/* $NetBSD: nextdma.c,v 1.50 2017/03/31 08:38:13 msaitoh Exp $ */ /* * Copyright (c) 1998 Darrin B. Jewell * 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. * * 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. */ #include __KERNEL_RCSID(0, "$NetBSD: nextdma.c,v 1.50 2017/03/31 08:38:13 msaitoh Exp $"); #include #include #include #include #include #include #include #include #include #define _M68K_BUS_DMA_PRIVATE #include #include #include #include #include #include #include #include "nextdmareg.h" #include "nextdmavar.h" #include "esp.h" #include "xe.h" #if DEBUG #define ND_DEBUG #endif extern int turbo; #define panic __asm volatile("trap #15"); printf #define NEXTDMA_DEBUG nextdma_debug /* (nsc->sc_chan->nd_intr == NEXT_I_SCSI_DMA) && nextdma_debug */ #if defined(ND_DEBUG) int nextdma_debug = 0; #define DPRINTF(x) if (NEXTDMA_DEBUG) printf x; int ndtrace_show = 0; char ndtrace_buf[8192+100]; size_t ndtrace_len = 0; #define NDTRACEIF(x) if (10) do {x;} while (0) #else #define DPRINTF(x) #define NDTRACEIF(x) #endif #define PRINTF(x) printf x void ndtrace_printf(const char *fmt, ...) { #ifdef ND_DEBUG int len; va_list ap; va_start(ap, fmt); len = vsnprintf(ndtrace_buf + ndtrace_len, sizeof(ndtrace_buf) - ndtrace_len, fmt, ap); va_end(ap); ndtrace_len += len; #endif } int ndtrace_empty(void) { #ifdef ND_DEBUG return ndtrace_len == 0; #else return 1; #endif } void ndtrace_reset(void) { #ifdef ND_DEBUG ndtrace_len = 0; #endif } void ndtrace_addc(int c) { #ifdef ND_DEBUG if (ndtrace_len < sizeof(ndtrace_buf) - 1) { ndtrace_buf[ndtrace_len++] = c; ndtrace_buf[ndtrace_len] = '\0'; } #endif } const char * ndtrace_get(void) { #ifdef ND_DEBUG return ndtrace_buf; #else return NULL; #endif } #if defined(ND_DEBUG) int nextdma_debug_enetr_idx = 0; unsigned int nextdma_debug_enetr_state[100] = { 0 }; int nextdma_debug_scsi_idx = 0; unsigned int nextdma_debug_scsi_state[100] = { 0 }; void nextdma_debug_initstate(struct nextdma_softc *); void nextdma_debug_savestate(struct nextdma_softc *, unsigned int); void nextdma_debug_scsi_dumpstate(void); void nextdma_debug_enetr_dumpstate(void); #endif int nextdma_match(device_t, cfdata_t, void *); void nextdma_attach(device_t, device_t, void *); void nextdmamap_sync(bus_dma_tag_t, bus_dmamap_t, bus_addr_t, bus_size_t, int); int nextdma_continue(struct nextdma_softc *); void nextdma_rotate(struct nextdma_softc *); void nextdma_setup_cont_regs(struct nextdma_softc *); void nextdma_setup_curr_regs(struct nextdma_softc *); #if NESP > 0 static int nextdma_esp_intr(void *); #endif #if NXE > 0 static int nextdma_enet_intr(void *); #endif #define nd_bsr4(reg) \ bus_space_read_4(nsc->sc_bst, nsc->sc_bsh, (reg)) #define nd_bsw4(reg,val) \ bus_space_write_4(nsc->sc_bst, nsc->sc_bsh, (reg), (val)) CFATTACH_DECL_NEW(nextdma, sizeof(struct nextdma_softc), nextdma_match, nextdma_attach, NULL, NULL); static struct nextdma_channel nextdma_channel[] = { #if NESP > 0 { "scsi", NEXT_P_SCSI_CSR, DD_SIZE, NEXT_I_SCSI_DMA, &nextdma_esp_intr }, #endif #if NXE > 0 { "enetx", NEXT_P_ENETX_CSR, DD_SIZE, NEXT_I_ENETX_DMA, &nextdma_enet_intr }, { "enetr", NEXT_P_ENETR_CSR, DD_SIZE, NEXT_I_ENETR_DMA, &nextdma_enet_intr }, #endif }; static int nnextdma_channels = (sizeof(nextdma_channel)/sizeof(nextdma_channel[0])); static int attached = 0; struct nextdma_softc * nextdma_findchannel(const char *name) { device_t dev; deviter_t di; for (dev = deviter_first(&di, DEVITER_F_ROOT_FIRST); dev != NULL; dev = deviter_next(&di)) { if (strncmp(device_xname(dev), "nextdma", 7) == 0) { struct nextdma_softc *nsc = device_private(dev); if (strcmp(nsc->sc_chan->nd_name, name) == 0) break; } } deviter_release(&di); if (dev == NULL) return NULL; return device_private(dev); } int nextdma_match(device_t parent, cfdata_t match, void *aux) { struct intio_attach_args *ia = (struct intio_attach_args *)aux; if (attached >= nnextdma_channels) return (0); ia->ia_addr = (void *)nextdma_channel[attached].nd_base; return (1); } void nextdma_attach(device_t parent, device_t self, void *aux) { struct nextdma_softc *nsc = device_private(self); struct intio_attach_args *ia = (struct intio_attach_args *)aux; if (attached >= nnextdma_channels) return; nsc->sc_dev = self; nsc->sc_chan = &nextdma_channel[attached]; nsc->sc_dmat = ia->ia_dmat; nsc->sc_bst = ia->ia_bst; if (bus_space_map(nsc->sc_bst, nsc->sc_chan->nd_base, nsc->sc_chan->nd_size, 0, &nsc->sc_bsh)) { panic("%s: can't map DMA registers for channel %s", device_xname(self), nsc->sc_chan->nd_name); } nextdma_init (nsc); isrlink_autovec(nsc->sc_chan->nd_intrfunc, nsc, NEXT_I_IPL(nsc->sc_chan->nd_intr), 10, NULL); INTR_ENABLE(nsc->sc_chan->nd_intr); printf (": channel %d (%s)\n", attached, nsc->sc_chan->nd_name); attached++; return; } void nextdma_init(struct nextdma_softc *nsc) { #ifdef ND_DEBUG if (NEXTDMA_DEBUG) { char sbuf[256]; snprintb(sbuf, sizeof(sbuf), NEXT_INTR_BITS, NEXT_I_BIT(nsc->sc_chan->nd_intr)); printf("DMA init ipl (%ld) intr(%s)\n", NEXT_I_IPL(nsc->sc_chan->nd_intr), sbuf); } #endif nsc->sc_stat.nd_map = NULL; nsc->sc_stat.nd_idx = 0; nsc->sc_stat.nd_map_cont = NULL; nsc->sc_stat.nd_idx_cont = 0; nsc->sc_stat.nd_exception = 0; nd_bsw4 (DD_CSR, DMACSR_RESET | DMACSR_CLRCOMPLETE); nd_bsw4 (DD_CSR, 0); #if 01 nextdma_setup_curr_regs(nsc); nextdma_setup_cont_regs(nsc); #endif #if defined(DIAGNOSTIC) { u_long state; state = nd_bsr4 (DD_CSR); #if 1 /* mourning (a 25 MHz 68040 mono slab) appears to set BUSEXC * milo (a 25 MHz 68040 mono cube) didn't have this problem * Darrin B. Jewell Mon May 25 07:53:05 1998 */ state &= (DMACSR_COMPLETE | DMACSR_SUPDATE | DMACSR_ENABLE); #else state &= (DMACSR_BUSEXC | DMACSR_COMPLETE | DMACSR_SUPDATE | DMACSR_ENABLE); #endif if (state) { nextdma_print(nsc); panic("DMA did not reset"); } } #endif } void nextdma_reset(struct nextdma_softc *nsc) { int s; struct nextdma_status *stat = &nsc->sc_stat; s = spldma(); DPRINTF(("DMA reset\n")); #if (defined(ND_DEBUG)) if (NEXTDMA_DEBUG > 1) nextdma_print(nsc); #endif nd_bsw4 (DD_CSR, DMACSR_CLRCOMPLETE | DMACSR_RESET); if ((stat->nd_map) || (stat->nd_map_cont)) { if (stat->nd_map_cont) { DPRINTF(("DMA: resetting with non null continue map\n")); if (nsc->sc_conf.nd_completed_cb) (*nsc->sc_conf.nd_completed_cb) (stat->nd_map_cont, nsc->sc_conf.nd_cb_arg); stat->nd_map_cont = 0; stat->nd_idx_cont = 0; } if (nsc->sc_conf.nd_shutdown_cb) (*nsc->sc_conf.nd_shutdown_cb)(nsc->sc_conf.nd_cb_arg); stat->nd_map = 0; stat->nd_idx = 0; } splx(s); } /****************************************************************/ /* Call the completed and continue callbacks to try to fill * in the dma continue buffers. */ void nextdma_rotate(struct nextdma_softc *nsc) { struct nextdma_status *stat = &nsc->sc_stat; NDTRACEIF (ndtrace_addc('r')); DPRINTF(("DMA nextdma_rotate()\n")); /* Rotate the continue map into the current map */ stat->nd_map = stat->nd_map_cont; stat->nd_idx = stat->nd_idx_cont; if ((!stat->nd_map_cont) || ((++stat->nd_idx_cont >= stat->nd_map_cont->dm_nsegs))) { if (nsc->sc_conf.nd_continue_cb) { stat->nd_map_cont = (*nsc->sc_conf.nd_continue_cb) (nsc->sc_conf.nd_cb_arg); if (stat->nd_map_cont) { stat->nd_map_cont->dm_xfer_len = 0; } } else { stat->nd_map_cont = 0; } stat->nd_idx_cont = 0; } #if defined(DIAGNOSTIC) && 0 if (stat->nd_map_cont) { if (!DMA_BEGINALIGNED(stat->nd_map_cont->dm_segs[stat->nd_idx_cont].ds_addr)) { nextdma_print(nsc); panic("DMA request unaligned at start"); } if (!DMA_ENDALIGNED(stat->nd_map_cont->dm_segs[stat->nd_idx_cont].ds_addr + stat->nd_map_cont->dm_segs[stat->nd_idx_cont].ds_len)) { nextdma_print(nsc); panic("DMA request unaligned at end"); } } #endif } void nextdma_setup_curr_regs(struct nextdma_softc *nsc) { bus_addr_t dd_next; bus_addr_t dd_limit; bus_addr_t dd_saved_next; bus_addr_t dd_saved_limit; struct nextdma_status *stat = &nsc->sc_stat; NDTRACEIF (ndtrace_addc('C')); DPRINTF(("DMA nextdma_setup_curr_regs()\n")); if (stat->nd_map) { dd_next = stat->nd_map->dm_segs[stat->nd_idx].ds_addr; dd_limit = (stat->nd_map->dm_segs[stat->nd_idx].ds_addr + stat->nd_map->dm_segs[stat->nd_idx].ds_len); if (!turbo && nsc->sc_chan->nd_intr == NEXT_I_ENETX_DMA) { dd_limit |= 0x80000000; /* Ethernet transmit needs secret magic */ dd_limit += 15; } } else { dd_next = turbo ? 0 : 0xdeadbeef; dd_limit = turbo ? 0 : 0xdeadbeef; } dd_saved_next = dd_next; dd_saved_limit = dd_limit; NDTRACEIF (if (stat->nd_map) { ndtrace_printf("%ld", stat->nd_map->dm_segs[stat->nd_idx].ds_len); }); if (!turbo && (nsc->sc_chan->nd_intr == NEXT_I_ENETX_DMA)) { nd_bsw4 (DD_NEXT_INITBUF, dd_next); } else { nd_bsw4 (DD_NEXT, dd_next); } nd_bsw4 (DD_LIMIT, dd_limit); if (!turbo) nd_bsw4 (DD_SAVED_NEXT, dd_saved_next); if (!turbo) nd_bsw4 (DD_SAVED_LIMIT, dd_saved_limit); #ifdef DIAGNOSTIC if ((nd_bsr4 (DD_NEXT_INITBUF) != dd_next) || (nd_bsr4 (DD_NEXT) != dd_next) || (nd_bsr4 (DD_LIMIT) != dd_limit) || (!turbo && (nd_bsr4 (DD_SAVED_NEXT) != dd_saved_next)) || (!turbo && (nd_bsr4 (DD_SAVED_LIMIT) != dd_saved_limit)) ) { nextdma_print(nsc); panic("DMA failure writing to current regs"); } #endif } void nextdma_setup_cont_regs(struct nextdma_softc *nsc) { bus_addr_t dd_start; bus_addr_t dd_stop; bus_addr_t dd_saved_start; bus_addr_t dd_saved_stop; struct nextdma_status *stat = &nsc->sc_stat; NDTRACEIF (ndtrace_addc('c')); DPRINTF(("DMA nextdma_setup_regs()\n")); if (stat->nd_map_cont) { dd_start = stat->nd_map_cont->dm_segs[stat->nd_idx_cont].ds_addr; dd_stop = (stat->nd_map_cont->dm_segs[stat->nd_idx_cont].ds_addr + stat->nd_map_cont->dm_segs[stat->nd_idx_cont].ds_len); if (!turbo && nsc->sc_chan->nd_intr == NEXT_I_ENETX_DMA) { dd_stop |= 0x80000000; /* Ethernet transmit needs secret magic */ dd_stop += 15; } } else { dd_start = turbo ? nd_bsr4 (DD_NEXT) : 0xdeadbee0; dd_stop = turbo ? 0 : 0xdeadbee0; } dd_saved_start = dd_start; dd_saved_stop = dd_stop; NDTRACEIF (if (stat->nd_map_cont) { ndtrace_printf("%ld", stat->nd_map_cont->dm_segs[stat->nd_idx_cont].ds_len); }); nd_bsw4 (DD_START, dd_start); nd_bsw4 (DD_STOP, dd_stop); if (!turbo) nd_bsw4 (DD_SAVED_START, dd_saved_start); if (!turbo) nd_bsw4 (DD_SAVED_STOP, dd_saved_stop); if (turbo && nsc->sc_chan->nd_intr == NEXT_I_ENETR_DMA) nd_bsw4 (DD_STOP - 0x40, dd_start); #ifdef DIAGNOSTIC if ((nd_bsr4 (DD_START) != dd_start) || (dd_stop && (nd_bsr4 (DD_STOP) != dd_stop)) || (!turbo && (nd_bsr4 (DD_SAVED_START) != dd_saved_start)) || (!turbo && (nd_bsr4 (DD_SAVED_STOP) != dd_saved_stop)) ) { nextdma_print(nsc); panic("DMA failure writing to continue regs"); } #endif } /****************************************************************/ #if NESP > 0 static int nextdma_esp_intr(void *arg) { /* @@@ This is bogus, we can't be certain of arg's type * unless the interrupt is for us. For now we successfully * cheat because DMA interrupts are the only things invoked * at this interrupt level. */ struct nextdma_softc *nsc = arg; int esp_dma_int(void *); /* XXX */ if (!INTR_OCCURRED(nsc->sc_chan->nd_intr)) return 0; /* Handle dma interrupts */ return esp_dma_int (nsc->sc_conf.nd_cb_arg); } #endif #if NXE > 0 static int nextdma_enet_intr(void *arg) { /* @@@ This is bogus, we can't be certain of arg's type * unless the interrupt is for us. For now we successfully * cheat because DMA interrupts are the only things invoked * at this interrupt level. */ struct nextdma_softc *nsc = arg; unsigned int state; bus_addr_t onext; bus_addr_t olimit; bus_addr_t slimit; int result; struct nextdma_status *stat = &nsc->sc_stat; if (!INTR_OCCURRED(nsc->sc_chan->nd_intr)) return 0; /* Handle dma interrupts */ NDTRACEIF (ndtrace_addc('D')); #ifdef ND_DEBUG if (NEXTDMA_DEBUG) { char sbuf[256]; snprintb(sbuf, sizeof(sbuf), NEXT_INTR_BITS, NEXT_I_BIT(nsc->sc_chan->nd_intr)); printf("DMA interrupt ipl (%ld) intr(%s)\n", NEXT_I_IPL(nsc->sc_chan->nd_intr), sbuf); } #endif #ifdef DIAGNOSTIC if (!stat->nd_map) { nextdma_print(nsc); panic("DMA missing current map in interrupt!"); } #endif state = nd_bsr4 (DD_CSR); #if defined(ND_DEBUG) nextdma_debug_savestate(nsc, state); #endif #ifdef DIAGNOSTIC if (/* (state & DMACSR_READ) || */ !(state & DMACSR_COMPLETE)) { char sbuf[256]; nextdma_print(nsc); snprintb(sbuf, sizeof(sbuf), DMACSR_BITS, state); printf("DMA: state %s\n",sbuf); panic("DMA complete not set in interrupt"); } #endif DPRINTF(("DMA: finishing xfer\n")); onext = stat->nd_map->dm_segs[stat->nd_idx].ds_addr; olimit = onext + stat->nd_map->dm_segs[stat->nd_idx].ds_len; result = 0; if (state & DMACSR_ENABLE) { /* enable bit was set */ result |= 0x01; } if (state & DMACSR_SUPDATE) { /* supdate bit was set */ result |= 0x02; } if (stat->nd_map_cont == NULL) { KASSERT(stat->nd_idx+1 == stat->nd_map->dm_nsegs); /* Expecting a shutdown, didn't SETSUPDATE last turn */ result |= 0x04; } if (state & DMACSR_BUSEXC) { /* bus exception bit was set */ result |= 0x08; } switch (result) { case 0x00: /* !BUSEXC && !expecting && !SUPDATE && !ENABLE */ case 0x08: /* BUSEXC && !expecting && !SUPDATE && !ENABLE */ if (turbo) { volatile u_int *limit = (volatile u_int *)IIOV(0x2000050+0x4000); slimit = *limit; } else { slimit = nd_bsr4 (DD_SAVED_LIMIT); } break; case 0x01: /* !BUSEXC && !expecting && !SUPDATE && ENABLE */ case 0x09: /* BUSEXC && !expecting && !SUPDATE && ENABLE */ if (turbo) { volatile u_int *limit = (volatile u_int *)IIOV(0x2000050+0x4000); slimit = *limit; } else { slimit = nd_bsr4 (DD_SAVED_LIMIT); } break; case 0x02: /* !BUSEXC && !expecting && SUPDATE && !ENABLE */ case 0x0a: /* BUSEXC && !expecting && SUPDATE && !ENABLE */ slimit = nd_bsr4 (DD_NEXT); break; case 0x04: /* !BUSEXC && expecting && !SUPDATE && !ENABLE */ case 0x0c: /* BUSEXC && expecting && !SUPDATE && !ENABLE */ slimit = nd_bsr4 (DD_LIMIT); break; default: #ifdef DIAGNOSTIC { char sbuf[256]; printf("DMA: please send this output to port-next68k-maintainer@NetBSD.org:\n"); snprintb(sbuf, sizeof(sbuf), DMACSR_BITS, state); printf("DMA: state %s\n",sbuf); nextdma_print(nsc); panic("DMA: condition 0x%02x not yet documented to occur",result); } #endif slimit = olimit; break; } if (!turbo && nsc->sc_chan->nd_intr == NEXT_I_ENETX_DMA) { slimit &= ~0x80000000; slimit -= 15; } #ifdef DIAGNOSTIC if ((state & DMACSR_READ)) DPRINTF (("limits: 0x%08lx <= 0x%08lx <= 0x%08lx %s\n", onext, slimit, olimit, (state & DMACSR_READ) ? "read" : "write")); if ((slimit < onext) || (slimit > olimit)) { char sbuf[256]; snprintb(sbuf, sizeof(sbuf), DMACSR_BITS, state); printf("DMA: state %s\n",sbuf); nextdma_print(nsc); panic("DMA: Unexpected limit register (0x%08lx) in finish_xfer",slimit); } #endif #ifdef DIAGNOSTIC if ((state & DMACSR_ENABLE) && ((stat->nd_idx+1) != stat->nd_map->dm_nsegs)) { if (slimit != olimit) { char sbuf[256]; snprintb(sbuf, sizeof(sbuf), DMACSR_BITS, state); printf("DMA: state %s\n",sbuf); nextdma_print(nsc); panic("DMA: short limit register (0x%08lx) w/o finishing map.",slimit); } } #endif #if (defined(ND_DEBUG)) if (NEXTDMA_DEBUG > 2) nextdma_print(nsc); #endif stat->nd_map->dm_xfer_len += slimit-onext; /* If we've reached the end of the current map, then inform * that we've completed that map. */ if ((stat->nd_idx+1) == stat->nd_map->dm_nsegs) { if (nsc->sc_conf.nd_completed_cb) (*nsc->sc_conf.nd_completed_cb) (stat->nd_map, nsc->sc_conf.nd_cb_arg); } else { KASSERT(stat->nd_map == stat->nd_map_cont); KASSERT(stat->nd_idx+1 == stat->nd_idx_cont); } stat->nd_map = 0; stat->nd_idx = 0; #if (defined(ND_DEBUG)) if (NEXTDMA_DEBUG) { char sbuf[256]; snprintb(sbuf, sizeof(sbuf), DMACSR_BITS, state); printf("CLNDMAP: dd->dd_csr = %s\n", sbuf); } #endif if (state & DMACSR_ENABLE) { u_long dmadir; /* DMACSR_SETREAD or DMACSR_SETWRITE */ nextdma_rotate(nsc); nextdma_setup_cont_regs(nsc); if (state & DMACSR_READ) { dmadir = DMACSR_SETREAD; } else { dmadir = DMACSR_SETWRITE; } if (stat->nd_map_cont == NULL) { KASSERT(stat->nd_idx+1 == stat->nd_map->dm_nsegs); nd_bsw4 (DD_CSR, DMACSR_CLRCOMPLETE | dmadir); NDTRACEIF (ndtrace_addc('g')); } else { nd_bsw4 (DD_CSR, DMACSR_CLRCOMPLETE | dmadir | DMACSR_SETSUPDATE); NDTRACEIF (ndtrace_addc('G')); } } else { DPRINTF(("DMA: a shutdown occurred\n")); nd_bsw4 (DD_CSR, DMACSR_CLRCOMPLETE | DMACSR_RESET); /* Cleanup more incomplete transfers */ /* cleanup continue map */ if (stat->nd_map_cont) { DPRINTF(("DMA: shutting down with non null continue map\n")); if (nsc->sc_conf.nd_completed_cb) (*nsc->sc_conf.nd_completed_cb) (stat->nd_map_cont, nsc->sc_conf.nd_cb_arg); stat->nd_map_cont = 0; stat->nd_idx_cont = 0; } if (nsc->sc_conf.nd_shutdown_cb) (*nsc->sc_conf.nd_shutdown_cb)(nsc->sc_conf.nd_cb_arg); } #ifdef ND_DEBUG if (NEXTDMA_DEBUG) { char sbuf[256]; snprintb(sbuf, sizeof(sbuf), NEXT_INTR_BITS, NEXT_I_BIT(nsc->sc_chan->nd_intr)); printf("DMA exiting interrupt ipl (%ld) intr(%s)\n", NEXT_I_IPL(nsc->sc_chan->nd_intr), sbuf); } #endif return(1); } #endif /* * Check to see if dma has finished for a channel */ int nextdma_finished(struct nextdma_softc *nsc) { int r; int s; struct nextdma_status *stat = &nsc->sc_stat; s = spldma(); r = (stat->nd_map == NULL) && (stat->nd_map_cont == NULL); splx(s); return(r); } void nextdma_start(struct nextdma_softc *nsc, u_long dmadir) { struct nextdma_status *stat = &nsc->sc_stat; NDTRACEIF (ndtrace_addc('n')); #ifdef DIAGNOSTIC if (!nextdma_finished(nsc)) { char sbuf[256]; snprintb(sbuf, sizeof(sbuf), NEXT_INTR_BITS, NEXT_I_BIT(nsc->sc_chan->nd_intr)); panic("DMA trying to start before previous finished on intr(%s)", sbuf); } #endif #ifdef ND_DEBUG if (NEXTDMA_DEBUG) { char sbuf[256]; snprintb(sbuf, sizeof(sbuf), NEXT_INTR_BITS, NEXT_I_BIT(nsc->sc_chan->nd_intr)); printf("DMA start (%ld) intr(%s)\n", NEXT_I_IPL(nsc->sc_chan->nd_intr), sbuf); } #endif #ifdef DIAGNOSTIC if (stat->nd_map) { nextdma_print(nsc); panic("DMA: nextdma_start() with non null map"); } if (stat->nd_map_cont) { nextdma_print(nsc); panic("DMA: nextdma_start() with non null continue map"); } #endif #ifdef DIAGNOSTIC if ((dmadir != DMACSR_SETREAD) && (dmadir != DMACSR_SETWRITE)) { panic("DMA: nextdma_start(), dmadir arg must be DMACSR_SETREAD or DMACSR_SETWRITE"); } #endif #if defined(ND_DEBUG) nextdma_debug_initstate(nsc); #endif /* preload both the current and the continue maps */ nextdma_rotate(nsc); #ifdef DIAGNOSTIC if (!stat->nd_map_cont) { panic("No map available in nextdma_start()"); } #endif nextdma_rotate(nsc); #ifdef ND_DEBUG if (NEXTDMA_DEBUG) { char sbuf[256]; snprintb(sbuf, sizeof(sbuf), NEXT_INTR_BITS, NEXT_I_BIT(nsc->sc_chan->nd_intr)); printf("DMA initiating DMA %s of %d segments on intr(%s)\n", (dmadir == DMACSR_SETREAD ? "read" : "write"), stat->nd_map->dm_nsegs, sbuf); } #endif nd_bsw4 (DD_CSR, (turbo ? DMACSR_INITBUFTURBO : DMACSR_INITBUF) | DMACSR_RESET | dmadir); nd_bsw4 (DD_CSR, 0); nextdma_setup_curr_regs(nsc); nextdma_setup_cont_regs(nsc); #if (defined(ND_DEBUG)) if (NEXTDMA_DEBUG > 2) nextdma_print(nsc); #endif if (stat->nd_map_cont == NULL) { nd_bsw4 (DD_CSR, DMACSR_SETENABLE | dmadir); } else { nd_bsw4 (DD_CSR, DMACSR_SETSUPDATE | DMACSR_SETENABLE | dmadir); } } /* This routine is used for debugging */ void nextdma_print(struct nextdma_softc *nsc) { u_long dd_csr; u_long dd_next; u_long dd_next_initbuf; u_long dd_limit; u_long dd_start; u_long dd_stop; u_long dd_saved_next; u_long dd_saved_limit; u_long dd_saved_start; u_long dd_saved_stop; char sbuf[256]; struct nextdma_status *stat = &nsc->sc_stat; /* Read all of the registers before we print anything out, * in case something changes */ dd_csr = nd_bsr4 (DD_CSR); dd_next = nd_bsr4 (DD_NEXT); dd_next_initbuf = nd_bsr4 (DD_NEXT_INITBUF); dd_limit = nd_bsr4 (DD_LIMIT); dd_start = nd_bsr4 (DD_START); dd_stop = nd_bsr4 (DD_STOP); dd_saved_next = nd_bsr4 (DD_SAVED_NEXT); dd_saved_limit = nd_bsr4 (DD_SAVED_LIMIT); dd_saved_start = nd_bsr4 (DD_SAVED_START); dd_saved_stop = nd_bsr4 (DD_SAVED_STOP); snprintb(sbuf, sizeof(sbuf), NEXT_INTR_BITS, *(volatile u_long *)IIOV(NEXT_P_INTRSTAT)); printf("NDMAP: *intrstat = %s\n", sbuf); snprintb(sbuf, sizeof(sbuf), NEXT_INTR_BITS, *(volatile u_long *)IIOV(NEXT_P_INTRMASK)); printf("NDMAP: *intrmask = %s\n", sbuf); /* NDMAP is Next DMA Print (really!) */ if (stat->nd_map) { int i; printf("NDMAP: nd_map->dm_mapsize = %ld\n", stat->nd_map->dm_mapsize); printf("NDMAP: nd_map->dm_nsegs = %d\n", stat->nd_map->dm_nsegs); printf("NDMAP: nd_map->dm_xfer_len = %ld\n", stat->nd_map->dm_xfer_len); printf("NDMAP: nd_map->dm_segs[%d].ds_addr = 0x%08lx\n", stat->nd_idx, stat->nd_map->dm_segs[stat->nd_idx].ds_addr); printf("NDMAP: nd_map->dm_segs[%d].ds_len = %ld\n", stat->nd_idx, stat->nd_map->dm_segs[stat->nd_idx].ds_len); printf("NDMAP: Entire map;\n"); for(i=0;ind_map->dm_nsegs;i++) { printf("NDMAP: nd_map->dm_segs[%d].ds_addr = 0x%08lx\n", i,stat->nd_map->dm_segs[i].ds_addr); printf("NDMAP: nd_map->dm_segs[%d].ds_len = %ld\n", i,stat->nd_map->dm_segs[i].ds_len); } } else { printf("NDMAP: nd_map = NULL\n"); } if (stat->nd_map_cont) { printf("NDMAP: nd_map_cont->dm_mapsize = %ld\n", stat->nd_map_cont->dm_mapsize); printf("NDMAP: nd_map_cont->dm_nsegs = %d\n", stat->nd_map_cont->dm_nsegs); printf("NDMAP: nd_map_cont->dm_xfer_len = %ld\n", stat->nd_map_cont->dm_xfer_len); printf("NDMAP: nd_map_cont->dm_segs[%d].ds_addr = 0x%08lx\n", stat->nd_idx_cont,stat->nd_map_cont->dm_segs[stat->nd_idx_cont].ds_addr); printf("NDMAP: nd_map_cont->dm_segs[%d].ds_len = %ld\n", stat->nd_idx_cont,stat->nd_map_cont->dm_segs[stat->nd_idx_cont].ds_len); if (stat->nd_map_cont != stat->nd_map) { int i; printf("NDMAP: Entire map;\n"); for(i=0;ind_map_cont->dm_nsegs;i++) { printf("NDMAP: nd_map_cont->dm_segs[%d].ds_addr = 0x%08lx\n", i,stat->nd_map_cont->dm_segs[i].ds_addr); printf("NDMAP: nd_map_cont->dm_segs[%d].ds_len = %ld\n", i,stat->nd_map_cont->dm_segs[i].ds_len); } } } else { printf("NDMAP: nd_map_cont = NULL\n"); } snprintb(sbuf, sizeof(sbuf), DMACSR_BITS, dd_csr); printf("NDMAP: dd->dd_csr = %s\n", sbuf); printf("NDMAP: dd->dd_saved_next = 0x%08lx\n", dd_saved_next); printf("NDMAP: dd->dd_saved_limit = 0x%08lx\n", dd_saved_limit); printf("NDMAP: dd->dd_saved_start = 0x%08lx\n", dd_saved_start); printf("NDMAP: dd->dd_saved_stop = 0x%08lx\n", dd_saved_stop); printf("NDMAP: dd->dd_next = 0x%08lx\n", dd_next); printf("NDMAP: dd->dd_next_initbuf = 0x%08lx\n", dd_next_initbuf); printf("NDMAP: dd->dd_limit = 0x%08lx\n", dd_limit); printf("NDMAP: dd->dd_start = 0x%08lx\n", dd_start); printf("NDMAP: dd->dd_stop = 0x%08lx\n", dd_stop); snprintb(sbuf, sizeof(sbuf), NEXT_INTR_BITS, NEXT_I_BIT(nsc->sc_chan->nd_intr)); printf("NDMAP: interrupt ipl (%ld) intr(%s)\n", NEXT_I_IPL(nsc->sc_chan->nd_intr), sbuf); } #if defined(ND_DEBUG) void nextdma_debug_initstate(struct nextdma_softc *nsc) { switch(nsc->sc_chan->nd_intr) { case NEXT_I_ENETR_DMA: memset(nextdma_debug_enetr_state,0,sizeof(nextdma_debug_enetr_state)); break; case NEXT_I_SCSI_DMA: memset(nextdma_debug_scsi_state,0,sizeof(nextdma_debug_scsi_state)); break; } } void nextdma_debug_savestate(struct nextdma_softc *nsc, unsigned int state) { switch(nsc->sc_chan->nd_intr) { case NEXT_I_ENETR_DMA: nextdma_debug_enetr_state[nextdma_debug_enetr_idx++] = state; nextdma_debug_enetr_idx %= (sizeof(nextdma_debug_enetr_state)/sizeof(unsigned int)); break; case NEXT_I_SCSI_DMA: nextdma_debug_scsi_state[nextdma_debug_scsi_idx++] = state; nextdma_debug_scsi_idx %= (sizeof(nextdma_debug_scsi_state)/sizeof(unsigned int)); break; } } void nextdma_debug_enetr_dumpstate(void) { int i; int s; s = spldma(); i = nextdma_debug_enetr_idx; do { char sbuf[256]; if (nextdma_debug_enetr_state[i]) { snprintb(sbuf, sizeof(sbuf), DMACSR_BITS, nextdma_debug_enetr_state[i]); printf("DMA: 0x%02x state %s\n",i,sbuf); } i++; i %= (sizeof(nextdma_debug_enetr_state)/sizeof(unsigned int)); } while (i != nextdma_debug_enetr_idx); splx(s); } void nextdma_debug_scsi_dumpstate(void) { int i; int s; s = spldma(); i = nextdma_debug_scsi_idx; do { char sbuf[256]; if (nextdma_debug_scsi_state[i]) { snprintb(sbuf, sizeof(sbuf), DMACSR_BITS, nextdma_debug_scsi_state[i]); printf("DMA: 0x%02x state %s\n",i,sbuf); } i++; i %= (sizeof(nextdma_debug_scsi_state)/sizeof(unsigned int)); } while (i != nextdma_debug_scsi_idx); splx(s); } #endif