#include #include #include #include #include #include #include #include #include #include #include #include #include "scsi.h" #include "wd33c93.h" #include "gvp11.h" #define CHECK_WD33C93 struct gvp11_hostdata { struct WD33C93_hostdata wh; struct gvp11_scsiregs *regs; }; static irqreturn_t gvp11_intr(int irq, void *data) { struct Scsi_Host *instance = data; struct gvp11_hostdata *hdata = shost_priv(instance); unsigned int status = hdata->regs->CNTR; unsigned long flags; if (!(status & GVP11_DMAC_INT_PENDING)) return IRQ_NONE; spin_lock_irqsave(instance->host_lock, flags); wd33c93_intr(instance); spin_unlock_irqrestore(instance->host_lock, flags); return IRQ_HANDLED; } static int gvp11_xfer_mask = 0; void gvp11_setup(char *str, int *ints) { gvp11_xfer_mask = ints[1]; } static int dma_setup(struct scsi_cmnd *cmd, int dir_in) { struct Scsi_Host *instance = cmd->device->host; struct gvp11_hostdata *hdata = shost_priv(instance); struct WD33C93_hostdata *wh = &hdata->wh; struct gvp11_scsiregs *regs = hdata->regs; unsigned short cntr = GVP11_DMAC_INT_ENABLE; unsigned long addr = virt_to_bus(cmd->SCp.ptr); int bank_mask; static int scsi_alloc_out_of_range = 0; /* use bounce buffer if the physical address is bad */ if (addr & wh->dma_xfer_mask) { wh->dma_bounce_len = (cmd->SCp.this_residual + 511) & ~0x1ff; if (!scsi_alloc_out_of_range) { wh->dma_bounce_buffer = kmalloc(wh->dma_bounce_len, GFP_KERNEL); wh->dma_buffer_pool = BUF_SCSI_ALLOCED; } if (scsi_alloc_out_of_range || !wh->dma_bounce_buffer) { wh->dma_bounce_buffer = amiga_chip_alloc(wh->dma_bounce_len, "GVP II SCSI Bounce Buffer"); if (!wh->dma_bounce_buffer) { wh->dma_bounce_len = 0; return 1; } wh->dma_buffer_pool = BUF_CHIP_ALLOCED; } /* check if the address of the bounce buffer is OK */ addr = virt_to_bus(wh->dma_bounce_buffer); if (addr & wh->dma_xfer_mask) { /* fall back to Chip RAM if address out of range */ if (wh->dma_buffer_pool == BUF_SCSI_ALLOCED) { kfree(wh->dma_bounce_buffer); scsi_alloc_out_of_range = 1; } else { amiga_chip_free(wh->dma_bounce_buffer); } wh->dma_bounce_buffer = amiga_chip_alloc(wh->dma_bounce_len, "GVP II SCSI Bounce Buffer"); if (!wh->dma_bounce_buffer) { wh->dma_bounce_len = 0; return 1; } addr = virt_to_bus(wh->dma_bounce_buffer); wh->dma_buffer_pool = BUF_CHIP_ALLOCED; } if (!dir_in) { /* copy to bounce buffer for a write */ memcpy(wh->dma_bounce_buffer, cmd->SCp.ptr, cmd->SCp.this_residual); } } /* setup dma direction */ if (!dir_in) cntr |= GVP11_DMAC_DIR_WRITE; wh->dma_dir = dir_in; regs->CNTR = cntr; /* setup DMA *physical* address */ regs->ACR = addr; if (dir_in) { /* invalidate any cache */ cache_clear(addr, cmd->SCp.this_residual); } else { /* push any dirty cache */ cache_push(addr, cmd->SCp.this_residual); } bank_mask = (~wh->dma_xfer_mask >> 18) & 0x01c0; if (bank_mask) regs->BANK = bank_mask & (addr >> 18); /* start DMA */ regs->ST_DMA = 1; /* return success */ return 0; } static void dma_stop(struct Scsi_Host *instance, struct scsi_cmnd *SCpnt, int status) { struct gvp11_hostdata *hdata = shost_priv(instance); struct WD33C93_hostdata *wh = &hdata->wh; struct gvp11_scsiregs *regs = hdata->regs; /* stop DMA */ regs->SP_DMA = 1; /* remove write bit from CONTROL bits */ regs->CNTR = GVP11_DMAC_INT_ENABLE; /* copy from a bounce buffer, if necessary */ if (status && wh->dma_bounce_buffer) { if (wh->dma_dir && SCpnt) memcpy(SCpnt->SCp.ptr, wh->dma_bounce_buffer, SCpnt->SCp.this_residual); if (wh->dma_buffer_pool == BUF_SCSI_ALLOCED) kfree(wh->dma_bounce_buffer); else amiga_chip_free(wh->dma_bounce_buffer); wh->dma_bounce_buffer = NULL; wh->dma_bounce_len = 0; } } static int gvp11_bus_reset(struct scsi_cmnd *cmd) { struct Scsi_Host *instance = cmd->device->host; /* FIXME perform bus-specific reset */ /* FIXME 2: shouldn't we no-op this function (return FAILED), and fall back to host reset function, wd33c93_host_reset ? */ spin_lock_irq(instance->host_lock); wd33c93_host_reset(cmd); spin_unlock_irq(instance->host_lock); return SUCCESS; } static struct scsi_host_template gvp11_scsi_template = { .module = THIS_MODULE, .name = "GVP Series II SCSI", .show_info = wd33c93_show_info, .write_info = wd33c93_write_info, .proc_name = "GVP11", .queuecommand = wd33c93_queuecommand, .eh_abort_handler = wd33c93_abort, .eh_bus_reset_handler = gvp11_bus_reset, .eh_host_reset_handler = wd33c93_host_reset, .can_queue = CAN_QUEUE, .this_id = 7, .sg_tablesize = SG_ALL, .cmd_per_lun = CMD_PER_LUN, .use_clustering = DISABLE_CLUSTERING }; static int check_wd33c93(struct gvp11_scsiregs *regs) { #ifdef CHECK_WD33C93 volatile unsigned char *sasr_3393, *scmd_3393; unsigned char save_sasr; unsigned char q, qq; /* * These darn GVP boards are a problem - it can be tough to tell * whether or not they include a SCSI controller. This is the * ultimate Yet-Another-GVP-Detection-Hack in that it actually * probes for a WD33c93 chip: If we find one, it's extremely * likely that this card supports SCSI, regardless of Product_ * Code, Board_Size, etc. */ /* Get pointers to the presumed register locations and save contents */ sasr_3393 = ®s->SASR; scmd_3393 = ®s->SCMD; save_sasr = *sasr_3393; /* First test the AuxStatus Reg */ q = *sasr_3393; /* read it */ if (q & 0x08) /* bit 3 should always be clear */ return -ENODEV; *sasr_3393 = WD_AUXILIARY_STATUS; /* setup indirect address */ if (*sasr_3393 == WD_AUXILIARY_STATUS) { /* shouldn't retain the write */ *sasr_3393 = save_sasr; /* Oops - restore this byte */ return -ENODEV; } if (*sasr_3393 != q) { /* should still read the same */ *sasr_3393 = save_sasr; /* Oops - restore this byte */ return -ENODEV; } if (*scmd_3393 != q) /* and so should the image at 0x1f */ return -ENODEV; /* * Ok, we probably have a wd33c93, but let's check a few other places * for good measure. Make sure that this works for both 'A and 'B * chip versions. */ *sasr_3393 = WD_SCSI_STATUS; q = *scmd_3393; *sasr_3393 = WD_SCSI_STATUS; *scmd_3393 = ~q; *sasr_3393 = WD_SCSI_STATUS; qq = *scmd_3393; *sasr_3393 = WD_SCSI_STATUS; *scmd_3393 = q; if (qq != q) /* should be read only */ return -ENODEV; *sasr_3393 = 0x1e; /* this register is unimplemented */ q = *scmd_3393; *sasr_3393 = 0x1e; *scmd_3393 = ~q; *sasr_3393 = 0x1e; qq = *scmd_3393; *sasr_3393 = 0x1e; *scmd_3393 = q; if (qq != q || qq != 0xff) /* should be read only, all 1's */ return -ENODEV; *sasr_3393 = WD_TIMEOUT_PERIOD; q = *scmd_3393; *sasr_3393 = WD_TIMEOUT_PERIOD; *scmd_3393 = ~q; *sasr_3393 = WD_TIMEOUT_PERIOD; qq = *scmd_3393; *sasr_3393 = WD_TIMEOUT_PERIOD; *scmd_3393 = q; if (qq != (~q & 0xff)) /* should be read/write */ return -ENODEV; #endif /* CHECK_WD33C93 */ return 0; } static int gvp11_probe(struct zorro_dev *z, const struct zorro_device_id *ent) { struct Scsi_Host *instance; unsigned long address; int error; unsigned int epc; unsigned int default_dma_xfer_mask; struct gvp11_hostdata *hdata; struct gvp11_scsiregs *regs; wd33c93_regs wdregs; default_dma_xfer_mask = ent->driver_data; /* * Rumors state that some GVP ram boards use the same product * code as the SCSI controllers. Therefore if the board-size * is not 64KB we assume it is a ram board and bail out. */ if (zorro_resource_len(z) != 0x10000) return -ENODEV; address = z->resource.start; if (!request_mem_region(address, 256, "wd33c93")) return -EBUSY; regs = (struct gvp11_scsiregs *)(ZTWO_VADDR(address)); error = check_wd33c93(regs); if (error) goto fail_check_or_alloc; instance = scsi_host_alloc(&gvp11_scsi_template, sizeof(struct gvp11_hostdata)); if (!instance) { error = -ENOMEM; goto fail_check_or_alloc; } instance->irq = IRQ_AMIGA_PORTS; instance->unique_id = z->slotaddr; regs->secret2 = 1; regs->secret1 = 0; regs->secret3 = 15; while (regs->CNTR & GVP11_DMAC_BUSY) ; regs->CNTR = 0; regs->BANK = 0; wdregs.SASR = ®s->SASR; wdregs.SCMD = ®s->SCMD; hdata = shost_priv(instance); if (gvp11_xfer_mask) hdata->wh.dma_xfer_mask = gvp11_xfer_mask; else hdata->wh.dma_xfer_mask = default_dma_xfer_mask; hdata->wh.no_sync = 0xff; hdata->wh.fast = 0; hdata->wh.dma_mode = CTRL_DMA; hdata->regs = regs; /* * Check for 14MHz SCSI clock */ epc = *(unsigned short *)(ZTWO_VADDR(address) + 0x8000); wd33c93_init(instance, wdregs, dma_setup, dma_stop, (epc & GVP_SCSICLKMASK) ? WD33C93_FS_8_10 : WD33C93_FS_12_15); error = request_irq(IRQ_AMIGA_PORTS, gvp11_intr, IRQF_SHARED, "GVP11 SCSI", instance); if (error) goto fail_irq; regs->CNTR = GVP11_DMAC_INT_ENABLE; error = scsi_add_host(instance, NULL); if (error) goto fail_host; zorro_set_drvdata(z, instance); scsi_scan_host(instance); return 0; fail_host: free_irq(IRQ_AMIGA_PORTS, instance); fail_irq: scsi_host_put(instance); fail_check_or_alloc: release_mem_region(address, 256); return error; } static void gvp11_remove(struct zorro_dev *z) { struct Scsi_Host *instance = zorro_get_drvdata(z); struct gvp11_hostdata *hdata = shost_priv(instance); hdata->regs->CNTR = 0; scsi_remove_host(instance); free_irq(IRQ_AMIGA_PORTS, instance); scsi_host_put(instance); release_mem_region(z->resource.start, 256); } /* * This should (hopefully) be the correct way to identify * all the different GVP SCSI controllers (except for the * SERIES I though). */ static struct zorro_device_id gvp11_zorro_tbl[] = { { ZORRO_PROD_GVP_COMBO_030_R3_SCSI, ~0x00ffffff }, { ZORRO_PROD_GVP_SERIES_II, ~0x00ffffff }, { ZORRO_PROD_GVP_GFORCE_030_SCSI, ~0x01ffffff }, { ZORRO_PROD_GVP_A530_SCSI, ~0x01ffffff }, { ZORRO_PROD_GVP_COMBO_030_R4_SCSI, ~0x01ffffff }, { ZORRO_PROD_GVP_A1291, ~0x07ffffff }, { ZORRO_PROD_GVP_GFORCE_040_SCSI_1, ~0x07ffffff }, { 0 } }; MODULE_DEVICE_TABLE(zorro, gvp11_zorro_tbl); static struct zorro_driver gvp11_driver = { .name = "gvp11", .id_table = gvp11_zorro_tbl, .probe = gvp11_probe, .remove = gvp11_remove, }; static int __init gvp11_init(void) { return zorro_register_driver(&gvp11_driver); } module_init(gvp11_init); static void __exit gvp11_exit(void) { zorro_unregister_driver(&gvp11_driver); } module_exit(gvp11_exit); MODULE_DESCRIPTION("GVP Series II SCSI"); MODULE_LICENSE("GPL");