The Design and Implementation of the FreeBSD Operating System, Second Edition
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FreeBSD/Linux Kernel Cross Reference
sys/dev/advansys/advlib.c

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    1 /*-
    2  * Low level routines for the Advanced Systems Inc. SCSI controllers chips
    3  *
    4  * Copyright (c) 1996-1997, 1999-2000 Justin Gibbs.
    5  * All rights reserved.
    6  *
    7  * Redistribution and use in source and binary forms, with or without
    8  * modification, are permitted provided that the following conditions
    9  * are met:
   10  * 1. Redistributions of source code must retain the above copyright
   11  *    notice, this list of conditions, and the following disclaimer,
   12  *    without modification, immediately at the beginning of the file.
   13  * 2. Redistributions in binary form must reproduce the above copyright
   14  *    notice, this list of conditions and the following disclaimer in the
   15  *    documentation and/or other materials provided with the distribution.
   16  * 3. The name of the author may not be used to endorse or promote products
   17  *    derived from this software without specific prior written permission.
   18  *
   19  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
   20  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
   21  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
   22  * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE FOR
   23  * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
   24  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
   25  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
   26  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
   27  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
   28  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
   29  * SUCH DAMAGE.
   30  */
   31 /*-
   32  * Ported from:
   33  * advansys.c - Linux Host Driver for AdvanSys SCSI Adapters
   34  *     
   35  * Copyright (c) 1995-1996 Advanced System Products, Inc.
   36  * All Rights Reserved.
   37  *   
   38  * Redistribution and use in source and binary forms, with or without
   39  * modification, are permitted provided that redistributions of source
   40  * code retain the above copyright notice and this comment without
   41  * modification.
   42  */
   43 
   44 #include <sys/cdefs.h>
   45 __FBSDID("$FreeBSD: releng/6.1/sys/dev/advansys/advlib.c 146734 2005-05-29 04:42:30Z nyan $");
   46 
   47 #include <sys/param.h>
   48 #include <sys/kernel.h>
   49 #include <sys/systm.h>
   50 
   51 #include <machine/bus.h>
   52 #include <machine/resource.h>
   53 #include <sys/bus.h> 
   54 #include <sys/rman.h> 
   55 
   56 #include <cam/cam.h>
   57 #include <cam/cam_ccb.h>
   58 #include <cam/cam_sim.h>
   59 #include <cam/cam_xpt_sim.h>
   60 
   61 #include <cam/scsi/scsi_all.h>
   62 #include <cam/scsi/scsi_message.h>
   63 #include <cam/scsi/scsi_da.h>
   64 #include <cam/scsi/scsi_cd.h>
   65 
   66 #include <vm/vm.h>
   67 #include <vm/vm_param.h>
   68 #include <vm/pmap.h>
   69 
   70 #include <dev/advansys/advansys.h>
   71 #include <dev/advansys/advmcode.h>
   72 
   73 struct adv_quirk_entry {
   74         struct scsi_inquiry_pattern inq_pat;
   75         u_int8_t quirks;
   76 #define ADV_QUIRK_FIX_ASYN_XFER_ALWAYS  0x01
   77 #define ADV_QUIRK_FIX_ASYN_XFER         0x02
   78 };
   79 
   80 static struct adv_quirk_entry adv_quirk_table[] =
   81 {
   82         {
   83                 { T_CDROM, SIP_MEDIA_REMOVABLE, "HP", "*", "*" },
   84                 ADV_QUIRK_FIX_ASYN_XFER_ALWAYS|ADV_QUIRK_FIX_ASYN_XFER
   85         },
   86         {
   87                 { T_CDROM, SIP_MEDIA_REMOVABLE, "NEC", "CD-ROM DRIVE", "*" },
   88                 0
   89         },
   90         {
   91                 {
   92                   T_SEQUENTIAL, SIP_MEDIA_REMOVABLE,
   93                   "TANDBERG", " TDC 36", "*"
   94                 },
   95                 0
   96         },
   97         {
   98                 { T_SEQUENTIAL, SIP_MEDIA_REMOVABLE, "WANGTEK", "*", "*" },
   99                 0
  100         },
  101         {
  102                 {
  103                   T_PROCESSOR, SIP_MEDIA_REMOVABLE|SIP_MEDIA_FIXED,
  104                   "*", "*", "*"
  105                 },
  106                 0
  107         },
  108         {
  109                 {
  110                   T_SCANNER, SIP_MEDIA_REMOVABLE|SIP_MEDIA_FIXED,
  111                   "*", "*", "*"
  112                 },
  113                 0
  114         },
  115         {
  116                 /* Default quirk entry */
  117                 {
  118                   T_ANY, SIP_MEDIA_REMOVABLE|SIP_MEDIA_FIXED,
  119                   /*vendor*/"*", /*product*/"*", /*revision*/"*"
  120                 }, 
  121                 ADV_QUIRK_FIX_ASYN_XFER,
  122         }
  123 };
  124 
  125 /*
  126  * Allowable periods in ns
  127  */
  128 static u_int8_t adv_sdtr_period_tbl[] =
  129 {
  130         25,
  131         30,
  132         35,
  133         40,
  134         50,
  135         60,
  136         70,
  137         85
  138 };
  139 
  140 static u_int8_t adv_sdtr_period_tbl_ultra[] =
  141 {
  142         12,
  143         19,
  144         25,
  145         32,
  146         38,
  147         44,
  148         50,
  149         57,
  150         63,
  151         69,
  152         75,
  153         82,
  154         88, 
  155         94,
  156         100,
  157         107
  158 };
  159 
  160 struct ext_msg {
  161         u_int8_t msg_type;
  162         u_int8_t msg_len;
  163         u_int8_t msg_req;
  164         union {
  165                 struct {
  166                         u_int8_t sdtr_xfer_period;
  167                         u_int8_t sdtr_req_ack_offset;
  168                 } sdtr;
  169                 struct {
  170                         u_int8_t wdtr_width;
  171                 } wdtr;
  172                 struct {
  173                         u_int8_t mdp[4];
  174                 } mdp;
  175         } u_ext_msg;
  176         u_int8_t res;
  177 };
  178 
  179 #define xfer_period     u_ext_msg.sdtr.sdtr_xfer_period
  180 #define req_ack_offset  u_ext_msg.sdtr.sdtr_req_ack_offset
  181 #define wdtr_width      u_ext_msg.wdtr.wdtr_width
  182 #define mdp_b3          u_ext_msg.mdp_b3
  183 #define mdp_b2          u_ext_msg.mdp_b2
  184 #define mdp_b1          u_ext_msg.mdp_b1
  185 #define mdp_b0          u_ext_msg.mdp_b0
  186 
  187 /*
  188  * Some of the early PCI adapters have problems with
  189  * async transfers.  Instead use an offset of 1.
  190  */
  191 #define ASYN_SDTR_DATA_FIX_PCI_REV_AB 0x41
  192 
  193 /* LRAM routines */
  194 static void      adv_read_lram_16_multi(struct adv_softc *adv, u_int16_t s_addr,
  195                                         u_int16_t *buffer, int count);
  196 static void      adv_write_lram_16_multi(struct adv_softc *adv,
  197                                          u_int16_t s_addr, u_int16_t *buffer,
  198                                          int count);
  199 static void      adv_mset_lram_16(struct adv_softc *adv, u_int16_t s_addr,
  200                                   u_int16_t set_value, int count);
  201 static u_int32_t adv_msum_lram_16(struct adv_softc *adv, u_int16_t s_addr,
  202                                   int count);
  203 
  204 static int       adv_write_and_verify_lram_16(struct adv_softc *adv,
  205                                               u_int16_t addr, u_int16_t value);
  206 static u_int32_t adv_read_lram_32(struct adv_softc *adv, u_int16_t addr);
  207 
  208 
  209 static void      adv_write_lram_32(struct adv_softc *adv, u_int16_t addr,
  210                                    u_int32_t value);
  211 static void      adv_write_lram_32_multi(struct adv_softc *adv,
  212                                          u_int16_t s_addr, u_int32_t *buffer,
  213                                          int count);
  214 
  215 /* EEPROM routines */
  216 static u_int16_t adv_read_eeprom_16(struct adv_softc *adv, u_int8_t addr);
  217 static u_int16_t adv_write_eeprom_16(struct adv_softc *adv, u_int8_t addr,
  218                                      u_int16_t value);
  219 static int       adv_write_eeprom_cmd_reg(struct adv_softc *adv,
  220                                           u_int8_t cmd_reg);
  221 static int       adv_set_eeprom_config_once(struct adv_softc *adv,
  222                                             struct adv_eeprom_config *eeconfig);
  223 
  224 /* Initialization */
  225 static u_int32_t adv_load_microcode(struct adv_softc *adv, u_int16_t s_addr,
  226                                     u_int16_t *mcode_buf, u_int16_t mcode_size);
  227 
  228 static void      adv_reinit_lram(struct adv_softc *adv);
  229 static void      adv_init_lram(struct adv_softc *adv);
  230 static int       adv_init_microcode_var(struct adv_softc *adv);
  231 static void      adv_init_qlink_var(struct adv_softc *adv);
  232 
  233 /* Interrupts */
  234 static void      adv_disable_interrupt(struct adv_softc *adv);
  235 static void      adv_enable_interrupt(struct adv_softc *adv);
  236 static void      adv_toggle_irq_act(struct adv_softc *adv);
  237 
  238 /* Chip Control */
  239 static int       adv_host_req_chip_halt(struct adv_softc *adv);
  240 static void      adv_set_chip_ih(struct adv_softc *adv, u_int16_t ins_code);
  241 #if UNUSED
  242 static u_int8_t  adv_get_chip_scsi_ctrl(struct adv_softc *adv);
  243 #endif
  244 
  245 /* Queue handling and execution */
  246 static __inline int
  247                  adv_sgcount_to_qcount(int sgcount);
  248 
  249 static __inline int
  250 adv_sgcount_to_qcount(int sgcount)
  251 {
  252         int     n_sg_list_qs;
  253 
  254         n_sg_list_qs = ((sgcount - 1) / ADV_SG_LIST_PER_Q);
  255         if (((sgcount - 1) % ADV_SG_LIST_PER_Q) != 0)
  256                 n_sg_list_qs++;
  257         return (n_sg_list_qs + 1);
  258 }
  259 
  260 #if BYTE_ORDER == BIG_ENDIAN
  261 static void      adv_adj_endian_qdone_info(struct adv_q_done_info *);
  262 static void      adv_adj_scsiq_endian(struct adv_scsi_q *);
  263 #endif
  264 static void      adv_get_q_info(struct adv_softc *adv, u_int16_t s_addr,
  265                                 u_int16_t *inbuf, int words);
  266 static u_int     adv_get_num_free_queues(struct adv_softc *adv, u_int8_t n_qs);
  267 static u_int8_t  adv_alloc_free_queues(struct adv_softc *adv,
  268                                        u_int8_t free_q_head, u_int8_t n_free_q);
  269 static u_int8_t  adv_alloc_free_queue(struct adv_softc *adv,
  270                                       u_int8_t free_q_head);
  271 static int       adv_send_scsi_queue(struct adv_softc *adv,
  272                                      struct adv_scsi_q *scsiq,
  273                                      u_int8_t n_q_required);
  274 static void      adv_put_ready_sg_list_queue(struct adv_softc *adv,
  275                                              struct adv_scsi_q *scsiq,
  276                                              u_int q_no);
  277 static void      adv_put_ready_queue(struct adv_softc *adv,
  278                                      struct adv_scsi_q *scsiq, u_int q_no);
  279 static void      adv_put_scsiq(struct adv_softc *adv, u_int16_t s_addr,
  280                                u_int16_t *buffer, int words);
  281 
  282 /* Messages */
  283 static void      adv_handle_extmsg_in(struct adv_softc *adv,
  284                                       u_int16_t halt_q_addr, u_int8_t q_cntl,
  285                                       target_bit_vector target_id,
  286                                       int tid);
  287 static void      adv_msgout_sdtr(struct adv_softc *adv, u_int8_t sdtr_period,
  288                                  u_int8_t sdtr_offset);
  289 static void      adv_set_sdtr_reg_at_id(struct adv_softc *adv, int id,
  290                                         u_int8_t sdtr_data);
  291 
  292 
  293 /* Exported functions first */
  294 
  295 void
  296 advasync(void *callback_arg, u_int32_t code, struct cam_path *path, void *arg)
  297 {
  298         struct adv_softc *adv;
  299 
  300         adv = (struct adv_softc *)callback_arg;
  301         switch (code) {
  302         case AC_FOUND_DEVICE:
  303         {
  304                 struct ccb_getdev *cgd;
  305                 target_bit_vector target_mask;
  306                 int num_entries;
  307                 caddr_t match;
  308                 struct adv_quirk_entry *entry;
  309                 struct adv_target_transinfo* tinfo;
  310  
  311                 cgd = (struct ccb_getdev *)arg;
  312 
  313                 target_mask = ADV_TID_TO_TARGET_MASK(cgd->ccb_h.target_id);
  314 
  315                 num_entries = sizeof(adv_quirk_table)/sizeof(*adv_quirk_table);
  316                 match = cam_quirkmatch((caddr_t)&cgd->inq_data,
  317                                        (caddr_t)adv_quirk_table,
  318                                        num_entries, sizeof(*adv_quirk_table),
  319                                        scsi_inquiry_match);
  320         
  321                 if (match == NULL)
  322                         panic("advasync: device didn't match wildcard entry!!");
  323 
  324                 entry = (struct adv_quirk_entry *)match;
  325 
  326                 if (adv->bug_fix_control & ADV_BUG_FIX_ASYN_USE_SYN) {
  327                         if ((entry->quirks & ADV_QUIRK_FIX_ASYN_XFER_ALWAYS)!=0)
  328                                 adv->fix_asyn_xfer_always |= target_mask;
  329                         else
  330                                 adv->fix_asyn_xfer_always &= ~target_mask;
  331                         /*
  332                          * We start out life with all bits set and clear them
  333                          * after we've determined that the fix isn't necessary.
  334                          * It may well be that we've already cleared a target
  335                          * before the full inquiry session completes, so don't
  336                          * gratuitously set a target bit even if it has this
  337                          * quirk.  But, if the quirk exonerates a device, clear
  338                          * the bit now.
  339                          */
  340                         if ((entry->quirks & ADV_QUIRK_FIX_ASYN_XFER) == 0)
  341                                 adv->fix_asyn_xfer &= ~target_mask;
  342                 }
  343                 /*
  344                  * Reset our sync settings now that we've determined
  345                  * what quirks are in effect for the device.
  346                  */
  347                 tinfo = &adv->tinfo[cgd->ccb_h.target_id];
  348                 adv_set_syncrate(adv, cgd->ccb_h.path,
  349                                  cgd->ccb_h.target_id,
  350                                  tinfo->current.period,
  351                                  tinfo->current.offset,
  352                                  ADV_TRANS_CUR);
  353                 break;
  354         }
  355         case AC_LOST_DEVICE:
  356         {
  357                 u_int target_mask;
  358 
  359                 if (adv->bug_fix_control & ADV_BUG_FIX_ASYN_USE_SYN) {
  360                         target_mask = 0x01 << xpt_path_target_id(path);
  361                         adv->fix_asyn_xfer |= target_mask;
  362                 }
  363 
  364                 /*
  365                  * Revert to async transfers
  366                  * for the next device.
  367                  */
  368                 adv_set_syncrate(adv, /*path*/NULL,
  369                                  xpt_path_target_id(path),
  370                                  /*period*/0,
  371                                  /*offset*/0,
  372                                  ADV_TRANS_GOAL|ADV_TRANS_CUR);
  373         }
  374         default:
  375                 break;
  376         }
  377 }
  378 
  379 void
  380 adv_set_bank(struct adv_softc *adv, u_int8_t bank)
  381 {
  382         u_int8_t control;
  383 
  384         /*
  385          * Start out with the bank reset to 0
  386          */
  387         control = ADV_INB(adv, ADV_CHIP_CTRL)
  388                   &  (~(ADV_CC_SINGLE_STEP | ADV_CC_TEST
  389                         | ADV_CC_DIAG | ADV_CC_SCSI_RESET
  390                         | ADV_CC_CHIP_RESET | ADV_CC_BANK_ONE));
  391         if (bank == 1) {
  392                 control |= ADV_CC_BANK_ONE;
  393         } else if (bank == 2) {
  394                 control |= ADV_CC_DIAG | ADV_CC_BANK_ONE;
  395         }
  396         ADV_OUTB(adv, ADV_CHIP_CTRL, control);
  397 }
  398 
  399 u_int8_t
  400 adv_read_lram_8(struct adv_softc *adv, u_int16_t addr)
  401 {
  402         u_int8_t   byte_data;
  403         u_int16_t  word_data;
  404 
  405         /*
  406          * LRAM is accessed on 16bit boundaries.
  407          */
  408         ADV_OUTW(adv, ADV_LRAM_ADDR, addr & 0xFFFE);
  409         word_data = ADV_INW(adv, ADV_LRAM_DATA);
  410         if (addr & 1) {
  411 #if BYTE_ORDER == BIG_ENDIAN
  412                 byte_data = (u_int8_t)(word_data & 0xFF);
  413 #else
  414                 byte_data = (u_int8_t)((word_data >> 8) & 0xFF);
  415 #endif
  416         } else {
  417 #if BYTE_ORDER == BIG_ENDIAN
  418                 byte_data = (u_int8_t)((word_data >> 8) & 0xFF);
  419 #else           
  420                 byte_data = (u_int8_t)(word_data & 0xFF);
  421 #endif
  422         }
  423         return (byte_data);
  424 }
  425 
  426 void
  427 adv_write_lram_8(struct adv_softc *adv, u_int16_t addr, u_int8_t value)
  428 {
  429         u_int16_t word_data;
  430 
  431         word_data = adv_read_lram_16(adv, addr & 0xFFFE);
  432         if (addr & 1) {
  433                 word_data &= 0x00FF;
  434                 word_data |= (((u_int8_t)value << 8) & 0xFF00);
  435         } else {
  436                 word_data &= 0xFF00;
  437                 word_data |= ((u_int8_t)value & 0x00FF);
  438         }
  439         adv_write_lram_16(adv, addr & 0xFFFE, word_data);
  440 }
  441 
  442 
  443 u_int16_t
  444 adv_read_lram_16(struct adv_softc *adv, u_int16_t addr)
  445 {
  446         ADV_OUTW(adv, ADV_LRAM_ADDR, addr);
  447         return (ADV_INW(adv, ADV_LRAM_DATA));
  448 }
  449 
  450 void
  451 adv_write_lram_16(struct adv_softc *adv, u_int16_t addr, u_int16_t value)
  452 {
  453         ADV_OUTW(adv, ADV_LRAM_ADDR, addr);
  454         ADV_OUTW(adv, ADV_LRAM_DATA, value);
  455 }
  456 
  457 /*
  458  * Determine if there is a board at "iobase" by looking
  459  * for the AdvanSys signatures.  Return 1 if a board is
  460  * found, 0 otherwise.
  461  */
  462 int                         
  463 adv_find_signature(bus_space_tag_t tag, bus_space_handle_t bsh)
  464 {                            
  465         u_int16_t signature;
  466 
  467         if (bus_space_read_1(tag, bsh, ADV_SIGNATURE_BYTE) == ADV_1000_ID1B) {
  468                 signature = bus_space_read_2(tag, bsh, ADV_SIGNATURE_WORD);
  469                 if ((signature == ADV_1000_ID0W)
  470                  || (signature == ADV_1000_ID0W_FIX))
  471                         return (1);
  472         }
  473         return (0);
  474 }
  475 
  476 void
  477 adv_lib_init(struct adv_softc *adv)
  478 {
  479         if ((adv->type & ADV_ULTRA) != 0) {
  480                 adv->sdtr_period_tbl = adv_sdtr_period_tbl_ultra;
  481                 adv->sdtr_period_tbl_size = sizeof(adv_sdtr_period_tbl_ultra);
  482         } else {
  483                 adv->sdtr_period_tbl = adv_sdtr_period_tbl;
  484                 adv->sdtr_period_tbl_size = sizeof(adv_sdtr_period_tbl);                
  485         }
  486 }
  487 
  488 u_int16_t
  489 adv_get_eeprom_config(struct adv_softc *adv, struct
  490                       adv_eeprom_config  *eeprom_config)
  491 {
  492         u_int16_t       sum;
  493         u_int16_t       *wbuf;
  494         u_int8_t        cfg_beg;
  495         u_int8_t        cfg_end;
  496         u_int8_t        s_addr;
  497 
  498         wbuf = (u_int16_t *)eeprom_config;
  499         sum = 0;
  500 
  501         for (s_addr = 0; s_addr < 2; s_addr++, wbuf++) {
  502                 *wbuf = adv_read_eeprom_16(adv, s_addr);
  503                 sum += *wbuf;
  504         }
  505 
  506         if (adv->type & ADV_VL) {
  507                 cfg_beg = ADV_EEPROM_CFG_BEG_VL;
  508                 cfg_end = ADV_EEPROM_MAX_ADDR_VL;
  509         } else {
  510                 cfg_beg = ADV_EEPROM_CFG_BEG;
  511                 cfg_end = ADV_EEPROM_MAX_ADDR;
  512         }
  513 
  514         for (s_addr = cfg_beg; s_addr <= (cfg_end - 1); s_addr++, wbuf++) {
  515                 *wbuf = adv_read_eeprom_16(adv, s_addr);
  516                 sum += *wbuf;
  517 #if ADV_DEBUG_EEPROM
  518                 printf("Addr 0x%x: 0x%04x\n", s_addr, *wbuf);
  519 #endif
  520         }
  521         *wbuf = adv_read_eeprom_16(adv, s_addr);
  522         return (sum);
  523 }
  524 
  525 int
  526 adv_set_eeprom_config(struct adv_softc *adv,
  527                       struct adv_eeprom_config *eeprom_config)
  528 {
  529         int     retry;
  530 
  531         retry = 0;
  532         while (1) {
  533                 if (adv_set_eeprom_config_once(adv, eeprom_config) == 0) {
  534                         break;
  535                 }
  536                 if (++retry > ADV_EEPROM_MAX_RETRY) {
  537                         break;
  538                 }
  539         }
  540         return (retry > ADV_EEPROM_MAX_RETRY);
  541 }
  542 
  543 int
  544 adv_reset_chip(struct adv_softc *adv, int reset_bus)
  545 {
  546         adv_stop_chip(adv);
  547         ADV_OUTB(adv, ADV_CHIP_CTRL, ADV_CC_CHIP_RESET | ADV_CC_HALT
  548                                      | (reset_bus ? ADV_CC_SCSI_RESET : 0));
  549         DELAY(60);
  550 
  551         adv_set_chip_ih(adv, ADV_INS_RFLAG_WTM);
  552         adv_set_chip_ih(adv, ADV_INS_HALT);
  553 
  554         if (reset_bus)
  555                 ADV_OUTB(adv, ADV_CHIP_CTRL, ADV_CC_CHIP_RESET | ADV_CC_HALT);
  556 
  557         ADV_OUTB(adv, ADV_CHIP_CTRL, ADV_CC_HALT);
  558         if (reset_bus)
  559                 DELAY(200 * 1000);
  560 
  561         ADV_OUTW(adv, ADV_CHIP_STATUS, ADV_CIW_CLR_SCSI_RESET_INT);
  562         ADV_OUTW(adv, ADV_CHIP_STATUS, 0);
  563         return (adv_is_chip_halted(adv));
  564 }
  565 
  566 int
  567 adv_test_external_lram(struct adv_softc* adv)
  568 {
  569         u_int16_t       q_addr;
  570         u_int16_t       saved_value;
  571         int             success;
  572 
  573         success = 0;
  574 
  575         q_addr = ADV_QNO_TO_QADDR(241);
  576         saved_value = adv_read_lram_16(adv, q_addr);
  577         if (adv_write_and_verify_lram_16(adv, q_addr, 0x55AA) == 0) {
  578                 success = 1;
  579                 adv_write_lram_16(adv, q_addr, saved_value);
  580         }
  581         return (success);
  582 }
  583 
  584 
  585 int
  586 adv_init_lram_and_mcode(struct adv_softc *adv)
  587 {
  588         u_int32_t       retval;
  589 
  590         adv_disable_interrupt(adv);
  591 
  592         adv_init_lram(adv);
  593 
  594         retval = adv_load_microcode(adv, 0, (u_int16_t *)adv_mcode,
  595                                     adv_mcode_size);
  596         if (retval != adv_mcode_chksum) {
  597                 printf("adv%d: Microcode download failed checksum!\n",
  598                        adv->unit);
  599                 return (1);
  600         }
  601         
  602         if (adv_init_microcode_var(adv) != 0)
  603                 return (1);
  604 
  605         adv_enable_interrupt(adv);
  606         return (0);
  607 }
  608 
  609 u_int8_t
  610 adv_get_chip_irq(struct adv_softc *adv)
  611 {
  612         u_int16_t       cfg_lsw;
  613         u_int8_t        chip_irq;
  614 
  615         cfg_lsw = ADV_INW(adv, ADV_CONFIG_LSW);
  616 
  617         if ((adv->type & ADV_VL) != 0) {
  618                 chip_irq = (u_int8_t)(((cfg_lsw >> 2) & 0x07));
  619                 if ((chip_irq == 0) ||
  620                     (chip_irq == 4) ||
  621                     (chip_irq == 7)) {
  622                         return (0);
  623                 }
  624                 return (chip_irq + (ADV_MIN_IRQ_NO - 1));
  625         }
  626         chip_irq = (u_int8_t)(((cfg_lsw >> 2) & 0x03));
  627         if (chip_irq == 3)
  628                 chip_irq += 2;
  629         return (chip_irq + ADV_MIN_IRQ_NO);
  630 }
  631 
  632 u_int8_t
  633 adv_set_chip_irq(struct adv_softc *adv, u_int8_t irq_no)
  634 {
  635         u_int16_t       cfg_lsw;
  636 
  637         if ((adv->type & ADV_VL) != 0) {
  638                 if (irq_no != 0) {
  639                         if ((irq_no < ADV_MIN_IRQ_NO)
  640                          || (irq_no > ADV_MAX_IRQ_NO)) {
  641                                 irq_no = 0;
  642                         } else {
  643                                 irq_no -= ADV_MIN_IRQ_NO - 1;
  644                         }
  645                 }
  646                 cfg_lsw = ADV_INW(adv, ADV_CONFIG_LSW) & 0xFFE3;
  647                 cfg_lsw |= 0x0010;
  648                 ADV_OUTW(adv, ADV_CONFIG_LSW, cfg_lsw);
  649                 adv_toggle_irq_act(adv);
  650 
  651                 cfg_lsw = ADV_INW(adv, ADV_CONFIG_LSW) & 0xFFE0;
  652                 cfg_lsw |= (irq_no & 0x07) << 2;
  653                 ADV_OUTW(adv, ADV_CONFIG_LSW, cfg_lsw);
  654                 adv_toggle_irq_act(adv);
  655         } else if ((adv->type & ADV_ISA) != 0) {
  656                 if (irq_no == 15)
  657                         irq_no -= 2;
  658                 irq_no -= ADV_MIN_IRQ_NO;
  659                 cfg_lsw = ADV_INW(adv, ADV_CONFIG_LSW) & 0xFFF3;
  660                 cfg_lsw |= (irq_no & 0x03) << 2;
  661                 ADV_OUTW(adv, ADV_CONFIG_LSW, cfg_lsw);
  662         }
  663         return (adv_get_chip_irq(adv));
  664 }
  665 
  666 void
  667 adv_set_chip_scsiid(struct adv_softc *adv, int new_id)
  668 {
  669         u_int16_t cfg_lsw;
  670 
  671         cfg_lsw = ADV_INW(adv, ADV_CONFIG_LSW);
  672         if (ADV_CONFIG_SCSIID(cfg_lsw) == new_id)
  673                 return;
  674         cfg_lsw &= ~ADV_CFG_LSW_SCSIID;
  675         cfg_lsw |= (new_id & ADV_MAX_TID) << ADV_CFG_LSW_SCSIID_SHIFT;
  676         ADV_OUTW(adv, ADV_CONFIG_LSW, cfg_lsw);
  677 }
  678 
  679 int
  680 adv_execute_scsi_queue(struct adv_softc *adv, struct adv_scsi_q *scsiq,
  681                        u_int32_t datalen)
  682 {
  683         struct          adv_target_transinfo* tinfo;
  684         u_int32_t       *p_data_addr;
  685         u_int32_t       *p_data_bcount;
  686         int             disable_syn_offset_one_fix;
  687         int             retval;
  688         u_int           n_q_required;
  689         u_int32_t       addr;
  690         u_int8_t        sg_entry_cnt;
  691         u_int8_t        target_ix;
  692         u_int8_t        sg_entry_cnt_minus_one;
  693         u_int8_t        tid_no;
  694 
  695         scsiq->q1.q_no = 0;
  696         retval = 1;  /* Default to error case */
  697         target_ix = scsiq->q2.target_ix;
  698         tid_no = ADV_TIX_TO_TID(target_ix);
  699         tinfo = &adv->tinfo[tid_no];
  700 
  701         if (scsiq->cdbptr[0] == REQUEST_SENSE) {
  702                 /* Renegotiate if appropriate. */
  703                 adv_set_syncrate(adv, /*struct cam_path */NULL,
  704                                  tid_no, /*period*/0, /*offset*/0,
  705                                  ADV_TRANS_CUR);
  706                 if (tinfo->current.period != tinfo->goal.period) {
  707                         adv_msgout_sdtr(adv, tinfo->goal.period,
  708                                         tinfo->goal.offset);
  709                         scsiq->q1.cntl |= (QC_MSG_OUT | QC_URGENT);
  710                 }
  711         }
  712 
  713         if ((scsiq->q1.cntl & QC_SG_HEAD) != 0) {
  714                 sg_entry_cnt = scsiq->sg_head->entry_cnt;
  715                 sg_entry_cnt_minus_one = sg_entry_cnt - 1;
  716 
  717 #ifdef DIAGNOSTIC
  718                 if (sg_entry_cnt <= 1) 
  719                         panic("adv_execute_scsi_queue: Queue "
  720                               "with QC_SG_HEAD set but %d segs.", sg_entry_cnt);
  721 
  722                 if (sg_entry_cnt > ADV_MAX_SG_LIST)
  723                         panic("adv_execute_scsi_queue: "
  724                               "Queue with too many segs.");
  725 
  726                 if ((adv->type & (ADV_ISA | ADV_VL | ADV_EISA)) != 0) {
  727                         int i;
  728 
  729                         for (i = 0; i < sg_entry_cnt_minus_one; i++) {
  730                                 addr = scsiq->sg_head->sg_list[i].addr +
  731                                        scsiq->sg_head->sg_list[i].bytes;
  732 
  733                                 if ((addr & 0x0003) != 0)
  734                                         panic("adv_execute_scsi_queue: SG "
  735                                               "with odd address or byte count");
  736                         }
  737                 }
  738 #endif
  739                 p_data_addr =
  740                     &scsiq->sg_head->sg_list[sg_entry_cnt_minus_one].addr;
  741                 p_data_bcount =
  742                     &scsiq->sg_head->sg_list[sg_entry_cnt_minus_one].bytes;
  743 
  744                 n_q_required = adv_sgcount_to_qcount(sg_entry_cnt);
  745                 scsiq->sg_head->queue_cnt = n_q_required - 1;
  746         } else {
  747                 p_data_addr = &scsiq->q1.data_addr;
  748                 p_data_bcount = &scsiq->q1.data_cnt;
  749                 n_q_required = 1;
  750         }
  751 
  752         disable_syn_offset_one_fix = FALSE;
  753 
  754         if ((adv->fix_asyn_xfer & scsiq->q1.target_id) != 0
  755          && (adv->fix_asyn_xfer_always & scsiq->q1.target_id) == 0) {
  756 
  757                 if (datalen != 0) {
  758                         if (datalen < 512) {
  759                                 disable_syn_offset_one_fix = TRUE;
  760                         } else {
  761                                 if (scsiq->cdbptr[0] == INQUIRY
  762                                  || scsiq->cdbptr[0] == REQUEST_SENSE
  763                                  || scsiq->cdbptr[0] == READ_CAPACITY
  764                                  || scsiq->cdbptr[0] == MODE_SELECT_6 
  765                                  || scsiq->cdbptr[0] == MODE_SENSE_6
  766                                  || scsiq->cdbptr[0] == MODE_SENSE_10 
  767                                  || scsiq->cdbptr[0] == MODE_SELECT_10 
  768                                  || scsiq->cdbptr[0] == READ_TOC) {
  769                                         disable_syn_offset_one_fix = TRUE;
  770                                 }
  771                         }
  772                 }
  773         }
  774 
  775         if (disable_syn_offset_one_fix) {
  776                 scsiq->q2.tag_code &=
  777                     ~(MSG_SIMPLE_Q_TAG|MSG_HEAD_OF_Q_TAG|MSG_ORDERED_Q_TAG);
  778                 scsiq->q2.tag_code |= (ADV_TAG_FLAG_DISABLE_ASYN_USE_SYN_FIX
  779                                      | ADV_TAG_FLAG_DISABLE_DISCONNECT);
  780         }
  781 
  782         if ((adv->bug_fix_control & ADV_BUG_FIX_IF_NOT_DWB) != 0
  783          && (scsiq->cdbptr[0] == READ_10 || scsiq->cdbptr[0] == READ_6)) {
  784                 u_int8_t extra_bytes;
  785 
  786                 addr = *p_data_addr + *p_data_bcount;
  787                 extra_bytes = addr & 0x0003;
  788                 if (extra_bytes != 0
  789                  && ((scsiq->q1.cntl & QC_SG_HEAD) != 0
  790                   || (scsiq->q1.data_cnt & 0x01FF) == 0)) {
  791                         scsiq->q2.tag_code |= ADV_TAG_FLAG_EXTRA_BYTES;
  792                         scsiq->q1.extra_bytes = extra_bytes;
  793                         *p_data_bcount -= extra_bytes;
  794                 }
  795         }
  796 
  797         if ((adv_get_num_free_queues(adv, n_q_required) >= n_q_required)
  798          || ((scsiq->q1.cntl & QC_URGENT) != 0))
  799                 retval = adv_send_scsi_queue(adv, scsiq, n_q_required);
  800         
  801         return (retval);
  802 }
  803 
  804 
  805 u_int8_t
  806 adv_copy_lram_doneq(struct adv_softc *adv, u_int16_t q_addr,
  807                     struct adv_q_done_info *scsiq, u_int32_t max_dma_count)
  808 {
  809         u_int16_t val;
  810         u_int8_t  sg_queue_cnt;
  811 
  812         adv_get_q_info(adv, q_addr + ADV_SCSIQ_DONE_INFO_BEG,
  813                        (u_int16_t *)scsiq,
  814                        (sizeof(scsiq->d2) + sizeof(scsiq->d3)) / 2);
  815 
  816 #if BYTE_ORDER == BIG_ENDIAN
  817         adv_adj_endian_qdone_info(scsiq);
  818 #endif
  819 
  820         val = adv_read_lram_16(adv, q_addr + ADV_SCSIQ_B_STATUS);
  821         scsiq->q_status = val & 0xFF;
  822         scsiq->q_no = (val >> 8) & 0XFF;
  823 
  824         val = adv_read_lram_16(adv, q_addr + ADV_SCSIQ_B_CNTL);
  825         scsiq->cntl = val & 0xFF;
  826         sg_queue_cnt = (val >> 8) & 0xFF;
  827 
  828         val = adv_read_lram_16(adv,q_addr + ADV_SCSIQ_B_SENSE_LEN);
  829         scsiq->sense_len = val & 0xFF;
  830         scsiq->extra_bytes = (val >> 8) & 0xFF;
  831 
  832         /*
  833          * Due to a bug in accessing LRAM on the 940UA, the residual
  834          * is split into separate high and low 16bit quantities.
  835          */
  836         scsiq->remain_bytes =
  837             adv_read_lram_16(adv, q_addr + ADV_SCSIQ_DW_REMAIN_XFER_CNT);
  838         scsiq->remain_bytes |=
  839             adv_read_lram_16(adv, q_addr + ADV_SCSIQ_W_ALT_DC1) << 16;
  840 
  841         /*
  842          * XXX Is this just a safeguard or will the counter really
  843          * have bogus upper bits?
  844          */
  845         scsiq->remain_bytes &= max_dma_count;
  846 
  847         return (sg_queue_cnt);
  848 }
  849 
  850 int
  851 adv_start_chip(struct adv_softc *adv)
  852 {
  853         ADV_OUTB(adv, ADV_CHIP_CTRL, 0);
  854         if ((ADV_INW(adv, ADV_CHIP_STATUS) & ADV_CSW_HALTED) != 0)
  855                 return (0);
  856         return (1);
  857 }
  858 
  859 int
  860 adv_stop_execution(struct adv_softc *adv)
  861 {
  862         int count;
  863 
  864         count = 0;
  865         if (adv_read_lram_8(adv, ADV_STOP_CODE_B) == 0) {
  866                 adv_write_lram_8(adv, ADV_STOP_CODE_B,
  867                                  ADV_STOP_REQ_RISC_STOP);
  868                 do {
  869                         if (adv_read_lram_8(adv, ADV_STOP_CODE_B) &
  870                                 ADV_STOP_ACK_RISC_STOP) {
  871                                 return (1);
  872                         }
  873                         DELAY(1000);
  874                 } while (count++ < 20);
  875         }
  876         return (0);
  877 }
  878 
  879 int
  880 adv_is_chip_halted(struct adv_softc *adv)
  881 {
  882         if ((ADV_INW(adv, ADV_CHIP_STATUS) & ADV_CSW_HALTED) != 0) {
  883                 if ((ADV_INB(adv, ADV_CHIP_CTRL) & ADV_CC_HALT) != 0) {
  884                         return (1);
  885                 }
  886         }
  887         return (0);
  888 }
  889 
  890 /*
  891  * XXX The numeric constants and the loops in this routine
  892  * need to be documented.
  893  */
  894 void
  895 adv_ack_interrupt(struct adv_softc *adv)
  896 {
  897         u_int8_t        host_flag;
  898         u_int8_t        risc_flag;
  899         int             loop;
  900 
  901         loop = 0;
  902         do {
  903                 risc_flag = adv_read_lram_8(adv, ADVV_RISC_FLAG_B);
  904                 if (loop++ > 0x7FFF) {
  905                         break;
  906                 }
  907         } while ((risc_flag & ADV_RISC_FLAG_GEN_INT) != 0);
  908 
  909         host_flag = adv_read_lram_8(adv, ADVV_HOST_FLAG_B);
  910         adv_write_lram_8(adv, ADVV_HOST_FLAG_B,
  911                          host_flag | ADV_HOST_FLAG_ACK_INT);
  912 
  913         ADV_OUTW(adv, ADV_CHIP_STATUS, ADV_CIW_INT_ACK);
  914         loop = 0;
  915         while (ADV_INW(adv, ADV_CHIP_STATUS) & ADV_CSW_INT_PENDING) {
  916                 ADV_OUTW(adv, ADV_CHIP_STATUS, ADV_CIW_INT_ACK);
  917                 if (loop++ > 3) {
  918                         break;
  919                 }
  920         }
  921 
  922         adv_write_lram_8(adv, ADVV_HOST_FLAG_B, host_flag);
  923 }
  924 
  925 /*
  926  * Handle all conditions that may halt the chip waiting
  927  * for us to intervene.
  928  */
  929 void
  930 adv_isr_chip_halted(struct adv_softc *adv)
  931 {
  932         u_int16_t         int_halt_code;
  933         u_int16_t         halt_q_addr;
  934         target_bit_vector target_mask;
  935         target_bit_vector scsi_busy;
  936         u_int8_t          halt_qp;
  937         u_int8_t          target_ix;
  938         u_int8_t          q_cntl;
  939         u_int8_t          tid_no;
  940 
  941         int_halt_code = adv_read_lram_16(adv, ADVV_HALTCODE_W);
  942         halt_qp = adv_read_lram_8(adv, ADVV_CURCDB_B);
  943         halt_q_addr = ADV_QNO_TO_QADDR(halt_qp);
  944         target_ix = adv_read_lram_8(adv, halt_q_addr + ADV_SCSIQ_B_TARGET_IX);
  945         q_cntl = adv_read_lram_8(adv, halt_q_addr + ADV_SCSIQ_B_CNTL);
  946         tid_no = ADV_TIX_TO_TID(target_ix);
  947         target_mask = ADV_TID_TO_TARGET_MASK(tid_no);
  948         if (int_halt_code == ADV_HALT_DISABLE_ASYN_USE_SYN_FIX) {
  949                 /*
  950                  * Temporarily disable the async fix by removing
  951                  * this target from the list of affected targets,
  952                  * setting our async rate, and then putting us
  953                  * back into the mask.
  954                  */
  955                 adv->fix_asyn_xfer &= ~target_mask;
  956                 adv_set_syncrate(adv, /*struct cam_path */NULL,
  957                                  tid_no, /*period*/0, /*offset*/0,
  958                                  ADV_TRANS_ACTIVE);
  959                 adv->fix_asyn_xfer |= target_mask;
  960         } else if (int_halt_code == ADV_HALT_ENABLE_ASYN_USE_SYN_FIX) {
  961                 adv_set_syncrate(adv, /*struct cam_path */NULL,
  962                                  tid_no, /*period*/0, /*offset*/0,
  963                                  ADV_TRANS_ACTIVE);
  964         } else if (int_halt_code == ADV_HALT_EXTMSG_IN) {
  965                 adv_handle_extmsg_in(adv, halt_q_addr, q_cntl,
  966                                      target_mask, tid_no);
  967         } else if (int_halt_code == ADV_HALT_CHK_CONDITION) {
  968                 struct    adv_target_transinfo* tinfo;
  969                 union     ccb *ccb;
  970                 u_int32_t cinfo_index;
  971                 u_int8_t  tag_code;
  972                 u_int8_t  q_status;
  973 
  974                 tinfo = &adv->tinfo[tid_no];
  975                 q_cntl |= QC_REQ_SENSE;
  976 
  977                 /* Renegotiate if appropriate. */
  978                 adv_set_syncrate(adv, /*struct cam_path */NULL,
  979                                  tid_no, /*period*/0, /*offset*/0,
  980                                  ADV_TRANS_CUR);
  981                 if (tinfo->current.period != tinfo->goal.period) {
  982                         adv_msgout_sdtr(adv, tinfo->goal.period,
  983                                         tinfo->goal.offset);
  984                         q_cntl |= QC_MSG_OUT;
  985                 }
  986                 adv_write_lram_8(adv, halt_q_addr + ADV_SCSIQ_B_CNTL, q_cntl);
  987 
  988                 /* Don't tag request sense commands */
  989                 tag_code = adv_read_lram_8(adv,
  990                                            halt_q_addr + ADV_SCSIQ_B_TAG_CODE);
  991                 tag_code &=
  992                     ~(MSG_SIMPLE_Q_TAG|MSG_HEAD_OF_Q_TAG|MSG_ORDERED_Q_TAG);
  993 
  994                 if ((adv->fix_asyn_xfer & target_mask) != 0
  995                  && (adv->fix_asyn_xfer_always & target_mask) == 0) {
  996                         tag_code |= (ADV_TAG_FLAG_DISABLE_DISCONNECT
  997                                  | ADV_TAG_FLAG_DISABLE_ASYN_USE_SYN_FIX);
  998                 }
  999                 adv_write_lram_8(adv, halt_q_addr + ADV_SCSIQ_B_TAG_CODE,
 1000                                  tag_code);
 1001                 q_status = adv_read_lram_8(adv,
 1002                                            halt_q_addr + ADV_SCSIQ_B_STATUS);
 1003                 q_status |= (QS_READY | QS_BUSY);
 1004                 adv_write_lram_8(adv, halt_q_addr + ADV_SCSIQ_B_STATUS,
 1005                                  q_status);
 1006                 /*
 1007                  * Freeze the devq until we can handle the sense condition.
 1008                  */
 1009                 cinfo_index =
 1010                     adv_read_lram_32(adv, halt_q_addr + ADV_SCSIQ_D_CINFO_IDX);
 1011                 ccb = adv->ccb_infos[cinfo_index].ccb;
 1012                 xpt_freeze_devq(ccb->ccb_h.path, /*count*/1);
 1013                 ccb->ccb_h.status |= CAM_DEV_QFRZN;
 1014                 adv_abort_ccb(adv, tid_no, ADV_TIX_TO_LUN(target_ix),
 1015                               /*ccb*/NULL, CAM_REQUEUE_REQ,
 1016                               /*queued_only*/TRUE);
 1017                 scsi_busy = adv_read_lram_8(adv, ADVV_SCSIBUSY_B);
 1018                 scsi_busy &= ~target_mask;
 1019                 adv_write_lram_8(adv, ADVV_SCSIBUSY_B, scsi_busy);
 1020                 /*
 1021                  * Ensure we have enough time to actually
 1022                  * retrieve the sense.
 1023                  */
 1024                 untimeout(adv_timeout, (caddr_t)ccb, ccb->ccb_h.timeout_ch);
 1025                 ccb->ccb_h.timeout_ch =
 1026                     timeout(adv_timeout, (caddr_t)ccb, 5 * hz);
 1027         } else if (int_halt_code == ADV_HALT_SDTR_REJECTED) {
 1028                 struct  ext_msg out_msg;
 1029 
 1030                 adv_read_lram_16_multi(adv, ADVV_MSGOUT_BEG,
 1031                                        (u_int16_t *) &out_msg,
 1032                                        sizeof(out_msg)/2);
 1033 
 1034                 if ((out_msg.msg_type == MSG_EXTENDED)
 1035                  && (out_msg.msg_len == MSG_EXT_SDTR_LEN)
 1036                  && (out_msg.msg_req == MSG_EXT_SDTR)) {
 1037 
 1038                         /* Revert to Async */
 1039                         adv_set_syncrate(adv, /*struct cam_path */NULL,
 1040                                          tid_no, /*period*/0, /*offset*/0,
 1041                                          ADV_TRANS_GOAL|ADV_TRANS_ACTIVE);
 1042                 }
 1043                 q_cntl &= ~QC_MSG_OUT;
 1044                 adv_write_lram_8(adv, halt_q_addr + ADV_SCSIQ_B_CNTL, q_cntl);
 1045         } else if (int_halt_code == ADV_HALT_SS_QUEUE_FULL) {
 1046                 u_int8_t scsi_status;
 1047                 union ccb *ccb;
 1048                 u_int32_t cinfo_index;
 1049                 
 1050                 scsi_status = adv_read_lram_8(adv, halt_q_addr
 1051                                               + ADV_SCSIQ_SCSI_STATUS);
 1052                 cinfo_index =
 1053                     adv_read_lram_32(adv, halt_q_addr + ADV_SCSIQ_D_CINFO_IDX);
 1054                 ccb = adv->ccb_infos[cinfo_index].ccb;
 1055                 xpt_freeze_devq(ccb->ccb_h.path, /*count*/1);
 1056                 ccb->ccb_h.status |= CAM_DEV_QFRZN|CAM_SCSI_STATUS_ERROR;
 1057                 ccb->csio.scsi_status = SCSI_STATUS_QUEUE_FULL; 
 1058                 adv_abort_ccb(adv, tid_no, ADV_TIX_TO_LUN(target_ix),
 1059                               /*ccb*/NULL, CAM_REQUEUE_REQ,
 1060                               /*queued_only*/TRUE);
 1061                 scsi_busy = adv_read_lram_8(adv, ADVV_SCSIBUSY_B);
 1062                 scsi_busy &= ~target_mask;
 1063                 adv_write_lram_8(adv, ADVV_SCSIBUSY_B, scsi_busy);              
 1064         } else {
 1065                 printf("Unhandled Halt Code %x\n", int_halt_code);
 1066         }
 1067         adv_write_lram_16(adv, ADVV_HALTCODE_W, 0);
 1068 }
 1069 
 1070 void
 1071 adv_sdtr_to_period_offset(struct adv_softc *adv,
 1072                           u_int8_t sync_data, u_int8_t *period,
 1073                           u_int8_t *offset, int tid)
 1074 {
 1075         if (adv->fix_asyn_xfer & ADV_TID_TO_TARGET_MASK(tid)
 1076          && (sync_data == ASYN_SDTR_DATA_FIX_PCI_REV_AB)) {
 1077                 *period = *offset = 0;
 1078         } else {
 1079                 *period = adv->sdtr_period_tbl[((sync_data >> 4) & 0xF)];
 1080                 *offset = sync_data & 0xF;
 1081         }
 1082 }
 1083 
 1084 void
 1085 adv_set_syncrate(struct adv_softc *adv, struct cam_path *path,
 1086                  u_int tid, u_int period, u_int offset, u_int type)
 1087 {
 1088         struct adv_target_transinfo* tinfo;
 1089         u_int old_period;
 1090         u_int old_offset;
 1091         u_int8_t sdtr_data;
 1092 
 1093         tinfo = &adv->tinfo[tid];
 1094 
 1095         /* Filter our input */
 1096         sdtr_data = adv_period_offset_to_sdtr(adv, &period,
 1097                                               &offset, tid);
 1098 
 1099         old_period = tinfo->current.period;
 1100         old_offset = tinfo->current.offset;
 1101 
 1102         if ((type & ADV_TRANS_CUR) != 0
 1103          && ((old_period != period || old_offset != offset)
 1104           || period == 0 || offset == 0) /*Changes in asyn fix settings*/) {
 1105                 int s;
 1106                 int halted;
 1107 
 1108                 s = splcam();
 1109                 halted = adv_is_chip_halted(adv);
 1110                 if (halted == 0)
 1111                         /* Must halt the chip first */
 1112                         adv_host_req_chip_halt(adv);
 1113 
 1114                 /* Update current hardware settings */
 1115                 adv_set_sdtr_reg_at_id(adv, tid, sdtr_data);
 1116 
 1117                 /*
 1118                  * If a target can run in sync mode, we don't need
 1119                  * to check it for sync problems.
 1120                  */
 1121                 if (offset != 0)
 1122                         adv->fix_asyn_xfer &= ~ADV_TID_TO_TARGET_MASK(tid);
 1123 
 1124                 if (halted == 0)
 1125                         /* Start the chip again */
 1126                         adv_start_chip(adv);
 1127 
 1128                 splx(s);
 1129                 tinfo->current.period = period;
 1130                 tinfo->current.offset = offset;
 1131 
 1132                 if (path != NULL) {
 1133                         /*
 1134                          * Tell the SCSI layer about the
 1135                          * new transfer parameters.
 1136                          */
 1137                         struct  ccb_trans_settings neg;
 1138 
 1139                         neg.sync_period = period;
 1140                         neg.sync_offset = offset;
 1141                         neg.valid = CCB_TRANS_SYNC_RATE_VALID
 1142                                   | CCB_TRANS_SYNC_OFFSET_VALID;
 1143                         xpt_setup_ccb(&neg.ccb_h, path, /*priority*/1);
 1144                         xpt_async(AC_TRANSFER_NEG, path, &neg);
 1145                 }
 1146         }
 1147 
 1148         if ((type & ADV_TRANS_GOAL) != 0) {
 1149                 tinfo->goal.period = period;
 1150                 tinfo->goal.offset = offset;
 1151         }
 1152 
 1153         if ((type & ADV_TRANS_USER) != 0) {
 1154                 tinfo->user.period = period;
 1155                 tinfo->user.offset = offset;
 1156         }
 1157 }
 1158 
 1159 u_int8_t
 1160 adv_period_offset_to_sdtr(struct adv_softc *adv, u_int *period,
 1161                           u_int *offset, int tid)
 1162 {
 1163         u_int i;
 1164         u_int dummy_offset;
 1165         u_int dummy_period;
 1166 
 1167         if (offset == NULL) {
 1168                 dummy_offset = 0;
 1169                 offset = &dummy_offset;
 1170         }
 1171 
 1172         if (period == NULL) {
 1173                 dummy_period = 0;
 1174                 period = &dummy_period;
 1175         }
 1176 
 1177         *offset = MIN(ADV_SYN_MAX_OFFSET, *offset);
 1178         if (*period != 0 && *offset != 0) {
 1179                 for (i = 0; i < adv->sdtr_period_tbl_size; i++) {
 1180                         if (*period <= adv->sdtr_period_tbl[i]) {
 1181                                 /*       
 1182                                  * When responding to a target that requests
 1183                                  * sync, the requested  rate may fall between
 1184                                  * two rates that we can output, but still be
 1185                                  * a rate that we can receive.  Because of this,
 1186                                  * we want to respond to the target with
 1187                                  * the same rate that it sent to us even
 1188                                  * if the period we use to send data to it
 1189                                  * is lower.  Only lower the response period
 1190                                  * if we must.
 1191                                  */        
 1192                                 if (i == 0 /* Our maximum rate */)
 1193                                         *period = adv->sdtr_period_tbl[0];
 1194                                 return ((i << 4) | *offset);
 1195                         }
 1196                 }
 1197         }
 1198         
 1199         /* Must go async */
 1200         *period = 0;
 1201         *offset = 0;
 1202         if (adv->fix_asyn_xfer & ADV_TID_TO_TARGET_MASK(tid))
 1203                 return (ASYN_SDTR_DATA_FIX_PCI_REV_AB);
 1204         return (0);
 1205 }
 1206 
 1207 /* Internal Routines */
 1208 
 1209 static void
 1210 adv_read_lram_16_multi(struct adv_softc *adv, u_int16_t s_addr,
 1211                        u_int16_t *buffer, int count)
 1212 {
 1213         ADV_OUTW(adv, ADV_LRAM_ADDR, s_addr);
 1214         ADV_INSW(adv, ADV_LRAM_DATA, buffer, count);
 1215 }
 1216 
 1217 static void
 1218 adv_write_lram_16_multi(struct adv_softc *adv, u_int16_t s_addr,
 1219                         u_int16_t *buffer, int count)
 1220 {
 1221         ADV_OUTW(adv, ADV_LRAM_ADDR, s_addr);
 1222         ADV_OUTSW(adv, ADV_LRAM_DATA, buffer, count);
 1223 }
 1224 
 1225 static void
 1226 adv_mset_lram_16(struct adv_softc *adv, u_int16_t s_addr,
 1227                  u_int16_t set_value, int count)
 1228 {
 1229         ADV_OUTW(adv, ADV_LRAM_ADDR, s_addr);
 1230         bus_space_set_multi_2(adv->tag, adv->bsh, ADV_LRAM_DATA,
 1231                               set_value, count);
 1232 }
 1233 
 1234 static u_int32_t
 1235 adv_msum_lram_16(struct adv_softc *adv, u_int16_t s_addr, int count)
 1236 {
 1237         u_int32_t       sum;
 1238         int             i;
 1239 
 1240         sum = 0;
 1241         ADV_OUTW(adv, ADV_LRAM_ADDR, s_addr);
 1242         for (i = 0; i < count; i++)
 1243                 sum += ADV_INW(adv, ADV_LRAM_DATA);
 1244         return (sum);
 1245 }
 1246 
 1247 static int
 1248 adv_write_and_verify_lram_16(struct adv_softc *adv, u_int16_t addr,
 1249                              u_int16_t value)
 1250 {
 1251         int     retval;
 1252 
 1253         retval = 0;
 1254         ADV_OUTW(adv, ADV_LRAM_ADDR, addr);
 1255         ADV_OUTW(adv, ADV_LRAM_DATA, value);
 1256         DELAY(10000);
 1257         ADV_OUTW(adv, ADV_LRAM_ADDR, addr);
 1258         if (value != ADV_INW(adv, ADV_LRAM_DATA))
 1259                 retval = 1;
 1260         return (retval);
 1261 }
 1262 
 1263 static u_int32_t
 1264 adv_read_lram_32(struct adv_softc *adv, u_int16_t addr)
 1265 {
 1266         u_int16_t           val_low, val_high;
 1267 
 1268         ADV_OUTW(adv, ADV_LRAM_ADDR, addr);
 1269 
 1270 #if BYTE_ORDER == BIG_ENDIAN
 1271         val_high = ADV_INW(adv, ADV_LRAM_DATA);
 1272         val_low = ADV_INW(adv, ADV_LRAM_DATA);
 1273 #else
 1274         val_low = ADV_INW(adv, ADV_LRAM_DATA);
 1275         val_high = ADV_INW(adv, ADV_LRAM_DATA);
 1276 #endif
 1277 
 1278         return (((u_int32_t)val_high << 16) | (u_int32_t)val_low);
 1279 }
 1280 
 1281 static void
 1282 adv_write_lram_32(struct adv_softc *adv, u_int16_t addr, u_int32_t value)
 1283 {
 1284         ADV_OUTW(adv, ADV_LRAM_ADDR, addr);
 1285 
 1286 #if BYTE_ORDER == BIG_ENDIAN
 1287         ADV_OUTW(adv, ADV_LRAM_DATA, (u_int16_t)((value >> 16) & 0xFFFF));
 1288         ADV_OUTW(adv, ADV_LRAM_DATA, (u_int16_t)(value & 0xFFFF));
 1289 #else
 1290         ADV_OUTW(adv, ADV_LRAM_DATA, (u_int16_t)(value & 0xFFFF));
 1291         ADV_OUTW(adv, ADV_LRAM_DATA, (u_int16_t)((value >> 16) & 0xFFFF));
 1292 #endif
 1293 }
 1294 
 1295 static void
 1296 adv_write_lram_32_multi(struct adv_softc *adv, u_int16_t s_addr,
 1297                         u_int32_t *buffer, int count)
 1298 {
 1299         ADV_OUTW(adv, ADV_LRAM_ADDR, s_addr);
 1300         ADV_OUTSW(adv, ADV_LRAM_DATA, (u_int16_t *)buffer, count * 2);
 1301 }
 1302 
 1303 static u_int16_t
 1304 adv_read_eeprom_16(struct adv_softc *adv, u_int8_t addr)
 1305 {
 1306         u_int16_t read_wval;
 1307         u_int8_t  cmd_reg;
 1308 
 1309         adv_write_eeprom_cmd_reg(adv, ADV_EEPROM_CMD_WRITE_DISABLE);
 1310         DELAY(1000);
 1311         cmd_reg = addr | ADV_EEPROM_CMD_READ;
 1312         adv_write_eeprom_cmd_reg(adv, cmd_reg);
 1313         DELAY(1000);
 1314         read_wval = ADV_INW(adv, ADV_EEPROM_DATA);
 1315         DELAY(1000);
 1316         return (read_wval);
 1317 }
 1318 
 1319 static u_int16_t
 1320 adv_write_eeprom_16(struct adv_softc *adv, u_int8_t addr, u_int16_t value)
 1321 {
 1322         u_int16_t       read_value;
 1323 
 1324         read_value = adv_read_eeprom_16(adv, addr);
 1325         if (read_value != value) {
 1326                 adv_write_eeprom_cmd_reg(adv, ADV_EEPROM_CMD_WRITE_ENABLE);
 1327                 DELAY(1000);
 1328                 
 1329                 ADV_OUTW(adv, ADV_EEPROM_DATA, value);
 1330                 DELAY(1000);
 1331 
 1332                 adv_write_eeprom_cmd_reg(adv, ADV_EEPROM_CMD_WRITE | addr);
 1333                 DELAY(20 * 1000);
 1334 
 1335                 adv_write_eeprom_cmd_reg(adv, ADV_EEPROM_CMD_WRITE_DISABLE);
 1336                 DELAY(1000);
 1337                 read_value = adv_read_eeprom_16(adv, addr);
 1338         }
 1339         return (read_value);
 1340 }
 1341 
 1342 static int
 1343 adv_write_eeprom_cmd_reg(struct adv_softc *adv, u_int8_t cmd_reg)
 1344 {
 1345         u_int8_t read_back;
 1346         int      retry;
 1347 
 1348         retry = 0;
 1349         while (1) {
 1350                 ADV_OUTB(adv, ADV_EEPROM_CMD, cmd_reg);
 1351                 DELAY(1000);
 1352                 read_back = ADV_INB(adv, ADV_EEPROM_CMD);
 1353                 if (read_back == cmd_reg) {
 1354                         return (1);
 1355                 }
 1356                 if (retry++ > ADV_EEPROM_MAX_RETRY) {
 1357                         return (0);
 1358                 }
 1359         }
 1360 }
 1361 
 1362 static int
 1363 adv_set_eeprom_config_once(struct adv_softc *adv,
 1364                            struct adv_eeprom_config *eeprom_config)
 1365 {
 1366         int             n_error;
 1367         u_int16_t       *wbuf;
 1368         u_int16_t       sum;
 1369         u_int8_t        s_addr;
 1370         u_int8_t        cfg_beg;
 1371         u_int8_t        cfg_end;
 1372 
 1373         wbuf = (u_int16_t *)eeprom_config;
 1374         n_error = 0;
 1375         sum = 0;
 1376         for (s_addr = 0; s_addr < 2; s_addr++, wbuf++) {
 1377                 sum += *wbuf;
 1378                 if (*wbuf != adv_write_eeprom_16(adv, s_addr, *wbuf)) {
 1379                         n_error++;
 1380                 }
 1381         }
 1382         if (adv->type & ADV_VL) {
 1383                 cfg_beg = ADV_EEPROM_CFG_BEG_VL;
 1384                 cfg_end = ADV_EEPROM_MAX_ADDR_VL;
 1385         } else {
 1386                 cfg_beg = ADV_EEPROM_CFG_BEG;
 1387                 cfg_end = ADV_EEPROM_MAX_ADDR;
 1388         }
 1389 
 1390         for (s_addr = cfg_beg; s_addr <= (cfg_end - 1); s_addr++, wbuf++) {
 1391                 sum += *wbuf;
 1392                 if (*wbuf != adv_write_eeprom_16(adv, s_addr, *wbuf)) {
 1393                         n_error++;
 1394                 }
 1395         }
 1396         *wbuf = sum;
 1397         if (sum != adv_write_eeprom_16(adv, s_addr, sum)) {
 1398                 n_error++;
 1399         }
 1400         wbuf = (u_int16_t *)eeprom_config;
 1401         for (s_addr = 0; s_addr < 2; s_addr++, wbuf++) {
 1402                 if (*wbuf != adv_read_eeprom_16(adv, s_addr)) {
 1403                         n_error++;
 1404                 }
 1405         }
 1406         for (s_addr = cfg_beg; s_addr <= cfg_end; s_addr++, wbuf++) {
 1407                 if (*wbuf != adv_read_eeprom_16(adv, s_addr)) {
 1408                         n_error++;
 1409                 }
 1410         }
 1411         return (n_error);
 1412 }
 1413 
 1414 static u_int32_t
 1415 adv_load_microcode(struct adv_softc *adv, u_int16_t s_addr,
 1416                    u_int16_t *mcode_buf, u_int16_t mcode_size)
 1417 {
 1418         u_int32_t chksum;
 1419         u_int16_t mcode_lram_size;
 1420         u_int16_t mcode_chksum;
 1421 
 1422         mcode_lram_size = mcode_size >> 1;
 1423         /* XXX Why zero the memory just before you write the whole thing?? */
 1424         adv_mset_lram_16(adv, s_addr, 0, mcode_lram_size);
 1425         adv_write_lram_16_multi(adv, s_addr, mcode_buf, mcode_lram_size);
 1426 
 1427         chksum = adv_msum_lram_16(adv, s_addr, mcode_lram_size);
 1428         mcode_chksum = (u_int16_t)adv_msum_lram_16(adv, ADV_CODE_SEC_BEG,
 1429                                                    ((mcode_size - s_addr
 1430                                                      - ADV_CODE_SEC_BEG) >> 1));
 1431         adv_write_lram_16(adv, ADVV_MCODE_CHKSUM_W, mcode_chksum);
 1432         adv_write_lram_16(adv, ADVV_MCODE_SIZE_W, mcode_size);
 1433         return (chksum);
 1434 }
 1435 
 1436 static void
 1437 adv_reinit_lram(struct adv_softc *adv) {
 1438         adv_init_lram(adv);
 1439         adv_init_qlink_var(adv);
 1440 }
 1441 
 1442 static void
 1443 adv_init_lram(struct adv_softc *adv)
 1444 {
 1445         u_int8_t  i;
 1446         u_int16_t s_addr;
 1447 
 1448         adv_mset_lram_16(adv, ADV_QADR_BEG, 0,
 1449                          (((adv->max_openings + 2 + 1) * 64) >> 1));
 1450         
 1451         i = ADV_MIN_ACTIVE_QNO;
 1452         s_addr = ADV_QADR_BEG + ADV_QBLK_SIZE;
 1453 
 1454         adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_FWD, i + 1);
 1455         adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_BWD, adv->max_openings);
 1456         adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_QNO, i);
 1457         i++;
 1458         s_addr += ADV_QBLK_SIZE;
 1459         for (; i < adv->max_openings; i++, s_addr += ADV_QBLK_SIZE) {
 1460                 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_FWD, i + 1);
 1461                 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_BWD, i - 1);
 1462                 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_QNO, i);
 1463         }
 1464 
 1465         adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_FWD, ADV_QLINK_END);
 1466         adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_BWD, adv->max_openings - 1);
 1467         adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_QNO, adv->max_openings);
 1468         i++;
 1469         s_addr += ADV_QBLK_SIZE;
 1470 
 1471         for (; i <= adv->max_openings + 3; i++, s_addr += ADV_QBLK_SIZE) {
 1472                 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_FWD, i);
 1473                 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_BWD, i);
 1474                 adv_write_lram_8(adv, s_addr + ADV_SCSIQ_B_QNO, i);
 1475         }
 1476 }
 1477 
 1478 static int
 1479 adv_init_microcode_var(struct adv_softc *adv)
 1480 {
 1481         int      i;
 1482 
 1483         for (i = 0; i <= ADV_MAX_TID; i++) {
 1484                 
 1485                 /* Start out async all around */
 1486                 adv_set_syncrate(adv, /*path*/NULL,
 1487                                  i, 0, 0,
 1488                                  ADV_TRANS_GOAL|ADV_TRANS_CUR);
 1489         }
 1490 
 1491         adv_init_qlink_var(adv);
 1492 
 1493         adv_write_lram_8(adv, ADVV_DISC_ENABLE_B, adv->disc_enable);
 1494         adv_write_lram_8(adv, ADVV_HOSTSCSI_ID_B, 0x01 << adv->scsi_id);
 1495 
 1496         adv_write_lram_32(adv, ADVV_OVERRUN_PADDR_D, adv->overrun_physbase);
 1497 
 1498         adv_write_lram_32(adv, ADVV_OVERRUN_BSIZE_D, ADV_OVERRUN_BSIZE);
 1499 
 1500         ADV_OUTW(adv, ADV_REG_PROG_COUNTER, ADV_MCODE_START_ADDR);
 1501         if (ADV_INW(adv, ADV_REG_PROG_COUNTER) != ADV_MCODE_START_ADDR) {
 1502                 printf("adv%d: Unable to set program counter. Aborting.\n",
 1503                        adv->unit);
 1504                 return (1);
 1505         }
 1506         return (0);
 1507 }
 1508 
 1509 static void
 1510 adv_init_qlink_var(struct adv_softc *adv)
 1511 {
 1512         int       i;
 1513         u_int16_t lram_addr;
 1514 
 1515         adv_write_lram_8(adv, ADVV_NEXTRDY_B, 1);
 1516         adv_write_lram_8(adv, ADVV_DONENEXT_B, adv->max_openings);
 1517 
 1518         adv_write_lram_16(adv, ADVV_FREE_Q_HEAD_W, 1);
 1519         adv_write_lram_16(adv, ADVV_DONE_Q_TAIL_W, adv->max_openings);
 1520 
 1521         adv_write_lram_8(adv, ADVV_BUSY_QHEAD_B,
 1522                          (u_int8_t)((int) adv->max_openings + 1));
 1523         adv_write_lram_8(adv, ADVV_DISC1_QHEAD_B,
 1524                          (u_int8_t)((int) adv->max_openings + 2));
 1525 
 1526         adv_write_lram_8(adv, ADVV_TOTAL_READY_Q_B, adv->max_openings);
 1527 
 1528         adv_write_lram_16(adv, ADVV_ASCDVC_ERR_CODE_W, 0);
 1529         adv_write_lram_16(adv, ADVV_HALTCODE_W, 0);
 1530         adv_write_lram_8(adv, ADVV_STOP_CODE_B, 0);
 1531         adv_write_lram_8(adv, ADVV_SCSIBUSY_B, 0);
 1532         adv_write_lram_8(adv, ADVV_WTM_FLAG_B, 0);
 1533         adv_write_lram_8(adv, ADVV_Q_DONE_IN_PROGRESS_B, 0);
 1534 
 1535         lram_addr = ADV_QADR_BEG;
 1536         for (i = 0; i < 32; i++, lram_addr += 2)
 1537                 adv_write_lram_16(adv, lram_addr, 0);
 1538 }
 1539 
 1540 static void
 1541 adv_disable_interrupt(struct adv_softc *adv)
 1542 {
 1543         u_int16_t cfg;
 1544 
 1545         cfg = ADV_INW(adv, ADV_CONFIG_LSW);
 1546         ADV_OUTW(adv, ADV_CONFIG_LSW, cfg & ~ADV_CFG_LSW_HOST_INT_ON);
 1547 }
 1548 
 1549 static void
 1550 adv_enable_interrupt(struct adv_softc *adv)
 1551 {
 1552         u_int16_t cfg;
 1553 
 1554         cfg = ADV_INW(adv, ADV_CONFIG_LSW);
 1555         ADV_OUTW(adv, ADV_CONFIG_LSW, cfg | ADV_CFG_LSW_HOST_INT_ON);
 1556 }
 1557 
 1558 static void
 1559 adv_toggle_irq_act(struct adv_softc *adv)
 1560 {
 1561         ADV_OUTW(adv, ADV_CHIP_STATUS, ADV_CIW_IRQ_ACT);
 1562         ADV_OUTW(adv, ADV_CHIP_STATUS, 0);
 1563 }
 1564 
 1565 void
 1566 adv_start_execution(struct adv_softc *adv)
 1567 {
 1568         if (adv_read_lram_8(adv, ADV_STOP_CODE_B) != 0) {
 1569                 adv_write_lram_8(adv, ADV_STOP_CODE_B, 0);
 1570         }
 1571 }
 1572 
 1573 int
 1574 adv_stop_chip(struct adv_softc *adv)
 1575 {
 1576         u_int8_t cc_val;
 1577 
 1578         cc_val = ADV_INB(adv, ADV_CHIP_CTRL)
 1579                  & (~(ADV_CC_SINGLE_STEP | ADV_CC_TEST | ADV_CC_DIAG));
 1580         ADV_OUTB(adv, ADV_CHIP_CTRL, cc_val | ADV_CC_HALT);
 1581         adv_set_chip_ih(adv, ADV_INS_HALT);
 1582         adv_set_chip_ih(adv, ADV_INS_RFLAG_WTM);
 1583         if ((ADV_INW(adv, ADV_CHIP_STATUS) & ADV_CSW_HALTED) == 0) {
 1584                 return (0);
 1585         }
 1586         return (1);
 1587 }
 1588 
 1589 static int
 1590 adv_host_req_chip_halt(struct adv_softc *adv)
 1591 {       
 1592         int      count;
 1593         u_int8_t saved_stop_code;
 1594 
 1595         if (adv_is_chip_halted(adv))
 1596                 return (1);
 1597 
 1598         count = 0;
 1599         saved_stop_code = adv_read_lram_8(adv, ADVV_STOP_CODE_B);
 1600         adv_write_lram_8(adv, ADVV_STOP_CODE_B,
 1601                          ADV_STOP_HOST_REQ_RISC_HALT | ADV_STOP_REQ_RISC_STOP);
 1602         while (adv_is_chip_halted(adv) == 0
 1603             && count++ < 2000)
 1604                 ;
 1605 
 1606         adv_write_lram_8(adv, ADVV_STOP_CODE_B, saved_stop_code);
 1607         return (count < 2000); 
 1608 }
 1609 
 1610 static void
 1611 adv_set_chip_ih(struct adv_softc *adv, u_int16_t ins_code)
 1612 {
 1613         adv_set_bank(adv, 1);
 1614         ADV_OUTW(adv, ADV_REG_IH, ins_code);
 1615         adv_set_bank(adv, 0);
 1616 }
 1617 
 1618 #if UNUSED
 1619 static u_int8_t
 1620 adv_get_chip_scsi_ctrl(struct adv_softc *adv)
 1621 {
 1622         u_int8_t scsi_ctrl;
 1623 
 1624         adv_set_bank(adv, 1);
 1625         scsi_ctrl = ADV_INB(adv, ADV_REG_SC);
 1626         adv_set_bank(adv, 0);
 1627         return (scsi_ctrl);
 1628 }
 1629 #endif
 1630 
 1631 /*
 1632  * XXX Looks like more padding issues in this routine as well.
 1633  *     There has to be a way to turn this into an insw.
 1634  */
 1635 static void
 1636 adv_get_q_info(struct adv_softc *adv, u_int16_t s_addr,
 1637                u_int16_t *inbuf, int words)
 1638 {
 1639         int     i;
 1640 
 1641         ADV_OUTW(adv, ADV_LRAM_ADDR, s_addr);
 1642         for (i = 0; i < words; i++, inbuf++) {
 1643                 if (i == 5) {
 1644                         continue;
 1645                 }
 1646                 *inbuf = ADV_INW(adv, ADV_LRAM_DATA);
 1647         }
 1648 }
 1649 
 1650 static u_int
 1651 adv_get_num_free_queues(struct adv_softc *adv, u_int8_t n_qs)
 1652 {
 1653         u_int     cur_used_qs;
 1654         u_int     cur_free_qs;
 1655 
 1656         cur_used_qs = adv->cur_active + ADV_MIN_FREE_Q;
 1657 
 1658         if ((cur_used_qs + n_qs) <= adv->max_openings) {
 1659                 cur_free_qs = adv->max_openings - cur_used_qs;
 1660                 return (cur_free_qs);
 1661         }
 1662         adv->openings_needed = n_qs;
 1663         return (0);
 1664 }
 1665 
 1666 static u_int8_t
 1667 adv_alloc_free_queues(struct adv_softc *adv, u_int8_t free_q_head,
 1668                       u_int8_t n_free_q)
 1669 {
 1670         int i;
 1671 
 1672         for (i = 0; i < n_free_q; i++) {
 1673                 free_q_head = adv_alloc_free_queue(adv, free_q_head);
 1674                 if (free_q_head == ADV_QLINK_END)
 1675                         break;
 1676         }
 1677         return (free_q_head);
 1678 }
 1679 
 1680 static u_int8_t
 1681 adv_alloc_free_queue(struct adv_softc *adv, u_int8_t free_q_head)
 1682 {
 1683         u_int16_t       q_addr;
 1684         u_int8_t        next_qp;
 1685         u_int8_t        q_status;
 1686 
 1687         next_qp = ADV_QLINK_END;
 1688         q_addr = ADV_QNO_TO_QADDR(free_q_head);
 1689         q_status = adv_read_lram_8(adv, q_addr + ADV_SCSIQ_B_STATUS);
 1690         
 1691         if ((q_status & QS_READY) == 0)
 1692                 next_qp = adv_read_lram_8(adv, q_addr + ADV_SCSIQ_B_FWD);
 1693 
 1694         return (next_qp);
 1695 }
 1696 
 1697 static int
 1698 adv_send_scsi_queue(struct adv_softc *adv, struct adv_scsi_q *scsiq,
 1699                     u_int8_t n_q_required)
 1700 {
 1701         u_int8_t        free_q_head;
 1702         u_int8_t        next_qp;
 1703         u_int8_t        tid_no;
 1704         u_int8_t        target_ix;
 1705         int             retval;
 1706 
 1707         retval = 1;
 1708         target_ix = scsiq->q2.target_ix;
 1709         tid_no = ADV_TIX_TO_TID(target_ix);
 1710         free_q_head = adv_read_lram_16(adv, ADVV_FREE_Q_HEAD_W) & 0xFF;
 1711         if ((next_qp = adv_alloc_free_queues(adv, free_q_head, n_q_required))
 1712             != ADV_QLINK_END) {
 1713                 scsiq->q1.q_no = free_q_head;
 1714 
 1715                 /*
 1716                  * Now that we know our Q number, point our sense
 1717                  * buffer pointer to a bus dma mapped area where
 1718                  * we can dma the data to.
 1719                  */
 1720                 scsiq->q1.sense_addr = adv->sense_physbase
 1721                     + ((free_q_head - 1) * sizeof(struct scsi_sense_data));
 1722                 adv_put_ready_sg_list_queue(adv, scsiq, free_q_head);
 1723                 adv_write_lram_16(adv, ADVV_FREE_Q_HEAD_W, next_qp);
 1724                 adv->cur_active += n_q_required;
 1725                 retval = 0;
 1726         }
 1727         return (retval);
 1728 }
 1729 
 1730 
 1731 static void
 1732 adv_put_ready_sg_list_queue(struct adv_softc *adv, struct adv_scsi_q *scsiq,
 1733                             u_int q_no)
 1734 {
 1735         u_int8_t        sg_list_dwords;
 1736         u_int8_t        sg_index, i;
 1737         u_int8_t        sg_entry_cnt;
 1738         u_int8_t        next_qp;
 1739         u_int16_t       q_addr;
 1740         struct          adv_sg_head *sg_head;
 1741         struct          adv_sg_list_q scsi_sg_q;
 1742 
 1743         sg_head = scsiq->sg_head;
 1744 
 1745         if (sg_head) {
 1746                 sg_entry_cnt = sg_head->entry_cnt - 1;
 1747 #ifdef DIAGNOSTIC
 1748                 if (sg_entry_cnt == 0)
 1749                         panic("adv_put_ready_sg_list_queue: ScsiQ with "
 1750                               "a SG list but only one element");
 1751                 if ((scsiq->q1.cntl & QC_SG_HEAD) == 0)
 1752                         panic("adv_put_ready_sg_list_queue: ScsiQ with "
 1753                               "a SG list but QC_SG_HEAD not set");
 1754 #endif                  
 1755                 q_addr = ADV_QNO_TO_QADDR(q_no);
 1756                 sg_index = 1;
 1757                 scsiq->q1.sg_queue_cnt = sg_head->queue_cnt;
 1758                 scsi_sg_q.sg_head_qp = q_no;
 1759                 scsi_sg_q.cntl = QCSG_SG_XFER_LIST;
 1760                 for (i = 0; i < sg_head->queue_cnt; i++) {
 1761                         u_int8_t segs_this_q;
 1762 
 1763                         if (sg_entry_cnt > ADV_SG_LIST_PER_Q)
 1764                                 segs_this_q = ADV_SG_LIST_PER_Q;
 1765                         else {
 1766                                 /* This will be the last segment then */
 1767                                 segs_this_q = sg_entry_cnt;
 1768                                 scsi_sg_q.cntl |= QCSG_SG_XFER_END;
 1769                         }
 1770                         scsi_sg_q.seq_no = i + 1;
 1771                         sg_list_dwords = segs_this_q << 1;
 1772                         if (i == 0) {
 1773                                 scsi_sg_q.sg_list_cnt = segs_this_q;
 1774                                 scsi_sg_q.sg_cur_list_cnt = segs_this_q;
 1775                         } else {
 1776                                 scsi_sg_q.sg_list_cnt = segs_this_q - 1;
 1777                                 scsi_sg_q.sg_cur_list_cnt = segs_this_q - 1;
 1778                         }
 1779                         next_qp = adv_read_lram_8(adv, q_addr + ADV_SCSIQ_B_FWD);
 1780                         scsi_sg_q.q_no = next_qp;
 1781                         q_addr = ADV_QNO_TO_QADDR(next_qp);
 1782 
 1783                         adv_write_lram_16_multi(adv,
 1784                                                 q_addr + ADV_SCSIQ_SGHD_CPY_BEG,
 1785                                                 (u_int16_t *)&scsi_sg_q,
 1786                                                 sizeof(scsi_sg_q) >> 1);
 1787                         adv_write_lram_32_multi(adv, q_addr + ADV_SGQ_LIST_BEG,
 1788                                                 (u_int32_t *)&sg_head->sg_list[sg_index],
 1789                                                 sg_list_dwords);
 1790                         sg_entry_cnt -= segs_this_q;
 1791                         sg_index += ADV_SG_LIST_PER_Q;
 1792                 }
 1793         }
 1794         adv_put_ready_queue(adv, scsiq, q_no);
 1795 }
 1796 
 1797 static void
 1798 adv_put_ready_queue(struct adv_softc *adv, struct adv_scsi_q *scsiq,
 1799                     u_int q_no)
 1800 {
 1801         struct          adv_target_transinfo* tinfo;
 1802         u_int           q_addr;
 1803         u_int           tid_no;
 1804 
 1805         tid_no = ADV_TIX_TO_TID(scsiq->q2.target_ix);
 1806         tinfo = &adv->tinfo[tid_no];
 1807         if ((tinfo->current.period != tinfo->goal.period)
 1808          || (tinfo->current.offset != tinfo->goal.offset)) {
 1809 
 1810                 adv_msgout_sdtr(adv, tinfo->goal.period, tinfo->goal.offset);
 1811                 scsiq->q1.cntl |= QC_MSG_OUT;
 1812         }
 1813         q_addr = ADV_QNO_TO_QADDR(q_no);
 1814 
 1815         scsiq->q1.status = QS_FREE;
 1816 
 1817         adv_write_lram_16_multi(adv, q_addr + ADV_SCSIQ_CDB_BEG,
 1818                                 (u_int16_t *)scsiq->cdbptr,
 1819                                 scsiq->q2.cdb_len >> 1);
 1820 
 1821 #if BYTE_ORDER == BIG_ENDIAN
 1822         adv_adj_scsiq_endian(scsiq);
 1823 #endif
 1824 
 1825         adv_put_scsiq(adv, q_addr + ADV_SCSIQ_CPY_BEG,
 1826                       (u_int16_t *) &scsiq->q1.cntl,
 1827                       ((sizeof(scsiq->q1) + sizeof(scsiq->q2)) / 2) - 1);
 1828 
 1829 #if CC_WRITE_IO_COUNT
 1830         adv_write_lram_16(adv, q_addr + ADV_SCSIQ_W_REQ_COUNT,
 1831                           adv->req_count);
 1832 #endif
 1833 
 1834 #if CC_CLEAR_DMA_REMAIN
 1835 
 1836         adv_write_lram_32(adv, q_addr + ADV_SCSIQ_DW_REMAIN_XFER_ADDR, 0);
 1837         adv_write_lram_32(adv, q_addr + ADV_SCSIQ_DW_REMAIN_XFER_CNT, 0);
 1838 #endif
 1839 
 1840         adv_write_lram_16(adv, q_addr + ADV_SCSIQ_B_STATUS,
 1841                           (scsiq->q1.q_no << 8) | QS_READY);
 1842 }
 1843 
 1844 static void
 1845 adv_put_scsiq(struct adv_softc *adv, u_int16_t s_addr,
 1846               u_int16_t *buffer, int words)
 1847 {
 1848         int     i;
 1849 
 1850         /*
 1851          * XXX This routine makes *gross* assumptions
 1852          * about padding in the data structures.
 1853          * Either the data structures should have explicit
 1854          * padding members added, or they should have padding
 1855          * turned off via compiler attributes depending on
 1856          * which yields better overall performance.  My hunch
 1857          * would be that turning off padding would be the
 1858          * faster approach as an outsw is much faster than
 1859          * this crude loop and accessing un-aligned data
 1860          * members isn't *that* expensive.  The other choice
 1861          * would be to modify the ASC script so that the
 1862          * the adv_scsiq_1 structure can be re-arranged so
 1863          * padding isn't required.
 1864          */
 1865         ADV_OUTW(adv, ADV_LRAM_ADDR, s_addr);
 1866         for (i = 0; i < words; i++, buffer++) {
 1867                 if (i == 2 || i == 10) {
 1868                         continue;
 1869                 }
 1870                 ADV_OUTW(adv, ADV_LRAM_DATA, *buffer);
 1871         }
 1872 }
 1873 
 1874 #if BYTE_ORDER == BIG_ENDIAN
 1875 void
 1876 adv_adj_endian_qdone_info(struct adv_q_done_info *scsiq)
 1877 {
 1878 
 1879         panic("adv(4) not supported on big-endian machines.\n");
 1880 }
 1881 
 1882 void
 1883 adv_adj_scsiq_endian(struct adv_scsi_q *scsiq)
 1884 {
 1885 
 1886         panic("adv(4) not supported on big-endian machines.\n");
 1887 }
 1888 #endif
 1889 
 1890 static void
 1891 adv_handle_extmsg_in(struct adv_softc *adv, u_int16_t halt_q_addr,
 1892                      u_int8_t q_cntl, target_bit_vector target_mask,
 1893                      int tid_no)
 1894 {
 1895         struct  ext_msg ext_msg;
 1896 
 1897         adv_read_lram_16_multi(adv, ADVV_MSGIN_BEG, (u_int16_t *) &ext_msg,
 1898                                sizeof(ext_msg) >> 1);
 1899         if ((ext_msg.msg_type == MSG_EXTENDED)
 1900          && (ext_msg.msg_req == MSG_EXT_SDTR)
 1901          && (ext_msg.msg_len == MSG_EXT_SDTR_LEN)) {
 1902                 union     ccb *ccb;
 1903                 struct    adv_target_transinfo* tinfo;
 1904                 u_int32_t cinfo_index;
 1905                 u_int    period;
 1906                 u_int    offset;
 1907                 int      sdtr_accept;
 1908                 u_int8_t orig_offset;
 1909 
 1910                 cinfo_index =
 1911                     adv_read_lram_32(adv, halt_q_addr + ADV_SCSIQ_D_CINFO_IDX);
 1912                 ccb = adv->ccb_infos[cinfo_index].ccb;
 1913                 tinfo = &adv->tinfo[tid_no];
 1914                 sdtr_accept = TRUE;
 1915 
 1916                 orig_offset = ext_msg.req_ack_offset;
 1917                 if (ext_msg.xfer_period < tinfo->goal.period) {
 1918                         sdtr_accept = FALSE;
 1919                         ext_msg.xfer_period = tinfo->goal.period;
 1920                 }
 1921 
 1922                 /* Perform range checking */
 1923                 period = ext_msg.xfer_period;
 1924                 offset = ext_msg.req_ack_offset;
 1925                 adv_period_offset_to_sdtr(adv, &period,  &offset, tid_no);
 1926                 ext_msg.xfer_period = period;
 1927                 ext_msg.req_ack_offset = offset;
 1928                 
 1929                 /* Record our current sync settings */
 1930                 adv_set_syncrate(adv, ccb->ccb_h.path,
 1931                                  tid_no, ext_msg.xfer_period,
 1932                                  ext_msg.req_ack_offset,
 1933                                  ADV_TRANS_GOAL|ADV_TRANS_ACTIVE);
 1934 
 1935                 /* Offset too high or large period forced async */
 1936                 if (orig_offset != ext_msg.req_ack_offset)
 1937                         sdtr_accept = FALSE;
 1938 
 1939                 if (sdtr_accept && (q_cntl & QC_MSG_OUT)) {
 1940                         /* Valid response to our requested negotiation */
 1941                         q_cntl &= ~QC_MSG_OUT;
 1942                 } else {
 1943                         /* Must Respond */
 1944                         q_cntl |= QC_MSG_OUT;
 1945                         adv_msgout_sdtr(adv, ext_msg.xfer_period,
 1946                                         ext_msg.req_ack_offset);
 1947                 }
 1948 
 1949         } else if (ext_msg.msg_type == MSG_EXTENDED
 1950                 && ext_msg.msg_req == MSG_EXT_WDTR
 1951                 && ext_msg.msg_len == MSG_EXT_WDTR_LEN) {
 1952 
 1953                 ext_msg.wdtr_width = 0;
 1954                 adv_write_lram_16_multi(adv, ADVV_MSGOUT_BEG,
 1955                                         (u_int16_t *)&ext_msg,
 1956                                         sizeof(ext_msg) >> 1);
 1957                 q_cntl |= QC_MSG_OUT;
 1958         } else {
 1959 
 1960                 ext_msg.msg_type = MSG_MESSAGE_REJECT;
 1961                 adv_write_lram_16_multi(adv, ADVV_MSGOUT_BEG,
 1962                                         (u_int16_t *)&ext_msg,
 1963                                         sizeof(ext_msg) >> 1);
 1964                 q_cntl |= QC_MSG_OUT;
 1965         }
 1966         adv_write_lram_8(adv, halt_q_addr + ADV_SCSIQ_B_CNTL, q_cntl);
 1967 }
 1968 
 1969 static void
 1970 adv_msgout_sdtr(struct adv_softc *adv, u_int8_t sdtr_period,
 1971                 u_int8_t sdtr_offset)
 1972 {
 1973         struct   ext_msg sdtr_buf;
 1974 
 1975         sdtr_buf.msg_type = MSG_EXTENDED;
 1976         sdtr_buf.msg_len = MSG_EXT_SDTR_LEN;
 1977         sdtr_buf.msg_req = MSG_EXT_SDTR;
 1978         sdtr_buf.xfer_period = sdtr_period;
 1979         sdtr_offset &= ADV_SYN_MAX_OFFSET;
 1980         sdtr_buf.req_ack_offset = sdtr_offset;
 1981         adv_write_lram_16_multi(adv, ADVV_MSGOUT_BEG,
 1982                                 (u_int16_t *) &sdtr_buf,
 1983                                 sizeof(sdtr_buf) / 2);
 1984 }
 1985 
 1986 int
 1987 adv_abort_ccb(struct adv_softc *adv, int target, int lun, union ccb *ccb,
 1988               u_int32_t status, int queued_only)
 1989 {
 1990         u_int16_t q_addr;
 1991         u_int8_t  q_no;
 1992         struct adv_q_done_info scsiq_buf;
 1993         struct adv_q_done_info *scsiq;
 1994         u_int8_t  target_ix;
 1995         int       count;
 1996 
 1997         scsiq = &scsiq_buf;
 1998         target_ix = ADV_TIDLUN_TO_IX(target, lun);
 1999         count = 0;
 2000         for (q_no = ADV_MIN_ACTIVE_QNO; q_no <= adv->max_openings; q_no++) {
 2001                 struct adv_ccb_info *ccb_info;
 2002                 q_addr = ADV_QNO_TO_QADDR(q_no);
 2003 
 2004                 adv_copy_lram_doneq(adv, q_addr, scsiq, adv->max_dma_count);
 2005                 ccb_info = &adv->ccb_infos[scsiq->d2.ccb_index];
 2006                 if (((scsiq->q_status & QS_READY) != 0)
 2007                  && ((scsiq->q_status & QS_ABORTED) == 0)
 2008                  && ((scsiq->cntl & QCSG_SG_XFER_LIST) == 0)
 2009                  && (scsiq->d2.target_ix == target_ix)
 2010                  && (queued_only == 0
 2011                   || !(scsiq->q_status & (QS_DISC1|QS_DISC2|QS_BUSY|QS_DONE)))
 2012                  && (ccb == NULL || (ccb == ccb_info->ccb))) {
 2013                         union ccb *aborted_ccb;
 2014                         struct adv_ccb_info *cinfo;
 2015 
 2016                         scsiq->q_status |= QS_ABORTED;
 2017                         adv_write_lram_8(adv, q_addr + ADV_SCSIQ_B_STATUS,
 2018                                          scsiq->q_status);
 2019                         aborted_ccb = ccb_info->ccb;
 2020                         /* Don't clobber earlier error codes */
 2021                         if ((aborted_ccb->ccb_h.status & CAM_STATUS_MASK)
 2022                           == CAM_REQ_INPROG)
 2023                                 aborted_ccb->ccb_h.status |= status;
 2024                         cinfo = (struct adv_ccb_info *)
 2025                             aborted_ccb->ccb_h.ccb_cinfo_ptr;
 2026                         cinfo->state |= ACCB_ABORT_QUEUED;
 2027                         count++;
 2028                 }
 2029         }
 2030         return (count);
 2031 }
 2032 
 2033 int
 2034 adv_reset_bus(struct adv_softc *adv, int initiate_bus_reset)
 2035 {
 2036         int count; 
 2037         int i;
 2038         union ccb *ccb;
 2039 
 2040         i = 200;
 2041         while ((ADV_INW(adv, ADV_CHIP_STATUS) & ADV_CSW_SCSI_RESET_ACTIVE) != 0
 2042             && i--)
 2043                 DELAY(1000);
 2044         adv_reset_chip(adv, initiate_bus_reset);
 2045         adv_reinit_lram(adv);
 2046         for (i = 0; i <= ADV_MAX_TID; i++)
 2047                 adv_set_syncrate(adv, NULL, i, /*period*/0,
 2048                                  /*offset*/0, ADV_TRANS_CUR);
 2049         ADV_OUTW(adv, ADV_REG_PROG_COUNTER, ADV_MCODE_START_ADDR);
 2050 
 2051         /* Tell the XPT layer that a bus reset occured */
 2052         if (adv->path != NULL)
 2053                 xpt_async(AC_BUS_RESET, adv->path, NULL);
 2054 
 2055         count = 0;
 2056         while ((ccb = (union ccb *)LIST_FIRST(&adv->pending_ccbs)) != NULL) {
 2057                 if ((ccb->ccb_h.status & CAM_STATUS_MASK) == CAM_REQ_INPROG)
 2058                         ccb->ccb_h.status |= CAM_SCSI_BUS_RESET;
 2059                 adv_done(adv, ccb, QD_ABORTED_BY_HOST, 0, 0, 0);
 2060                 count++;
 2061         }
 2062 
 2063         adv_start_chip(adv);
 2064         return (count);
 2065 }
 2066 
 2067 static void
 2068 adv_set_sdtr_reg_at_id(struct adv_softc *adv, int tid, u_int8_t sdtr_data)
 2069 {
 2070         int orig_id;
 2071 
 2072         adv_set_bank(adv, 1);
 2073         orig_id = ffs(ADV_INB(adv, ADV_HOST_SCSIID)) - 1;
 2074         ADV_OUTB(adv, ADV_HOST_SCSIID, tid);
 2075         if (ADV_INB(adv, ADV_HOST_SCSIID) == (0x01 << tid)) {
 2076                 adv_set_bank(adv, 0);
 2077                 ADV_OUTB(adv, ADV_SYN_OFFSET, sdtr_data);
 2078         }
 2079         adv_set_bank(adv, 1);
 2080         ADV_OUTB(adv, ADV_HOST_SCSIID, orig_id);
 2081         adv_set_bank(adv, 0);
 2082 }

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