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[/] [or1k/] [trunk/] [linux/] [linux-2.4/] [arch/] [sparc64/] [kernel/] [central.c] - Rev 1765
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/* $Id: central.c,v 1.1.1.1 2004-04-15 01:34:31 phoenix Exp $ * central.c: Central FHC driver for Sunfire/Starfire/Wildfire. * * Copyright (C) 1997, 1999 David S. Miller (davem@redhat.com) */ #include <linux/kernel.h> #include <linux/types.h> #include <linux/string.h> #include <linux/timer.h> #include <linux/sched.h> #include <linux/delay.h> #include <linux/init.h> #include <linux/bootmem.h> #include <asm/page.h> #include <asm/fhc.h> #include <asm/starfire.h> struct linux_central *central_bus = NULL; struct linux_fhc *fhc_list = NULL; #define IS_CENTRAL_FHC(__fhc) ((__fhc) == central_bus->child) static inline unsigned long long_align(unsigned long addr) { return ((addr + (sizeof(unsigned long) - 1)) & ~(sizeof(unsigned long) - 1)); } static void central_ranges_init(int cnode, struct linux_central *central) { int success; central->num_central_ranges = 0; success = prom_getproperty(central->prom_node, "ranges", (char *) central->central_ranges, sizeof (central->central_ranges)); if (success != -1) central->num_central_ranges = (success/sizeof(struct linux_prom_ranges)); } static void fhc_ranges_init(int fnode, struct linux_fhc *fhc) { int success; fhc->num_fhc_ranges = 0; success = prom_getproperty(fhc->prom_node, "ranges", (char *) fhc->fhc_ranges, sizeof (fhc->fhc_ranges)); if (success != -1) fhc->num_fhc_ranges = (success/sizeof(struct linux_prom_ranges)); } /* Range application routines are exported to various drivers, * so do not __init this. */ static void adjust_regs(struct linux_prom_registers *regp, int nregs, struct linux_prom_ranges *rangep, int nranges) { int regc, rngc; for (regc = 0; regc < nregs; regc++) { for (rngc = 0; rngc < nranges; rngc++) if (regp[regc].which_io == rangep[rngc].ot_child_space) break; /* Fount it */ if (rngc == nranges) /* oops */ prom_printf("adjust_regs: Could not find range with matching bus type...\n"); regp[regc].which_io = rangep[rngc].ot_parent_space; regp[regc].phys_addr -= rangep[rngc].ot_child_base; regp[regc].phys_addr += rangep[rngc].ot_parent_base; } } /* Apply probed fhc ranges to registers passed, if no ranges return. */ void apply_fhc_ranges(struct linux_fhc *fhc, struct linux_prom_registers *regs, int nregs) { if(fhc->num_fhc_ranges) adjust_regs(regs, nregs, fhc->fhc_ranges, fhc->num_fhc_ranges); } /* Apply probed central ranges to registers passed, if no ranges return. */ void apply_central_ranges(struct linux_central *central, struct linux_prom_registers *regs, int nregs) { if(central->num_central_ranges) adjust_regs(regs, nregs, central->central_ranges, central->num_central_ranges); } void * __init central_alloc_bootmem(unsigned long size) { void *ret; ret = __alloc_bootmem(size, SMP_CACHE_BYTES, 0UL); if (ret != NULL) memset(ret, 0, size); return ret; } static void probe_other_fhcs(void) { struct linux_prom64_registers fpregs[6]; char namebuf[128]; int node; node = prom_getchild(prom_root_node); node = prom_searchsiblings(node, "fhc"); if (node == 0) { prom_printf("FHC: Cannot find any toplevel firehose controllers.\n"); prom_halt(); } while(node) { struct linux_fhc *fhc; int board; u32 tmp; fhc = (struct linux_fhc *) central_alloc_bootmem(sizeof(struct linux_fhc)); if (fhc == NULL) { prom_printf("probe_other_fhcs: Cannot alloc fhc.\n"); prom_halt(); } /* Link it into the FHC chain. */ fhc->next = fhc_list; fhc_list = fhc; /* Toplevel FHCs have no parent. */ fhc->parent = NULL; fhc->prom_node = node; prom_getstring(node, "name", namebuf, sizeof(namebuf)); strcpy(fhc->prom_name, namebuf); fhc_ranges_init(node, fhc); /* Non-central FHC's have 64-bit OBP format registers. */ if(prom_getproperty(node, "reg", (char *)&fpregs[0], sizeof(fpregs)) == -1) { prom_printf("FHC: Fatal error, cannot get fhc regs.\n"); prom_halt(); } /* Only central FHC needs special ranges applied. */ fhc->fhc_regs.pregs = fpregs[0].phys_addr; fhc->fhc_regs.ireg = fpregs[1].phys_addr; fhc->fhc_regs.ffregs = fpregs[2].phys_addr; fhc->fhc_regs.sregs = fpregs[3].phys_addr; fhc->fhc_regs.uregs = fpregs[4].phys_addr; fhc->fhc_regs.tregs = fpregs[5].phys_addr; board = prom_getintdefault(node, "board#", -1); fhc->board = board; tmp = upa_readl(fhc->fhc_regs.pregs + FHC_PREGS_JCTRL); if((tmp & FHC_JTAG_CTRL_MENAB) != 0) fhc->jtag_master = 1; else fhc->jtag_master = 0; tmp = upa_readl(fhc->fhc_regs.pregs + FHC_PREGS_ID); printk("FHC(board %d): Version[%x] PartID[%x] Manuf[%x] %s\n", board, (tmp & FHC_ID_VERS) >> 28, (tmp & FHC_ID_PARTID) >> 12, (tmp & FHC_ID_MANUF) >> 1, (fhc->jtag_master ? "(JTAG Master)" : "")); /* This bit must be set in all non-central FHC's in * the system. When it is clear, this identifies * the central board. */ tmp = upa_readl(fhc->fhc_regs.pregs + FHC_PREGS_CTRL); tmp |= FHC_CONTROL_IXIST; upa_writel(tmp, fhc->fhc_regs.pregs + FHC_PREGS_CTRL); /* Look for the next FHC. */ node = prom_getsibling(node); if(node == 0) break; node = prom_searchsiblings(node, "fhc"); if(node == 0) break; } } static void probe_clock_board(struct linux_central *central, struct linux_fhc *fhc, int cnode, int fnode) { struct linux_prom_registers cregs[3]; int clknode, nslots, tmp, nregs; clknode = prom_searchsiblings(prom_getchild(fnode), "clock-board"); if(clknode == 0 || clknode == -1) { prom_printf("Critical error, central lacks clock-board.\n"); prom_halt(); } nregs = prom_getproperty(clknode, "reg", (char *)&cregs[0], sizeof(cregs)); if (nregs == -1) { prom_printf("CENTRAL: Fatal error, cannot map clock-board regs.\n"); prom_halt(); } nregs /= sizeof(struct linux_prom_registers); apply_fhc_ranges(fhc, &cregs[0], nregs); apply_central_ranges(central, &cregs[0], nregs); central->cfreg = ((((unsigned long)cregs[0].which_io) << 32UL) | ((unsigned long)cregs[0].phys_addr)); central->clkregs = ((((unsigned long)cregs[1].which_io) << 32UL) | ((unsigned long)cregs[1].phys_addr)); if(nregs == 2) central->clkver = 0UL; else central->clkver = ((((unsigned long)cregs[2].which_io) << 32UL) | ((unsigned long)cregs[2].phys_addr)); tmp = upa_readb(central->clkregs + CLOCK_STAT1); tmp &= 0xc0; switch(tmp) { case 0x40: nslots = 16; break; case 0xc0: nslots = 8; break; case 0x80: if(central->clkver != 0UL && upa_readb(central->clkver) != 0) { if((upa_readb(central->clkver) & 0x80) != 0) nslots = 4; else nslots = 5; break; } default: nslots = 4; break; }; central->slots = nslots; printk("CENTRAL: Detected %d slot Enterprise system. cfreg[%02x] cver[%02x]\n", central->slots, upa_readb(central->cfreg), (central->clkver ? upa_readb(central->clkver) : 0x00)); } static void init_all_fhc_hw(void) { struct linux_fhc *fhc; for(fhc = fhc_list; fhc != NULL; fhc = fhc->next) { u32 tmp; /* Clear all of the interrupt mapping registers * just in case OBP left them in a foul state. */ #define ZAP(ICLR, IMAP) \ do { u32 imap_tmp; \ upa_writel(0, (ICLR)); \ upa_readl(ICLR); \ imap_tmp = upa_readl(IMAP); \ imap_tmp &= ~(0x80000000); \ upa_writel(imap_tmp, (IMAP)); \ upa_readl(IMAP); \ } while (0) ZAP(fhc->fhc_regs.ffregs + FHC_FFREGS_ICLR, fhc->fhc_regs.ffregs + FHC_FFREGS_IMAP); ZAP(fhc->fhc_regs.sregs + FHC_SREGS_ICLR, fhc->fhc_regs.sregs + FHC_SREGS_IMAP); ZAP(fhc->fhc_regs.uregs + FHC_UREGS_ICLR, fhc->fhc_regs.uregs + FHC_UREGS_IMAP); ZAP(fhc->fhc_regs.tregs + FHC_TREGS_ICLR, fhc->fhc_regs.tregs + FHC_TREGS_IMAP); #undef ZAP /* Setup FHC control register. */ tmp = upa_readl(fhc->fhc_regs.pregs + FHC_PREGS_CTRL); /* All non-central boards have this bit set. */ if(! IS_CENTRAL_FHC(fhc)) tmp |= FHC_CONTROL_IXIST; /* For all FHCs, clear the firmware synchronization * line and both low power mode enables. */ tmp &= ~(FHC_CONTROL_AOFF | FHC_CONTROL_BOFF | FHC_CONTROL_SLINE); upa_writel(tmp, fhc->fhc_regs.pregs + FHC_PREGS_CTRL); upa_readl(fhc->fhc_regs.pregs + FHC_PREGS_CTRL); } } void central_probe(void) { struct linux_prom_registers fpregs[6]; struct linux_fhc *fhc; char namebuf[128]; int cnode, fnode, err; cnode = prom_finddevice("/central"); if(cnode == 0 || cnode == -1) { if (this_is_starfire) starfire_cpu_setup(); return; } /* Ok we got one, grab some memory for software state. */ central_bus = (struct linux_central *) central_alloc_bootmem(sizeof(struct linux_central)); if (central_bus == NULL) { prom_printf("central_probe: Cannot alloc central_bus.\n"); prom_halt(); } fhc = (struct linux_fhc *) central_alloc_bootmem(sizeof(struct linux_fhc)); if (fhc == NULL) { prom_printf("central_probe: Cannot alloc central fhc.\n"); prom_halt(); } /* First init central. */ central_bus->child = fhc; central_bus->prom_node = cnode; prom_getstring(cnode, "name", namebuf, sizeof(namebuf)); strcpy(central_bus->prom_name, namebuf); central_ranges_init(cnode, central_bus); /* And then central's FHC. */ fhc->next = fhc_list; fhc_list = fhc; fhc->parent = central_bus; fnode = prom_searchsiblings(prom_getchild(cnode), "fhc"); if(fnode == 0 || fnode == -1) { prom_printf("Critical error, central board lacks fhc.\n"); prom_halt(); } fhc->prom_node = fnode; prom_getstring(fnode, "name", namebuf, sizeof(namebuf)); strcpy(fhc->prom_name, namebuf); fhc_ranges_init(fnode, fhc); /* Now, map in FHC register set. */ if (prom_getproperty(fnode, "reg", (char *)&fpregs[0], sizeof(fpregs)) == -1) { prom_printf("CENTRAL: Fatal error, cannot get fhc regs.\n"); prom_halt(); } apply_central_ranges(central_bus, &fpregs[0], 6); fhc->fhc_regs.pregs = ((((unsigned long)fpregs[0].which_io)<<32UL) | ((unsigned long)fpregs[0].phys_addr)); fhc->fhc_regs.ireg = ((((unsigned long)fpregs[1].which_io)<<32UL) | ((unsigned long)fpregs[1].phys_addr)); fhc->fhc_regs.ffregs = ((((unsigned long)fpregs[2].which_io)<<32UL) | ((unsigned long)fpregs[2].phys_addr)); fhc->fhc_regs.sregs = ((((unsigned long)fpregs[3].which_io)<<32UL) | ((unsigned long)fpregs[3].phys_addr)); fhc->fhc_regs.uregs = ((((unsigned long)fpregs[4].which_io)<<32UL) | ((unsigned long)fpregs[4].phys_addr)); fhc->fhc_regs.tregs = ((((unsigned long)fpregs[5].which_io)<<32UL) | ((unsigned long)fpregs[5].phys_addr)); /* Obtain board number from board status register, Central's * FHC lacks "board#" property. */ err = upa_readl(fhc->fhc_regs.pregs + FHC_PREGS_BSR); fhc->board = (((err >> 16) & 0x01) | ((err >> 12) & 0x0e)); fhc->jtag_master = 0; /* Attach the clock board registers for CENTRAL. */ probe_clock_board(central_bus, fhc, cnode, fnode); err = upa_readl(fhc->fhc_regs.pregs + FHC_PREGS_ID); printk("FHC(board %d): Version[%x] PartID[%x] Manuf[%x] (CENTRAL)\n", fhc->board, ((err & FHC_ID_VERS) >> 28), ((err & FHC_ID_PARTID) >> 12), ((err & FHC_ID_MANUF) >> 1)); probe_other_fhcs(); init_all_fhc_hw(); } static __inline__ void fhc_ledblink(struct linux_fhc *fhc, int on) { u32 tmp; tmp = upa_readl(fhc->fhc_regs.pregs + FHC_PREGS_CTRL); /* NOTE: reverse logic on this bit */ if (on) tmp &= ~(FHC_CONTROL_RLED); else tmp |= FHC_CONTROL_RLED; tmp &= ~(FHC_CONTROL_AOFF | FHC_CONTROL_BOFF | FHC_CONTROL_SLINE); upa_writel(tmp, fhc->fhc_regs.pregs + FHC_PREGS_CTRL); upa_readl(fhc->fhc_regs.pregs + FHC_PREGS_CTRL); } static __inline__ void central_ledblink(struct linux_central *central, int on) { u8 tmp; tmp = upa_readb(central->clkregs + CLOCK_CTRL); /* NOTE: reverse logic on this bit */ if(on) tmp &= ~(CLOCK_CTRL_RLED); else tmp |= CLOCK_CTRL_RLED; upa_writeb(tmp, central->clkregs + CLOCK_CTRL); upa_readb(central->clkregs + CLOCK_CTRL); } static struct timer_list sftimer; static int led_state; static void sunfire_timer(unsigned long __ignored) { struct linux_fhc *fhc; central_ledblink(central_bus, led_state); for(fhc = fhc_list; fhc != NULL; fhc = fhc->next) if(! IS_CENTRAL_FHC(fhc)) fhc_ledblink(fhc, led_state); led_state = ! led_state; sftimer.expires = jiffies + (HZ >> 1); add_timer(&sftimer); } /* After PCI/SBUS busses have been probed, this is called to perform * final initialization of all FireHose Controllers in the system. */ void firetruck_init(void) { struct linux_central *central = central_bus; u8 ctrl; /* No central bus, nothing to do. */ if (central == NULL) return; /* OBP leaves it on, turn it off so clock board timer LED * is in sync with FHC ones. */ ctrl = upa_readb(central->clkregs + CLOCK_CTRL); ctrl &= ~(CLOCK_CTRL_RLED); upa_writeb(ctrl, central->clkregs + CLOCK_CTRL); led_state = 0; init_timer(&sftimer); sftimer.data = 0; sftimer.function = &sunfire_timer; sftimer.expires = jiffies + (HZ >> 1); add_timer(&sftimer); }