ref: f0f2d452c873255dec4b3359b3f93e349be0f2c5
dir: /sys/src/9/port/sdmmc.c/
/* * mmc / sd memory card * * Copyright © 2012 Richard Miller <r.miller@acm.org> * */ #include "u.h" #include "../port/lib.h" #include "../port/error.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" #include "../port/sd.h" /* Commands */ SDiocmd GO_IDLE_STATE = { 0, 0, 0, 0, "GO_IDLE_STATE" }; SDiocmd SEND_OP_COND = { 1, 3, 0, 0, "SEND_OP_COND" }; SDiocmd ALL_SEND_CID = { 2, 2, 0, 0, "ALL_SEND_CID" }; SDiocmd SET_RELATIVE_ADDR = { 3, 1, 0, 0, "SET_RELATIVE_ADDR" }; SDiocmd SEND_RELATIVE_ADDR = { 3, 6, 0, 0, "SEND_RELATIVE_ADDR" }; SDiocmd SWITCH = { 6, 1, 1, 0, "SWITCH" }; SDiocmd SWITCH_FUNC = { 6, 1, 0, 1, "SWITCH_FUNC" }; SDiocmd SELECT_CARD = { 7, 1, 1, 0, "SELECT_CARD" }; SDiocmd SEND_EXT_CSD = { 8, 1, 0, 1, "SEND_EXT_CSD" }; SDiocmd SD_SEND_IF_COND = { 8, 1, 0, 0, "SD_SEND_IF_COND" }; SDiocmd SEND_CSD = { 9, 2, 0, 0, "SEND_CSD" }; SDiocmd STOP_TRANSMISSION = {12, 1, 1, 0, "STOP_TRANSMISSION" }; SDiocmd SEND_STATUS = {13, 1, 0, 0, "SEND_STATUS" }; SDiocmd SET_BLOCKLEN = {16, 1, 0, 0, "SET_BLOCKLEN" }; SDiocmd READ_SINGLE_BLOCK = {17, 1, 0, 1, "READ_SINGLE_BLOCK" }; SDiocmd READ_MULTIPLE_BLOCK = {18, 1, 0, 3, "READ_MULTIPLE_BLOCK" }; SDiocmd WRITE_SINGLE_BLOCK = {24, 1, 0, 2, "WRITE_SINGLE_BLOCK" }; SDiocmd WRITE_MULTIPLE_BLOCK = {25, 1, 0, 4, "WRITE_MULTIPLE_BLOCK" }; /* prefix for following app-specific commands */ SDiocmd APP_CMD = {55, 1, 0, 0, "APP_CMD" }; SDiocmd SD_SET_BUS_WIDTH = { 6, 1, 0, 0, "SD_SET_BUS_WIDTH" }; SDiocmd SD_SEND_OP_COND = {41, 3, 0, 0, "SD_SEND_OP_COND" }; /* Command arguments */ enum { /* SD_SEND_IF_COND */ Voltage = 1<<8, /* Host supplied voltage range 2.7-3.6 volts*/ Checkpattern = 0x42, /* SELECT_CARD */ Rcashift = 16, /* SD_SET_BUS_WIDTH */ Width1 = 0<<0, Width4 = 2<<0, /* SWITCH_FUNC */ Dfltspeed = 0<<0, Hispeed = 1<<0, Checkfunc = 0x00FFFFF0, Setfunc = 0x80FFFFF0, Funcbytes = 64, /* SWITCH */ MMCSetSDTiming = 0x3B90000, MMCSetHSTiming = 0x3B90100, MMCSetBusWidth1 = 0x3B70000, MMCSetBusWidth4 = 0x3B70100, MMCSetBusWidth8 = 0x3B70200, /* OCR (operating conditions register) */ Powerup = 1<<31, Hcs = 1<<30, /* Host capacity support */ Ccs = 1<<30, /* Card capacity status */ V3_3 = 3<<20, /* 3.2-3.4 volts */ }; enum { Multiblock = 1, Inittimeout = 15, Initfreq = 400000, /* initialisation frequency for MMC */ SDfreq = 25000000, /* standard SD frequency */ SDfreqhs = 50000000, /* highspeed frequency */ }; typedef struct Card Card; struct Card { QLock; SDev *dev; SDio *io; int ismmc; int specver; int buswidth; int busspeed; /* SD card registers */ u32int rca; u32int ocr; u32int cid[4]; u32int csd[4]; u8int ext_csd[512]; uvlong sectors[3]; uint secsize; int retry; }; extern SDifc sdmmcifc; static SDio *sdio[8]; static int nsdio, isdio; void addmmcio(SDio *io) { assert(io != nil); assert(isdio == 0); if(nsdio >= nelem(sdio)){ print("addmmcio: out of slots for %s\n", io->name); return; } sdio[nsdio++] = io; } static SDev* init1(void) { SDev *sdev; Card *card; SDio *io; int more; if(isdio >= nsdio) return nil; if((sdev = malloc(sizeof(SDev))) == nil) return nil; if((card = malloc(sizeof(Card))) == nil){ free(sdev); return nil; } if((io = malloc(sizeof(SDio))) == nil){ free(card); free(sdev); return nil; } Next: memmove(io, sdio[isdio++], sizeof(SDio)); if(io->init != nil){ more = (*io->init)(io); if(more < 0){ if(isdio < nsdio) goto Next; free(io); free(card); free(sdev); return nil; } if(more > 0) isdio--; /* try again */ } card->dev = sdev; card->io = io; sdev->idno = 'M'; sdev->ifc = &sdmmcifc; sdev->nunit = nelem(card->sectors); sdev->ctlr = card; return sdev; } static SDev* mmcpnp(void) { SDev *list = nil, **link = &list; while((*link = init1()) != nil) link = &(*link)->next; return list; } static SDio* freecard(Card *card) { SDio *io = card->io; /* wait for retryproc() */ do { qlock(card); qunlock(card); } while(card->retry); free(card); return io; } SDio* annexsdio(char *spec) { return freecard(sdannexctlr(spec, &sdmmcifc)); } static void mmcclear(SDev *sdev) { free(freecard(sdev->ctlr)); } static void readextcsd(Card *card) { SDio *io = card->io; u32int r[4]; uchar *buf; buf = sdmalloc(512); if(waserror()){ sdfree(buf); nexterror(); } (*io->iosetup)(io, 0, buf, 512, 1); (*io->cmd)(io, &SEND_EXT_CSD, 0, r); (*io->io)(io, 0, buf, 512); memmove(card->ext_csd, buf, sizeof card->ext_csd); sdfree(buf); poperror(); } static uint rbits(u32int *p, uint start, uint len) { uint w, off, v; w = start / 32; off = start % 32; if(off == 0) v = p[w]; else v = p[w] >> off | p[w+1] << (32-off); if(len < 32) return v & ((1<<len) - 1); else return v; } static uvlong rbytes(uchar *p, uint start, uint len) { uvlong v = 0; uint i; p += start; for(i = 0; i < len; i++) v |= (uvlong)p[i] << 8*i; return v; } static void identify(Card *card) { uint csize, mult; uvlong capacity; #define CSD(end, start) rbits(card->csd, start, (end)-(start)+1) mult = CSD(49, 47); csize = CSD(73, 62); card->secsize = 1 << CSD(83, 80); card->sectors[0] = (csize+1) * (1<<(mult+2)); card->sectors[1] = 0; card->sectors[2] = 0; card->specver = 0; if(card->ismmc){ switch(CSD(125, 122)){ case 0: default: card->specver = 120; /* 1.2 */ break; case 1: card->specver = 140; /* 1.4 */ break; case 2: card->specver = 122; /* 1.22 */ break; case 3: card->specver = 300; /* 3.0 */ break; case 4: card->specver = 400; /* 4.0 */ break; } switch(CSD(127, 126)){ case 2: /* MMC CSD Version 1.2 */ case 3: /* MMC Version coded in EXT_CSD */ if(card->specver < 400) break; readextcsd(card); #define EXT_CSD(end, start) rbytes(card->ext_csd, start, (end)-(start)+1) switch((uchar)EXT_CSD(192, 192)){ case 8: card->specver = 510; /* 5.1 */ break; case 7: card->specver = 500; /* 5.0 */ break; case 6: card->specver = 450; /* 4.5/4.51 */ break; case 5: card->specver = 441; /* 4.41 */ break; case 3: card->specver = 430; /* 4.3 */ break; case 2: card->specver = 420; /* 4.2 */ break; case 1: card->specver = 410; /* 4.1 */ break; case 0: card->specver = 400; /* 4.0 */ break; } } if(card->specver >= 420) { capacity = EXT_CSD(215, 212) * 512ULL; if(capacity > 0x80000000ULL) card->sectors[0] = capacity / card->secsize; capacity = EXT_CSD(226, 226) * 0x20000ULL; card->sectors[1] = capacity / card->secsize; card->sectors[2] = capacity / card->secsize; } } else { switch(CSD(127, 126)){ case 0: /* SD Version 1.0 */ card->specver = 100; break; case 1: /* SD Version 2.0 */ card->specver = 200; csize = CSD(69, 48); capacity = (csize+1) * 0x80000ULL; card->sectors[0] = capacity / card->secsize; break; } } if(card->secsize == 1024){ card->secsize = 512; card->sectors[0] <<= 1; card->sectors[1] <<= 1; card->sectors[2] <<= 1; } } static int mmcverify(SDunit *unit) { Card *card = unit->dev->ctlr; SDio *io = card->io; int n; eqlock(card); if(waserror()){ qunlock(card); nexterror(); } n = (*io->inquiry)(io, (char*)&unit->inquiry[8], sizeof(unit->inquiry)-8); qunlock(card); poperror(); if(n < 0) return 0; unit->inquiry[0] = 0x00; /* direct access (disk) */ unit->inquiry[1] = 0x80; /* removable */ unit->inquiry[4] = sizeof(unit->inquiry)-4; return 1; } static int mmcenable(SDev* dev) { Card *card = dev->ctlr; SDio *io = card->io; (*io->enable)(io); return 1; } static void mmcswitch(Card *card, u32int arg) { SDio *io = card->io; u32int r[4]; int i; (*io->cmd)(io, &SWITCH, arg, r); for(i=0; i<10;i++){ tsleep(&up->sleep, return0, nil, 100); (*io->cmd)(io, &SEND_STATUS, card->rca<<Rcashift, r); if(r[0] & (1<<7)) error(Eio); if(r[0] & (1<<8)) return; } error(Eio); } static void sdswitchfunc(Card *card, int arg) { SDio *io = card->io; u32int r[4]; uchar *buf; int n; n = Funcbytes; buf = sdmalloc(n); if(waserror()){ sdfree(buf); nexterror(); } (*io->iosetup)(io, 0, buf, n, 1); (*io->cmd)(io, &SWITCH_FUNC, arg, r); if((arg & 0xFFFFFFF0) == Setfunc){ card->busspeed = (arg & Hispeed) != 0? SDfreqhs: SDfreq; tsleep(&up->sleep, return0, nil, 10); (*io->bus)(io, 0, card->busspeed); tsleep(&up->sleep, return0, nil, 10); } (*io->io)(io, 0, buf, n); sdfree(buf); poperror(); } static int cardinit(Card *card) { SDio *io = card->io; u32int r[4], ocr; int i; card->secsize = 0; card->sectors[0] = 0; card->sectors[1] = 0; card->sectors[2] = 0; card->buswidth = 1; card->busspeed = Initfreq; (*io->bus)(io, card->buswidth, card->busspeed); tsleep(&up->sleep, return0, nil, 10); (*io->cmd)(io, &GO_IDLE_STATE, 0, r); /* card type unknown */ card->ismmc = -1; if(!waserror()){ /* try SD card first */ ocr = V3_3; if(!waserror()){ (*io->cmd)(io, &SD_SEND_IF_COND, Voltage|Checkpattern, r); if(r[0] == (Voltage|Checkpattern)){ /* SD 2.0 or above */ ocr |= Hcs; card->ismmc = 0; /* this is SD card */ } poperror(); } for(i = 0; i < Inittimeout; i++){ tsleep(&up->sleep, return0, nil, 100); (*io->cmd)(io, &APP_CMD, 0, r); (*io->cmd)(io, &SD_SEND_OP_COND, ocr, r); if(r[0] & Powerup) break; } card->ismmc = 0; /* this is SD card */ poperror(); if(i == Inittimeout) return 2; } else if(card->ismmc) { /* try MMC if not ruled out */ (*io->cmd)(io, &GO_IDLE_STATE, 0, r); ocr = Hcs|V3_3; for(i = 0; i < Inittimeout; i++){ tsleep(&up->sleep, return0, nil, 100); (*io->cmd)(io, &SEND_OP_COND, ocr, r); if(r[0] & Powerup) break; } card->ismmc = 1; /* this is MMC */ if(i == Inittimeout) return 2; } card->ocr = r[0]; (*io->cmd)(io, &ALL_SEND_CID, 0, r); memmove(card->cid, r, sizeof card->cid); if(card->ismmc){ card->rca = 0; (*io->cmd)(io, &SET_RELATIVE_ADDR, card->rca<<16, r); } else { (*io->cmd)(io, &SEND_RELATIVE_ADDR, 0, r); card->rca = r[0]>>16; } (*io->cmd)(io, &SEND_CSD, card->rca<<Rcashift, r); memmove(card->csd, r, sizeof card->csd); return 1; } static void retryproc(void *arg) { Card *card = arg; int i = 0; qlock(card); while(waserror()) ; if(i++ < card->retry) cardinit(card); USED(i); card->retry = 0; qunlock(card); pexit("", 1); } static int mmconline(SDunit *unit) { Card *card = unit->dev->ctlr; SDio *io = card->io; u32int r[4]; if(card->retry) return 0; eqlock(card); if(waserror()){ unit->sectors = 0; if(card->retry++ == 0) kproc(unit->name, retryproc, card); qunlock(card); return 0; } if(card->secsize != 0 && card->sectors[0] != 0){ unit->secsize = card->secsize; unit->sectors = card->sectors[unit->subno]; if(unit->sectors == 0){ qunlock(card); poperror(); return 0; } (*io->cmd)(io, &SEND_STATUS, card->rca<<Rcashift, r); qunlock(card); poperror(); return 1; } if(cardinit(card) != 1){ qunlock(card); poperror(); return 2; } (*io->cmd)(io, &SELECT_CARD, card->rca<<Rcashift, r); tsleep(&up->sleep, return0, nil, 10); (*io->bus)(io, 0, card->busspeed = SDfreq); tsleep(&up->sleep, return0, nil, 10); identify(card); unit->secsize = card->secsize; unit->sectors = card->sectors[unit->subno]; (*io->cmd)(io, &SET_BLOCKLEN, card->secsize, r); if(card->ismmc && card->specver >= 400){ if(!waserror()){ mmcswitch(card, MMCSetHSTiming); (*io->bus)(io, 0, card->busspeed = SDfreqhs); tsleep(&up->sleep, return0, nil, 10); readextcsd(card); poperror(); } else { mmcswitch(card, MMCSetSDTiming); (*io->bus)(io, 0, card->busspeed = SDfreq); tsleep(&up->sleep, return0, nil, 10); readextcsd(card); } if(!waserror()){ mmcswitch(card, MMCSetBusWidth8); (*io->bus)(io, card->buswidth = 8, 0); readextcsd(card); poperror(); } else if(!waserror()){ mmcswitch(card, MMCSetBusWidth4); (*io->bus)(io, card->buswidth = 4, 0); readextcsd(card); poperror(); } else { mmcswitch(card, MMCSetBusWidth1); (*io->bus)(io, card->buswidth = 1, 0); readextcsd(card); } } else if(!card->ismmc) { (*io->cmd)(io, &APP_CMD, card->rca<<Rcashift, r); (*io->cmd)(io, &SD_SET_BUS_WIDTH, Width4, r); (*io->bus)(io, card->buswidth = 4, 0); if(!waserror()){ sdswitchfunc(card, Hispeed|Setfunc); poperror(); } } qunlock(card); poperror(); return 1; } static char* mmcrctl(SDunit *unit, char *p, char *e) { Card *card = unit->dev->ctlr; int i; if(card->sectors[0] == 0) mmconline(unit); if(unit->sectors == 0) return p; p = seprint(p, e, "version %s %d.%2.2d\n", card->ismmc? "MMC": "SD", card->specver/100, card->specver%100); p = seprint(p, e, "rca %4.4ux ocr %8.8ux", card->rca, card->ocr); p = seprint(p, e, "\ncid "); for(i = nelem(card->cid)-1; i >= 0; i--) p = seprint(p, e, "%8.8ux", card->cid[i]); p = seprint(p, e, "\ncsd "); for(i = nelem(card->csd)-1; i >= 0; i--) p = seprint(p, e, "%8.8ux", card->csd[i]); if(card->ismmc) p = seprint(p, e, "\nboot %s", ((card->ext_csd[179]>>3)&7) == (unit->subno==0? 7: unit->subno)? "enabled": "disabled" ); p = seprint(p, e, "\ngeometry %llud %ld\n", unit->sectors, unit->secsize); return p; } static long mmcbio(SDunit *unit, int lun, int write, void *data, long nb, uvlong bno) { Card *card = unit->dev->ctlr; SDio *io = card->io; int len, tries; u32int r[4]; uchar *buf; ulong b; USED(lun); if(unit->sectors == 0) error(Echange); eqlock(card); if(waserror()){ if(io->led != nil) (*io->led)(io, 0); qunlock(card); nexterror(); } if(io->led != nil) (*io->led)(io, 1); if(card->ismmc && unit->subno != (card->ext_csd[179]&7)){ b = (card->ext_csd[179] & ~7) | unit->subno; mmcswitch(card, 3<<24 | 179<<16 | b<<8); card->ext_csd[179] = b; } buf = data; len = unit->secsize; if(Multiblock && (!write || !io->nomultiwrite)){ b = bno; tries = 0; while(waserror()) if(++tries == 3) nexterror(); (*io->iosetup)(io, write, buf, len, nb); if(waserror()){ (*io->cmd)(io, &STOP_TRANSMISSION, 0, r); nexterror(); } (*io->cmd)(io, write? &WRITE_MULTIPLE_BLOCK: &READ_MULTIPLE_BLOCK, card->ocr & Ccs? b: b * len, r); (*io->io)(io, write, buf, nb * len); poperror(); (*io->cmd)(io, &STOP_TRANSMISSION, 0, r); poperror(); b += nb; }else{ for(b = bno; b < bno + nb; b++){ (*io->iosetup)(io, write, buf, len, 1); (*io->cmd)(io, write? &WRITE_SINGLE_BLOCK: &READ_SINGLE_BLOCK, card->ocr & Ccs? b: b * len, r); (*io->io)(io, write, buf, len); buf += len; } } if(io->led != nil) (*io->led)(io, 0); qunlock(card); poperror(); return (b - bno) * len; } static int mmcrio(SDreq *r) { int i, rw, count; uvlong lba; if((i = sdfakescsi(r)) != SDnostatus) return r->status = i; if((i = sdfakescsirw(r, &lba, &count, &rw)) != SDnostatus) return i; r->rlen = mmcbio(r->unit, r->lun, rw == SDwrite, r->data, count, lba); return r->status = SDok; } SDifc sdmmcifc = { .name = "mmc", .pnp = mmcpnp, .enable = mmcenable, .verify = mmcverify, .online = mmconline, .rctl = mmcrctl, .bio = mmcbio, .rio = mmcrio, .clear = mmcclear, };