ref: a15863b8ae23a26a2f825daf6107ab92e53c2669
dir: /sys/src/9/bcm64/sdhc.c/
/* * bcm2711 sd host controller * * Copyright © 2012,2019 Richard Miller <r.miller@acm.org> * * adapted from emmc.c - the two should really be merged */ #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" #define SDHCREGS (VIRTIO+0x340000) enum { Extfreq = 100*Mhz, /* guess external clock frequency if */ }; enum { /* Controller registers */ SDMAaddr = 0x00>>2, Blksizecnt = 0x04>>2, Arg1 = 0x08>>2, Cmdtm = 0x0c>>2, Resp0 = 0x10>>2, Resp1 = 0x14>>2, Resp2 = 0x18>>2, Resp3 = 0x1c>>2, Data = 0x20>>2, Status = 0x24>>2, Control0 = 0x28>>2, Control1 = 0x2c>>2, Interrupt = 0x30>>2, Irptmask = 0x34>>2, Irpten = 0x38>>2, Control2 = 0x3c>>2, Capability = 0x40>>2, Forceirpt = 0x50>>2, Dmadesc = 0x58>>2, Boottimeout = 0x70>>2, Dbgsel = 0x74>>2, Exrdfifocfg = 0x80>>2, Exrdfifoen = 0x84>>2, Tunestep = 0x88>>2, Tunestepsstd = 0x8c>>2, Tunestepsddr = 0x90>>2, Spiintspt = 0xf0>>2, Slotisrver = 0xfc>>2, /* Control0 */ Busvoltage = 7<<9, V1_8 = 5<<9, V3_0 = 6<<9, V3_3 = 7<<9, Buspower = 1<<8, Dwidth8 = 1<<5, Dmaselect = 3<<3, DmaSDMA = 0<<3, DmaADMA1 = 1<<3, DmaADMA2 = 2<<3, Hispeed = 1<<2, Dwidth4 = 1<<1, Dwidth1 = 0<<1, DwidthMask = Dwidth4|Dwidth8, LED = 1<<0, /* Control1 */ Srstdata = 1<<26, /* reset data circuit */ Srstcmd = 1<<25, /* reset command circuit */ Srsthc = 1<<24, /* reset complete host controller */ Datatoshift = 16, /* data timeout unit exponent */ DTO = 14, /* data timeout exponent (guesswork) */ Datatomask = 0xF0000, Clkfreq8shift = 8, /* SD clock base divider LSBs */ Clkfreq8mask = 0xFF00, Clkfreqms2shift = 6, /* SD clock base divider MSBs */ Clkfreqms2mask = 0xC0, Clkgendiv = 0<<5, /* SD clock divided */ Clkgenprog = 1<<5, /* SD clock programmable */ Clken = 1<<2, /* SD clock enable */ Clkstable = 1<<1, Clkintlen = 1<<0, /* enable internal EMMC clocks */ /* Cmdtm */ Indexshift = 24, Suspend = 1<<22, Resume = 2<<22, Abort = 3<<22, Isdata = 1<<21, Ixchken = 1<<20, Crcchken = 1<<19, Respmask = 3<<16, Respnone = 0<<16, Resp136 = 1<<16, Resp48 = 2<<16, Resp48busy = 3<<16, Multiblock = 1<<5, Host2card = 0<<4, Card2host = 1<<4, Autocmd12 = 1<<2, Autocmd23 = 2<<2, Blkcnten = 1<<1, Dmaen = 1<<0, /* Interrupt */ Admaerr = 1<<25, Acmderr = 1<<24, Denderr = 1<<22, Dcrcerr = 1<<21, Dtoerr = 1<<20, Cbaderr = 1<<19, Cenderr = 1<<18, Ccrcerr = 1<<17, Ctoerr = 1<<16, Err = 1<<15, Cardintr = 1<<8, Cardinsert = 1<<6, /* not in Broadcom datasheet */ Readrdy = 1<<5, Writerdy = 1<<4, Dmaintr = 1<<3, Datadone = 1<<1, Cmddone = 1<<0, /* Status */ Bufread = 1<<11, /* not in Broadcom datasheet */ Bufwrite = 1<<10, /* not in Broadcom datasheet */ Readtrans = 1<<9, Writetrans = 1<<8, Datactive = 1<<2, Datinhibit = 1<<1, Cmdinhibit = 1<<0, }; /* * ADMA2 descriptor * See SD Host Controller Simplified Specification Version 2.00 */ typedef struct Adma Adma; struct Adma { u32int desc; u32int addr; }; enum { /* desc fields */ Valid = 1<<0, End = 1<<1, Int = 1<<2, Nop = 0<<4, Tran = 2<<4, Link = 3<<4, OLength = 16, /* maximum value for Length field */ Maxdma = ((1<<16) - 4), }; typedef struct Ctlr Ctlr; struct Ctlr { Rendez r; ulong extclk; Adma *dma; uintptr busdram; }; static Ctlr sdhc; static void sdhcinterrupt(Ureg*, void*); static void WR(int reg, u32int val) { u32int *r = (u32int*)SDHCREGS; if(0)print("WR %2.2ux %ux\n", reg<<2, val); coherence(); r[reg] = val; } static uint clkdiv(uint d) { uint v; assert(d < 1<<10); v = (d << Clkfreq8shift) & Clkfreq8mask; v |= ((d >> 8) << Clkfreqms2shift) & Clkfreqms2mask; return v; } static Adma* dmaalloc(void *addr, int len) { int n; uintptr a; Adma *adma, *p; a = (uintptr)addr; n = (len + Maxdma-1) / Maxdma; adma = sdmalloc(n * sizeof(Adma)); for(p = adma; len > 0; p++){ p->desc = Valid | Tran; if(n == 1) p->desc |= len<<OLength | End | Int; else p->desc |= Maxdma<<OLength; p->addr = sdhc.busdram + (PADDR(a) - PHYSDRAM); a += Maxdma; len -= Maxdma; n--; } cachedwbse(adma, (char*)p - (char*)adma); return adma; } static void sdhcclk(uint freq) { u32int *r = (u32int*)SDHCREGS; uint div; int i; div = sdhc.extclk / (freq<<1); if(sdhc.extclk / (div<<1) > freq) div++; WR(Control1, clkdiv(div) | DTO<<Datatoshift | Clkgendiv | Clken | Clkintlen); for(i = 0; i < 1000; i++){ delay(1); if(r[Control1] & Clkstable) break; } if(i == 1000) print("sdhc: can't set clock to %ud\n", freq); } static void sdhcbus(SDio*, int width, int speed) { u32int *r = (u32int*)SDHCREGS; switch(width){ case 1: WR(Control0, (r[Control0] & ~DwidthMask) | Dwidth1); break; case 4: WR(Control0, (r[Control0] & ~DwidthMask) | Dwidth4); break; case 8: WR(Control0, (r[Control0] & ~DwidthMask) | Dwidth8); break; } if(speed) sdhcclk(speed); } static int datadone(void*) { u32int *r = (u32int*)SDHCREGS; int i; i = r[Interrupt]; return i & (Datadone|Err); } static int sdhcinit(SDio *io) { u32int *r = (u32int*)SDHCREGS; ulong clk; char *s; sdhc.busdram = soc.busdram; if((s = getconf("*emmc2bus")) != nil) sdhc.busdram = strtoull(s, nil, 16); clk = getclkrate(ClkEmmc2); if(clk == 0){ clk = Extfreq; print("%s: assuming external clock %lud Mhz\n", io->name, clk/1000000); } sdhc.extclk = clk; if(0)print("sdhc control %8.8ux %8.8ux %8.8ux\n", r[Control0], r[Control1], r[Control2]); WR(Control1, Srsthc); delay(10); while(r[Control1] & Srsthc) ; WR(Control1, Srstdata); delay(10); WR(Control1, 0); return 0; } static int sdhcinquiry(SDio *, char *inquiry, int inqlen) { u32int *r = (u32int*)SDHCREGS; uint ver; ver = r[Slotisrver] >> 16; return snprint(inquiry, inqlen, "BCM SD Host Controller %2.2x Version %2.2x", ver&0xFF, ver>>8); } static void sdhcenable(SDio *io) { WR(Control0, 0); delay(1); WR(Control0, V3_3 | Buspower | Dwidth1 | DmaADMA2); WR(Control1, 0); delay(1); sdhcclk(400000); WR(Irpten, 0); WR(Irptmask, ~(Cardintr|Dmaintr)); WR(Interrupt, ~0); intrenable(IRQmmc, sdhcinterrupt, nil, BUSUNKNOWN, io->name); } static int sdhccmd(SDio*, SDiocmd *cmd, u32int arg, u32int *resp) { u32int *r = (u32int*)SDHCREGS; u32int c; int i; ulong now; c = (u32int)cmd->index << Indexshift; switch(cmd->resp){ case 0: c |= Respnone; break; case 1: if(cmd->busy){ c |= Resp48busy | Ixchken | Crcchken; break; } default: c |= Resp48 | Ixchken | Crcchken; break; case 2: c |= Resp136 | Crcchken; break; case 3: c |= Resp48; break; } if(cmd->data){ if(cmd->data & 1) c |= Isdata | Card2host | Dmaen; else c |= Isdata | Host2card | Dmaen; if(cmd->data > 2) c |= Multiblock | Blkcnten; } if(r[Status] & Cmdinhibit){ print("sdhccmd: need to reset Cmdinhibit intr %ux stat %ux\n", r[Interrupt], r[Status]); WR(Control1, r[Control1] | Srstcmd); while(r[Control1] & Srstcmd) ; while(r[Status] & Cmdinhibit) ; } if((r[Status] & Datinhibit) && ((c & Isdata) || (c & Respmask) == Resp48busy)){ print("sdhccmd: need to reset Datinhibit intr %ux stat %ux\n", r[Interrupt], r[Status]); WR(Control1, r[Control1] | Srstdata); while(r[Control1] & Srstdata) ; while(r[Status] & Datinhibit) ; } WR(Arg1, arg); if((i = (r[Interrupt] & ~Cardintr)) != 0){ if(i != Cardinsert) print("sdhc: before command, intr was %ux\n", i); WR(Interrupt, i); } WR(Cmdtm, c); now = MACHP(0)->ticks; while(((i=r[Interrupt])&(Cmddone|Err)) == 0) if(MACHP(0)->ticks - now > HZ) break; if((i&(Cmddone|Err)) != Cmddone){ if((i&~(Err|Cardintr)) != Ctoerr) print("sdhc: %s cmd %ux arg %ux error intr %ux stat %ux\n", cmd->name, c, arg, i, r[Status]); WR(Interrupt, i); if(r[Status]&Cmdinhibit){ WR(Control1, r[Control1]|Srstcmd); while(r[Control1]&Srstcmd) ; } error(Eio); } WR(Interrupt, i & ~(Datadone|Readrdy|Writerdy)); switch(c & Respmask){ case Resp136: resp[0] = r[Resp0]<<8; resp[1] = r[Resp0]>>24 | r[Resp1]<<8; resp[2] = r[Resp1]>>24 | r[Resp2]<<8; resp[3] = r[Resp2]>>24 | r[Resp3]<<8; break; case Resp48: case Resp48busy: resp[0] = r[Resp0]; break; case Respnone: resp[0] = 0; break; } if((c & Respmask) == Resp48busy){ WR(Irpten, r[Irpten]|Datadone|Err); tsleep(&sdhc.r, datadone, 0, 3000); i = r[Interrupt]; if((i & Datadone) == 0) print("sdhcio: no Datadone after %s\n", cmd->name); if(i & Err) print("sdhcio: %s error interrupt %ux\n", cmd->name, r[Interrupt]); WR(Interrupt, i); } return 0; } static void sdhciosetup(SDio*, int write, void *buf, int bsize, int bcount) { int len; len = bsize * bcount; assert(((uintptr)buf&3) == 0); assert((len&3) == 0); assert(bsize <= 2048); WR(Blksizecnt, bcount<<16 | bsize); if(sdhc.dma) sdfree(sdhc.dma); sdhc.dma = dmaalloc(buf, len); if(write) cachedwbse(buf, len); else cachedwbinvse(buf, len); WR(Dmadesc, sdhc.busdram + (PADDR(sdhc.dma) - PHYSDRAM)); okay(1); } static void sdhcio(SDio*, int write, uchar *buf, int len) { u32int *r = (u32int*)SDHCREGS; int i; if(waserror()){ okay(0); nexterror(); } WR(Irpten, r[Irpten] | Datadone|Err); tsleep(&sdhc.r, datadone, 0, 3000); WR(Irpten, r[Irpten] & ~(Datadone|Err)); i = r[Interrupt]; if((i & (Datadone|Err)) != Datadone){ print("sdhc: %s error intr %ux stat %ux\n", write? "write" : "read", i, r[Status]); WR(Interrupt, i); error(Eio); } WR(Interrupt, i); if(!write) cachedinvse(buf, len); poperror(); okay(0); } static void sdhcinterrupt(Ureg*, void*) { u32int *r = (u32int*)SDHCREGS; int i; i = r[Interrupt]; if(i&(Datadone|Err)) wakeup(&sdhc.r); WR(Irpten, r[Irpten] & ~i); } void sdhclink(void) { static SDio io = { "sdhc", sdhcinit, sdhcenable, sdhcinquiry, sdhccmd, sdhciosetup, sdhcio, sdhcbus, }; addmmcio(&io); }