ref: e2328dc30d3c88259875dc6e6759bc2d408dfe32
dir: /os/pxa/dma.c/
#include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "../port/error.h" #include "io.h" #define DMAREGS ((Dmaregs*)PHYSDMA) typedef struct Dmadesc Dmadesc; typedef struct Dmaregs Dmaregs; struct Dmadesc { ulong ddadr; /* next descriptor address (0 mod 16) */ ulong dsadr; /* source address (0 mod 8 if external, 0 mod 4 internal) */ ulong dtadr; /* target address (same) */ ulong dcmd; /* command */ }; struct Dmaregs { ulong dcsr[16]; /* control and status */ uchar pad0[0xF0-0x40]; ulong dint; /* mask of interrupting channels: 0 is bit 0 */ uchar pad1[0x100-0xF4]; ulong drcmr[40]; Dmadesc chan[16]; /* offset 0x200 */ }; enum { /* dcsr */ DcsRun= 1<<31, /* start the channel */ DcsNodesc= 1<<30, /* set if channel is in no-descriptor fetch mode */ DcsStopirq= 1<<29, /* enable interrupt if channel is uninitialised or stopped */ DcsReqpend= 1<<8, /* channel has pending request */ DcsStopstate= 1<<3, /* channel is uninitialised or stopped */ DcsEndintr= 1<<2, /* transaction complete, length now 0 */ DcsStartintr= 1<<1, /* successful descriptor fetch */ DcsBuserr= 1<<0, /* bus error */ /* drcmr */ DmrValid= 1<<7, /* mapped to channel given by bits 0-3 */ DmrChan= 0xF, /* channel number mask */ /* ddadr */ DdaStop= 1<<1, /* =0, run channel; =1, stop channel after this descriptor */ /* dcmd */ DcmIncsrc= 1<<31, /* increment source address after use */ DcmIncdest= 1<<30, /* increment destination address after use */ DcmFlowsrc= 1<<29, /* enable flow control on source */ DcmFlowdest= 1<<28, /* enable flow control on target */ DcmStartirq= 1<<22, /* interrupt when descriptor loaded (fetch mode) */ DcmEndirq= 1<<21, /* interrupt when transfer complete */ DcmEndian= 1<<18, /* must be zero (little endian) */ DcmBurst8= 1<<16, /* burst size in bytes */ DcmBurst16= 2<<16, DcmBurst32= 3<<16, DcmWidth0= 0<<14, /* width for external memory */ DcmWidth1= 1<<14, /* width of on-chip peripheral */ DcmWidth2= 2<<14, DcmWidth4= 3<<14, DcmLength= (1<<13)-1, Ndma= 16, /* number of dma channels */ MaxDMAbytes= 8192-1, /* annoyingly small limit */ }; struct Dma { int chan; Dmadesc* desc; Dmadesc stop; ulong *csr; void (*interrupt)(void*, ulong); void* arg; Rendez r; ulong attrs; /* transfer attributes: flow control, burst size, width */ }; static struct { Lock; ulong avail; Dma dma[Ndma]; } dmachans; static void dmaintr(Ureg*, void*); void dmareset(void) { int i; Dma *d; for(i=0; i<Ndma; i++){ dmachans.avail |= 1<<i; d = &dmachans.dma[i]; d->chan = i; d->csr = &DMAREGS->dcsr[i]; d->desc = &DMAREGS->chan[i]; d->stop.ddadr = (ulong)&d->stop | DdaStop; d->stop.dcmd = 0; } intrenable(IRQ, IRQdma, dmaintr, nil, "dma"); } /* * allocate a DMA channel, reset it, and configure it for the given device */ Dma* dmasetup(int owner, void (*interrupt)(void*, ulong), void *arg, ulong attrs) { Dma *d; Dmadesc *dc; int i; ilock(&dmachans); for(i=0; (dmachans.avail & (1<<i)) == 0; i++) if(i >= Ndma){ iunlock(&dmachans); return nil; } dmachans.avail &= ~(1<<i); iunlock(&dmachans); d = &dmachans.dma[i]; d->owner = owner; d->interrupt = interrupt; d->arg = arg; d->attrs = attrs; dc = d->desc; dc->ddadr = (ulong)&d->stop | DdaStop; /* empty list */ dc->dcmd = 0; *d->csr = DcsEndintr | DcsStartintr | DcsBuserr; /* clear status, stopped */ DMAREGS->drcmr[owner] = DmrValid | i; return d; } void dmafree(Dma *dma) { dmastop(dma); DMAREGS->drcmr[d->owner] = 0; ilock(&dmachans); dmachans.avail |= 1<<dma->chan; dma->interrupt = nil; iunlock(&dmachans); } /* * simple dma transfer on a channel, using `no fetch descriptor' mode. * virtual buffer addresses are assumed to refer to contiguous physical addresses. */ int dmastart(Dma *dma, void *from, void *to, int nbytes) { Dmadesc *dc; if((ulong)nbytes > MaxDMAbytes) panic("dmastart"); if((*dma->csr & DcsStopstate) == 0) return 0; /* busy */ dc = dma->desc; dc->ddadr = DdaStop; dc->dsadr = PADDR(from); dc->dtadr = PADDR(to); dc->dcmd = dma->attrs | DcmEndirq | nbytes; *dma->csr = DcsRun | DcsNodesc | DcsEndintr | DcsStartintr | DcsBuserr; return 1; } /* * stop dma on a channel */ void dmastop(Dma *dma) { *dma->csr = 0; while((*dma->csr & DcsStopstate) == 0) ; *dma->csr = DcsStopstate; } /* * return nonzero if there was a memory error during DMA, * and clear the error state */ int dmaerror(Dma *dma) { ulong e; e = *dma->csr & DcsBuserr; *dma->csr |= e; return e; } /* * return nonzero if the DMA channel is not busy */ int dmaidle(Dma *d) { return (*d->csr & DcsStopstate) == 0; } static int dmaidlep(void *a) { return dmaidle((Dma*)a); } void dmawait(Dma *d) { while(!dmaidle(d)) sleep(&d->r, dmaidlep, d); } /* * this interface really only copes with one buffer at once */ static void dmaintr(Ureg*, void*) { Dma *d; Dmaregs *dr; int i; ulong s, csr; dr = DMAREGS; s = dr->dint; dr->dint = s; for(i=0; i<Ndma && s != 0; i++) if(s & (1<<i)){ d = &dmachans.dma[i]; csr = *d->csr; if(csr & DcsBuserr) iprint("DMA error, chan %d status #%8.8lux\n", d->chan, csr); *d->csr = csr & (DcsRun | DcsNodesc | DcsEndintr | DcsStartintr | DcsBuserr); if(d->interrupt != nil) d->interrupt(d->arg, csr); else wakeup(&d->r); } }