u_int mbuf_npages; u_int mbuf_max_pages; struct mbufx_free *mbuf_list[2]; /* mbuf cluster tracking and mapping for group 0 */ struct mbuf **lbufs; /* mbufs */ bus_dmamap_t *rmaps; /* DMA maps */ u_int lbufs_size; u_int lbufs_next; /* VCCs */ struct hevcc *vccs[HE_MAX_VCCS]; u_int cbr_bw; /* BW allocated to CBR */ u_int max_tpd; /* per VCC */ u_int open_vccs; uma_zone_t vcc_zone; /* rate groups */ struct herg rate_ctrl[HE_REGN_CS_STPER]; /* memory offsets */ u_int tsrb, tsrc, tsrd; u_int rsrb; struct cv cv_rcclose; /* condition variable */ uint32_t rate_grid[16][16]; /* our copy */ /* sysctl support */ struct sysctl_ctx_list sysctl_ctx; struct sysctl_oid *sysctl_tree; /* internal statistics */ struct istats istats; u_int mpsafe; #ifdef HATM_DEBUG /* debugging */ u_int debug; /* transmit mbuf count */ int txmbuf; #endif }; #define READ4(SC,OFF) bus_space_read_4(SC->memt, SC->memh, (OFF)) #define READ2(SC,OFF) bus_space_read_2(SC->memt, SC->memh, (OFF)) #define READ1(SC,OFF) bus_space_read_1(SC->memt, SC->memh, (OFF)) #define WRITE4(SC,OFF,VAL) bus_space_write_4(SC->memt, SC->memh, (OFF), (VAL)) #define WRITE2(SC,OFF,VAL) bus_space_write_2(SC->memt, SC->memh, (OFF), (VAL)) #define WRITE1(SC,OFF,VAL) bus_space_write_1(SC->memt, SC->memh, (OFF), (VAL)) #define BARRIER_R(SC) bus_space_barrier(SC->memt, SC->memh, 0, HE_REGO_END, \ BUS_SPACE_BARRIER_READ) #define BARRIER_W(SC) bus_space_barrier(SC->memt, SC->memh, 0, HE_REGO_END, \ BUS_SPACE_BARRIER_WRITE) #define BARRIER_RW(SC) bus_space_barrier(SC->memt, SC->memh, 0, HE_REGO_END, \ BUS_SPACE_BARRIER_READ | BUS_SPACE_BARRIER_WRITE) #define READ_SUNI(SC,OFF) READ4(SC, HE_REGO_SUNI + 4 * (OFF)) #define WRITE_SUNI(SC,OFF,VAL) WRITE4(SC, HE_REGO_SUNI + 4 * (OFF), (VAL)) #define READ_LB4(SC,OFF) \ ({ \ WRITE4(SC, HE_REGO_LB_MEM_ADDR, (OFF)); \ WRITE4(SC, HE_REGO_LB_MEM_ACCESS, \ (HE_REGM_LB_MEM_HNDSHK | HE_REGM_LB_MEM_READ)); \ while((READ4(SC, HE_REGO_LB_MEM_ACCESS) & HE_REGM_LB_MEM_HNDSHK))\ ; \ READ4(SC, HE_REGO_LB_MEM_DATA); \ }) #define WRITE_LB4(SC,OFF,VAL) \ do { \ WRITE4(SC, HE_REGO_LB_MEM_ADDR, (OFF)); \ WRITE4(SC, HE_REGO_LB_MEM_DATA, (VAL)); \ WRITE4(SC, HE_REGO_LB_MEM_ACCESS, \ (HE_REGM_LB_MEM_HNDSHK | HE_REGM_LB_MEM_WRITE)); \ while((READ4(SC, HE_REGO_LB_MEM_ACCESS) & HE_REGM_LB_MEM_HNDSHK))\ ; \ } while(0) #define WRITE_MEM4(SC,OFF,VAL,SPACE) \ do { \ WRITE4(SC, HE_REGO_CON_DAT, (VAL)); \ WRITE4(SC, HE_REGO_CON_CTL, \ (SPACE | HE_REGM_CON_WE | HE_REGM_CON_STATUS | (OFF))); \ while((READ4(SC, HE_REGO_CON_CTL) & HE_REGM_CON_STATUS) != 0) \ ; \ } while(0) #define READ_MEM4(SC,OFF,SPACE) \ ({ \ WRITE4(SC, HE_REGO_CON_CTL, \ (SPACE | HE_REGM_CON_STATUS | (OFF))); \ while((READ4(SC, HE_REGO_CON_CTL) & HE_REGM_CON_STATUS) != 0) \ ; \ READ4(SC, HE_REGO_CON_DAT); \ }) #define WRITE_TCM4(SC,OFF,VAL) WRITE_MEM4(SC,(OFF),(VAL),HE_REGM_CON_TCM) #define WRITE_RCM4(SC,OFF,VAL) WRITE_MEM4(SC,(OFF),(VAL),HE_REGM_CON_RCM) #define WRITE_MBOX4(SC,OFF,VAL) WRITE_MEM4(SC,(OFF),(VAL),HE_REGM_CON_MBOX) #define READ_TCM4(SC,OFF) READ_MEM4(SC,(OFF),HE_REGM_CON_TCM) #define READ_RCM4(SC,OFF) READ_MEM4(SC,(OFF),HE_REGM_CON_RCM) #define READ_MBOX4(SC,OFF) READ_MEM4(SC,(OFF),HE_REGM_CON_MBOX) #define WRITE_TCM(SC,OFF,BYTES,VAL) \ WRITE_MEM4(SC,(OFF) | ((~(BYTES) & 0xf) << HE_REGS_CON_DIS), \ (VAL), HE_REGM_CON_TCM) #define WRITE_RCM(SC,OFF,BYTES,VAL) \ WRITE_MEM4(SC,(OFF) | ((~(BYTES) & 0xf) << HE_REGS_CON_DIS), \ (VAL), HE_REGM_CON_RCM) #define READ_TSR(SC,CID,NR) \ ({ \ uint32_t _v; \ if((NR) <= 7) { \ _v = READ_TCM4(SC, HE_REGO_TSRA(0,CID,NR)); \ } else if((NR) <= 11) { \ _v = READ_TCM4(SC, HE_REGO_TSRB((SC)->tsrb,CID,(NR-8)));\ } else if((NR) <= 13) { \ _v = READ_TCM4(SC, HE_REGO_TSRC((SC)->tsrc,CID,(NR-12)));\ } else { \ _v = READ_TCM4(SC, HE_REGO_TSRD((SC)->tsrd,CID)); \ } \ _v; \ }) #define WRITE_TSR(SC,CID,NR,BEN,VAL) \ do { \ if((NR) <= 7) { \ WRITE_TCM(SC, HE_REGO_TSRA(0,CID,NR),BEN,VAL); \ } else if((NR) <= 11) { \ WRITE_TCM(SC, HE_REGO_TSRB((SC)->tsrb,CID,(NR-8)),BEN,VAL);\ } else if((NR) <= 13) { \ WRITE_TCM(SC, HE_REGO_TSRC((SC)->tsrc,CID,(NR-12)),BEN,VAL);\ } else { \ WRITE_TCM(SC, HE_REGO_TSRD((SC)->tsrd,CID),BEN,VAL); \ } \ } while(0) #define READ_RSR(SC,CID,NR) \ ({ \ uint32_t _v; \ if((NR) <= 7) { \ _v = READ_RCM4(SC, HE_REGO_RSRA(0,CID,NR)); \ } else { \ _v = READ_RCM4(SC, HE_REGO_RSRB((SC)->rsrb,CID,(NR-8)));\ } \ _v; \ }) #define WRITE_RSR(SC,CID,NR,BEN,VAL) \ do { \ if((NR) <= 7) { \ WRITE_RCM(SC, HE_REGO_RSRA(0,CID,NR),BEN,VAL); \ } else { \ WRITE_RCM(SC, HE_REGO_RSRB((SC)->rsrb,CID,(NR-8)),BEN,VAL);\ } \ } while(0) #ifdef HATM_DEBUG #define DBG(SC, FL, PRINT) do { \ if((SC)->debug & DBG_##FL) { \ if_printf((SC)->ifp, "%s: ", __func__); \ printf PRINT; \ printf("\n"); \ } \ } while (0) enum { DBG_DUMMY = 0x0001, /* default value for -DHATM_DEBUG */ DBG_RX = 0x0002, DBG_TX = 0x0004, DBG_VCC = 0x0008, DBG_IOCTL = 0x0010, DBG_ATTACH = 0x0020, DBG_INTR = 0x0040, DBG_DMA = 0x0080, DBG_DMAH = 0x0100, DBG_DUMP = 0x0200, DBG_ALL = 0x03ff }; #else #define DBG(SC, FL, PRINT) #endif u_int hatm_cps2atmf(uint32_t); u_int hatm_atmf2cps(uint32_t); void hatm_intr(void *); int hatm_ioctl(struct ifnet *, u_long, caddr_t); void hatm_initialize(struct hatm_softc *); void hatm_stop(struct hatm_softc *sc); void hatm_start(struct ifnet *); void hatm_rx(struct hatm_softc *sc, u_int cid, u_int flags, struct mbuf *m, u_int len); void hatm_tx_complete(struct hatm_softc *sc, struct tpd *tpd, uint32_t); int hatm_tx_vcc_can_open(struct hatm_softc *sc, u_int cid, struct hevcc *); void hatm_tx_vcc_open(struct hatm_softc *sc, u_int cid); void hatm_rx_vcc_open(struct hatm_softc *sc, u_int cid); void hatm_tx_vcc_close(struct hatm_softc *sc, u_int cid); void hatm_rx_vcc_close(struct hatm_softc *sc, u_int cid); void hatm_tx_vcc_closed(struct hatm_softc *sc, u_int cid); void hatm_vcc_closed(struct hatm_softc *sc, u_int cid); void hatm_load_vc(struct hatm_softc *sc, u_int cid, int reopen); void hatm_ext_free(struct mbufx_free **, struct mbufx_free *);