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|
/*
* Copyright 2015 Advanced Micro Devices, Inc.
*
* 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
* on the rights to use, copy, modify, merge, publish, distribute, sub
* license, 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 (including the next
* paragraph) 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 NON-INFRINGEMENT. IN NO EVENT SHALL
* THE AUTHOR(S) AND/OR THEIR SUPPLIERS 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 "ac_debug.h"
#ifdef HAVE_VALGRIND
#include <valgrind.h>
#include <memcheck.h>
#define VG(x) x
#else
#define VG(x)
#endif
#include <inttypes.h>
#include "sid.h"
#include "gfx9d.h"
#include "sid_tables.h"
#include "util/u_math.h"
#include "util/u_memory.h"
#include "util/u_string.h"
#include <assert.h>
/* Parsed IBs are difficult to read without colors. Use "less -R file" to
* read them, or use "aha -b -f file" to convert them to html.
*/
#define COLOR_RESET "\033[0m"
#define COLOR_RED "\033[31m"
#define COLOR_GREEN "\033[1;32m"
#define COLOR_YELLOW "\033[1;33m"
#define COLOR_CYAN "\033[1;36m"
#define INDENT_PKT 8
struct ac_ib_parser {
FILE *f;
uint32_t *ib;
unsigned num_dw;
const int *trace_ids;
unsigned trace_id_count;
enum chip_class chip_class;
ac_debug_addr_callback addr_callback;
void *addr_callback_data;
unsigned cur_dw;
};
static void ac_do_parse_ib(FILE *f, struct ac_ib_parser *ib);
static void print_spaces(FILE *f, unsigned num)
{
fprintf(f, "%*s", num, "");
}
static void print_value(FILE *file, uint32_t value, int bits)
{
/* Guess if it's int or float */
if (value <= (1 << 15)) {
if (value <= 9)
fprintf(file, "%u\n", value);
else
fprintf(file, "%u (0x%0*x)\n", value, bits / 4, value);
} else {
float f = uif(value);
if (fabs(f) < 100000 && f*10 == floor(f*10))
fprintf(file, "%.1ff (0x%0*x)\n", f, bits / 4, value);
else
/* Don't print more leading zeros than there are bits. */
fprintf(file, "0x%0*x\n", bits / 4, value);
}
}
static void print_named_value(FILE *file, const char *name, uint32_t value,
int bits)
{
print_spaces(file, INDENT_PKT);
fprintf(file, COLOR_YELLOW "%s" COLOR_RESET " <- ", name);
print_value(file, value, bits);
}
static const struct si_reg *find_register(const struct si_reg *table,
unsigned table_size,
unsigned offset)
{
for (unsigned i = 0; i < table_size; i++) {
const struct si_reg *reg = &table[i];
if (reg->offset == offset)
return reg;
}
return NULL;
}
void ac_dump_reg(FILE *file, enum chip_class chip_class, unsigned offset,
uint32_t value, uint32_t field_mask)
{
const struct si_reg *reg = NULL;
if (chip_class >= GFX9)
reg = find_register(gfx9d_reg_table, ARRAY_SIZE(gfx9d_reg_table), offset);
if (!reg)
reg = find_register(sid_reg_table, ARRAY_SIZE(sid_reg_table), offset);
if (reg) {
const char *reg_name = sid_strings + reg->name_offset;
bool first_field = true;
print_spaces(file, INDENT_PKT);
fprintf(file, COLOR_YELLOW "%s" COLOR_RESET " <- ",
reg_name);
if (!reg->num_fields) {
print_value(file, value, 32);
return;
}
for (unsigned f = 0; f < reg->num_fields; f++) {
const struct si_field *field = sid_fields_table + reg->fields_offset + f;
const int *values_offsets = sid_strings_offsets + field->values_offset;
uint32_t val = (value & field->mask) >>
(ffs(field->mask) - 1);
if (!(field->mask & field_mask))
continue;
/* Indent the field. */
if (!first_field)
print_spaces(file,
INDENT_PKT + strlen(reg_name) + 4);
/* Print the field. */
fprintf(file, "%s = ", sid_strings + field->name_offset);
if (val < field->num_values && values_offsets[val] >= 0)
fprintf(file, "%s\n", sid_strings + values_offsets[val]);
else
print_value(file, val,
util_bitcount(field->mask));
first_field = false;
}
return;
}
print_spaces(file, INDENT_PKT);
fprintf(file, COLOR_YELLOW "0x%05x" COLOR_RESET " <- 0x%08x\n", offset, value);
}
static uint32_t ac_ib_get(struct ac_ib_parser *ib)
{
uint32_t v = 0;
if (ib->cur_dw < ib->num_dw) {
v = ib->ib[ib->cur_dw];
#ifdef HAVE_VALGRIND
/* Help figure out where garbage data is written to IBs.
*
* Arguably we should do this already when the IBs are written,
* see RADEON_VALGRIND. The problem is that client-requests to
* Valgrind have an overhead even when Valgrind isn't running,
* and radeon_emit is performance sensitive...
*/
if (VALGRIND_CHECK_VALUE_IS_DEFINED(v))
fprintf(ib->f, COLOR_RED "Valgrind: The next DWORD is garbage"
COLOR_RESET "\n");
#endif
fprintf(ib->f, "\n\035#%08x ", v);
} else {
fprintf(ib->f, "\n\035#???????? ");
}
ib->cur_dw++;
return v;
}
static void ac_parse_set_reg_packet(FILE *f, unsigned count, unsigned reg_offset,
struct ac_ib_parser *ib)
{
unsigned reg_dw = ac_ib_get(ib);
unsigned reg = ((reg_dw & 0xFFFF) << 2) + reg_offset;
unsigned index = reg_dw >> 28;
int i;
if (index != 0) {
print_spaces(f, INDENT_PKT);
fprintf(f, "INDEX = %u\n", index);
}
for (i = 0; i < count; i++)
ac_dump_reg(f, ib->chip_class, reg + i*4, ac_ib_get(ib), ~0);
}
static void ac_parse_packet3(FILE *f, uint32_t header, struct ac_ib_parser *ib,
int *current_trace_id)
{
unsigned first_dw = ib->cur_dw;
int count = PKT_COUNT_G(header);
unsigned op = PKT3_IT_OPCODE_G(header);
const char *predicate = PKT3_PREDICATE(header) ? "(predicate)" : "";
int i;
/* Print the name first. */
for (i = 0; i < ARRAY_SIZE(packet3_table); i++)
if (packet3_table[i].op == op)
break;
if (i < ARRAY_SIZE(packet3_table)) {
const char *name = sid_strings + packet3_table[i].name_offset;
if (op == PKT3_SET_CONTEXT_REG ||
op == PKT3_SET_CONFIG_REG ||
op == PKT3_SET_UCONFIG_REG ||
op == PKT3_SET_UCONFIG_REG_INDEX ||
op == PKT3_SET_SH_REG)
fprintf(f, COLOR_CYAN "%s%s" COLOR_CYAN ":\n",
name, predicate);
else
fprintf(f, COLOR_GREEN "%s%s" COLOR_RESET ":\n",
name, predicate);
} else
fprintf(f, COLOR_RED "PKT3_UNKNOWN 0x%x%s" COLOR_RESET ":\n",
op, predicate);
/* Print the contents. */
switch (op) {
case PKT3_SET_CONTEXT_REG:
ac_parse_set_reg_packet(f, count, SI_CONTEXT_REG_OFFSET, ib);
break;
case PKT3_SET_CONFIG_REG:
ac_parse_set_reg_packet(f, count, SI_CONFIG_REG_OFFSET, ib);
break;
case PKT3_SET_UCONFIG_REG:
case PKT3_SET_UCONFIG_REG_INDEX:
ac_parse_set_reg_packet(f, count, CIK_UCONFIG_REG_OFFSET, ib);
break;
case PKT3_SET_SH_REG:
ac_parse_set_reg_packet(f, count, SI_SH_REG_OFFSET, ib);
break;
case PKT3_ACQUIRE_MEM:
ac_dump_reg(f, ib->chip_class, R_0301F0_CP_COHER_CNTL, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_0301F4_CP_COHER_SIZE, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_030230_CP_COHER_SIZE_HI, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_0301F8_CP_COHER_BASE, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_0301E4_CP_COHER_BASE_HI, ac_ib_get(ib), ~0);
print_named_value(f, "POLL_INTERVAL", ac_ib_get(ib), 16);
break;
case PKT3_SURFACE_SYNC:
if (ib->chip_class >= CIK) {
ac_dump_reg(f, ib->chip_class, R_0301F0_CP_COHER_CNTL, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_0301F4_CP_COHER_SIZE, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_0301F8_CP_COHER_BASE, ac_ib_get(ib), ~0);
} else {
ac_dump_reg(f, ib->chip_class, R_0085F0_CP_COHER_CNTL, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_0085F4_CP_COHER_SIZE, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_0085F8_CP_COHER_BASE, ac_ib_get(ib), ~0);
}
print_named_value(f, "POLL_INTERVAL", ac_ib_get(ib), 16);
break;
case PKT3_EVENT_WRITE: {
uint32_t event_dw = ac_ib_get(ib);
ac_dump_reg(f, ib->chip_class, R_028A90_VGT_EVENT_INITIATOR, event_dw,
S_028A90_EVENT_TYPE(~0));
print_named_value(f, "EVENT_INDEX", (event_dw >> 8) & 0xf, 4);
print_named_value(f, "INV_L2", (event_dw >> 20) & 0x1, 1);
if (count > 0) {
print_named_value(f, "ADDRESS_LO", ac_ib_get(ib), 32);
print_named_value(f, "ADDRESS_HI", ac_ib_get(ib), 16);
}
break;
}
case PKT3_EVENT_WRITE_EOP: {
uint32_t event_dw = ac_ib_get(ib);
ac_dump_reg(f, ib->chip_class, R_028A90_VGT_EVENT_INITIATOR, event_dw,
S_028A90_EVENT_TYPE(~0));
print_named_value(f, "EVENT_INDEX", (event_dw >> 8) & 0xf, 4);
print_named_value(f, "TCL1_VOL_ACTION_ENA", (event_dw >> 12) & 0x1, 1);
print_named_value(f, "TC_VOL_ACTION_ENA", (event_dw >> 13) & 0x1, 1);
print_named_value(f, "TC_WB_ACTION_ENA", (event_dw >> 15) & 0x1, 1);
print_named_value(f, "TCL1_ACTION_ENA", (event_dw >> 16) & 0x1, 1);
print_named_value(f, "TC_ACTION_ENA", (event_dw >> 17) & 0x1, 1);
print_named_value(f, "ADDRESS_LO", ac_ib_get(ib), 32);
uint32_t addr_hi_dw = ac_ib_get(ib);
print_named_value(f, "ADDRESS_HI", addr_hi_dw, 16);
print_named_value(f, "DST_SEL", (addr_hi_dw >> 16) & 0x3, 2);
print_named_value(f, "INT_SEL", (addr_hi_dw >> 24) & 0x7, 3);
print_named_value(f, "DATA_SEL", addr_hi_dw >> 29, 3);
print_named_value(f, "DATA_LO", ac_ib_get(ib), 32);
print_named_value(f, "DATA_HI", ac_ib_get(ib), 32);
break;
}
case PKT3_RELEASE_MEM: {
uint32_t event_dw = ac_ib_get(ib);
ac_dump_reg(f, ib->chip_class, R_028A90_VGT_EVENT_INITIATOR, event_dw,
S_028A90_EVENT_TYPE(~0));
print_named_value(f, "EVENT_INDEX", (event_dw >> 8) & 0xf, 4);
print_named_value(f, "TCL1_VOL_ACTION_ENA", (event_dw >> 12) & 0x1, 1);
print_named_value(f, "TC_VOL_ACTION_ENA", (event_dw >> 13) & 0x1, 1);
print_named_value(f, "TC_WB_ACTION_ENA", (event_dw >> 15) & 0x1, 1);
print_named_value(f, "TCL1_ACTION_ENA", (event_dw >> 16) & 0x1, 1);
print_named_value(f, "TC_ACTION_ENA", (event_dw >> 17) & 0x1, 1);
print_named_value(f, "TC_NC_ACTION_ENA", (event_dw >> 19) & 0x1, 1);
print_named_value(f, "TC_WC_ACTION_ENA", (event_dw >> 20) & 0x1, 1);
print_named_value(f, "TC_MD_ACTION_ENA", (event_dw >> 21) & 0x1, 1);
uint32_t sel_dw = ac_ib_get(ib);
print_named_value(f, "DST_SEL", (sel_dw >> 16) & 0x3, 2);
print_named_value(f, "INT_SEL", (sel_dw >> 24) & 0x7, 3);
print_named_value(f, "DATA_SEL", sel_dw >> 29, 3);
print_named_value(f, "ADDRESS_LO", ac_ib_get(ib), 32);
print_named_value(f, "ADDRESS_HI", ac_ib_get(ib), 32);
print_named_value(f, "DATA_LO", ac_ib_get(ib), 32);
print_named_value(f, "DATA_HI", ac_ib_get(ib), 32);
print_named_value(f, "CTXID", ac_ib_get(ib), 32);
break;
}
case PKT3_WAIT_REG_MEM:
print_named_value(f, "OP", ac_ib_get(ib), 32);
print_named_value(f, "ADDRESS_LO", ac_ib_get(ib), 32);
print_named_value(f, "ADDRESS_HI", ac_ib_get(ib), 32);
print_named_value(f, "REF", ac_ib_get(ib), 32);
print_named_value(f, "MASK", ac_ib_get(ib), 32);
print_named_value(f, "POLL_INTERVAL", ac_ib_get(ib), 16);
break;
case PKT3_DRAW_INDEX_AUTO:
ac_dump_reg(f, ib->chip_class, R_030930_VGT_NUM_INDICES, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_0287F0_VGT_DRAW_INITIATOR, ac_ib_get(ib), ~0);
break;
case PKT3_DRAW_INDEX_2:
ac_dump_reg(f, ib->chip_class, R_028A78_VGT_DMA_MAX_SIZE, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_0287E8_VGT_DMA_BASE, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_0287E4_VGT_DMA_BASE_HI, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_030930_VGT_NUM_INDICES, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_0287F0_VGT_DRAW_INITIATOR, ac_ib_get(ib), ~0);
break;
case PKT3_INDEX_TYPE:
ac_dump_reg(f, ib->chip_class, R_028A7C_VGT_DMA_INDEX_TYPE, ac_ib_get(ib), ~0);
break;
case PKT3_NUM_INSTANCES:
ac_dump_reg(f, ib->chip_class, R_030934_VGT_NUM_INSTANCES, ac_ib_get(ib), ~0);
break;
case PKT3_WRITE_DATA:
ac_dump_reg(f, ib->chip_class, R_370_CONTROL, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_371_DST_ADDR_LO, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_372_DST_ADDR_HI, ac_ib_get(ib), ~0);
/* The payload is written automatically */
break;
case PKT3_CP_DMA:
ac_dump_reg(f, ib->chip_class, R_410_CP_DMA_WORD0, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_411_CP_DMA_WORD1, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_412_CP_DMA_WORD2, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_413_CP_DMA_WORD3, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_414_COMMAND, ac_ib_get(ib), ~0);
break;
case PKT3_DMA_DATA:
ac_dump_reg(f, ib->chip_class, R_500_DMA_DATA_WORD0, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_501_SRC_ADDR_LO, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_502_SRC_ADDR_HI, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_503_DST_ADDR_LO, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_504_DST_ADDR_HI, ac_ib_get(ib), ~0);
ac_dump_reg(f, ib->chip_class, R_414_COMMAND, ac_ib_get(ib), ~0);
break;
case PKT3_INDIRECT_BUFFER_SI:
case PKT3_INDIRECT_BUFFER_CONST:
case PKT3_INDIRECT_BUFFER_CIK: {
uint32_t base_lo_dw = ac_ib_get(ib);
ac_dump_reg(f, ib->chip_class, R_3F0_IB_BASE_LO, base_lo_dw, ~0);
uint32_t base_hi_dw = ac_ib_get(ib);
ac_dump_reg(f, ib->chip_class, R_3F1_IB_BASE_HI, base_hi_dw, ~0);
uint32_t control_dw = ac_ib_get(ib);
ac_dump_reg(f, ib->chip_class, R_3F2_CONTROL, control_dw, ~0);
if (!ib->addr_callback)
break;
uint64_t addr = ((uint64_t)base_hi_dw << 32) | base_lo_dw;
void *data = ib->addr_callback(ib->addr_callback_data, addr);
if (!data)
break;
if (G_3F2_CHAIN(control_dw)) {
ib->ib = data;
ib->num_dw = G_3F2_IB_SIZE(control_dw);
ib->cur_dw = 0;
return;
}
struct ac_ib_parser ib_recurse;
memcpy(&ib_recurse, ib, sizeof(ib_recurse));
ib_recurse.ib = data;
ib_recurse.num_dw = G_3F2_IB_SIZE(control_dw);
ib_recurse.cur_dw = 0;
if(ib_recurse.trace_id_count) {
if (*current_trace_id == *ib->trace_ids) {
++ib_recurse.trace_ids;
--ib_recurse.trace_id_count;
} else {
ib_recurse.trace_id_count = 0;
}
}
fprintf(f, "\n\035>------------------ nested begin ------------------\n");
ac_do_parse_ib(f, &ib_recurse);
fprintf(f, "\n\035<------------------- nested end -------------------\n");
break;
}
case PKT3_CLEAR_STATE:
case PKT3_INCREMENT_DE_COUNTER:
case PKT3_PFP_SYNC_ME:
break;
case PKT3_NOP:
if (header == 0xffff1000) {
count = -1; /* One dword NOP. */
} else if (count == 0 && ib->cur_dw < ib->num_dw &&
AC_IS_TRACE_POINT(ib->ib[ib->cur_dw])) {
unsigned packet_id = AC_GET_TRACE_POINT_ID(ib->ib[ib->cur_dw]);
print_spaces(f, INDENT_PKT);
fprintf(f, COLOR_RED "Trace point ID: %u\n", packet_id);
if (!ib->trace_id_count)
break; /* tracing was disabled */
*current_trace_id = packet_id;
print_spaces(f, INDENT_PKT);
if (packet_id < *ib->trace_ids)
fprintf(f, COLOR_RED
"This trace point was reached by the CP."
COLOR_RESET "\n");
else if (packet_id == *ib->trace_ids)
fprintf(f, COLOR_RED
"!!!!! This is the last trace point that "
"was reached by the CP !!!!!"
COLOR_RESET "\n");
else if (packet_id+1 == *ib->trace_ids)
fprintf(f, COLOR_RED
"!!!!! This is the first trace point that "
"was NOT been reached by the CP !!!!!"
COLOR_RESET "\n");
else
fprintf(f, COLOR_RED
"!!!!! This trace point was NOT reached "
"by the CP !!!!!"
COLOR_RESET "\n");
break;
}
break;
}
/* print additional dwords */
while (ib->cur_dw <= first_dw + count)
ac_ib_get(ib);
if (ib->cur_dw > first_dw + count + 1)
fprintf(f, COLOR_RED "\n!!!!! count in header too low !!!!!"
COLOR_RESET "\n");
}
/**
* Parse and print an IB into a file.
*/
static void ac_do_parse_ib(FILE *f, struct ac_ib_parser *ib)
{
int current_trace_id = -1;
while (ib->cur_dw < ib->num_dw) {
uint32_t header = ac_ib_get(ib);
unsigned type = PKT_TYPE_G(header);
switch (type) {
case 3:
ac_parse_packet3(f, header, ib, ¤t_trace_id);
break;
case 2:
/* type-2 nop */
if (header == 0x80000000) {
fprintf(f, COLOR_GREEN "NOP (type 2)" COLOR_RESET "\n");
break;
}
/* fall through */
default:
fprintf(f, "Unknown packet type %i\n", type);
break;
}
}
}
static void format_ib_output(FILE *f, char *out)
{
unsigned depth = 0;
for (;;) {
char op = 0;
if (out[0] == '\n' && out[1] == '\035')
out++;
if (out[0] == '\035') {
op = out[1];
out += 2;
}
if (op == '<')
depth--;
unsigned indent = 4 * depth;
if (op != '#')
indent += 9;
if (indent)
print_spaces(f, indent);
char *end = util_strchrnul(out, '\n');
fwrite(out, end - out, 1, f);
fputc('\n', f); /* always end with a new line */
if (!*end)
break;
out = end + 1;
if (op == '>')
depth++;
}
}
/**
* Parse and print an IB into a file.
*
* \param f file
* \param ib_ptr IB
* \param num_dw size of the IB
* \param chip_class chip class
* \param trace_ids the last trace IDs that are known to have been reached
* and executed by the CP, typically read from a buffer
* \param trace_id_count The number of entries in the trace_ids array.
* \param addr_callback Get a mapped pointer of the IB at a given address. Can
* be NULL.
* \param addr_callback_data user data for addr_callback
*/
void ac_parse_ib_chunk(FILE *f, uint32_t *ib_ptr, int num_dw, const int *trace_ids,
unsigned trace_id_count, enum chip_class chip_class,
ac_debug_addr_callback addr_callback, void *addr_callback_data)
{
struct ac_ib_parser ib = {};
ib.ib = ib_ptr;
ib.num_dw = num_dw;
ib.trace_ids = trace_ids;
ib.trace_id_count = trace_id_count;
ib.chip_class = chip_class;
ib.addr_callback = addr_callback;
ib.addr_callback_data = addr_callback_data;
char *out;
size_t outsize;
FILE *memf = open_memstream(&out, &outsize);
ib.f = memf;
ac_do_parse_ib(memf, &ib);
fclose(memf);
if (out) {
format_ib_output(f, out);
free(out);
}
if (ib.cur_dw > ib.num_dw) {
printf("\nPacket ends after the end of IB.\n");
exit(1);
}
}
/**
* Parse and print an IB into a file.
*
* \param f file
* \param ib IB
* \param num_dw size of the IB
* \param chip_class chip class
* \param trace_ids the last trace IDs that are known to have been reached
* and executed by the CP, typically read from a buffer
* \param trace_id_count The number of entries in the trace_ids array.
* \param addr_callback Get a mapped pointer of the IB at a given address. Can
* be NULL.
* \param addr_callback_data user data for addr_callback
*/
void ac_parse_ib(FILE *f, uint32_t *ib, int num_dw, const int *trace_ids,
unsigned trace_id_count, const char *name,
enum chip_class chip_class, ac_debug_addr_callback addr_callback,
void *addr_callback_data)
{
fprintf(f, "------------------ %s begin ------------------\n", name);
ac_parse_ib_chunk(f, ib, num_dw, trace_ids, trace_id_count,
chip_class, addr_callback, addr_callback_data);
fprintf(f, "------------------- %s end -------------------\n\n", name);
}
/**
* Parse dmesg and return TRUE if a VM fault has been detected.
*
* \param chip_class chip class
* \param old_dmesg_timestamp previous dmesg timestamp parsed at init time
* \param out_addr detected VM fault addr
*/
bool ac_vm_fault_occured(enum chip_class chip_class,
uint64_t *old_dmesg_timestamp, uint64_t *out_addr)
{
char line[2000];
unsigned sec, usec;
int progress = 0;
uint64_t dmesg_timestamp = 0;
bool fault = false;
FILE *p = popen("dmesg", "r");
if (!p)
return false;
while (fgets(line, sizeof(line), p)) {
char *msg, len;
if (!line[0] || line[0] == '\n')
continue;
/* Get the timestamp. */
if (sscanf(line, "[%u.%u]", &sec, &usec) != 2) {
static bool hit = false;
if (!hit) {
fprintf(stderr, "%s: failed to parse line '%s'\n",
__func__, line);
hit = true;
}
continue;
}
dmesg_timestamp = sec * 1000000ull + usec;
/* If just updating the timestamp. */
if (!out_addr)
continue;
/* Process messages only if the timestamp is newer. */
if (dmesg_timestamp <= *old_dmesg_timestamp)
continue;
/* Only process the first VM fault. */
if (fault)
continue;
/* Remove trailing \n */
len = strlen(line);
if (len && line[len-1] == '\n')
line[len-1] = 0;
/* Get the message part. */
msg = strchr(line, ']');
if (!msg)
continue;
msg++;
const char *header_line, *addr_line_prefix, *addr_line_format;
if (chip_class >= GFX9) {
/* Match this:
* ..: [gfxhub] VMC page fault (src_id:0 ring:158 vm_id:2 pas_id:0)
* ..: at page 0x0000000219f8f000 from 27
* ..: VM_L2_PROTECTION_FAULT_STATUS:0x0020113C
*/
header_line = "VMC page fault";
addr_line_prefix = " at page";
addr_line_format = "%"PRIx64;
} else {
header_line = "GPU fault detected:";
addr_line_prefix = "VM_CONTEXT1_PROTECTION_FAULT_ADDR";
addr_line_format = "%"PRIX64;
}
switch (progress) {
case 0:
if (strstr(msg, header_line))
progress = 1;
break;
case 1:
msg = strstr(msg, addr_line_prefix);
if (msg) {
msg = strstr(msg, "0x");
if (msg) {
msg += 2;
if (sscanf(msg, addr_line_format, out_addr) == 1)
fault = true;
}
}
progress = 0;
break;
default:
progress = 0;
}
}
pclose(p);
if (dmesg_timestamp > *old_dmesg_timestamp)
*old_dmesg_timestamp = dmesg_timestamp;
return fault;
}
static int compare_wave(const void *p1, const void *p2)
{
struct ac_wave_info *w1 = (struct ac_wave_info *)p1;
struct ac_wave_info *w2 = (struct ac_wave_info *)p2;
/* Sort waves according to PC and then SE, SH, CU, etc. */
if (w1->pc < w2->pc)
return -1;
if (w1->pc > w2->pc)
return 1;
if (w1->se < w2->se)
return -1;
if (w1->se > w2->se)
return 1;
if (w1->sh < w2->sh)
return -1;
if (w1->sh > w2->sh)
return 1;
if (w1->cu < w2->cu)
return -1;
if (w1->cu > w2->cu)
return 1;
if (w1->simd < w2->simd)
return -1;
if (w1->simd > w2->simd)
return 1;
if (w1->wave < w2->wave)
return -1;
if (w1->wave > w2->wave)
return 1;
return 0;
}
/* Return wave information. "waves" should be a large enough array. */
unsigned ac_get_wave_info(struct ac_wave_info waves[AC_MAX_WAVES_PER_CHIP])
{
char line[2000];
unsigned num_waves = 0;
FILE *p = popen("umr -O halt_waves -wa", "r");
if (!p)
return 0;
if (!fgets(line, sizeof(line), p) ||
strncmp(line, "SE", 2) != 0) {
pclose(p);
return 0;
}
while (fgets(line, sizeof(line), p)) {
struct ac_wave_info *w;
uint32_t pc_hi, pc_lo, exec_hi, exec_lo;
assert(num_waves < AC_MAX_WAVES_PER_CHIP);
w = &waves[num_waves];
if (sscanf(line, "%u %u %u %u %u %x %x %x %x %x %x %x",
&w->se, &w->sh, &w->cu, &w->simd, &w->wave,
&w->status, &pc_hi, &pc_lo, &w->inst_dw0,
&w->inst_dw1, &exec_hi, &exec_lo) == 12) {
w->pc = ((uint64_t)pc_hi << 32) | pc_lo;
w->exec = ((uint64_t)exec_hi << 32) | exec_lo;
w->matched = false;
num_waves++;
}
}
qsort(waves, num_waves, sizeof(struct ac_wave_info), compare_wave);
pclose(p);
return num_waves;
}
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