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#define _PCILIB_DMA_IPE_C
#define _BSD_SOURCE
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <sys/time.h>
#include <arpa/inet.h>
#include "pci.h"
#include "pcilib.h"
#include "error.h"
#include "tools.h"
#include "ipe.h"
#include "ipe_private.h"
#include "ipe_registers.h"
#define WR(addr, value) { *(uint32_t*)(ctx->base_addr + addr) = value; }
#define RD(addr, value) { value = *(uint32_t*)(ctx->base_addr + addr); }
pcilib_dma_context_t *dma_ipe_init(pcilib_t *pcilib, pcilib_dma_modification_t type, void *arg) {
int err = 0;
pcilib_model_description_t *model_info = pcilib_get_model_description(pcilib);
ipe_dma_t *ctx = malloc(sizeof(ipe_dma_t));
if (ctx) {
memset(ctx, 0, sizeof(ipe_dma_t));
ctx->pcilib = pcilib;
memset(ctx->engine, 0, 2 * sizeof(pcilib_dma_engine_description_t));
ctx->engine[0].addr = 0;
ctx->engine[0].type = PCILIB_DMA_TYPE_PACKET;
ctx->engine[0].direction = PCILIB_DMA_FROM_DEVICE;
ctx->engine[0].addr_bits = 32;
pcilib_set_dma_engine_description(pcilib, 0, &ctx->engine[0]);
pcilib_set_dma_engine_description(pcilib, 1, NULL);
pcilib_register_bank_t dma_bank = pcilib_find_bank_by_addr(pcilib, PCILIB_REGISTER_BANK_DMA);
if (dma_bank == PCILIB_REGISTER_BANK_INVALID) {
free(ctx);
pcilib_error("DMA Register Bank could not be found");
return NULL;
}
ctx->dma_bank = model_info->banks + dma_bank;
ctx->base_addr = pcilib_resolve_register_address(pcilib, ctx->dma_bank->bar, ctx->dma_bank->read_addr);
err = pcilib_add_registers(ctx->pcilib, 0, ipe_dma_registers);
if (err) {
free(ctx);
pcilib_error("Error adding DMA registers");
return NULL;
}
}
return (pcilib_dma_context_t*)ctx;
}
void dma_ipe_free(pcilib_dma_context_t *vctx) {
ipe_dma_t *ctx = (ipe_dma_t*)vctx;
if (ctx) {
dma_ipe_stop(vctx, PCILIB_DMA_ENGINE_ALL, PCILIB_DMA_FLAGS_DEFAULT);
free(ctx);
}
}
int dma_ipe_start(pcilib_dma_context_t *vctx, pcilib_dma_engine_t dma, pcilib_dma_flags_t flags) {
size_t i;
ipe_dma_t *ctx = (ipe_dma_t*)vctx;
int preserve = 0;
pcilib_kmem_flags_t kflags;
pcilib_kmem_reuse_state_t reuse_desc, reuse_pages;
volatile void *desc_va;
volatile uint32_t *last_written_addr_ptr;
pcilib_register_value_t value;
if (dma == PCILIB_DMA_ENGINE_INVALID) return 0;
else if (dma > 1) return PCILIB_ERROR_INVALID_BANK;
if (!ctx->started) ctx->started = 1;
if (flags&PCILIB_DMA_FLAG_PERSISTENT) ctx->preserve = 1;
if (ctx->pages) return 0;
kflags = PCILIB_KMEM_FLAG_REUSE|PCILIB_KMEM_FLAG_EXCLUSIVE|PCILIB_KMEM_FLAG_HARDWARE|(ctx->preserve?PCILIB_KMEM_FLAG_PERSISTENT:0);
pcilib_kmem_handle_t *desc = pcilib_alloc_kernel_memory(ctx->pcilib, PCILIB_KMEM_TYPE_CONSISTENT, 1, IPEDMA_DESCRIPTOR_SIZE, IPEDMA_DESCRIPTOR_ALIGNMENT, PCILIB_KMEM_USE(PCILIB_KMEM_USE_DMA_RING, 0x00), kflags);
pcilib_kmem_handle_t *pages = pcilib_alloc_kernel_memory(ctx->pcilib, PCILIB_KMEM_TYPE_DMA_C2S_PAGE, IPEDMA_DMA_PAGES, 0, 0, PCILIB_KMEM_USE(PCILIB_KMEM_USE_DMA_PAGES, 0x00), kflags);
if (!desc||!pages) {
if (pages) pcilib_free_kernel_memory(ctx->pcilib, pages, 0);
if (desc) pcilib_free_kernel_memory(ctx->pcilib, desc, 0);
return PCILIB_ERROR_MEMORY;
}
reuse_desc = pcilib_kmem_is_reused(ctx->pcilib, desc);
reuse_pages = pcilib_kmem_is_reused(ctx->pcilib, pages);
if (reuse_desc == reuse_pages) {
if (reuse_desc & PCILIB_KMEM_REUSE_PARTIAL) pcilib_warning("Inconsistent DMA buffers are found (only part of required buffers is available), reinitializing...");
else if (reuse_desc & PCILIB_KMEM_REUSE_REUSED) {
if ((reuse_desc & PCILIB_KMEM_REUSE_PERSISTENT) == 0) pcilib_warning("Lost DMA buffers are found (non-persistent mode), reinitializing...");
else if ((reuse_desc & PCILIB_KMEM_REUSE_HARDWARE) == 0) pcilib_warning("Lost DMA buffers are found (missing HW reference), reinitializing...");
else {
#ifndef IPEDMA_BUG_DMARD
RD(IPEDMA_REG_PAGE_COUNT, value);
if ((value + 1) != IPEDMA_DMA_PAGES) pcilib_warning("Inconsistent DMA buffers are found (Number of allocated buffers does not match current request), reinitializing...");
else
#endif /* IPEDMA_BUG_DMARD */
preserve = 1;
}
}
} else pcilib_warning("Inconsistent DMA buffers (modes of ring and page buffers does not match), reinitializing....");
desc_va = pcilib_kmem_get_ua(ctx->pcilib, desc);
if (ctx->mode64) last_written_addr_ptr = desc_va + 3 * sizeof(uint32_t);
else last_written_addr_ptr = desc_va + 4 * sizeof(uint32_t);
if (preserve) {
ctx->reused = 1;
ctx->preserve = 1;
// usleep(100000);
// Detect the current state of DMA engine
#ifdef IPEDMA_BUG_DMARD
FILE *f = fopen("/tmp/pcitool_lastread", "r");
if (!f) pcilib_error("Can't read current status");
fread(&value, 1, sizeof(pcilib_register_value_t), f);
fclose(f);
#else /* IPEDMA_BUG_DMARD */
RD(IPEDMA_REG_LAST_READ, value);
if (value == IPEDMA_DMA_PAGES) value = 0;
#endif /* IPEDMA_BUG_DMARD */
ctx->last_read = value;
} else {
ctx->reused = 0;
// Disable DMA
WR(IPEDMA_REG_CONTROL, 0x0);
// Reset DMA engine
WR(IPEDMA_REG_RESET, 0x1);
usleep(100000);
WR(IPEDMA_REG_RESET, 0x0);
#ifndef IPEDMA_BUG_DMARD
// Verify PCIe link status
RD(IPEDMA_REG_RESET, value);
if (value != 0x14031700) pcilib_warning("PCIe is not ready");
#endif /* IPEDMA_BUG_DMARD */
// Configuring TLP and PACKET sizes (40 bit mode can be used with big pre-allocated buffers later)
WR(IPEDMA_REG_TLP_SIZE, IPEDMA_TLP_SIZE);
WR(IPEDMA_REG_TLP_COUNT, IPEDMA_PAGE_SIZE / (4 * IPEDMA_TLP_SIZE * IPEDMA_CORES));
// Setting progress register threshold
WR(IPEDMA_REG_UPDATE_THRESHOLD, IPEDMA_DMA_PROGRESS_THRESHOLD);
// Reseting configured DMA pages
WR(IPEDMA_REG_PAGE_COUNT, 0);
// Setting current read position and configuring progress register
WR(IPEDMA_REG_LAST_READ, IPEDMA_DMA_PAGES - 2 + 1);
WR(IPEDMA_REG_UPDATE_ADDR, pcilib_kmem_get_block_ba(ctx->pcilib, desc, 0));
// Instructing DMA engine that writting should start from the first DMA page
*last_written_addr_ptr = 0;//htonl(pcilib_kmem_get_block_ba(ctx->pcilib, pages, IPEDMA_DMA_PAGES - 1));
for (i = 0; i < IPEDMA_DMA_PAGES; i++) {
uintptr_t bus_addr = pcilib_kmem_get_block_ba(ctx->pcilib, pages, i);
WR(IPEDMA_REG_PAGE_ADDR, bus_addr);
if (bus_addr%4096) printf("Bad address %lu: %lx\n", i, bus_addr);
usleep(1000);
}
// Enable DMA
WR(IPEDMA_REG_CONTROL, 0x1);
ctx->last_read = IPEDMA_DMA_PAGES - 1;
#ifdef IPEDMA_BUG_DMARD
FILE *f = fopen("/tmp/pcitool_lastread", "w");
if (!f) pcilib_error("Can't write current status");
value = ctx->last_read;
fwrite(&value, 1, sizeof(pcilib_register_value_t), f);
fclose(f);
#endif /* IPEDMA_BUG_DMARD */
}
ctx->last_read_addr = htonl(pcilib_kmem_get_block_ba(ctx->pcilib, pages, ctx->last_read));
ctx->desc = desc;
ctx->pages = pages;
ctx->page_size = pcilib_kmem_get_block_size(ctx->pcilib, pages, 0);;
ctx->ring_size = IPEDMA_DMA_PAGES;
return 0;
}
int dma_ipe_stop(pcilib_dma_context_t *vctx, pcilib_dma_engine_t dma, pcilib_dma_flags_t flags) {
pcilib_kmem_flags_t kflags;
ipe_dma_t *ctx = (ipe_dma_t*)vctx;
if (!ctx->started) return 0;
if ((dma != PCILIB_DMA_ENGINE_INVALID)&&(dma > 1)) return PCILIB_ERROR_INVALID_BANK;
// ignoring previous setting if flag specified
if (flags&PCILIB_DMA_FLAG_PERSISTENT) {
ctx->preserve = 0;
}
if (ctx->preserve) {
kflags = PCILIB_KMEM_FLAG_REUSE;
} else {
kflags = PCILIB_KMEM_FLAG_HARDWARE|PCILIB_KMEM_FLAG_PERSISTENT;
ctx->started = 0;
// Disable DMA
WR(IPEDMA_REG_CONTROL, 0);
// Reset DMA engine
WR(IPEDMA_REG_RESET, 0x1);
usleep(100000);
WR(IPEDMA_REG_RESET, 0x0);
// Reseting configured DMA pages
WR(IPEDMA_REG_PAGE_COUNT, 0);
}
// Clean buffers
if (ctx->desc) {
pcilib_free_kernel_memory(ctx->pcilib, ctx->desc, kflags);
ctx->desc = NULL;
}
if (ctx->pages) {
pcilib_free_kernel_memory(ctx->pcilib, ctx->pages, kflags);
ctx->pages = NULL;
}
return 0;
}
int dma_ipe_get_status(pcilib_dma_context_t *vctx, pcilib_dma_engine_t dma, pcilib_dma_engine_status_t *status, size_t n_buffers, pcilib_dma_buffer_status_t *buffers) {
size_t i;
ipe_dma_t *ctx = (ipe_dma_t*)vctx;
void *desc_va = (void*)pcilib_kmem_get_ua(ctx->pcilib, ctx->desc);
uint32_t *last_written_addr_ptr;
uint32_t last_written_addr;
if (!status) return -1;
if (ctx->mode64) last_written_addr_ptr = desc_va + 3 * sizeof(uint32_t);
else last_written_addr_ptr = desc_va + 4 * sizeof(uint32_t);
last_written_addr = ntohl(*last_written_addr_ptr);
status->started = ctx->started;
status->ring_size = ctx->ring_size;
status->buffer_size = ctx->page_size;
status->ring_tail = ctx->last_read + 1;
if (status->ring_tail == status->ring_size) status->ring_tail = 0;
// Find where the ring head is actually are
for (i = 0; i < ctx->ring_size; i++) {
uintptr_t bus_addr = pcilib_kmem_get_block_ba(ctx->pcilib, ctx->pages, i);
if (bus_addr == last_written_addr) {
status->ring_head = bus_addr;
break;
}
}
if (i == ctx->ring_size) {
// ERROR
}
if (n_buffers > ctx->ring_size) n_buffers = ctx->ring_size;
memset(buffers, 0, n_buffers * sizeof(pcilib_dma_engine_status_t));
if (status->ring_head > status->ring_tail) {
for (i = status->ring_tail; i <= status->ring_head; i++) {
buffers[i].used = 1;
buffers[i].size = ctx->page_size;
buffers[i].first = 1;
buffers[i].last = 1;
}
} else {
for (i = 0; i <= status->ring_tail; i++) {
buffers[i].used = 1;
buffers[i].size = ctx->page_size;
buffers[i].first = 1;
buffers[i].last = 1;
}
for (i = status->ring_head; i < status->ring_size; i++) {
buffers[i].used = 1;
buffers[i].size = ctx->page_size;
buffers[i].first = 1;
buffers[i].last = 1;
}
}
return 0;
}
int dma_ipe_stream_read(pcilib_dma_context_t *vctx, pcilib_dma_engine_t dma, uintptr_t addr, size_t size, pcilib_dma_flags_t flags, pcilib_timeout_t timeout, pcilib_dma_callback_t cb, void *cbattr) {
int err, ret = PCILIB_STREAMING_REQ_PACKET;
pcilib_register_value_t value;
pcilib_timeout_t wait = 0;
struct timeval start, cur;
volatile void *desc_va;
volatile uint32_t *last_written_addr_ptr;
size_t cur_read;
ipe_dma_t *ctx = (ipe_dma_t*)vctx;
err = dma_ipe_start(vctx, dma, PCILIB_DMA_FLAGS_DEFAULT);
if (err) return err;
desc_va = (void*)pcilib_kmem_get_ua(ctx->pcilib, ctx->desc);
if (ctx->mode64) last_written_addr_ptr = desc_va + 3 * sizeof(uint32_t);
else last_written_addr_ptr = desc_va + 4 * sizeof(uint32_t);
do {
switch (ret&PCILIB_STREAMING_TIMEOUT_MASK) {
case PCILIB_STREAMING_CONTINUE: wait = PCILIB_DMA_TIMEOUT; break;
case PCILIB_STREAMING_WAIT: wait = timeout; break;
// case PCILIB_STREAMING_CHECK: wait = 0; break;
}
#ifdef IPEDMA_DEBUG
printf("Waiting for data: %u (last read) 0x%x (last read addr) 0x%x (last_written)\n", ctx->last_read, ctx->last_read_addr, *last_written_addr_ptr);
#endif /* IPEDMA_DEBUG */
gettimeofday(&start, NULL);
while (((*last_written_addr_ptr == 0)||(ctx->last_read_addr == (*last_written_addr_ptr)))&&((wait == PCILIB_TIMEOUT_INFINITE)||(((cur.tv_sec - start.tv_sec)*1000000 + (cur.tv_usec - start.tv_usec)) < wait))) {
usleep(10);
gettimeofday(&cur, NULL);
}
// Failing out if we exited on timeout
if ((ctx->last_read_addr == (*last_written_addr_ptr))||(*last_written_addr_ptr == 0))
return (ret&PCILIB_STREAMING_FAIL)?PCILIB_ERROR_TIMEOUT:0;
// Getting next page to read
cur_read = ctx->last_read + 1;
if (cur_read == ctx->ring_size) cur_read = 0;
#ifdef IPEDMA_DEBUG
printf("Reading: %u (last read) 0x%x (last read addr) 0x%x (last_written)\n", cur_read, ctx->last_read_addr, *last_written_addr_ptr);
#endif /* IPEDMA_DEBUG */
pcilib_kmem_sync_block(ctx->pcilib, ctx->pages, PCILIB_KMEM_SYNC_FROMDEVICE, cur_read);
void *buf = pcilib_kmem_get_block_ua(ctx->pcilib, ctx->pages, cur_read);
ret = cb(cbattr, PCILIB_DMA_FLAG_EOP, ctx->page_size, buf);
if (ret < 0) return -ret;
// DS: Fixme, it looks like we can avoid calling this for the sake of performance
// pcilib_kmem_sync_block(ctx->pcilib, ctx->pages, PCILIB_KMEM_SYNC_TODEVICE, cur_read);
WR(IPEDMA_REG_LAST_READ, ctx->last_read + 1);
ctx->last_read = cur_read;
ctx->last_read_addr = htonl(pcilib_kmem_get_block_ba(ctx->pcilib, ctx->pages, cur_read));
#ifdef IPEDMA_BUG_DMARD
FILE *f = fopen("/tmp/pcitool_lastread", "w");
if (!f) pcilib_error("Can't write current status");
value = cur_read;
fwrite(&value, 1, sizeof(pcilib_register_value_t), f);
fclose(f);
#endif /* IPEDMA_BUG_DMARD */
} while (ret);
return 0;
}
double dma_ipe_benchmark(pcilib_dma_context_t *vctx, pcilib_dma_engine_addr_t dma, uintptr_t addr, size_t size, size_t iterations, pcilib_dma_direction_t direction) {
return 0;
}
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