/* $Id: sbus.c,v 1.80 1999/09/02 05:44:33 shadow Exp $ * sbus.c: SBus support routines. * * Copyright (C) 1995 David S. Miller (davem@caip.rutgers.edu) */ #include #include #include #include #include #include #include #include #include #include #include /* This file has been written to be more dynamic and a bit cleaner, * but it still needs some spring cleaning. */ struct linux_sbus *SBus_chain; static struct linux_prom_irqs irqs[PROMINTR_MAX] __initdata = { { 0 } }; static char lbuf[128]; extern void prom_sbus_ranges_init (int, struct linux_sbus *); /* Perhaps when I figure out more about the iommu we'll put a * device registration routine here that probe_sbus() calls to * setup the iommu for each Sbus. */ /* We call this for each SBus device, and fill the structure based * upon the prom device tree. We return the start of memory after * the things we have allocated. */ /* #define DEBUG_FILL */ static void __init fill_sbus_device(int nd, struct linux_sbus_device *sbus_dev) { int grrr, len; unsigned long dev_base_addr, base; sbus_dev->prom_node = nd; prom_getstring(nd, "name", lbuf, sizeof(lbuf)); strcpy(sbus_dev->prom_name, lbuf); dev_base_addr = prom_getint(nd, "address"); if(dev_base_addr != -1) sbus_dev->sbus_addr = dev_base_addr; len = prom_getproperty(nd, "reg", (void *) sbus_dev->reg_addrs, sizeof(sbus_dev->reg_addrs)); if(len == -1) goto no_regs; if(len%sizeof(struct linux_prom_registers)) { prom_printf("WHOOPS: proplen for %s was %d, need multiple of %d\n", sbus_dev->prom_name, len, (int) sizeof(struct linux_prom_registers)); panic("fill_sbus_device"); } sbus_dev->num_registers = (len/sizeof(struct linux_prom_registers)); sbus_dev->ranges_applied = 0; base = (unsigned long) sbus_dev->reg_addrs[0].phys_addr; if(base>=SUN_SBUS_BVADDR || (sparc_cpu_model != sun4c && sparc_cpu_model != sun4)) { /* Ahh, we can determine the slot and offset */ if(sparc_cpu_model == sun4u) { /* A bit tricky on the SYSIO. */ sbus_dev->slot = sbus_dev->reg_addrs[0].which_io; sbus_dev->offset = sbus_dev_offset(base); } else if (sparc_cpu_model == sun4d) { sbus_dev->slot = sbus_dev->reg_addrs[0].which_io; sbus_dev->offset = base; } else { sbus_dev->slot = sbus_dev_slot(base); sbus_dev->offset = sbus_dev_offset(base); } } else { /* Grrr, gotta do calculations to fix things up */ sbus_dev->slot = sbus_dev->reg_addrs[0].which_io; sbus_dev->offset = base; sbus_dev->reg_addrs[0].phys_addr = sbus_devaddr(sbus_dev->slot, base); for(grrr=1; grrrnum_registers; grrr++) { base = (unsigned long) sbus_dev->reg_addrs[grrr].phys_addr; sbus_dev->reg_addrs[grrr].phys_addr = sbus_devaddr(sbus_dev->slot, base); } /* That surely sucked */ } sbus_dev->sbus_addr = (unsigned long) sbus_dev->reg_addrs[0].phys_addr; if(len>(sizeof(struct linux_prom_registers)*PROMREG_MAX)) { prom_printf("WHOOPS: I got too many register addresses for %s len=%d\n", sbus_dev->prom_name, len); panic("sbus device register overflow"); } no_regs: len = prom_getproperty(nd, "address", (void *) sbus_dev->sbus_vaddrs, sizeof(sbus_dev->sbus_vaddrs)); if(len == -1) len=0; if(len&3) { prom_printf("Grrr, I didn't get a multiple of 4 proplen " "for device %s got %d\n", sbus_dev->prom_name, len); len=0; } sbus_dev->num_vaddrs = (len/4); #ifdef __sparc_v9__ len = prom_getproperty(nd, "interrupts", (void *)irqs, sizeof(irqs)); if((len == -1) || (len == 0)) { sbus_dev->irqs[0] = 0; sbus_dev->num_irqs = 0; } else { sbus_dev->num_irqs = 1; if (irqs[0].pri < 0x20) sbus_dev->irqs[0] = sbus_build_irq(sbus_dev->my_bus, irqs[0].pri + (sbus_dev->slot * 8)); else sbus_dev->irqs[0] = sbus_build_irq(sbus_dev->my_bus, irqs[0].pri); } #else len = prom_getproperty(nd, "intr", (void *)irqs, sizeof(irqs)); if (len == -1) len=0; if (len&7) { prom_printf("Grrr, I didn't get a multiple of 8 proplen for " "device %s got %d\n", sbus_dev->prom_name, len); len=0; } if (len > 4 * 8) { prom_printf("Device %s has more than 4 interrupts\n", sbus_dev->prom_name); len = 4 * 8; } sbus_dev->num_irqs=(len/8); if(sbus_dev->num_irqs == 0) sbus_dev->irqs[0]=0; else if (sparc_cpu_model != sun4d) for (len = 0; len < sbus_dev->num_irqs; len++) sbus_dev->irqs[len] = irqs[len].pri; else { extern unsigned int sun4d_build_irq(struct linux_sbus_device *sdev, int irq); for (len = 0; len < sbus_dev->num_irqs; len++) sbus_dev->irqs[len] = sun4d_build_irq(sbus_dev, irqs[len].pri); } #endif #ifdef DEBUG_FILL #ifdef __sparc_v9__ prom_printf("Found %s at SBUS slot %x offset %016lx ", sbus_dev->prom_name, sbus_dev->slot, sbus_dev->offset); if (sbus_dev->irqs[0]) prom_printf("irq %s\n", __irq_itoa(sbus_dev->irqs[0])); else prom_printf("\n"); prom_printf("Base address %016lx\n", sbus_dev->sbus_addr); #else prom_printf("Found %s at SBUS slot %x offset %08lx irq-level %d\n", sbus_dev->prom_name, sbus_dev->slot, sbus_dev->offset, sbus_dev->irqs[0]); prom_printf("Base address %08lx\n", sbus_dev->sbus_addr); #endif prom_printf("REGISTERS: Probed %d register(s)\n", sbus_dev->num_registers); for(len=0; lennum_registers; len++) #ifdef __sparc_v9__ prom_printf("Regs<%d> at address<%08lx> IO-space<%d> size<%d " "bytes, %d words>\n", (int) len, (unsigned long) sbus_dev->reg_addrs[len].phys_addr, sbus_dev->reg_addrs[len].which_io, sbus_dev->reg_addrs[len].reg_size, (sbus_dev->reg_addrs[len].reg_size/4)); #else prom_printf("Regs<%d> at address<%016lx> IO-space<%d> size<%d " "bytes, %d words>\n", (int) len, (unsigned long) sbus_dev->reg_addrs[len].phys_addr, sbus_dev->reg_addrs[len].which_io, sbus_dev->reg_addrs[len].reg_size, (sbus_dev->reg_addrs[len].reg_size/4)); #endif #endif } /* This routine gets called from whoever needs the sbus first, to scan * the SBus device tree. Currently it just prints out the devices * found on the bus and builds trees of SBUS structs and attached * devices. */ extern void iommu_init(int iommu_node, struct linux_sbus *sbus); extern void iounit_init(int sbi_node, int iounit_node, struct linux_sbus *sbus); void sun4_init(void); #ifdef CONFIG_SUN_OPENPROMIO extern int openprom_init(void); #endif #ifdef CONFIG_SUN_AUXIO extern void auxio_probe(void); #endif #ifdef CONFIG_OBP_FLASH extern int flash_init(void); #endif #ifdef CONFIG_SUN_AURORA extern int aurora_init(void); #endif #ifdef CONFIG_TADPOLE_TS102_UCTRL extern int ts102_uctrl_init(void); #endif static void __init sbus_do_child_siblings(int start_node, struct linux_sbus_device *child, struct linux_sbus *sbus) { struct linux_sbus_device *this_dev = child; int this_node = start_node; /* Child already filled in, just need to traverse siblings. */ child->child = 0; while((this_node = prom_getsibling(this_node)) != 0) { this_dev->next = kmalloc(sizeof(struct linux_sbus_device), GFP_ATOMIC); this_dev = this_dev->next; this_dev->next = 0; this_dev->my_bus = sbus; fill_sbus_device(this_node, this_dev); if(prom_getchild(this_node)) { this_dev->child = kmalloc(sizeof(struct linux_sbus_device), GFP_ATOMIC); this_dev->child->my_bus = sbus; fill_sbus_device(prom_getchild(this_node), this_dev->child); sbus_do_child_siblings(prom_getchild(this_node), this_dev->child, sbus); } else { this_dev->child = 0; } } } void __init sbus_init(void) { register int nd, this_sbus, sbus_devs, topnd, iommund; unsigned int sbus_clock; struct linux_sbus *sbus; struct linux_sbus_device *this_dev; int num_sbus = 0; /* How many did we find? */ #ifdef CONFIG_SUN4 return sun4_dvma_init(); #endif topnd = prom_getchild(prom_root_node); /* Finding the first sbus is a special case... */ iommund = 0; if(sparc_cpu_model == sun4u) { nd = prom_searchsiblings(topnd, "sbus"); if(nd == 0) { #ifdef CONFIG_PCI if (!pcibios_present()) { prom_printf("Neither SBUS nor PCI found.\n"); prom_halt(); } else { #ifdef __sparc_v9__ extern void firetruck_init(void); firetruck_init(); #endif } return; #else prom_printf("YEEE, UltraSparc sbus not found\n"); prom_halt(); #endif } } else if(sparc_cpu_model == sun4d) { if((iommund = prom_searchsiblings(topnd, "io-unit")) == 0 || (nd = prom_getchild(iommund)) == 0 || (nd = prom_searchsiblings(nd, "sbi")) == 0) { panic("sbi not found"); } } else if((nd = prom_searchsiblings(topnd, "sbus")) == 0) { if((iommund = prom_searchsiblings(topnd, "iommu")) == 0 || (nd = prom_getchild(iommund)) == 0 || (nd = prom_searchsiblings(nd, "sbus")) == 0) { #ifdef CONFIG_PCI if (!pcibios_present()) { prom_printf("Neither SBUS nor PCI found.\n"); prom_halt(); } return; #else /* No reason to run further - the data access trap will occur. */ panic("sbus not found"); #endif } } /* Ok, we've found the first one, allocate first SBus struct * and place in chain. */ sbus = SBus_chain = kmalloc(sizeof(struct linux_sbus), GFP_ATOMIC); sbus->next = 0; sbus->prom_node = nd; this_sbus=nd; if(iommund && sparc_cpu_model != sun4u && sparc_cpu_model != sun4d) iommu_init(iommund, sbus); /* Loop until we find no more SBUS's */ while(this_sbus) { /* IOMMU hides inside SBUS/SYSIO prom node on Ultra. */ if(sparc_cpu_model == sun4u) iommu_init(this_sbus, sbus); #ifndef __sparc_v9__ else if (sparc_cpu_model == sun4d) iounit_init(this_sbus, iommund, sbus); #endif printk("sbus%d: ", num_sbus); sbus_clock = prom_getint(this_sbus, "clock-frequency"); if(sbus_clock==-1) sbus_clock = (25*1000*1000); printk("Clock %d.%d MHz\n", (int) ((sbus_clock/1000)/1000), (int) (((sbus_clock/1000)%1000 != 0) ? (((sbus_clock/1000)%1000) + 1000) : 0)); prom_getstring(this_sbus, "name", lbuf, sizeof(lbuf)); lbuf[sizeof(sbus->prom_name) - 1] = 0; strcpy(sbus->prom_name, lbuf); sbus->clock_freq = sbus_clock; #ifndef __sparc_v9__ if (sparc_cpu_model == sun4d) { sbus->devid = prom_getint(iommund, "device-id"); sbus->board = prom_getint(iommund, "board#"); } #endif prom_sbus_ranges_init (iommund, sbus); sbus_devs = prom_getchild(this_sbus); sbus->devices = kmalloc(sizeof(struct linux_sbus_device), GFP_ATOMIC); this_dev = sbus->devices; this_dev->next = 0; this_dev->my_bus = sbus; fill_sbus_device(sbus_devs, this_dev); /* Should we traverse for children? */ if(prom_getchild(sbus_devs)) { /* Allocate device node */ this_dev->child = kmalloc(sizeof(struct linux_sbus_device), GFP_ATOMIC); /* Fill it */ this_dev->child->my_bus = sbus; fill_sbus_device(prom_getchild(sbus_devs), this_dev->child); sbus_do_child_siblings(prom_getchild(sbus_devs), this_dev->child, sbus); } else { this_dev->child = 0; } while((sbus_devs = prom_getsibling(sbus_devs)) != 0) { /* Allocate device node */ this_dev->next = kmalloc(sizeof(struct linux_sbus_device), GFP_ATOMIC); this_dev=this_dev->next; this_dev->next=0; /* Fill it */ this_dev->my_bus = sbus; fill_sbus_device(sbus_devs, this_dev); /* Is there a child node hanging off of us? */ if(prom_getchild(sbus_devs)) { /* Get new device struct */ this_dev->child = kmalloc(sizeof(struct linux_sbus_device), GFP_ATOMIC); /* Fill it */ this_dev->child->my_bus = sbus; fill_sbus_device(prom_getchild(sbus_devs), this_dev->child); sbus_do_child_siblings(prom_getchild(sbus_devs), this_dev->child, sbus); } else { this_dev->child = 0; } } dvma_init(sbus); num_sbus++; if(sparc_cpu_model == sun4u) { this_sbus = prom_getsibling(this_sbus); if(!this_sbus) break; this_sbus = prom_searchsiblings(this_sbus, "sbus"); } else if(sparc_cpu_model == sun4d) { iommund = prom_getsibling(iommund); if(!iommund) break; iommund = prom_searchsiblings(iommund, "io-unit"); if(!iommund) break; this_sbus = prom_searchsiblings(prom_getchild(iommund), "sbi"); } else { this_sbus = prom_getsibling(this_sbus); if(!this_sbus) break; this_sbus = prom_searchsiblings(this_sbus, "sbus"); } if(this_sbus) { sbus->next = kmalloc(sizeof(struct linux_sbus), GFP_ATOMIC); sbus = sbus->next; sbus->next = 0; sbus->prom_node = this_sbus; } else { break; } } /* while(this_sbus) */ if (sparc_cpu_model == sun4d) { extern void sun4d_init_sbi_irq(void); sun4d_init_sbi_irq(); } #ifdef __sparc_v9__ if (sparc_cpu_model == sun4u) { extern void firetruck_init(void); firetruck_init(); } #endif #ifdef CONFIG_SUN_OPENPROMIO openprom_init(); #endif #ifdef CONFIG_SUN_BPP bpp_init(); #endif #ifdef CONFIG_SUN_AUXIO if (sparc_cpu_model == sun4u) auxio_probe (); #endif #ifdef CONFIG_OBP_FLASH flash_init(); #endif #ifdef CONFIG_SUN_AURORA aurora_init(); #endif #ifdef CONFIG_TADPOLE_TS102_UCTRL ts102_uctrl_init(); #endif #ifdef __sparc_v9__ if (sparc_cpu_model == sun4u) { extern void clock_probe(void); clock_probe(); } #endif }