/* * Intel PCIC or compatible Controller driver * May be built to make a loadable module. *------------------------------------------------------------------------- * * Copyright (c) 1995 Andrew McRae. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /* * pcic98 : PC9801 original PCMCIA controller code for NS/A,Ne,NX/C,NR/L. * by Noriyuki Hosobuchi */ #include #include #include #include #include #include #include #include #include #include #ifdef PC98 #include #endif #include #include #include #include #ifdef APIC_IO #include #endif /* * Prototypes for interrupt handler. */ static inthand2_t pcicintr; static int pcic_ioctl __P((struct slot *, int, caddr_t)); static int pcic_power __P((struct slot *)); static timeout_t pcic_reset; static void pcic_resume(struct slot *); static void pcic_disable __P((struct slot *)); static void pcic_mapirq __P((struct slot *, int)); static timeout_t pcictimeout; static struct callout_handle pcictimeout_ch = CALLOUT_HANDLE_INITIALIZER(&pcictimeout_ch); static int pcic_modevent __P((module_t, int, void *)); static int pcic_unload __P((void)); static int pcic_memory(struct slot *, int); static int pcic_io(struct slot *, int); static u_int build_freelist(u_int); /* * Per-slot data table. */ static struct pcic_slot { int slotnum; /* My slot number */ int index; /* Index register */ int data; /* Data register */ int offset; /* Offset value for index */ char controller; /* Device type */ char revision; /* Device Revision */ struct slot *slt; /* Back ptr to slot */ u_char (*getb)(struct pcic_slot *, int); void (*putb)(struct pcic_slot *, int, u_char); u_char *regs; /* Pointer to regs in mem */ } pcic_slots[PCIC_MAX_SLOTS]; static int pcic_irq; static unsigned pcic_imask; static struct slot_ctrl cinfo; /* * Internal inline functions for accessing the PCIC. */ /* * Read a register from the PCIC. */ static __inline unsigned char getb1(struct pcic_slot *sp, int reg) { outb(sp->index, sp->offset + reg); return inb(sp->data); } static __inline unsigned char getb2(struct pcic_slot *sp, int reg) { return (sp->regs[reg]); } /* * Write a register on the PCIC */ static __inline void putb1(struct pcic_slot *sp, int reg, unsigned char val) { outb(sp->index, sp->offset + reg); outb(sp->data, val); } static __inline void putb2(struct pcic_slot *sp, int reg, unsigned char val) { sp->regs[reg] = val; } /* * Clear bit(s) of a register. */ static __inline void clrb(struct pcic_slot *sp, int reg, unsigned char mask) { sp->putb(sp, reg, sp->getb(sp, reg) & ~mask); } /* * Set bit(s) of a register */ static __inline void setb(struct pcic_slot *sp, int reg, unsigned char mask) { sp->putb(sp, reg, sp->getb(sp, reg) | mask); } /* * Write a 16 bit value to 2 adjacent PCIC registers */ static __inline void putw(struct pcic_slot *sp, int reg, unsigned short word) { sp->putb(sp, reg, word & 0xFF); sp->putb(sp, reg + 1, (word >> 8) & 0xff); } /* * Gerneral functions for registering and unregistering interrupts. * isa_to_apic() is used to map the ISA IRQ onto the APIC IRQ to * check if the APIC IRQ is used or free. */ #ifdef APIC_IO int register_pcic_intr(int intr, int device_id, u_int flags, inthand2_t handler, u_int *maskptr, int unit){ int apic_intr; apic_intr = isa_apic_irq(intr); if (apic_intr <0) return -1; else return register_intr(apic_intr, device_id, flags, handler, maskptr, unit); } int unregister_pcic_intr(int intr, inthand2_t handler){ int apic_intr; apic_intr = isa_apic_irq(intr); return unregister_intr(apic_intr, handler); } #else /* Not APIC_IO */ int register_pcic_intr(int intr, int device_id, u_int flags, inthand2_t handler, u_int *maskptr, int unit){ return register_intr(intr, device_id, flags, handler, maskptr, unit); } int unregister_pcic_intr(int intr, inthand2_t handler){ return unregister_intr(intr, handler); } #endif /* APIC_IO */ /* * Loadable kernel module interface. */ /* * Module handler that processes loads and unloads. * Once the module is loaded, the probe routine * is called to install the slots (if any). */ static int pcic_modevent(module_t mod, int what, void *arg) { int err = 0; /* default = success*/ static int pcic_started = 0; switch (what) { case MOD_LOAD: /* * Call the probe routine to find the slots. If * no slots exist, then don't bother loading the module. * XXX but this is not appropriate as a static module. */ if (pcic_probe()) pcic_started = 1; break; case MOD_UNLOAD: /* * Attempt to unload the slot driver. */ if (pcic_started) { printf("Unloading PCIC driver\n"); err = pcic_unload(); pcic_started = 0; } break; /* Success*/ default: /* we only care about load/unload; ignore shutdown */ break; } return(err); } static moduledata_t pcic_mod = { "pcic", pcic_modevent, 0 }; /* After configure() has run.. bring on the new bus system! */ DECLARE_MODULE(pcic, pcic_mod, SI_SUB_CONFIGURE, SI_ORDER_MIDDLE); /* * pcic_unload - Called when unloading a LKM. * Disables interrupts and resets PCIC. */ static int pcic_unload() { int slot; struct pcic_slot *sp = pcic_slots; untimeout(pcictimeout, 0, pcictimeout_ch); if (pcic_irq) { for (slot = 0; slot < PCIC_MAX_SLOTS; slot++, sp++) { if (sp->slt) sp->putb(sp, PCIC_STAT_INT, 0); } unregister_pcic_intr(pcic_irq, pcicintr); } pccard_remove_controller(&cinfo); return(0); } #if 0 static void pcic_dump_attributes(unsigned char *scratch, int maxlen) { int i,j,k; i = 0; while (scratch[i] != 0xff && i < maxlen) { unsigned char link = scratch[i+2]; /* * Dump attribute memory */ if (scratch[i]) { printf("[%02x] ", i); for (j = 0; j < 2 * link + 4 && j < 128; j += 2) printf("%02x ", scratch[j + i]); printf("\n"); } i += 4 + 2 * link; } } #endif static void nullfunc(void *unused) { /* empty */ } static u_int build_freelist(u_int pcic_mask) { int irq; u_int mask, freemask; /* No free IRQs (yet). */ freemask = 0; /* Walk through all of the IRQ's and find any that aren't allocated. */ for (irq = 1; irq < ICU_LEN; irq++) { /* * If the PCIC controller can't generate it, don't * bother checking to see if it it's free. */ mask = 1 << irq; if (!(mask & pcic_mask)) continue; /* See if the IRQ is free. */ if (register_pcic_intr(irq, 0, 0, nullfunc, NULL, irq) == 0) { /* Give it back, but add it to the mask */ INTRMASK(freemask, mask); unregister_pcic_intr(irq, nullfunc); } } #ifdef PCIC_DEBUG printf("Freelist of IRQ's <0x%x>\n", freemask); #endif return freemask; } /* * entry point from main code to map/unmap memory context. */ static int pcic_memory(struct slot *slt, int win) { struct pcic_slot *sp = slt->cdata; struct mem_desc *mp = &slt->mem[win]; int reg = mp->window * PCIC_MEMSIZE + PCIC_MEMBASE; #ifdef PC98 if (sp->controller == PCIC_PC98) { if (mp->flags & MDF_ACTIVE) { /* slot = 0, window = 0, sys_addr = 0xda000, length = 8KB */ unsigned char x; if ((unsigned long)mp->start != 0xda000) { printf("sys_addr must be 0xda000. requested address = 0x%x\n", mp->start); return(EINVAL); } /* omajinai ??? */ outb(PCIC98_REG0, 0); x = inb(PCIC98_REG1); x &= 0xfc; x |= 0x02; outb(PCIC98_REG1, x); outw(PCIC98_REG_PAGOFS, 0); if (mp->flags & MDF_ATTR) { outb(PCIC98_REG6, inb(PCIC98_REG6) | PCIC98_ATTRMEM); }else{ outb(PCIC98_REG6, inb(PCIC98_REG6) & (~PCIC98_ATTRMEM)); } outb(PCIC98_REG_WINSEL, PCIC98_MAPWIN); #if 0 if (mp->flags & MDF_16BITS == 1) { /* 16bit */ outb(PCIC98_REG2, inb(PCIC98_REG2) & (~PCIC98_8BIT)); }else{ /* 8bit */ outb(PCIC98_REG2, inb(PCIC98_REG2) | PCIC98_8BIT); } #endif }else{ outb(PCIC98_REG_WINSEL, PCIC98_UNMAPWIN); } return 0; } #endif /* PC98 */ if (mp->flags & MDF_ACTIVE) { unsigned long sys_addr = (uintptr_t)(void *)mp->start >> 12; /* * Write the addresses, card offsets and length. * The values are all stored as the upper 12 bits of the * 24 bit address i.e everything is allocated as 4 Kb chunks. */ putw(sp, reg, sys_addr & 0xFFF); putw(sp, reg+2, (sys_addr + (mp->size >> 12) - 1) & 0xFFF); putw(sp, reg+4, ((mp->card >> 12) - sys_addr) & 0x3FFF); #if 0 printf("card offs = card_adr = 0x%x 0x%x, sys_addr = 0x%x\n", mp->card, ((mp->card >> 12) - sys_addr) & 0x3FFF, sys_addr); #endif /* * Each 16 bit register has some flags in the upper bits. */ if (mp->flags & MDF_16BITS) setb(sp, reg+1, PCIC_DATA16); if (mp->flags & MDF_ZEROWS) setb(sp, reg+1, PCIC_ZEROWS); if (mp->flags & MDF_WS0) setb(sp, reg+3, PCIC_MW0); if (mp->flags & MDF_WS1) setb(sp, reg+3, PCIC_MW1); if (mp->flags & MDF_ATTR) setb(sp, reg+5, PCIC_REG); if (mp->flags & MDF_WP) setb(sp, reg+5, PCIC_WP); #if 0 printf("Slot number %d, reg 0x%x, offs 0x%x\n", sp->slotnum, reg, sp->offset); printf("Map window to sys addr 0x%x for %d bytes, card 0x%x\n", mp->start, mp->size, mp->card); printf("regs are: 0x%02x%02x 0x%02x%02x 0x%02x%02x flags 0x%x\n", sp->getb(sp, reg), sp->getb(sp, reg+1), sp->getb(sp, reg+2), sp->getb(sp, reg+3), sp->getb(sp, reg+4), sp->getb(sp, reg+5), mp->flags); #endif /* * Enable the memory window. By experiment, we need a delay. */ setb(sp, PCIC_ADDRWINE, (1<cdata; struct io_desc *ip = &slt->io[win]; #ifdef PC98 if (sp->controller == PCIC_PC98) { unsigned char x; #if 0 if (win =! 0) { printf("pcic98:Illegal PCIC I/O window request(%d)!", win); return(EINVAL); } #endif if (ip->flags & IODF_ACTIVE) { unsigned short base; x = inb(PCIC98_REG2) & 0x0f; if (! (ip->flags & IODF_16BIT)) x |= PCIC98_8BIT; if (ip->size > 16) /* 128bytes mapping */ x |= PCIC98_MAP128; x |= PCIC98_IOMEMORY; outb(PCIC98_REG2, x); base = 0x80d0; outw(PCIC98_REG4, base); /* 98side IO base */ outw(PCIC98_REG5, ip->start); /* card side IO base */ #ifdef PCIC_DEBUG printf("pcic98: IO mapped 0x%04x(98) -> 0x%04x(Card) and width %d bytes\n", base, ip->start, ip->size); #endif ip->start = base; }else{ outb(PCIC98_REG2, inb(PCIC98_REG2) & (~PCIC98_IOMEMORY)); } return 0; } #endif switch (win) { case 0: mask = PCIC_IO0_EN; reg = PCIC_IO0; break; case 1: mask = PCIC_IO1_EN; reg = PCIC_IO1; break; default: panic("Illegal PCIC I/O window request!"); } if (ip->flags & IODF_ACTIVE) { unsigned char x, ioctlv; #ifdef PCIC_DEBUG printf("Map I/O 0x%x (size 0x%x) on Window %d\n", ip->start, ip->size, win); #endif /* PCIC_DEBUG */ putw(sp, reg, ip->start); putw(sp, reg+2, ip->start+ip->size-1); x = 0; if (ip->flags & IODF_ZEROWS) x |= PCIC_IO_0WS; if (ip->flags & IODF_WS) x |= PCIC_IO_WS; if (ip->flags & IODF_CS16) x |= PCIC_IO_CS16; if (ip->flags & IODF_16BIT) x |= PCIC_IO_16BIT; /* * Extract the current flags and merge with new flags. * Flags for window 0 in lower nybble, and in upper nybble * for window 1. */ ioctlv = sp->getb(sp, PCIC_IOCTL); DELAY(100); switch (win) { case 0: sp->putb(sp, PCIC_IOCTL, x | (ioctlv & 0xf0)); break; case 1: sp->putb(sp, PCIC_IOCTL, (x << 4) | (ioctlv & 0xf)); break; } DELAY(100); setb(sp, PCIC_ADDRWINE, mask); DELAY(100); } else { clrb(sp, PCIC_ADDRWINE, mask); DELAY(100); putw(sp, reg, 0); putw(sp, reg + 2, 0); } return(0); } /* * Look for an Intel PCIC (or compatible). * For each available slot, allocate a PC-CARD slot. */ /* * VLSI 82C146 has incompatibilities about the I/O address * of slot 1. Assume it's the only PCIC whose vendor ID is 0x84, * contact Nate Williams if incorrect. */ int pcic_probe(void) { int slotnum, validslots = 0; u_int free_irqs, desired_irq; struct slot *slt; struct pcic_slot *sp; unsigned char c; static int maybe_vlsi = 0; /* Determine the list of free interrupts */ free_irqs = build_freelist(PCIC_INT_MASK_ALLOWED); /* * Initialise controller information structure. */ cinfo.mapmem = pcic_memory; cinfo.mapio = pcic_io; cinfo.ioctl = pcic_ioctl; cinfo.power = pcic_power; cinfo.mapirq = pcic_mapirq; cinfo.reset = pcic_reset; cinfo.disable = pcic_disable; cinfo.resume = pcic_resume; cinfo.maxmem = PCIC_MEM_WIN; cinfo.maxio = PCIC_IO_WIN; cinfo.irqs = free_irqs; cinfo.imask = &pcic_imask; sp = pcic_slots; for (slotnum = 0; slotnum < PCIC_MAX_SLOTS; slotnum++, sp++) { /* * Initialise the PCIC slot table. */ sp->getb = getb1; sp->putb = putb1; if (slotnum < 4) { sp->index = PCIC_INDEX_0; sp->data = PCIC_DATA_0; sp->offset = slotnum * PCIC_SLOT_SIZE; } else { sp->index = PCIC_INDEX_1; sp->data = PCIC_DATA_1; sp->offset = (slotnum - 4) * PCIC_SLOT_SIZE; } /* * XXX - Screwed up slot 1 on the VLSI chips. According to * the Linux PCMCIA code from David Hinds, working chipsets * return 0x84 from their (correct) ID ports, while the broken * ones would need to be probed at the new offset we set after * we assume it's broken. */ if (slotnum == 1 && maybe_vlsi && sp->getb(sp, PCIC_ID_REV) != 0x84) { sp->index += 4; sp->data += 4; sp->offset = PCIC_SLOT_SIZE << 1; } /* * see if there's a PCMCIA controller here * Intel PCMCIA controllers use 0x82 and 0x83 * IBM clone chips use 0x88 and 0x89, apparently */ c = sp->getb(sp, PCIC_ID_REV); sp->revision = -1; switch(c) { /* * 82365 or clones. */ case 0x82: case 0x83: sp->controller = PCIC_I82365; sp->revision = c & 1; /* * Now check for VADEM chips. */ outb(sp->index, 0x0E); outb(sp->index, 0x37); setb(sp, 0x3A, 0x40); c = sp->getb(sp, PCIC_ID_REV); if (c & 0x08) { switch (sp->revision = c & 7) { case 1: sp->controller = PCIC_VG365; break; case 2: sp->controller = PCIC_VG465; break; case 3: sp->controller = PCIC_VG468; break; default: sp->controller = PCIC_VG469; break; } clrb(sp, 0x3A, 0x40); } /* * Check for RICOH RF5C396 PCMCIA Controller */ c = sp->getb(sp, 0x3a); if (c == 0xb2) { sp->controller = PCIC_RF5C396; } break; /* * VLSI chips. */ case 0x84: sp->controller = PCIC_VLSI; maybe_vlsi = 1; break; case 0x88: case 0x89: sp->controller = PCIC_IBM; sp->revision = c & 1; break; case 0x8a: sp->controller = PCIC_IBM_KING; sp->revision = c & 1; break; default: continue; } /* * Check for Cirrus logic chips. */ sp->putb(sp, 0x1F, 0); c = sp->getb(sp, 0x1F); if ((c & 0xC0) == 0xC0) { c = sp->getb(sp, 0x1F); if ((c & 0xC0) == 0) { if (c & 0x20) sp->controller = PCIC_PD672X; else sp->controller = PCIC_PD6710; sp->revision = 8 - ((c & 0x1F) >> 2); } } switch(sp->controller) { case PCIC_I82365: cinfo.name = "Intel 82365"; break; case PCIC_IBM: cinfo.name = "IBM PCIC"; break; case PCIC_IBM_KING: cinfo.name = "IBM KING PCMCIA Controller"; break; case PCIC_PD672X: cinfo.name = "Cirrus Logic PD672X"; break; case PCIC_PD6710: cinfo.name = "Cirrus Logic PD6710"; break; case PCIC_VG365: cinfo.name = "Vadem 365"; break; case PCIC_VG465: cinfo.name = "Vadem 465"; break; case PCIC_VG468: cinfo.name = "Vadem 468"; break; case PCIC_VG469: cinfo.name = "Vadem 469"; break; case PCIC_RF5C396: cinfo.name = "Ricoh RF5C396"; break; case PCIC_VLSI: cinfo.name = "VLSI 82C146"; break; default: cinfo.name = "Unknown!"; break; } /* * OK it seems we have a PCIC or lookalike. * Allocate a slot and initialise the data structures. */ validslots++; sp->slotnum = slotnum; slt = pccard_alloc_slot(&cinfo); if (slt == 0) continue; slt->cdata = sp; sp->slt = slt; /* * If we haven't allocated an interrupt for the controller, * then attempt to get one. */ if (pcic_irq == 0) { pcic_imask = soft_imask; /* See if the user has requested a specific IRQ */ if (getenv_int("machdep.pccard.pcic_irq", &desired_irq)) /* legal IRQ? */ if (desired_irq >= 1 && desired_irq <= ICU_LEN && (1ul << desired_irq) & free_irqs) free_irqs = 1ul << desired_irq; else /* illeagal, disable use of IRQ */ free_irqs = 0; pcic_irq = pccard_alloc_intr(free_irqs, pcicintr, 0, &pcic_imask, NULL); if (pcic_irq < 0) printf("pcic: failed to allocate IRQ\n"); else printf("pcic: controller irq %d\n", pcic_irq); } /* * Modem cards send the speaker audio (dialing noises) * to the host's speaker. Cirrus Logic PCIC chips must * enable this. There is also a Low Power Dynamic Mode bit * that claims to reduce power consumption by 30%, so * enable it and hope for the best. */ if (sp->controller == PCIC_PD672X) { setb(sp, PCIC_MISC1, PCIC_SPKR_EN); setb(sp, PCIC_MISC2, PCIC_LPDM_EN); } /* * Check for a card in this slot. */ setb(sp, PCIC_POWER, PCIC_PCPWRE| PCIC_DISRST); if ((sp->getb(sp, PCIC_STATUS) & PCIC_CD) != PCIC_CD) { slt->laststate = slt->state = empty; } else { slt->laststate = slt->state = filled; pccard_event(sp->slt, card_inserted); } /* * Assign IRQ for slot changes */ if (pcic_irq > 0) sp->putb(sp, PCIC_STAT_INT, (pcic_irq << 4) | 0xF); } #ifdef PC98 if (validslots == 0) { sp = pcic_slots; slotnum = 0; if (inb(PCIC98_REG0) != 0xff) { sp->controller = PCIC_PC98; sp->revision = 0; cinfo.name = "PC98 Original"; cinfo.maxmem = 1; cinfo.maxio = 1; /* cinfo.irqs = PCIC_INT_MASK_ALLOWED;*/ cinfo.irqs = 0x1468; validslots++; sp->slotnum = slotnum; slt = pccard_alloc_slot(&cinfo); if (slt == 0) { printf("pcic98: slt == NULL\n"); goto pcic98_probe_end; } slt->cdata = sp; sp->slt = slt; /* Check for a card in this slot */ if (inb(PCIC98_REG1) & PCIC98_CARDEXIST) { /* PCMCIA card exist */ slt->laststate = slt->state = filled; pccard_event(sp->slt, card_inserted); } else { slt->laststate = slt->state = empty; } } pcic98_probe_end: } #endif /* PC98 */ if (validslots && pcic_irq <= 0) pcictimeout_ch = timeout(pcictimeout, 0, hz/2); return(validslots); } /* * ioctl calls - Controller specific ioctls */ static int pcic_ioctl(struct slot *slt, int cmd, caddr_t data) { struct pcic_slot *sp = slt->cdata; switch(cmd) { default: return(EINVAL); /* * Get/set PCIC registers */ case PIOCGREG: ((struct pcic_reg *)data)->value = sp->getb(sp, ((struct pcic_reg *)data)->reg); break; case PIOCSREG: sp->putb(sp, ((struct pcic_reg *)data)->reg, ((struct pcic_reg *)data)->value); break; } return(0); } /* * pcic_power - Enable the power of the slot according to * the parameters in the power structure(s). */ static int pcic_power(struct slot *slt) { unsigned char reg = PCIC_DISRST|PCIC_PCPWRE; struct pcic_slot *sp = slt->cdata; switch(sp->controller) { #ifdef PC98 case PCIC_PC98: reg = inb(PCIC98_REG6) & (~PCIC98_VPP12V); switch(slt->pwr.vpp) { default: return(EINVAL); case 50: break; case 120: reg |= PCIC98_VPP12V; break; } outb(PCIC98_REG6, reg); DELAY(100*1000); reg = inb(PCIC98_REG2) & (~PCIC98_VCC3P3V); switch(slt->pwr.vcc) { default: return(EINVAL); case 33: reg |= PCIC98_VCC3P3V; break; case 50: break; } outb(PCIC98_REG2, reg); DELAY(100*1000); return (0); #endif case PCIC_PD672X: case PCIC_PD6710: case PCIC_VG365: case PCIC_VG465: case PCIC_VG468: case PCIC_VG469: case PCIC_RF5C396: case PCIC_VLSI: case PCIC_IBM_KING: switch(slt->pwr.vpp) { default: return(EINVAL); case 0: break; case 50: case 33: reg |= PCIC_VPP_5V; break; case 120: reg |= PCIC_VPP_12V; break; } switch(slt->pwr.vcc) { default: return(EINVAL); case 0: break; case 33: if (sp->controller == PCIC_IBM_KING) { reg |= PCIC_VCC_5V_KING; break; } reg |= PCIC_VCC_3V; if ((sp->controller == PCIC_VG468) || (sp->controller == PCIC_VG469) || (sp->controller == PCIC_VG465) || (sp->controller == PCIC_VG365)) setb(sp, 0x2f, 0x03) ; else setb(sp, 0x16, 0x02); break; case 50: if (sp->controller == PCIC_IBM_KING) { reg |= PCIC_VCC_5V_KING; break; } reg |= PCIC_VCC_5V; if ((sp->controller == PCIC_VG468) || (sp->controller == PCIC_VG469) || (sp->controller == PCIC_VG465) || (sp->controller == PCIC_VG365)) clrb(sp, 0x2f, 0x03) ; else clrb(sp, 0x16, 0x02); break; } break; } sp->putb(sp, PCIC_POWER, reg); DELAY(300*1000); if (slt->pwr.vcc) { reg |= PCIC_OUTENA; sp->putb(sp, PCIC_POWER, reg); DELAY(100*1000); } /* Some chips are smarter than us it seems, so if we weren't * allowed to use 5V, try 3.3 instead */ if (!(sp->getb(sp, PCIC_STATUS) & 0x40) && slt->pwr.vcc == 50) { slt->pwr.vcc = 33; slt->pwr.vpp = 0; return (pcic_power(slt)); } return(0); } /* * tell the PCIC which irq we want to use. only the following are legal: * 3, 4, 5, 7, 9, 10, 11, 12, 14, 15 */ static void pcic_mapirq(struct slot *slt, int irq) { struct pcic_slot *sp = slt->cdata; #ifdef PC98 if (sp->controller == PCIC_PC98) { unsigned char x; switch (irq) { case 3: x = PCIC98_INT0; break; case 5: x = PCIC98_INT1; break; case 6: x = PCIC98_INT2; break; case 10: x = PCIC98_INT4; break; case 12: x = PCIC98_INT5; break; case 0: /* disable */ x = PCIC98_INTDISABLE; break; default: printf("pcic98: illegal irq %d\n", irq); return; } #ifdef PCIC_DEBUG printf("pcic98: irq=%d mapped.\n", irq); #endif outb(PCIC98_REG3, x); return; } #endif if (irq == 0) clrb(sp, PCIC_INT_GEN, 0xF); else sp->putb(sp, PCIC_INT_GEN, (sp->getb(sp, PCIC_INT_GEN) & 0xF0) | irq); } /* * pcic_reset - Reset the card and enable initial power. */ static void pcic_reset(void *chan) { struct slot *slt = chan; struct pcic_slot *sp = slt->cdata; #ifdef PC98 if (sp->controller == PCIC_PC98) { outb(PCIC98_REG0, 0); outb(PCIC98_REG2, inb(PCIC98_REG2) & (~PCIC98_IOMEMORY)); outb(PCIC98_REG3, PCIC98_INTDISABLE); outb(PCIC98_REG2, inb(PCIC98_REG2) & (~PCIC98_VCC3P3V)); outb(PCIC98_REG6, inb(PCIC98_REG6) & (~PCIC98_VPP12V)); outb(PCIC98_REG1, 0); selwakeup(&slt->selp); return; } #endif switch (slt->insert_seq) { case 0: /* Something funny happended on the way to the pub... */ return; case 1: /* Assert reset */ clrb(sp, PCIC_INT_GEN, PCIC_CARDRESET); slt->insert_seq = 2; timeout(pcic_reset, (void *)slt, hz/4); return; case 2: /* Deassert it again */ setb(sp, PCIC_INT_GEN, PCIC_CARDRESET|PCIC_IOCARD); slt->insert_seq = 3; timeout(pcic_reset, (void *)slt, hz/4); return; case 3: /* Wait if card needs more time */ if (!sp->getb(sp, PCIC_STATUS) & PCIC_READY) { timeout(pcic_reset, (void *)slt, hz/10); return; } } slt->insert_seq = 0; if (sp->controller == PCIC_PD672X || sp->controller == PCIC_PD6710) { sp->putb(sp, PCIC_TIME_SETUP0, 0x1); sp->putb(sp, PCIC_TIME_CMD0, 0x6); sp->putb(sp, PCIC_TIME_RECOV0, 0x0); sp->putb(sp, PCIC_TIME_SETUP1, 1); sp->putb(sp, PCIC_TIME_CMD1, 0xf); sp->putb(sp, PCIC_TIME_RECOV1, 0); } selwakeup(&slt->selp); } /* * pcic_disable - Disable the slot. */ static void pcic_disable(struct slot *slt) { struct pcic_slot *sp = slt->cdata; #ifdef PC98 if (sp->controller == PCIC_PC98) { return; } #endif sp->putb(sp, PCIC_INT_GEN, 0); sp->putb(sp, PCIC_POWER, 0); } /* * PCIC timer. If the controller doesn't have a free IRQ to use * or if interrupt steering doesn't work, poll the controller for * insertion/removal events. */ static void pcictimeout(void *chan) { pcicintr(NULL); pcictimeout_ch = timeout(pcictimeout, 0, hz/2); } /* * PCIC Interrupt handler. * Check each slot in turn, and read the card status change * register. If this is non-zero, then a change has occurred * on this card, so send an event to the main code. */ static void pcicintr(void *unused) { int slot, s; unsigned char chg; struct pcic_slot *sp = pcic_slots; #ifdef PC98 if (sp->controller == PCIC_PC98) { slot = 0; s = splhigh(); /* Check for a card in this slot */ if (inb(PCIC98_REG1) & PCIC98_CARDEXIST) { if (sp->slt->laststate != filled) { pccard_event(sp->slt, card_inserted); } } else { if (sp->slt->laststate != empty) { pccard_event(sp->slt, card_removed); } } splx(s); return; } #endif /* PC98 */ s = splhigh(); for (slot = 0; slot < PCIC_MAX_SLOTS; slot++, sp++) if (sp->slt && (chg = sp->getb(sp, PCIC_STAT_CHG)) != 0) if (chg & PCIC_CDTCH) { if ((sp->getb(sp, PCIC_STATUS) & PCIC_CD) == PCIC_CD) { pccard_event(sp->slt, card_inserted); } else { pccard_event(sp->slt, card_removed); } } splx(s); } /* * pcic_resume - Suspend/resume support for PCIC */ static void pcic_resume(struct slot *slt) { struct pcic_slot *sp = slt->cdata; if (pcic_irq > 0) sp->putb(sp, PCIC_STAT_INT, (pcic_irq << 4) | 0xF); if (sp->controller == PCIC_PD672X) { setb(sp, PCIC_MISC1, PCIC_SPKR_EN); setb(sp, PCIC_MISC2, PCIC_LPDM_EN); } }