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/*
* Copyright © 2019 Google LLC
* SPDX-License-Identifier: MIT
*/
#include "tu_cs.h"
#include "tu_suballoc.h"
/**
* Initialize a command stream.
*/
void
tu_cs_init(struct tu_cs *cs,
struct tu_device *device,
enum tu_cs_mode mode,
uint32_t initial_size, const char *name)
{
assert(mode != TU_CS_MODE_EXTERNAL);
memset(cs, 0, sizeof(*cs));
cs->device = device;
cs->mode = mode;
cs->next_bo_size = initial_size;
cs->name = name;
}
/**
* Initialize a command stream as a wrapper to an external buffer.
*/
void
tu_cs_init_external(struct tu_cs *cs, struct tu_device *device,
uint32_t *start, uint32_t *end)
{
memset(cs, 0, sizeof(*cs));
cs->device = device;
cs->mode = TU_CS_MODE_EXTERNAL;
cs->start = cs->reserved_end = cs->cur = start;
cs->end = end;
}
/**
* Initialize a sub-command stream as a wrapper to an externally sub-allocated
* buffer.
*/
void
tu_cs_init_suballoc(struct tu_cs *cs, struct tu_device *device,
struct tu_suballoc_bo *suballoc_bo)
{
uint32_t *start = tu_suballoc_bo_map(suballoc_bo);
uint32_t *end = start + (suballoc_bo->size >> 2);
memset(cs, 0, sizeof(*cs));
cs->device = device;
cs->mode = TU_CS_MODE_SUB_STREAM;
cs->start = cs->reserved_end = cs->cur = start;
cs->end = end;
cs->refcount_bo = tu_bo_get_ref(suballoc_bo->bo);
}
/**
* Finish and release all resources owned by a command stream.
*/
void
tu_cs_finish(struct tu_cs *cs)
{
for (uint32_t i = 0; i < cs->bo_count; ++i) {
tu_bo_finish(cs->device, cs->bos[i]);
}
if (cs->refcount_bo)
tu_bo_finish(cs->device, cs->refcount_bo);
free(cs->entries);
free(cs->bos);
}
static struct tu_bo *
tu_cs_current_bo(const struct tu_cs *cs)
{
if (cs->refcount_bo) {
return cs->refcount_bo;
} else {
assert(cs->bo_count);
return cs->bos[cs->bo_count - 1];
}
}
/**
* Get the offset of the command packets emitted since the last call to
* tu_cs_add_entry.
*/
static uint32_t
tu_cs_get_offset(const struct tu_cs *cs)
{
return cs->start - (uint32_t *) tu_cs_current_bo(cs)->map;
}
/*
* Allocate and add a BO to a command stream. Following command packets will
* be emitted to the new BO.
*/
static VkResult
tu_cs_add_bo(struct tu_cs *cs, uint32_t size)
{
/* no BO for TU_CS_MODE_EXTERNAL */
assert(cs->mode != TU_CS_MODE_EXTERNAL);
/* No adding more BOs if suballocating from a suballoc_bo. */
assert(!cs->refcount_bo);
/* no dangling command packet */
assert(tu_cs_is_empty(cs));
/* grow cs->bos if needed */
if (cs->bo_count == cs->bo_capacity) {
uint32_t new_capacity = MAX2(4, 2 * cs->bo_capacity);
struct tu_bo **new_bos =
realloc(cs->bos, new_capacity * sizeof(struct tu_bo *));
if (!new_bos)
return VK_ERROR_OUT_OF_HOST_MEMORY;
cs->bo_capacity = new_capacity;
cs->bos = new_bos;
}
struct tu_bo *new_bo;
VkResult result =
tu_bo_init_new(cs->device, &new_bo, size * sizeof(uint32_t),
TU_BO_ALLOC_GPU_READ_ONLY | TU_BO_ALLOC_ALLOW_DUMP, cs->name);
if (result != VK_SUCCESS) {
return result;
}
result = tu_bo_map(cs->device, new_bo);
if (result != VK_SUCCESS) {
tu_bo_finish(cs->device, new_bo);
return result;
}
cs->bos[cs->bo_count++] = new_bo;
cs->start = cs->cur = cs->reserved_end = (uint32_t *) new_bo->map;
cs->end = cs->start + new_bo->size / sizeof(uint32_t);
return VK_SUCCESS;
}
/**
* Reserve an IB entry.
*/
static VkResult
tu_cs_reserve_entry(struct tu_cs *cs)
{
/* entries are only for TU_CS_MODE_GROW */
assert(cs->mode == TU_CS_MODE_GROW);
/* grow cs->entries if needed */
if (cs->entry_count == cs->entry_capacity) {
uint32_t new_capacity = MAX2(4, cs->entry_capacity * 2);
struct tu_cs_entry *new_entries =
realloc(cs->entries, new_capacity * sizeof(struct tu_cs_entry));
if (!new_entries)
return VK_ERROR_OUT_OF_HOST_MEMORY;
cs->entry_capacity = new_capacity;
cs->entries = new_entries;
}
return VK_SUCCESS;
}
/**
* Add an IB entry for the command packets emitted since the last call to this
* function.
*/
static void
tu_cs_add_entry(struct tu_cs *cs)
{
/* entries are only for TU_CS_MODE_GROW */
assert(cs->mode == TU_CS_MODE_GROW);
/* disallow empty entry */
assert(!tu_cs_is_empty(cs));
/*
* because we disallow empty entry, tu_cs_add_bo and tu_cs_reserve_entry
* must both have been called
*/
assert(cs->bo_count);
assert(cs->entry_count < cs->entry_capacity);
/* add an entry for [cs->start, cs->cur] */
cs->entries[cs->entry_count++] = (struct tu_cs_entry) {
.bo = tu_cs_current_bo(cs),
.size = tu_cs_get_size(cs) * sizeof(uint32_t),
.offset = tu_cs_get_offset(cs) * sizeof(uint32_t),
};
cs->start = cs->cur;
}
/**
* same behavior as tu_cs_emit_call but without the indirect
*/
VkResult
tu_cs_add_entries(struct tu_cs *cs, struct tu_cs *target)
{
VkResult result;
assert(cs->mode == TU_CS_MODE_GROW);
assert(target->mode == TU_CS_MODE_GROW);
if (!tu_cs_is_empty(cs))
tu_cs_add_entry(cs);
for (unsigned i = 0; i < target->entry_count; i++) {
result = tu_cs_reserve_entry(cs);
if (result != VK_SUCCESS)
return result;
cs->entries[cs->entry_count++] = target->entries[i];
}
return VK_SUCCESS;
}
/**
* Begin (or continue) command packet emission. This does nothing but sanity
* checks currently. \a cs must not be in TU_CS_MODE_SUB_STREAM mode.
*/
void
tu_cs_begin(struct tu_cs *cs)
{
assert(cs->mode != TU_CS_MODE_SUB_STREAM);
assert(tu_cs_is_empty(cs));
}
/**
* End command packet emission. This adds an IB entry when \a cs is in
* TU_CS_MODE_GROW mode.
*/
void
tu_cs_end(struct tu_cs *cs)
{
assert(cs->mode != TU_CS_MODE_SUB_STREAM);
if (cs->mode == TU_CS_MODE_GROW && !tu_cs_is_empty(cs))
tu_cs_add_entry(cs);
}
/**
* Begin command packet emission to a sub-stream. \a cs must be in
* TU_CS_MODE_SUB_STREAM mode.
*
* Return \a sub_cs which is in TU_CS_MODE_EXTERNAL mode. tu_cs_begin and
* tu_cs_reserve_space are implied and \a sub_cs is ready for command packet
* emission.
*/
VkResult
tu_cs_begin_sub_stream(struct tu_cs *cs, uint32_t size, struct tu_cs *sub_cs)
{
assert(cs->mode == TU_CS_MODE_SUB_STREAM);
assert(size);
VkResult result = tu_cs_reserve_space(cs, size);
if (result != VK_SUCCESS)
return result;
tu_cs_init_external(sub_cs, cs->device, cs->cur, cs->reserved_end);
tu_cs_begin(sub_cs);
result = tu_cs_reserve_space(sub_cs, size);
assert(result == VK_SUCCESS);
return VK_SUCCESS;
}
/**
* Allocate count*size dwords, aligned to size dwords.
* \a cs must be in TU_CS_MODE_SUB_STREAM mode.
*
*/
VkResult
tu_cs_alloc(struct tu_cs *cs,
uint32_t count,
uint32_t size,
struct tu_cs_memory *memory)
{
assert(cs->mode == TU_CS_MODE_SUB_STREAM);
assert(size && size <= 1024);
if (!count)
return VK_SUCCESS;
/* TODO: smarter way to deal with alignment? */
VkResult result = tu_cs_reserve_space(cs, count * size + (size-1));
if (result != VK_SUCCESS)
return result;
struct tu_bo *bo = tu_cs_current_bo(cs);
size_t offset = align(tu_cs_get_offset(cs), size);
memory->map = bo->map + offset * sizeof(uint32_t);
memory->iova = bo->iova + offset * sizeof(uint32_t);
cs->start = cs->cur = (uint32_t*) bo->map + offset + count * size;
return VK_SUCCESS;
}
/**
* End command packet emission to a sub-stream. \a sub_cs becomes invalid
* after this call.
*
* Return an IB entry for the sub-stream. The entry has the same lifetime as
* \a cs.
*/
struct tu_cs_entry
tu_cs_end_sub_stream(struct tu_cs *cs, struct tu_cs *sub_cs)
{
assert(cs->mode == TU_CS_MODE_SUB_STREAM);
assert(sub_cs->start == cs->cur && sub_cs->end == cs->reserved_end);
tu_cs_sanity_check(sub_cs);
tu_cs_end(sub_cs);
cs->cur = sub_cs->cur;
struct tu_cs_entry entry = {
.bo = tu_cs_current_bo(cs),
.size = tu_cs_get_size(cs) * sizeof(uint32_t),
.offset = tu_cs_get_offset(cs) * sizeof(uint32_t),
};
cs->start = cs->cur;
return entry;
}
/**
* Reserve space from a command stream for \a reserved_size uint32_t values.
* This never fails when \a cs has mode TU_CS_MODE_EXTERNAL.
*/
VkResult
tu_cs_reserve_space(struct tu_cs *cs, uint32_t reserved_size)
{
if (tu_cs_get_space(cs) < reserved_size) {
if (cs->mode == TU_CS_MODE_EXTERNAL) {
unreachable("cannot grow external buffer");
return VK_ERROR_OUT_OF_HOST_MEMORY;
}
/* add an entry for the exiting command packets */
if (!tu_cs_is_empty(cs)) {
/* no direct command packet for TU_CS_MODE_SUB_STREAM */
assert(cs->mode != TU_CS_MODE_SUB_STREAM);
tu_cs_add_entry(cs);
}
for (uint32_t i = 0; i < cs->cond_stack_depth; i++) {
/* Subtract one here to account for the DWORD field itself. */
*cs->cond_dwords[i] = cs->cur - cs->cond_dwords[i] - 1;
/* space for CP_COND_REG_EXEC in next bo */
reserved_size += 3;
}
/* switch to a new BO */
uint32_t new_size = MAX2(cs->next_bo_size, reserved_size);
VkResult result = tu_cs_add_bo(cs, new_size);
if (result != VK_SUCCESS)
return result;
if (cs->cond_stack_depth) {
cs->reserved_end = cs->cur + reserved_size;
}
/* Re-emit CP_COND_REG_EXECs */
for (uint32_t i = 0; i < cs->cond_stack_depth; i++) {
tu_cs_emit_pkt7(cs, CP_COND_REG_EXEC, 2);
tu_cs_emit(cs, cs->cond_flags[i]);
cs->cond_dwords[i] = cs->cur;
/* Emit dummy DWORD field here */
tu_cs_emit(cs, CP_COND_REG_EXEC_1_DWORDS(0));
}
/* double the size for the next bo, also there is an upper
* bound on IB size, which appears to be 0x0fffff
*/
new_size = MIN2(new_size << 1, 0x0fffff);
if (cs->next_bo_size < new_size)
cs->next_bo_size = new_size;
}
assert(tu_cs_get_space(cs) >= reserved_size);
cs->reserved_end = cs->cur + reserved_size;
if (cs->mode == TU_CS_MODE_GROW) {
/* reserve an entry for the next call to this function or tu_cs_end */
return tu_cs_reserve_entry(cs);
}
return VK_SUCCESS;
}
/**
* Reset a command stream to its initial state. This discards all comand
* packets in \a cs, but does not necessarily release all resources.
*/
void
tu_cs_reset(struct tu_cs *cs)
{
if (cs->mode == TU_CS_MODE_EXTERNAL) {
assert(!cs->bo_count && !cs->refcount_bo && !cs->entry_count);
cs->reserved_end = cs->cur = cs->start;
return;
}
for (uint32_t i = 0; i + 1 < cs->bo_count; ++i) {
tu_bo_finish(cs->device, cs->bos[i]);
}
if (cs->bo_count) {
cs->bos[0] = cs->bos[cs->bo_count - 1];
cs->bo_count = 1;
cs->start = cs->cur = cs->reserved_end = (uint32_t *) cs->bos[0]->map;
cs->end = cs->start + cs->bos[0]->size / sizeof(uint32_t);
}
cs->entry_count = 0;
}
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