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Diffstat (limited to 'src/compiler/glsl/ir_reader.cpp')
| -rw-r--r-- | src/compiler/glsl/ir_reader.cpp | 1167 |
1 files changed, 1167 insertions, 0 deletions
diff --git a/src/compiler/glsl/ir_reader.cpp b/src/compiler/glsl/ir_reader.cpp new file mode 100644 index 00000000000..15315aac522 --- /dev/null +++ b/src/compiler/glsl/ir_reader.cpp @@ -0,0 +1,1167 @@ +/* + * Copyright © 2010 Intel Corporation + * + * 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 (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 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 "ir_reader.h" +#include "glsl_parser_extras.h" +#include "compiler/glsl_types.h" +#include "s_expression.h" + +static const bool debug = false; + +namespace { + +class ir_reader { +public: + ir_reader(_mesa_glsl_parse_state *); + + void read(exec_list *instructions, const char *src, bool scan_for_protos); + +private: + void *mem_ctx; + _mesa_glsl_parse_state *state; + + void ir_read_error(s_expression *, const char *fmt, ...); + + const glsl_type *read_type(s_expression *); + + void scan_for_prototypes(exec_list *, s_expression *); + ir_function *read_function(s_expression *, bool skip_body); + void read_function_sig(ir_function *, s_expression *, bool skip_body); + + void read_instructions(exec_list *, s_expression *, ir_loop *); + ir_instruction *read_instruction(s_expression *, ir_loop *); + ir_variable *read_declaration(s_expression *); + ir_if *read_if(s_expression *, ir_loop *); + ir_loop *read_loop(s_expression *); + ir_call *read_call(s_expression *); + ir_return *read_return(s_expression *); + ir_rvalue *read_rvalue(s_expression *); + ir_assignment *read_assignment(s_expression *); + ir_expression *read_expression(s_expression *); + ir_swizzle *read_swizzle(s_expression *); + ir_constant *read_constant(s_expression *); + ir_texture *read_texture(s_expression *); + ir_emit_vertex *read_emit_vertex(s_expression *); + ir_end_primitive *read_end_primitive(s_expression *); + ir_barrier *read_barrier(s_expression *); + + ir_dereference *read_dereference(s_expression *); + ir_dereference_variable *read_var_ref(s_expression *); +}; + +} /* anonymous namespace */ + +ir_reader::ir_reader(_mesa_glsl_parse_state *state) : state(state) +{ + this->mem_ctx = state; +} + +void +_mesa_glsl_read_ir(_mesa_glsl_parse_state *state, exec_list *instructions, + const char *src, bool scan_for_protos) +{ + ir_reader r(state); + r.read(instructions, src, scan_for_protos); +} + +void +ir_reader::read(exec_list *instructions, const char *src, bool scan_for_protos) +{ + void *sx_mem_ctx = ralloc_context(NULL); + s_expression *expr = s_expression::read_expression(sx_mem_ctx, src); + if (expr == NULL) { + ir_read_error(NULL, "couldn't parse S-Expression."); + return; + } + + if (scan_for_protos) { + scan_for_prototypes(instructions, expr); + if (state->error) + return; + } + + read_instructions(instructions, expr, NULL); + ralloc_free(sx_mem_ctx); + + if (debug) + validate_ir_tree(instructions); +} + +void +ir_reader::ir_read_error(s_expression *expr, const char *fmt, ...) +{ + va_list ap; + + state->error = true; + + if (state->current_function != NULL) + ralloc_asprintf_append(&state->info_log, "In function %s:\n", + state->current_function->function_name()); + ralloc_strcat(&state->info_log, "error: "); + + va_start(ap, fmt); + ralloc_vasprintf_append(&state->info_log, fmt, ap); + va_end(ap); + ralloc_strcat(&state->info_log, "\n"); + + if (expr != NULL) { + ralloc_strcat(&state->info_log, "...in this context:\n "); + expr->print(); + ralloc_strcat(&state->info_log, "\n\n"); + } +} + +const glsl_type * +ir_reader::read_type(s_expression *expr) +{ + s_expression *s_base_type; + s_int *s_size; + + s_pattern pat[] = { "array", s_base_type, s_size }; + if (MATCH(expr, pat)) { + const glsl_type *base_type = read_type(s_base_type); + if (base_type == NULL) { + ir_read_error(NULL, "when reading base type of array type"); + return NULL; + } + + return glsl_type::get_array_instance(base_type, s_size->value()); + } + + s_symbol *type_sym = SX_AS_SYMBOL(expr); + if (type_sym == NULL) { + ir_read_error(expr, "expected <type>"); + return NULL; + } + + const glsl_type *type = state->symbols->get_type(type_sym->value()); + if (type == NULL) + ir_read_error(expr, "invalid type: %s", type_sym->value()); + + return type; +} + + +void +ir_reader::scan_for_prototypes(exec_list *instructions, s_expression *expr) +{ + s_list *list = SX_AS_LIST(expr); + if (list == NULL) { + ir_read_error(expr, "Expected (<instruction> ...); found an atom."); + return; + } + + foreach_in_list(s_list, sub, &list->subexpressions) { + if (!sub->is_list()) + continue; // not a (function ...); ignore it. + + s_symbol *tag = SX_AS_SYMBOL(sub->subexpressions.get_head()); + if (tag == NULL || strcmp(tag->value(), "function") != 0) + continue; // not a (function ...); ignore it. + + ir_function *f = read_function(sub, true); + if (f == NULL) + return; + instructions->push_tail(f); + } +} + +ir_function * +ir_reader::read_function(s_expression *expr, bool skip_body) +{ + bool added = false; + s_symbol *name; + + s_pattern pat[] = { "function", name }; + if (!PARTIAL_MATCH(expr, pat)) { + ir_read_error(expr, "Expected (function <name> (signature ...) ...)"); + return NULL; + } + + ir_function *f = state->symbols->get_function(name->value()); + if (f == NULL) { + f = new(mem_ctx) ir_function(name->value()); + added = state->symbols->add_function(f); + assert(added); + } + + /* Skip over "function" tag and function name (which are guaranteed to be + * present by the above PARTIAL_MATCH call). + */ + exec_node *node = ((s_list *) expr)->subexpressions.head->next->next; + for (/* nothing */; !node->is_tail_sentinel(); node = node->next) { + s_expression *s_sig = (s_expression *) node; + read_function_sig(f, s_sig, skip_body); + } + return added ? f : NULL; +} + +static bool +always_available(const _mesa_glsl_parse_state *) +{ + return true; +} + +void +ir_reader::read_function_sig(ir_function *f, s_expression *expr, bool skip_body) +{ + s_expression *type_expr; + s_list *paramlist; + s_list *body_list; + + s_pattern pat[] = { "signature", type_expr, paramlist, body_list }; + if (!MATCH(expr, pat)) { + ir_read_error(expr, "Expected (signature <type> (parameters ...) " + "(<instruction> ...))"); + return; + } + + const glsl_type *return_type = read_type(type_expr); + if (return_type == NULL) + return; + + s_symbol *paramtag = SX_AS_SYMBOL(paramlist->subexpressions.get_head()); + if (paramtag == NULL || strcmp(paramtag->value(), "parameters") != 0) { + ir_read_error(paramlist, "Expected (parameters ...)"); + return; + } + + // Read the parameters list into a temporary place. + exec_list hir_parameters; + state->symbols->push_scope(); + + /* Skip over the "parameters" tag. */ + exec_node *node = paramlist->subexpressions.head->next; + for (/* nothing */; !node->is_tail_sentinel(); node = node->next) { + ir_variable *var = read_declaration((s_expression *) node); + if (var == NULL) + return; + + hir_parameters.push_tail(var); + } + + ir_function_signature *sig = + f->exact_matching_signature(state, &hir_parameters); + if (sig == NULL && skip_body) { + /* If scanning for prototypes, generate a new signature. */ + /* ir_reader doesn't know what languages support a given built-in, so + * just say that they're always available. For now, other mechanisms + * guarantee the right built-ins are available. + */ + sig = new(mem_ctx) ir_function_signature(return_type, always_available); + f->add_signature(sig); + } else if (sig != NULL) { + const char *badvar = sig->qualifiers_match(&hir_parameters); + if (badvar != NULL) { + ir_read_error(expr, "function `%s' parameter `%s' qualifiers " + "don't match prototype", f->name, badvar); + return; + } + + if (sig->return_type != return_type) { + ir_read_error(expr, "function `%s' return type doesn't " + "match prototype", f->name); + return; + } + } else { + /* No prototype for this body exists - skip it. */ + state->symbols->pop_scope(); + return; + } + assert(sig != NULL); + + sig->replace_parameters(&hir_parameters); + + if (!skip_body && !body_list->subexpressions.is_empty()) { + if (sig->is_defined) { + ir_read_error(expr, "function %s redefined", f->name); + return; + } + state->current_function = sig; + read_instructions(&sig->body, body_list, NULL); + state->current_function = NULL; + sig->is_defined = true; + } + + state->symbols->pop_scope(); +} + +void +ir_reader::read_instructions(exec_list *instructions, s_expression *expr, + ir_loop *loop_ctx) +{ + // Read in a list of instructions + s_list *list = SX_AS_LIST(expr); + if (list == NULL) { + ir_read_error(expr, "Expected (<instruction> ...); found an atom."); + return; + } + + foreach_in_list(s_expression, sub, &list->subexpressions) { + ir_instruction *ir = read_instruction(sub, loop_ctx); + if (ir != NULL) { + /* Global variable declarations should be moved to the top, before + * any functions that might use them. Functions are added to the + * instruction stream when scanning for prototypes, so without this + * hack, they always appear before variable declarations. + */ + if (state->current_function == NULL && ir->as_variable() != NULL) + instructions->push_head(ir); + else + instructions->push_tail(ir); + } + } +} + + +ir_instruction * +ir_reader::read_instruction(s_expression *expr, ir_loop *loop_ctx) +{ + s_symbol *symbol = SX_AS_SYMBOL(expr); + if (symbol != NULL) { + if (strcmp(symbol->value(), "break") == 0 && loop_ctx != NULL) + return new(mem_ctx) ir_loop_jump(ir_loop_jump::jump_break); + if (strcmp(symbol->value(), "continue") == 0 && loop_ctx != NULL) + return new(mem_ctx) ir_loop_jump(ir_loop_jump::jump_continue); + } + + s_list *list = SX_AS_LIST(expr); + if (list == NULL || list->subexpressions.is_empty()) { + ir_read_error(expr, "Invalid instruction.\n"); + return NULL; + } + + s_symbol *tag = SX_AS_SYMBOL(list->subexpressions.get_head()); + if (tag == NULL) { + ir_read_error(expr, "expected instruction tag"); + return NULL; + } + + ir_instruction *inst = NULL; + if (strcmp(tag->value(), "declare") == 0) { + inst = read_declaration(list); + } else if (strcmp(tag->value(), "assign") == 0) { + inst = read_assignment(list); + } else if (strcmp(tag->value(), "if") == 0) { + inst = read_if(list, loop_ctx); + } else if (strcmp(tag->value(), "loop") == 0) { + inst = read_loop(list); + } else if (strcmp(tag->value(), "call") == 0) { + inst = read_call(list); + } else if (strcmp(tag->value(), "return") == 0) { + inst = read_return(list); + } else if (strcmp(tag->value(), "function") == 0) { + inst = read_function(list, false); + } else if (strcmp(tag->value(), "emit-vertex") == 0) { + inst = read_emit_vertex(list); + } else if (strcmp(tag->value(), "end-primitive") == 0) { + inst = read_end_primitive(list); + } else if (strcmp(tag->value(), "barrier") == 0) { + inst = read_barrier(list); + } else { + inst = read_rvalue(list); + if (inst == NULL) + ir_read_error(NULL, "when reading instruction"); + } + return inst; +} + +ir_variable * +ir_reader::read_declaration(s_expression *expr) +{ + s_list *s_quals; + s_expression *s_type; + s_symbol *s_name; + + s_pattern pat[] = { "declare", s_quals, s_type, s_name }; + if (!MATCH(expr, pat)) { + ir_read_error(expr, "expected (declare (<qualifiers>) <type> <name>)"); + return NULL; + } + + const glsl_type *type = read_type(s_type); + if (type == NULL) + return NULL; + + ir_variable *var = new(mem_ctx) ir_variable(type, s_name->value(), + ir_var_auto); + + foreach_in_list(s_symbol, qualifier, &s_quals->subexpressions) { + if (!qualifier->is_symbol()) { + ir_read_error(expr, "qualifier list must contain only symbols"); + return NULL; + } + + // FINISHME: Check for duplicate/conflicting qualifiers. + if (strcmp(qualifier->value(), "centroid") == 0) { + var->data.centroid = 1; + } else if (strcmp(qualifier->value(), "sample") == 0) { + var->data.sample = 1; + } else if (strcmp(qualifier->value(), "patch") == 0) { + var->data.patch = 1; + } else if (strcmp(qualifier->value(), "invariant") == 0) { + var->data.invariant = 1; + } else if (strcmp(qualifier->value(), "uniform") == 0) { + var->data.mode = ir_var_uniform; + } else if (strcmp(qualifier->value(), "shader_storage") == 0) { + var->data.mode = ir_var_shader_storage; + } else if (strcmp(qualifier->value(), "auto") == 0) { + var->data.mode = ir_var_auto; + } else if (strcmp(qualifier->value(), "in") == 0) { + var->data.mode = ir_var_function_in; + } else if (strcmp(qualifier->value(), "shader_in") == 0) { + var->data.mode = ir_var_shader_in; + } else if (strcmp(qualifier->value(), "const_in") == 0) { + var->data.mode = ir_var_const_in; + } else if (strcmp(qualifier->value(), "out") == 0) { + var->data.mode = ir_var_function_out; + } else if (strcmp(qualifier->value(), "shader_out") == 0) { + var->data.mode = ir_var_shader_out; + } else if (strcmp(qualifier->value(), "inout") == 0) { + var->data.mode = ir_var_function_inout; + } else if (strcmp(qualifier->value(), "temporary") == 0) { + var->data.mode = ir_var_temporary; + } else if (strcmp(qualifier->value(), "stream1") == 0) { + var->data.stream = 1; + } else if (strcmp(qualifier->value(), "stream2") == 0) { + var->data.stream = 2; + } else if (strcmp(qualifier->value(), "stream3") == 0) { + var->data.stream = 3; + } else if (strcmp(qualifier->value(), "smooth") == 0) { + var->data.interpolation = INTERP_QUALIFIER_SMOOTH; + } else if (strcmp(qualifier->value(), "flat") == 0) { + var->data.interpolation = INTERP_QUALIFIER_FLAT; + } else if (strcmp(qualifier->value(), "noperspective") == 0) { + var->data.interpolation = INTERP_QUALIFIER_NOPERSPECTIVE; + } else { + ir_read_error(expr, "unknown qualifier: %s", qualifier->value()); + return NULL; + } + } + + // Add the variable to the symbol table + state->symbols->add_variable(var); + + return var; +} + + +ir_if * +ir_reader::read_if(s_expression *expr, ir_loop *loop_ctx) +{ + s_expression *s_cond; + s_expression *s_then; + s_expression *s_else; + + s_pattern pat[] = { "if", s_cond, s_then, s_else }; + if (!MATCH(expr, pat)) { + ir_read_error(expr, "expected (if <condition> (<then>...) (<else>...))"); + return NULL; + } + + ir_rvalue *condition = read_rvalue(s_cond); + if (condition == NULL) { + ir_read_error(NULL, "when reading condition of (if ...)"); + return NULL; + } + + ir_if *iff = new(mem_ctx) ir_if(condition); + + read_instructions(&iff->then_instructions, s_then, loop_ctx); + read_instructions(&iff->else_instructions, s_else, loop_ctx); + if (state->error) { + delete iff; + iff = NULL; + } + return iff; +} + + +ir_loop * +ir_reader::read_loop(s_expression *expr) +{ + s_expression *s_body; + + s_pattern loop_pat[] = { "loop", s_body }; + if (!MATCH(expr, loop_pat)) { + ir_read_error(expr, "expected (loop <body>)"); + return NULL; + } + + ir_loop *loop = new(mem_ctx) ir_loop; + + read_instructions(&loop->body_instructions, s_body, loop); + if (state->error) { + delete loop; + loop = NULL; + } + return loop; +} + + +ir_return * +ir_reader::read_return(s_expression *expr) +{ + s_expression *s_retval; + + s_pattern return_value_pat[] = { "return", s_retval}; + s_pattern return_void_pat[] = { "return" }; + if (MATCH(expr, return_value_pat)) { + ir_rvalue *retval = read_rvalue(s_retval); + if (retval == NULL) { + ir_read_error(NULL, "when reading return value"); + return NULL; + } + return new(mem_ctx) ir_return(retval); + } else if (MATCH(expr, return_void_pat)) { + return new(mem_ctx) ir_return; + } else { + ir_read_error(expr, "expected (return <rvalue>) or (return)"); + return NULL; + } +} + + +ir_rvalue * +ir_reader::read_rvalue(s_expression *expr) +{ + s_list *list = SX_AS_LIST(expr); + if (list == NULL || list->subexpressions.is_empty()) + return NULL; + + s_symbol *tag = SX_AS_SYMBOL(list->subexpressions.get_head()); + if (tag == NULL) { + ir_read_error(expr, "expected rvalue tag"); + return NULL; + } + + ir_rvalue *rvalue = read_dereference(list); + if (rvalue != NULL || state->error) + return rvalue; + else if (strcmp(tag->value(), "swiz") == 0) { + rvalue = read_swizzle(list); + } else if (strcmp(tag->value(), "expression") == 0) { + rvalue = read_expression(list); + } else if (strcmp(tag->value(), "constant") == 0) { + rvalue = read_constant(list); + } else { + rvalue = read_texture(list); + if (rvalue == NULL && !state->error) + ir_read_error(expr, "unrecognized rvalue tag: %s", tag->value()); + } + + return rvalue; +} + +ir_assignment * +ir_reader::read_assignment(s_expression *expr) +{ + s_expression *cond_expr = NULL; + s_expression *lhs_expr, *rhs_expr; + s_list *mask_list; + + s_pattern pat4[] = { "assign", mask_list, lhs_expr, rhs_expr }; + s_pattern pat5[] = { "assign", cond_expr, mask_list, lhs_expr, rhs_expr }; + if (!MATCH(expr, pat4) && !MATCH(expr, pat5)) { + ir_read_error(expr, "expected (assign [<condition>] (<write mask>) " + "<lhs> <rhs>)"); + return NULL; + } + + ir_rvalue *condition = NULL; + if (cond_expr != NULL) { + condition = read_rvalue(cond_expr); + if (condition == NULL) { + ir_read_error(NULL, "when reading condition of assignment"); + return NULL; + } + } + + unsigned mask = 0; + + s_symbol *mask_symbol; + s_pattern mask_pat[] = { mask_symbol }; + if (MATCH(mask_list, mask_pat)) { + const char *mask_str = mask_symbol->value(); + unsigned mask_length = strlen(mask_str); + if (mask_length > 4) { + ir_read_error(expr, "invalid write mask: %s", mask_str); + return NULL; + } + + const unsigned idx_map[] = { 3, 0, 1, 2 }; /* w=bit 3, x=0, y=1, z=2 */ + + for (unsigned i = 0; i < mask_length; i++) { + if (mask_str[i] < 'w' || mask_str[i] > 'z') { + ir_read_error(expr, "write mask contains invalid character: %c", + mask_str[i]); + return NULL; + } + mask |= 1 << idx_map[mask_str[i] - 'w']; + } + } else if (!mask_list->subexpressions.is_empty()) { + ir_read_error(mask_list, "expected () or (<write mask>)"); + return NULL; + } + + ir_dereference *lhs = read_dereference(lhs_expr); + if (lhs == NULL) { + ir_read_error(NULL, "when reading left-hand side of assignment"); + return NULL; + } + + ir_rvalue *rhs = read_rvalue(rhs_expr); + if (rhs == NULL) { + ir_read_error(NULL, "when reading right-hand side of assignment"); + return NULL; + } + + if (mask == 0 && (lhs->type->is_vector() || lhs->type->is_scalar())) { + ir_read_error(expr, "non-zero write mask required."); + return NULL; + } + + return new(mem_ctx) ir_assignment(lhs, rhs, condition, mask); +} + +ir_call * +ir_reader::read_call(s_expression *expr) +{ + s_symbol *name; + s_list *params; + s_list *s_return = NULL; + + ir_dereference_variable *return_deref = NULL; + + s_pattern void_pat[] = { "call", name, params }; + s_pattern non_void_pat[] = { "call", name, s_return, params }; + if (MATCH(expr, non_void_pat)) { + return_deref = read_var_ref(s_return); + if (return_deref == NULL) { + ir_read_error(s_return, "when reading a call's return storage"); + return NULL; + } + } else if (!MATCH(expr, void_pat)) { + ir_read_error(expr, "expected (call <name> [<deref>] (<param> ...))"); + return NULL; + } + + exec_list parameters; + + foreach_in_list(s_expression, e, ¶ms->subexpressions) { + ir_rvalue *param = read_rvalue(e); + if (param == NULL) { + ir_read_error(e, "when reading parameter to function call"); + return NULL; + } + parameters.push_tail(param); + } + + ir_function *f = state->symbols->get_function(name->value()); + if (f == NULL) { + ir_read_error(expr, "found call to undefined function %s", + name->value()); + return NULL; + } + + ir_function_signature *callee = + f->matching_signature(state, ¶meters, true); + if (callee == NULL) { + ir_read_error(expr, "couldn't find matching signature for function " + "%s", name->value()); + return NULL; + } + + if (callee->return_type == glsl_type::void_type && return_deref) { + ir_read_error(expr, "call has return value storage but void type"); + return NULL; + } else if (callee->return_type != glsl_type::void_type && !return_deref) { + ir_read_error(expr, "call has non-void type but no return value storage"); + return NULL; + } + + return new(mem_ctx) ir_call(callee, return_deref, ¶meters); +} + +ir_expression * +ir_reader::read_expression(s_expression *expr) +{ + s_expression *s_type; + s_symbol *s_op; + s_expression *s_arg[4] = {NULL}; + + s_pattern pat[] = { "expression", s_type, s_op, s_arg[0] }; + if (!PARTIAL_MATCH(expr, pat)) { + ir_read_error(expr, "expected (expression <type> <operator> " + "<operand> [<operand>] [<operand>] [<operand>])"); + return NULL; + } + s_arg[1] = (s_expression *) s_arg[0]->next; // may be tail sentinel + s_arg[2] = (s_expression *) s_arg[1]->next; // may be tail sentinel or NULL + if (s_arg[2]) + s_arg[3] = (s_expression *) s_arg[2]->next; // may be tail sentinel or NULL + + const glsl_type *type = read_type(s_type); + if (type == NULL) + return NULL; + + /* Read the operator */ + ir_expression_operation op = ir_expression::get_operator(s_op->value()); + if (op == (ir_expression_operation) -1) { + ir_read_error(expr, "invalid operator: %s", s_op->value()); + return NULL; + } + + /* Skip "expression" <type> <operation> by subtracting 3. */ + int num_operands = (int) ((s_list *) expr)->subexpressions.length() - 3; + + int expected_operands = ir_expression::get_num_operands(op); + if (num_operands != expected_operands) { + ir_read_error(expr, "found %d expression operands, expected %d", + num_operands, expected_operands); + return NULL; + } + + ir_rvalue *arg[4] = {NULL}; + for (int i = 0; i < num_operands; i++) { + arg[i] = read_rvalue(s_arg[i]); + if (arg[i] == NULL) { + ir_read_error(NULL, "when reading operand #%d of %s", i, s_op->value()); + return NULL; + } + } + + return new(mem_ctx) ir_expression(op, type, arg[0], arg[1], arg[2], arg[3]); +} + +ir_swizzle * +ir_reader::read_swizzle(s_expression *expr) +{ + s_symbol *swiz; + s_expression *sub; + + s_pattern pat[] = { "swiz", swiz, sub }; + if (!MATCH(expr, pat)) { + ir_read_error(expr, "expected (swiz <swizzle> <rvalue>)"); + return NULL; + } + + if (strlen(swiz->value()) > 4) { + ir_read_error(expr, "expected a valid swizzle; found %s", swiz->value()); + return NULL; + } + + ir_rvalue *rvalue = read_rvalue(sub); + if (rvalue == NULL) + return NULL; + + ir_swizzle *ir = ir_swizzle::create(rvalue, swiz->value(), + rvalue->type->vector_elements); + if (ir == NULL) + ir_read_error(expr, "invalid swizzle"); + + return ir; +} + +ir_constant * +ir_reader::read_constant(s_expression *expr) +{ + s_expression *type_expr; + s_list *values; + + s_pattern pat[] = { "constant", type_expr, values }; + if (!MATCH(expr, pat)) { + ir_read_error(expr, "expected (constant <type> (...))"); + return NULL; + } + + const glsl_type *type = read_type(type_expr); + if (type == NULL) + return NULL; + + if (values == NULL) { + ir_read_error(expr, "expected (constant <type> (...))"); + return NULL; + } + + if (type->is_array()) { + unsigned elements_supplied = 0; + exec_list elements; + foreach_in_list(s_expression, elt, &values->subexpressions) { + ir_constant *ir_elt = read_constant(elt); + if (ir_elt == NULL) + return NULL; + elements.push_tail(ir_elt); + elements_supplied++; + } + + if (elements_supplied != type->length) { + ir_read_error(values, "expected exactly %u array elements, " + "given %u", type->length, elements_supplied); + return NULL; + } + return new(mem_ctx) ir_constant(type, &elements); + } + + ir_constant_data data = { { 0 } }; + + // Read in list of values (at most 16). + unsigned k = 0; + foreach_in_list(s_expression, expr, &values->subexpressions) { + if (k >= 16) { + ir_read_error(values, "expected at most 16 numbers"); + return NULL; + } + + if (type->base_type == GLSL_TYPE_FLOAT) { + s_number *value = SX_AS_NUMBER(expr); + if (value == NULL) { + ir_read_error(values, "expected numbers"); + return NULL; + } + data.f[k] = value->fvalue(); + } else { + s_int *value = SX_AS_INT(expr); + if (value == NULL) { + ir_read_error(values, "expected integers"); + return NULL; + } + + switch (type->base_type) { + case GLSL_TYPE_UINT: { + data.u[k] = value->value(); + break; + } + case GLSL_TYPE_INT: { + data.i[k] = value->value(); + break; + } + case GLSL_TYPE_BOOL: { + data.b[k] = value->value(); + break; + } + default: + ir_read_error(values, "unsupported constant type"); + return NULL; + } + } + ++k; + } + if (k != type->components()) { + ir_read_error(values, "expected %u constant values, found %u", + type->components(), k); + return NULL; + } + + return new(mem_ctx) ir_constant(type, &data); +} + +ir_dereference_variable * +ir_reader::read_var_ref(s_expression *expr) +{ + s_symbol *s_var; + s_pattern var_pat[] = { "var_ref", s_var }; + + if (MATCH(expr, var_pat)) { + ir_variable *var = state->symbols->get_variable(s_var->value()); + if (var == NULL) { + ir_read_error(expr, "undeclared variable: %s", s_var->value()); + return NULL; + } + return new(mem_ctx) ir_dereference_variable(var); + } + return NULL; +} + +ir_dereference * +ir_reader::read_dereference(s_expression *expr) +{ + s_expression *s_subject; + s_expression *s_index; + s_symbol *s_field; + + s_pattern array_pat[] = { "array_ref", s_subject, s_index }; + s_pattern record_pat[] = { "record_ref", s_subject, s_field }; + + ir_dereference_variable *var_ref = read_var_ref(expr); + if (var_ref != NULL) { + return var_ref; + } else if (MATCH(expr, array_pat)) { + ir_rvalue *subject = read_rvalue(s_subject); + if (subject == NULL) { + ir_read_error(NULL, "when reading the subject of an array_ref"); + return NULL; + } + + ir_rvalue *idx = read_rvalue(s_index); + if (idx == NULL) { + ir_read_error(NULL, "when reading the index of an array_ref"); + return NULL; + } + return new(mem_ctx) ir_dereference_array(subject, idx); + } else if (MATCH(expr, record_pat)) { + ir_rvalue *subject = read_rvalue(s_subject); + if (subject == NULL) { + ir_read_error(NULL, "when reading the subject of a record_ref"); + return NULL; + } + return new(mem_ctx) ir_dereference_record(subject, s_field->value()); + } + return NULL; +} + +ir_texture * +ir_reader::read_texture(s_expression *expr) +{ + s_symbol *tag = NULL; + s_expression *s_type = NULL; + s_expression *s_sampler = NULL; + s_expression *s_coord = NULL; + s_expression *s_offset = NULL; + s_expression *s_proj = NULL; + s_list *s_shadow = NULL; + s_expression *s_lod = NULL; + s_expression *s_sample_index = NULL; + s_expression *s_component = NULL; + + ir_texture_opcode op = ir_tex; /* silence warning */ + + s_pattern tex_pattern[] = + { "tex", s_type, s_sampler, s_coord, s_offset, s_proj, s_shadow }; + s_pattern lod_pattern[] = + { "lod", s_type, s_sampler, s_coord }; + s_pattern txf_pattern[] = + { "txf", s_type, s_sampler, s_coord, s_offset, s_lod }; + s_pattern txf_ms_pattern[] = + { "txf_ms", s_type, s_sampler, s_coord, s_sample_index }; + s_pattern txs_pattern[] = + { "txs", s_type, s_sampler, s_lod }; + s_pattern tg4_pattern[] = + { "tg4", s_type, s_sampler, s_coord, s_offset, s_component }; + s_pattern query_levels_pattern[] = + { "query_levels", s_type, s_sampler }; + s_pattern texture_samples_pattern[] = + { "samples", s_type, s_sampler }; + s_pattern other_pattern[] = + { tag, s_type, s_sampler, s_coord, s_offset, s_proj, s_shadow, s_lod }; + + if (MATCH(expr, lod_pattern)) { + op = ir_lod; + } else if (MATCH(expr, tex_pattern)) { + op = ir_tex; + } else if (MATCH(expr, txf_pattern)) { + op = ir_txf; + } else if (MATCH(expr, txf_ms_pattern)) { + op = ir_txf_ms; + } else if (MATCH(expr, txs_pattern)) { + op = ir_txs; + } else if (MATCH(expr, tg4_pattern)) { + op = ir_tg4; + } else if (MATCH(expr, query_levels_pattern)) { + op = ir_query_levels; + } else if (MATCH(expr, texture_samples_pattern)) { + op = ir_texture_samples; + } else if (MATCH(expr, other_pattern)) { + op = ir_texture::get_opcode(tag->value()); + if (op == (ir_texture_opcode) -1) + return NULL; + } else { + ir_read_error(NULL, "unexpected texture pattern %s", tag->value()); + return NULL; + } + + ir_texture *tex = new(mem_ctx) ir_texture(op); + + // Read return type + const glsl_type *type = read_type(s_type); + if (type == NULL) { + ir_read_error(NULL, "when reading type in (%s ...)", + tex->opcode_string()); + return NULL; + } + + // Read sampler (must be a deref) + ir_dereference *sampler = read_dereference(s_sampler); + if (sampler == NULL) { + ir_read_error(NULL, "when reading sampler in (%s ...)", + tex->opcode_string()); + return NULL; + } + tex->set_sampler(sampler, type); + + if (op != ir_txs) { + // Read coordinate (any rvalue) + tex->coordinate = read_rvalue(s_coord); + if (tex->coordinate == NULL) { + ir_read_error(NULL, "when reading coordinate in (%s ...)", + tex->opcode_string()); + return NULL; + } + + if (op != ir_txf_ms && op != ir_lod) { + // Read texel offset - either 0 or an rvalue. + s_int *si_offset = SX_AS_INT(s_offset); + if (si_offset == NULL || si_offset->value() != 0) { + tex->offset = read_rvalue(s_offset); + if (tex->offset == NULL) { + ir_read_error(s_offset, "expected 0 or an expression"); + return NULL; + } + } + } + } + + if (op != ir_txf && op != ir_txf_ms && + op != ir_txs && op != ir_lod && op != ir_tg4 && + op != ir_query_levels && op != ir_texture_samples) { + s_int *proj_as_int = SX_AS_INT(s_proj); + if (proj_as_int && proj_as_int->value() == 1) { + tex->projector = NULL; + } else { + tex->projector = read_rvalue(s_proj); + if (tex->projector == NULL) { + ir_read_error(NULL, "when reading projective divide in (%s ..)", + tex->opcode_string()); + return NULL; + } + } + + if (s_shadow->subexpressions.is_empty()) { + tex->shadow_comparitor = NULL; + } else { + tex->shadow_comparitor = read_rvalue(s_shadow); + if (tex->shadow_comparitor == NULL) { + ir_read_error(NULL, "when reading shadow comparitor in (%s ..)", + tex->opcode_string()); + return NULL; + } + } + } + + switch (op) { + case ir_txb: + tex->lod_info.bias = read_rvalue(s_lod); + if (tex->lod_info.bias == NULL) { + ir_read_error(NULL, "when reading LOD bias in (txb ...)"); + return NULL; + } + break; + case ir_txl: + case ir_txf: + case ir_txs: + tex->lod_info.lod = read_rvalue(s_lod); + if (tex->lod_info.lod == NULL) { + ir_read_error(NULL, "when reading LOD in (%s ...)", + tex->opcode_string()); + return NULL; + } + break; + case ir_txf_ms: + tex->lod_info.sample_index = read_rvalue(s_sample_index); + if (tex->lod_info.sample_index == NULL) { + ir_read_error(NULL, "when reading sample_index in (txf_ms ...)"); + return NULL; + } + break; + case ir_txd: { + s_expression *s_dx, *s_dy; + s_pattern dxdy_pat[] = { s_dx, s_dy }; + if (!MATCH(s_lod, dxdy_pat)) { + ir_read_error(s_lod, "expected (dPdx dPdy) in (txd ...)"); + return NULL; + } + tex->lod_info.grad.dPdx = read_rvalue(s_dx); + if (tex->lod_info.grad.dPdx == NULL) { + ir_read_error(NULL, "when reading dPdx in (txd ...)"); + return NULL; + } + tex->lod_info.grad.dPdy = read_rvalue(s_dy); + if (tex->lod_info.grad.dPdy == NULL) { + ir_read_error(NULL, "when reading dPdy in (txd ...)"); + return NULL; + } + break; + } + case ir_tg4: + tex->lod_info.component = read_rvalue(s_component); + if (tex->lod_info.component == NULL) { + ir_read_error(NULL, "when reading component in (tg4 ...)"); + return NULL; + } + break; + default: + // tex and lod don't have any extra parameters. + break; + }; + return tex; +} + +ir_emit_vertex * +ir_reader::read_emit_vertex(s_expression *expr) +{ + s_expression *s_stream = NULL; + + s_pattern pat[] = { "emit-vertex", s_stream }; + + if (MATCH(expr, pat)) { + ir_rvalue *stream = read_dereference(s_stream); + if (stream == NULL) { + ir_read_error(NULL, "when reading stream info in emit-vertex"); + return NULL; + } + return new(mem_ctx) ir_emit_vertex(stream); + } + ir_read_error(NULL, "when reading emit-vertex"); + return NULL; +} + +ir_end_primitive * +ir_reader::read_end_primitive(s_expression *expr) +{ + s_expression *s_stream = NULL; + + s_pattern pat[] = { "end-primitive", s_stream }; + + if (MATCH(expr, pat)) { + ir_rvalue *stream = read_dereference(s_stream); + if (stream == NULL) { + ir_read_error(NULL, "when reading stream info in end-primitive"); + return NULL; + } + return new(mem_ctx) ir_end_primitive(stream); + } + ir_read_error(NULL, "when reading end-primitive"); + return NULL; +} + +ir_barrier * +ir_reader::read_barrier(s_expression *expr) +{ + s_pattern pat[] = { "barrier" }; + + if (MATCH(expr, pat)) { + return new(mem_ctx) ir_barrier(); + } + ir_read_error(NULL, "when reading barrier"); + return NULL; +} |