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/*
* SPU processing offload to TI C64x DSP using bsp's c64_tools
* (C) Gražvydas "notaz" Ignotas, 2015
*
* Permission is hereby granted, free of charge, to any person obtaining a copy of
* this software and associated documentation files (the "Software"), to deal in
* the Software without restriction, including without limitation the rights to
* use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies
* of the Software, and to permit persons to whom the Software is furnished to do
* so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all
* copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
#include <dlfcn.h>
#include <stddef.h>
#include <unistd.h>
#include <inc_libc64_mini.h>
#include "spu_c64x.h"
static struct {
void *handle;
int (*dsp_open)(void);
dsp_mem_region_t (*dsp_shm_alloc)(dsp_cache_t _type, sU32 _numBytes);
int (*dsp_shm_free)(dsp_mem_region_t _mem);
void (*dsp_close)(void);
int (*dsp_component_load)(const char *_path, const char *_name, dsp_component_id_t *_id);
int (*dsp_cache_inv_virt)(void *_virtAddr, sU32 _size);
int (*dsp_rpc_send)(const dsp_msg_t *_msgTo);
int (*dsp_rpc_recv)(dsp_msg_t *_msgFrom);
int (*dsp_rpc)(const dsp_msg_t *_msgTo, dsp_msg_t *_msgFrom);
void (*dsp_logbuf_print)(void);
dsp_mem_region_t region;
dsp_component_id_t compid;
unsigned int stale_caches:1;
unsigned int req_sent:1;
} f;
static noinline void dsp_fault(void)
{
dsp_msg_t msg;
f.dsp_cache_inv_virt(worker, sizeof(*worker));
printf("dsp crash/fault/corruption:\n");
printf("state rdy/reap/done: %u %u %u\n",
worker->i_ready, worker->i_reaped, worker->i_done);
printf("active/boot: %u %u\n",
worker->active, worker->boot_cnt);
if (f.req_sent) {
f.dsp_rpc_recv(&msg);
f.req_sent = 0;
}
f.dsp_logbuf_print();
spu_config.iUseThread = 0;
}
static void thread_work_start(void)
{
struct region_mem *mem;
dsp_msg_t msg;
int ret;
// make sure new work is written out
__sync_synchronize();
// this should be safe, as dsp checks for new work even
// after it decrements ->active
// cacheline: i_done, active
f.dsp_cache_inv_virt(&worker->i_done, 64);
if (worker->active == ACTIVE_CNT)
return;
// to start the DSP, dsp_rpc_send() must be used,
// but before that, previous request must be finished
if (f.req_sent) {
if (worker->boot_cnt == worker->last_boot_cnt) {
// hopefully still booting
//printf("booting?\n");
return;
}
ret = f.dsp_rpc_recv(&msg);
if (ret != 0) {
fprintf(stderr, "dsp_rpc_recv failed: %d\n", ret);
f.dsp_logbuf_print();
f.req_sent = 0;
spu_config.iUseThread = 0;
return;
}
}
f.dsp_cache_inv_virt(&worker->i_done, 64);
worker->last_boot_cnt = worker->boot_cnt;
worker->ram_dirty = spu.bMemDirty;
spu.bMemDirty = 0;
mem = (void *)f.region.virt_addr;
memcpy(&mem->in.spu_config, &spu_config, sizeof(mem->in.spu_config));
DSP_MSG_INIT(&msg, f.compid, CCMD_DOIT, f.region.phys_addr, 0);
ret = f.dsp_rpc_send(&msg);
if (ret != 0) {
fprintf(stderr, "dsp_rpc_send failed: %d\n", ret);
f.dsp_logbuf_print();
spu_config.iUseThread = 0;
return;
}
f.req_sent = 1;
#if 0
f.dsp_rpc_recv(&msg);
f.req_sent = 0;
#endif
}
static int thread_get_i_done(void)
{
f.dsp_cache_inv_virt(&worker->i_done, sizeof(worker->i_done));
return worker->i_done;
}
static void thread_work_wait_sync(struct work_item *work, int force)
{
int limit = 1000;
int ns_to;
if ((unsigned int)(worker->i_done - worker->i_reaped) > WORK_MAXCNT) {
dsp_fault();
return;
}
while (worker->i_done == worker->i_reaped && limit-- > 0) {
if (!f.req_sent) {
printf("dsp: req not sent?\n");
break;
}
if (worker->boot_cnt != worker->last_boot_cnt && !worker->active) {
printf("dsp: broken sync\n");
worker->last_boot_cnt = ~0;
break;
}
usleep(500);
f.dsp_cache_inv_virt(&worker->i_done, 64);
}
ns_to = work->ns_to;
f.dsp_cache_inv_virt(work->SSumLR, sizeof(work->SSumLR[0]) * 2 * ns_to);
preload(work->SSumLR);
preload(work->SSumLR + 64/4);
f.stale_caches = 1; // SB, spuMem
if (limit == 0)
printf("dsp: wait timeout\n");
// still in results loop?
if (worker->i_reaped != worker->i_done - 1)
return;
if (f.req_sent && (force || worker->i_done == worker->i_ready)) {
dsp_msg_t msg;
int ret;
ret = f.dsp_rpc_recv(&msg);
if (ret != 0) {
fprintf(stderr, "dsp_rpc_recv failed: %d\n", ret);
f.dsp_logbuf_print();
spu_config.iUseThread = 0;
}
f.req_sent = 0;
}
}
static void thread_sync_caches(void)
{
if (f.stale_caches) {
f.dsp_cache_inv_virt(spu.SB, sizeof(spu.SB[0]) * SB_SIZE * 24);
f.dsp_cache_inv_virt(spu.spuMemC + 0x800, 0x800);
if (spu.rvb->StartAddr) {
int left = 0x40000 - spu.rvb->StartAddr;
f.dsp_cache_inv_virt(spu.spuMem + spu.rvb->StartAddr, left * 2);
}
f.stale_caches = 0;
}
}
static void init_spu_thread(void)
{
dsp_msg_t init_msg, msg_in;
struct region_mem *mem;
int ret;
if (f.handle == NULL) {
const char lib[] = "libc64.so.1";
int failed = 0;
f.handle = dlopen(lib, RTLD_NOW);
if (f.handle == NULL) {
fprintf(stderr, "can't load %s: %s\n", lib, dlerror());
goto fail_open;
}
#define LDS(name) \
failed |= (f.name = dlsym(f.handle, #name)) == NULL
LDS(dsp_open);
LDS(dsp_close);
LDS(dsp_shm_alloc);
LDS(dsp_shm_free);
LDS(dsp_cache_inv_virt);
LDS(dsp_component_load);
LDS(dsp_rpc_send);
LDS(dsp_rpc_recv);
LDS(dsp_rpc);
LDS(dsp_logbuf_print);
#undef LDS
if (failed) {
fprintf(stderr, "missing symbol(s) in %s\n", lib);
dlclose(f.handle);
f.handle = NULL;
goto fail_open;
}
}
ret = f.dsp_open();
if (ret != 0) {
fprintf(stderr, "dsp_open failed: %d\n", ret);
goto fail_open;
}
ret = f.dsp_component_load(NULL, COMPONENT_NAME, &f.compid);
if (ret != 0) {
fprintf(stderr, "dsp_component_load failed: %d\n", ret);
goto fail_cload;
}
f.region = f.dsp_shm_alloc(DSP_CACHE_R, sizeof(*mem)); // writethrough
if (f.region.size < sizeof(*mem) || f.region.virt_addr == 0) {
fprintf(stderr, "dsp_shm_alloc failed\n");
goto fail_mem;
}
mem = (void *)f.region.virt_addr;
memcpy(&mem->in.spu_config, &spu_config, sizeof(mem->in.spu_config));
DSP_MSG_INIT(&init_msg, f.compid, CCMD_INIT, f.region.phys_addr, 0);
ret = f.dsp_rpc(&init_msg, &msg_in);
if (ret != 0) {
fprintf(stderr, "dsp_rpc failed: %d\n", ret);
goto fail_init;
}
if (mem->sizeof_region_mem != sizeof(*mem)) {
fprintf(stderr, "error: size mismatch 1: %d vs %zd\n",
mem->sizeof_region_mem, sizeof(*mem));
goto fail_init;
}
if (mem->offsetof_s_chan1 != offsetof(typeof(*mem), in.s_chan[1])) {
fprintf(stderr, "error: size mismatch 2: %d vs %zd\n",
mem->offsetof_s_chan1, offsetof(typeof(*mem), in.s_chan[1]));
goto fail_init;
}
if (mem->offsetof_spos_3_20 != offsetof(typeof(*mem), worker.i[3].ch[20])) {
fprintf(stderr, "error: size mismatch 3: %d vs %zd\n",
mem->offsetof_spos_3_20, offsetof(typeof(*mem), worker.i[3].ch[20]));
goto fail_init;
}
// override default allocations
free(spu.spuMemC);
spu.spuMemC = mem->spu_ram;
free(spu.SB);
spu.SB = mem->SB;
free(spu.s_chan);
spu.s_chan = mem->in.s_chan;
free(spu.rvb);
spu.rvb = &mem->in.rvb;
worker = &mem->worker;
printf("spu: C64x DSP ready (id=%d).\n", (int)f.compid);
f.dsp_logbuf_print();
spu_config.iThreadAvail = 1;
(void)do_channel_work; // used by DSP instead
return;
fail_init:
f.dsp_shm_free(f.region);
fail_mem:
// no component unload func?
fail_cload:
f.dsp_logbuf_print();
f.dsp_close();
fail_open:
printf("spu: C64x DSP init failed.\n");
spu_config.iUseThread = spu_config.iThreadAvail = 0;
worker = NULL;
}
static void exit_spu_thread(void)
{
dsp_msg_t msg;
if (worker == NULL)
return;
if (f.req_sent) {
f.dsp_rpc_recv(&msg);
f.req_sent = 0;
}
f.dsp_logbuf_print();
f.dsp_shm_free(f.region);
f.dsp_close();
spu.spuMemC = NULL;
spu.SB = NULL;
spu.s_chan = NULL;
spu.rvb = NULL;
worker = NULL;
}
/* debug: "access" shared mem from gdb */
#if 0
struct region_mem *dbg_dsp_mem;
void dbg_dsp_mem_update(void)
{
struct region_mem *mem;
if (dbg_dsp_mem == NULL)
dbg_dsp_mem = malloc(sizeof(*dbg_dsp_mem));
if (dbg_dsp_mem == NULL)
return;
mem = (void *)f.region.virt_addr;
f.dsp_cache_inv_virt(mem, sizeof(*mem));
memcpy(dbg_dsp_mem, mem, sizeof(*dbg_dsp_mem));
}
#endif
// vim:shiftwidth=1:expandtab
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