vkd3d/libs/vkd3d-shader/hlsl_codegen.c

439 lines
14 KiB
C
Raw Normal View History

/*
* HLSL optimization and code generation
*
* Copyright 2019-2020 Zebediah Figura for CodeWeavers
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
*/
#include "hlsl.h"
static bool transform_ir(struct hlsl_ctx *ctx, bool (*func)(struct hlsl_ctx *ctx, struct hlsl_ir_node *, void *),
struct list *instrs, void *context)
{
struct hlsl_ir_node *instr, *next;
bool progress = 0;
LIST_FOR_EACH_ENTRY_SAFE(instr, next, instrs, struct hlsl_ir_node, entry)
{
if (instr->type == HLSL_IR_IF)
{
struct hlsl_ir_if *iff = hlsl_ir_if(instr);
progress |= transform_ir(ctx, func, &iff->then_instrs, context);
progress |= transform_ir(ctx, func, &iff->else_instrs, context);
}
else if (instr->type == HLSL_IR_LOOP)
progress |= transform_ir(ctx, func, &hlsl_ir_loop(instr)->body, context);
progress |= func(ctx, instr, context);
}
return progress;
}
static void replace_node(struct hlsl_ir_node *old, struct hlsl_ir_node *new)
{
struct hlsl_src *src, *next;
LIST_FOR_EACH_ENTRY_SAFE(src, next, &old->uses, struct hlsl_src, entry)
{
hlsl_src_remove(src);
hlsl_src_from_node(src, new);
}
list_remove(&old->entry);
hlsl_free_instr(old);
}
static bool is_vec1(const struct hlsl_type *type)
{
return (type->type == HLSL_CLASS_SCALAR) || (type->type == HLSL_CLASS_VECTOR && type->dimx == 1);
}
static bool fold_redundant_casts(struct hlsl_ctx *ctx, struct hlsl_ir_node *instr, void *context)
{
if (instr->type == HLSL_IR_EXPR)
{
struct hlsl_ir_expr *expr = hlsl_ir_expr(instr);
const struct hlsl_type *src_type = expr->operands[0].node->data_type;
const struct hlsl_type *dst_type = expr->node.data_type;
if (expr->op != HLSL_IR_UNOP_CAST)
return false;
if (hlsl_types_are_equal(src_type, dst_type)
|| (src_type->base_type == dst_type->base_type && is_vec1(src_type) && is_vec1(dst_type)))
{
replace_node(&expr->node, expr->operands[0].node);
return true;
}
}
return false;
}
static bool split_struct_copies(struct hlsl_ctx *ctx, struct hlsl_ir_node *instr, void *context)
{
const struct hlsl_struct_field *field;
const struct hlsl_ir_load *rhs_load;
struct hlsl_ir_assignment *assign;
const struct hlsl_ir_node *rhs;
const struct hlsl_type *type;
if (instr->type != HLSL_IR_ASSIGNMENT)
return false;
assign = hlsl_ir_assignment(instr);
rhs = assign->rhs.node;
type = rhs->data_type;
if (type->type != HLSL_CLASS_STRUCT)
return false;
rhs_load = hlsl_ir_load(rhs);
LIST_FOR_EACH_ENTRY(field, type->e.elements, struct hlsl_struct_field, entry)
{
struct hlsl_ir_node *offset, *add;
struct hlsl_ir_assignment *store;
struct hlsl_ir_load *field_load;
struct hlsl_ir_constant *c;
if (!(c = hlsl_new_uint_constant(ctx, field->reg_offset * 4, instr->loc)))
{
ctx->failed = true;
return false;
}
list_add_before(&instr->entry, &c->node.entry);
offset = &c->node;
if (rhs_load->src.offset.node)
{
if (!(add = hlsl_new_binary_expr(HLSL_IR_BINOP_ADD, rhs_load->src.offset.node, &c->node)))
{
ctx->failed = true;
return false;
}
list_add_before(&instr->entry, &add->entry);
offset = add;
}
if (!(field_load = hlsl_new_load(rhs_load->src.var, offset, field->type, instr->loc)))
{
ctx->failed = true;
return false;
}
list_add_before(&instr->entry, &field_load->node.entry);
offset = &c->node;
if (assign->lhs.offset.node)
{
if (!(add = hlsl_new_binary_expr(HLSL_IR_BINOP_ADD, assign->lhs.offset.node, &c->node)))
{
ctx->failed = true;
return false;
}
list_add_before(&instr->entry, &add->entry);
offset = add;
}
if (!(store = hlsl_new_assignment(assign->lhs.var, offset, &field_load->node, 0, instr->loc)))
{
ctx->failed = true;
return false;
}
list_add_before(&instr->entry, &store->node.entry);
}
/* Remove the assignment instruction, so that we can split structs
* which contain other structs. Although assignment instructions
* produce a value, we don't allow HLSL_IR_ASSIGNMENT to be used as
* a source. */
list_remove(&assign->node.entry);
hlsl_free_instr(&assign->node);
return true;
}
static bool fold_constants(struct hlsl_ctx *ctx, struct hlsl_ir_node *instr, void *context)
{
struct hlsl_ir_constant *arg1, *arg2 = NULL, *res;
struct hlsl_ir_expr *expr;
unsigned int i;
if (instr->type != HLSL_IR_EXPR)
return false;
expr = hlsl_ir_expr(instr);
for (i = 0; i < ARRAY_SIZE(expr->operands); ++i)
{
if (expr->operands[i].node && expr->operands[i].node->type != HLSL_IR_CONSTANT)
return false;
}
arg1 = hlsl_ir_constant(expr->operands[0].node);
if (expr->operands[1].node)
arg2 = hlsl_ir_constant(expr->operands[1].node);
if (!(res = vkd3d_calloc(1, sizeof(*res))))
{
ctx->failed = true;
return false;
}
init_node(&res->node, HLSL_IR_CONSTANT, instr->data_type, instr->loc);
switch (instr->data_type->base_type)
{
case HLSL_TYPE_UINT:
{
unsigned int i;
switch (expr->op)
{
case HLSL_IR_BINOP_ADD:
for (i = 0; i < instr->data_type->dimx; ++i)
res->value.u[i] = arg1->value.u[i] + arg2->value.u[i];
break;
case HLSL_IR_BINOP_MUL:
for (i = 0; i < instr->data_type->dimx; ++i)
res->value.u[i] = arg1->value.u[i] * arg2->value.u[i];
break;
default:
FIXME("Fold uint op %#x.\n", expr->op);
vkd3d_free(res);
return false;
}
break;
}
default:
FIXME("Fold type %#x op %#x.\n", instr->data_type->base_type, expr->op);
vkd3d_free(res);
return false;
}
list_add_before(&expr->node.entry, &res->node.entry);
replace_node(&expr->node, &res->node);
return true;
}
static bool dce(struct hlsl_ctx *ctx, struct hlsl_ir_node *instr, void *context)
{
switch (instr->type)
{
case HLSL_IR_CONSTANT:
case HLSL_IR_EXPR:
case HLSL_IR_LOAD:
case HLSL_IR_SWIZZLE:
if (list_empty(&instr->uses))
{
list_remove(&instr->entry);
hlsl_free_instr(instr);
return true;
}
break;
case HLSL_IR_ASSIGNMENT:
{
struct hlsl_ir_assignment *assignment = hlsl_ir_assignment(instr);
struct hlsl_ir_var *var = assignment->lhs.var;
if (var->last_read < instr->index)
{
list_remove(&instr->entry);
hlsl_free_instr(instr);
return true;
}
break;
}
case HLSL_IR_IF:
case HLSL_IR_JUMP:
case HLSL_IR_LOOP:
break;
}
return false;
}
/* Allocate a unique, ordered index to each instruction, which will be used for
* computing liveness ranges. */
static unsigned int index_instructions(struct list *instrs, unsigned int index)
{
struct hlsl_ir_node *instr;
LIST_FOR_EACH_ENTRY(instr, instrs, struct hlsl_ir_node, entry)
{
instr->index = index++;
if (instr->type == HLSL_IR_IF)
{
struct hlsl_ir_if *iff = hlsl_ir_if(instr);
index = index_instructions(&iff->then_instrs, index);
index = index_instructions(&iff->else_instrs, index);
}
else if (instr->type == HLSL_IR_LOOP)
{
index = index_instructions(&hlsl_ir_loop(instr)->body, index);
hlsl_ir_loop(instr)->next_index = index;
}
}
return index;
}
static void dump_function_decl(struct rb_entry *entry, void *context)
{
struct hlsl_ir_function_decl *func = RB_ENTRY_VALUE(entry, struct hlsl_ir_function_decl, entry);
if (func->body)
hlsl_dump_function(func);
}
static void dump_function(struct rb_entry *entry, void *context)
{
struct hlsl_ir_function *func = RB_ENTRY_VALUE(entry, struct hlsl_ir_function, entry);
rb_for_each_entry(&func->overloads, dump_function_decl, NULL);
}
/* Compute the earliest and latest liveness for each variable. In the case that
* a variable is accessed inside of a loop, we promote its liveness to extend
* to at least the range of the entire loop. Note that we don't need to do this
* for anonymous nodes, since there's currently no way to use a node which was
* calculated in an earlier iteration of the loop. */
static void compute_liveness_recurse(struct list *instrs, unsigned int loop_first, unsigned int loop_last)
{
struct hlsl_ir_node *instr;
struct hlsl_ir_var *var;
LIST_FOR_EACH_ENTRY(instr, instrs, struct hlsl_ir_node, entry)
{
switch (instr->type)
{
case HLSL_IR_ASSIGNMENT:
{
struct hlsl_ir_assignment *assignment = hlsl_ir_assignment(instr);
var = assignment->lhs.var;
if (!var->first_write)
var->first_write = loop_first ? min(instr->index, loop_first) : instr->index;
assignment->rhs.node->last_read = instr->index;
if (assignment->lhs.offset.node)
assignment->lhs.offset.node->last_read = instr->index;
break;
}
case HLSL_IR_EXPR:
{
struct hlsl_ir_expr *expr = hlsl_ir_expr(instr);
unsigned int i;
for (i = 0; i < ARRAY_SIZE(expr->operands) && expr->operands[i].node; ++i)
expr->operands[i].node->last_read = instr->index;
break;
}
case HLSL_IR_IF:
{
struct hlsl_ir_if *iff = hlsl_ir_if(instr);
compute_liveness_recurse(&iff->then_instrs, loop_first, loop_last);
compute_liveness_recurse(&iff->else_instrs, loop_first, loop_last);
iff->condition.node->last_read = instr->index;
break;
}
case HLSL_IR_LOAD:
{
struct hlsl_ir_load *load = hlsl_ir_load(instr);
var = load->src.var;
var->last_read = max(var->last_read, loop_last ? max(instr->index, loop_last) : instr->index);
if (load->src.offset.node)
load->src.offset.node->last_read = instr->index;
break;
}
case HLSL_IR_LOOP:
{
struct hlsl_ir_loop *loop = hlsl_ir_loop(instr);
compute_liveness_recurse(&loop->body, loop_first ? loop_first : instr->index,
loop_last ? loop_last : loop->next_index);
break;
}
case HLSL_IR_SWIZZLE:
{
struct hlsl_ir_swizzle *swizzle = hlsl_ir_swizzle(instr);
swizzle->val.node->last_read = instr->index;
break;
}
case HLSL_IR_CONSTANT:
case HLSL_IR_JUMP:
break;
}
}
}
static void compute_liveness(struct hlsl_ctx *ctx, struct hlsl_ir_function_decl *entry_func)
{
struct hlsl_scope *scope;
struct hlsl_ir_var *var;
/* Index 0 means unused; index 1 means function entry, so start at 2. */
index_instructions(entry_func->body, 2);
LIST_FOR_EACH_ENTRY(scope, &ctx->scopes, struct hlsl_scope, entry)
{
LIST_FOR_EACH_ENTRY(var, &scope->vars, struct hlsl_ir_var, scope_entry)
var->first_write = var->last_read = 0;
}
LIST_FOR_EACH_ENTRY(var, &ctx->globals->vars, struct hlsl_ir_var, scope_entry)
{
var->first_write = 1;
}
LIST_FOR_EACH_ENTRY(var, entry_func->parameters, struct hlsl_ir_var, param_entry)
{
if (var->is_input_varying)
var->first_write = 1;
if (var->is_output_varying)
var->last_read = UINT_MAX;
}
if (entry_func->return_var)
entry_func->return_var->last_read = UINT_MAX;
compute_liveness_recurse(entry_func->body, 0, 0);
}
int hlsl_emit_dxbc(struct hlsl_ctx *ctx, struct hlsl_ir_function_decl *entry_func)
{
list_move_head(entry_func->body, &ctx->static_initializers);
while (transform_ir(ctx, fold_redundant_casts, entry_func->body, NULL));
while (transform_ir(ctx, split_struct_copies, entry_func->body, NULL));
while (transform_ir(ctx, fold_constants, entry_func->body, NULL));
do
compute_liveness(ctx, entry_func);
while (transform_ir(ctx, dce, entry_func->body, NULL));
compute_liveness(ctx, entry_func);
if (TRACE_ON())
rb_for_each_entry(&ctx->functions, dump_function, NULL);
if (ctx->failed)
return VKD3D_ERROR_INVALID_SHADER;
return VKD3D_ERROR_NOT_IMPLEMENTED;
}