ref: cabbe0a84c7aae53316347185a5bdf8095bac9c8
dir: /sys/src/9/pc/dma.c/
#include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" typedef struct DMAport DMAport; typedef struct DMA DMA; typedef struct DMAxfer DMAxfer; /* * state of a dma transfer */ struct DMAxfer { ulong bpa; /* bounce buffer physical address */ void* bva; /* bounce buffer virtual address */ int blen; /* bounce buffer length */ void* va; /* virtual address destination/src */ long len; /* bytes to be transferred */ int flags; }; /* * the dma controllers. the first half of this structure specifies * the I/O ports used by the DMA controllers. */ struct DMAport { uchar addr[4]; /* current address (4 channels) */ uchar count[4]; /* current count (4 channels) */ uchar page[4]; /* page registers (4 channels) */ uchar cmd; /* command status register */ uchar req; /* request registers */ uchar sbm; /* single bit mask register */ uchar mode; /* mode register */ uchar cbp; /* clear byte pointer */ uchar mc; /* master clear */ uchar cmask; /* clear mask register */ uchar wam; /* write all mask register bit */ }; struct DMA { DMAport; int shift; Lock; DMAxfer x[4]; }; DMA dma[2] = { { 0x00, 0x02, 0x04, 0x06, 0x01, 0x03, 0x05, 0x07, 0x87, 0x83, 0x81, 0x82, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0 }, { 0xc0, 0xc4, 0xc8, 0xcc, 0xc2, 0xc6, 0xca, 0xce, 0x8f, 0x8b, 0x89, 0x8a, 0xd0, 0xd2, 0xd4, 0xd6, 0xd8, 0xda, 0xdc, 0xde, 1 }, }; extern int i8237dma; static void* i8237bva[2]; static int i8237used; /* * DMA must be in the first 16MB. This gets called early by the * initialisation routines of any devices which require DMA to ensure * the allocated bounce buffers are below the 16MB limit. */ void _i8237alloc(void) { void* bva; if(i8237dma <= 0) return; if(i8237dma > 2) i8237dma = 2; bva = xspanalloc(64*1024*i8237dma, 0, 64*1024); if(bva == nil || PADDR(bva)+64*1024*i8237dma > 16*MB){ /* * This will panic with the current * implementation of xspanalloc(). if(bva != nil) xfree(bva); */ return; } i8237bva[0] = bva; if(i8237dma == 2) i8237bva[1] = ((uchar*)i8237bva[0])+64*1024; } /* * DMA must be in the first 16MB. This gets called early by the * initialisation routines of any devices which require DMA to ensure * the allocated bounce buffers are below the 16MB limit. */ int dmainit(int chan, int maxtransfer) { DMA *dp; DMAxfer *xp; static int once; if(once == 0){ if(ioalloc(0x00, 0x10, 0, "dma") < 0 || ioalloc(0x80, 0x10, 0, "dma") < 0 || ioalloc(0xd0, 0x10, 0, "dma") < 0) panic("dmainit"); once = 1; } if(maxtransfer > 64*1024) maxtransfer = 64*1024; dp = &dma[(chan>>2)&1]; chan = chan & 3; xp = &dp->x[chan]; if(xp->bva != nil){ if(xp->blen < maxtransfer) return 1; return 0; } if(i8237used >= i8237dma || i8237bva[i8237used] == nil){ print("no i8237 DMA bounce buffer < 16MB\n"); return 1; } xp->bva = i8237bva[i8237used++]; xp->bpa = PADDR(xp->bva); xp->blen = maxtransfer; xp->len = 0; xp->flags = 0; return 0; } void* dmabva(int chan) { DMA *dp; DMAxfer *xp; dp = &dma[(chan>>2)&1]; chan = chan & 3; xp = &dp->x[chan]; return xp->bva; } int dmacount(int chan) { int retval; DMA *dp; dp = &dma[(chan>>2)&1]; chan = chan & 3; ilock(dp); retval = inb(dp->count[chan]); retval |= inb(dp->count[chan]) << 8; iunlock(dp); return ((retval<<dp->shift)+1) & 0xFFFF; } /* * setup a dma transfer. if the destination is not in kernel * memory, allocate a page for the transfer. * * we assume BIOS has set up the command register before we * are booted. * * return the updated transfer length (we can't transfer across 64k * boundaries) */ long dmasetup(int chan, void *va, long len, int flags) { DMA *dp; ulong pa; uchar mode; DMAxfer *xp; dp = &dma[(chan>>2)&1]; chan = chan & 3; xp = &dp->x[chan]; /* * if this isn't kernel memory or crossing 64k boundary or above 16 meg * use the bounce buffer. */ if((uintptr)va < KZERO || ((pa=PADDR(va))&0xFFFF0000) != ((pa+len)&0xFFFF0000) || pa >= 16*MB){ if(xp->bva == nil) return -1; if(len > xp->blen) len = xp->blen; if(!(flags & DMAREAD)) memmove(xp->bva, va, len); xp->va = va; xp->len = len; xp->flags = flags; pa = xp->bpa; } else xp->len = 0; mode = ((flags & DMAREAD) ? 0x44 : 0x48) | /* read or write */ ((flags & DMALOOP) ? 0x10 : 0) | /* auto init mode */ chan; /* * this setup must be atomic */ ilock(dp); outb(dp->mode, mode); outb(dp->page[chan], pa>>16); outb(dp->cbp, 0); /* set count & address to their first byte */ outb(dp->addr[chan], pa>>dp->shift); /* set address */ outb(dp->addr[chan], pa>>(8+dp->shift)); outb(dp->count[chan], (len>>dp->shift)-1); /* set count */ outb(dp->count[chan], ((len>>dp->shift)-1)>>8); outb(dp->sbm, chan); /* enable the channel */ iunlock(dp); return len; } int dmadone(int chan) { DMA *dp; dp = &dma[(chan>>2)&1]; chan = chan & 3; return inb(dp->cmd) & (1<<chan); } /* * this must be called after a dma has been completed. * * if a page has been allocated for the dma, * copy the data into the actual destination * and free the page. */ void dmaend(int chan) { DMA *dp; DMAxfer *xp; dp = &dma[(chan>>2)&1]; chan = chan & 3; /* * disable the channel */ ilock(dp); outb(dp->sbm, 4|chan); iunlock(dp); xp = &dp->x[chan]; if(xp->len == 0 || !(xp->flags & DMAREAD)) return; /* * copy out of temporary page */ memmove(xp->va, xp->bva, xp->len); xp->len = 0; }