/* * Mesa 3-D graphics library * * Copyright (C) 2005-2007 Brian Paul All Rights Reserved. * Copyright (C) 2008 VMware, Inc. All Rights Reserved. * * 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 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 * BRIAN PAUL 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. */ /** * \file slang_codegen.c * Generate IR tree from AST. * \author Brian Paul */ /*** *** NOTES: *** The new_() functions return a new instance of a simple IR node. *** The gen_() functions generate larger IR trees from the simple nodes. ***/ #include "main/imports.h" #include "main/macros.h" #include "main/mtypes.h" #include "shader/program.h" #include "shader/prog_instruction.h" #include "shader/prog_parameter.h" #include "shader/prog_print.h" #include "shader/prog_statevars.h" #include "slang_typeinfo.h" #include "slang_codegen.h" #include "slang_compile.h" #include "slang_label.h" #include "slang_mem.h" #include "slang_simplify.h" #include "slang_emit.h" #include "slang_vartable.h" #include "slang_ir.h" #include "slang_print.h" /** Max iterations to unroll */ const GLuint MAX_FOR_LOOP_UNROLL_ITERATIONS = 20; /** Max for-loop body size (in slang operations) to unroll */ const GLuint MAX_FOR_LOOP_UNROLL_BODY_SIZE = 50; /** Max for-loop body complexity to unroll. * We'll compute complexity as the product of the number of iterations * and the size of the body. So long-ish loops with very simple bodies * can be unrolled, as well as short loops with larger bodies. */ const GLuint MAX_FOR_LOOP_UNROLL_COMPLEXITY = 200; static slang_ir_node * _slang_gen_operation(slang_assemble_ctx * A, slang_operation *oper); /** * Retrieves type information about an operation. * Returns GL_TRUE on success. * Returns GL_FALSE otherwise. */ static GLboolean typeof_operation(const struct slang_assemble_ctx_ *A, slang_operation *op, slang_typeinfo *ti) { return _slang_typeof_operation(op, &A->space, ti, A->atoms, A->log); } static GLboolean is_sampler_type(const slang_fully_specified_type *t) { switch (t->specifier.type) { case SLANG_SPEC_SAMPLER1D: case SLANG_SPEC_SAMPLER2D: case SLANG_SPEC_SAMPLER3D: case SLANG_SPEC_SAMPLERCUBE: case SLANG_SPEC_SAMPLER1DSHADOW: case SLANG_SPEC_SAMPLER2DSHADOW: case SLANG_SPEC_SAMPLER2DRECT: case SLANG_SPEC_SAMPLER2DRECTSHADOW: return GL_TRUE; default: return GL_FALSE; } } /** * Return the offset (in floats or ints) of the named field within * the given struct. Return -1 if field not found. * If field is NULL, return the size of the struct instead. */ static GLint _slang_field_offset(const slang_type_specifier *spec, slang_atom field) { GLint offset = 0; GLuint i; for (i = 0; i < spec->_struct->fields->num_variables; i++) { const slang_variable *v = spec->_struct->fields->variables[i]; const GLuint sz = _slang_sizeof_type_specifier(&v->type.specifier); if (sz > 1) { /* types larger than 1 float are register (4-float) aligned */ offset = (offset + 3) & ~3; } if (field && v->a_name == field) { return offset; } offset += sz; } if (field) return -1; /* field not found */ else return offset; /* struct size */ } /** * Return the size (in floats) of the given type specifier. * If the size is greater than 4, the size should be a multiple of 4 * so that the correct number of 4-float registers are allocated. * For example, a mat3x2 is size 12 because we want to store the * 3 columns in 3 float[4] registers. */ GLuint _slang_sizeof_type_specifier(const slang_type_specifier *spec) { GLuint sz; switch (spec->type) { case SLANG_SPEC_VOID: sz = 0; break; case SLANG_SPEC_BOOL: sz = 1; break; case SLANG_SPEC_BVEC2: sz = 2; break; case SLANG_SPEC_BVEC3: sz = 3; break; case SLANG_SPEC_BVEC4: sz = 4; break; case SLANG_SPEC_INT: sz = 1; break; case SLANG_SPEC_IVEC2: sz = 2; break; case SLANG_SPEC_IVEC3: sz = 3; break; case SLANG_SPEC_IVEC4: sz = 4; break; case SLANG_SPEC_FLOAT: sz = 1; break; case SLANG_SPEC_VEC2: sz = 2; break; case SLANG_SPEC_VEC3: sz = 3; break; case SLANG_SPEC_VEC4: sz = 4; break; case SLANG_SPEC_MAT2: sz = 2 * 4; /* 2 columns (regs) */ break; case SLANG_SPEC_MAT3: sz = 3 * 4; break; case SLANG_SPEC_MAT4: sz = 4 * 4; break; case SLANG_SPEC_MAT23: sz = 2 * 4; /* 2 columns (regs) */ break; case SLANG_SPEC_MAT32: sz = 3 * 4; /* 3 columns (regs) */ break; case SLANG_SPEC_MAT24: sz = 2 * 4; break; case SLANG_SPEC_MAT42: sz = 4 * 4; /* 4 columns (regs) */ break; case SLANG_SPEC_MAT34: sz = 3 * 4; break; case SLANG_SPEC_MAT43: sz = 4 * 4; /* 4 columns (regs) */ break; case SLANG_SPEC_SAMPLER1D: case SLANG_SPEC_SAMPLER2D: case SLANG_SPEC_SAMPLER3D: case SLANG_SPEC_SAMPLERCUBE: case SLANG_SPEC_SAMPLER1DSHADOW: case SLANG_SPEC_SAMPLER2DSHADOW: case SLANG_SPEC_SAMPLER2DRECT: case SLANG_SPEC_SAMPLER2DRECTSHADOW: sz = 1; /* a sampler is basically just an integer index */ break; case SLANG_SPEC_STRUCT: sz = _slang_field_offset(spec, 0); /* special use */ if (sz > 4) { sz = (sz + 3) & ~0x3; /* round up to multiple of four */ } break; case SLANG_SPEC_ARRAY: sz = _slang_sizeof_type_specifier(spec->_array); break; default: _mesa_problem(NULL, "Unexpected type in _slang_sizeof_type_specifier()"); sz = 0; } if (sz > 4) { /* if size is > 4, it should be a multiple of four */ assert((sz & 0x3) == 0); } return sz; } /** * Query variable/array length (number of elements). * This is slightly non-trivial because there are two ways to express * arrays: "float x[3]" vs. "float[3] x". * \return the length of the array for the given variable, or 0 if not an array */ static GLint _slang_array_length(const slang_variable *var) { if (var->type.array_len > 0) { /* Ex: float[4] x; */ return var->type.array_len; } if (var->array_len > 0) { /* Ex: float x[4]; */ return var->array_len; } return 0; } /** * Compute total size of array give size of element, number of elements. * \return size in floats */ static GLint _slang_array_size(GLint elemSize, GLint arrayLen) { GLint total; assert(elemSize > 0); if (arrayLen > 1) { /* round up base type to multiple of 4 */ total = ((elemSize + 3) & ~0x3) * MAX2(arrayLen, 1); } else { total = elemSize; } return total; } /** * Establish the binding between a slang_ir_node and a slang_variable. * Then, allocate/attach a slang_ir_storage object to the IR node if needed. * The IR node must be a IR_VAR or IR_VAR_DECL node. * \param n the IR node * \param var the variable to associate with the IR node */ static void _slang_attach_storage(slang_ir_node *n, slang_variable *var) { assert(n); assert(var); assert(n->Opcode == IR_VAR || n->Opcode == IR_VAR_DECL); assert(!n->Var || n->Var == var); n->Var = var; if (!n->Store) { /* need to setup storage */ if (n->Var && n->Var->store) { /* node storage info = var storage info */ n->Store = n->Var->store; } else { /* alloc new storage info */ n->Store = _slang_new_ir_storage(PROGRAM_UNDEFINED, -7, -5); #if 0 printf("%s var=%s Store=%p Size=%d\n", __FUNCTION__, (char*) var->a_name, (void*) n->Store, n->Store->Size); #endif if (n->Var) n->Var->store = n->Store; assert(n->Var->store); } } } /** * Return the TEXTURE_*_INDEX value that corresponds to a sampler type, * or -1 if the type is not a sampler. */ static GLint sampler_to_texture_index(const slang_type_specifier_type type) { switch (type) { case SLANG_SPEC_SAMPLER1D: return TEXTURE_1D_INDEX; case SLANG_SPEC_SAMPLER2D: return TEXTURE_2D_INDEX; case SLANG_SPEC_SAMPLER3D: return TEXTURE_3D_INDEX; case SLANG_SPEC_SAMPLERCUBE: return TEXTURE_CUBE_INDEX; case SLANG_SPEC_SAMPLER1DSHADOW: return TEXTURE_1D_INDEX; /* XXX fix */ case SLANG_SPEC_SAMPLER2DSHADOW: return TEXTURE_2D_INDEX; /* XXX fix */ case SLANG_SPEC_SAMPLER2DRECT: return TEXTURE_RECT_INDEX; case SLANG_SPEC_SAMPLER2DRECTSHADOW: return TEXTURE_RECT_INDEX; /* XXX fix */ default: return -1; } } #define SWIZZLE_ZWWW MAKE_SWIZZLE4(SWIZZLE_Z, SWIZZLE_W, SWIZZLE_W, SWIZZLE_W) /** * Return the VERT_ATTRIB_* or FRAG_ATTRIB_* value that corresponds to * a vertex or fragment program input variable. Return -1 if the input * name is invalid. * XXX return size too */ static GLint _slang_input_index(const char *name, GLenum target, GLuint *swizzleOut) { struct input_info { const char *Name; GLuint Attrib; GLuint Swizzle; }; static const struct input_info vertInputs[] = { { "gl_Vertex", VERT_ATTRIB_POS, SWIZZLE_NOOP }, { "gl_Normal", VERT_ATTRIB_NORMAL, SWIZZLE_NOOP }, { "gl_Color", VERT_ATTRIB_COLOR0, SWIZZLE_NOOP }, { "gl_SecondaryColor", VERT_ATTRIB_COLOR1, SWIZZLE_NOOP }, { "gl_FogCoord", VERT_ATTRIB_FOG, SWIZZLE_XXXX }, { "gl_MultiTexCoord0", VERT_ATTRIB_TEX0, SWIZZLE_NOOP }, { "gl_MultiTexCoord1", VERT_ATTRIB_TEX1, SWIZZLE_NOOP }, { "gl_MultiTexCoord2", VERT_ATTRIB_TEX2, SWIZZLE_NOOP }, { "gl_MultiTexCoord3", VERT_ATTRIB_TEX3, SWIZZLE_NOOP }, { "gl_MultiTexCoord4", VERT_ATTRIB_TEX4, SWIZZLE_NOOP }, { "gl_MultiTexCoord5", VERT_ATTRIB_TEX5, SWIZZLE_NOOP }, { "gl_MultiTexCoord6", VERT_ATTRIB_TEX6, SWIZZLE_NOOP }, { "gl_MultiTexCoord7", VERT_ATTRIB_TEX7, SWIZZLE_NOOP }, { NULL, 0, SWIZZLE_NOOP } }; static const struct input_info fragInputs[] = { { "gl_FragCoord", FRAG_ATTRIB_WPOS, SWIZZLE_NOOP }, { "gl_Color", FRAG_ATTRIB_COL0, SWIZZLE_NOOP }, { "gl_SecondaryColor", FRAG_ATTRIB_COL1, SWIZZLE_NOOP }, { "gl_TexCoord", FRAG_ATTRIB_TEX0, SWIZZLE_NOOP }, /* note: we're packing several quantities into the fogcoord vector */ { "gl_FogFragCoord", FRAG_ATTRIB_FOGC, SWIZZLE_XXXX }, { "gl_FrontFacing", FRAG_ATTRIB_FOGC, SWIZZLE_YYYY }, /*XXX*/ { "gl_PointCoord", FRAG_ATTRIB_FOGC, SWIZZLE_ZWWW }, { NULL, 0, SWIZZLE_NOOP } }; GLuint i; const struct input_info *inputs = (target == GL_VERTEX_PROGRAM_ARB) ? vertInputs : fragInputs; ASSERT(MAX_TEXTURE_COORD_UNITS == 8); /* if this fails, fix vertInputs above */ for (i = 0; inputs[i].Name; i++) { if (strcmp(inputs[i].Name, name) == 0) { /* found */ *swizzleOut = inputs[i].Swizzle; return inputs[i].Attrib; } } return -1; } /** * Return the VERT_RESULT_* or FRAG_RESULT_* value that corresponds to * a vertex or fragment program output variable. Return -1 for an invalid * output name. */ static GLint _slang_output_index(const char *name, GLenum target) { struct output_info { const char *Name; GLuint Attrib; }; static const struct output_info vertOutputs[] = { { "gl_Position", VERT_RESULT_HPOS }, { "gl_FrontColor", VERT_RESULT_COL0 }, { "gl_BackColor", VERT_RESULT_BFC0 }, { "gl_FrontSecondaryColor", VERT_RESULT_COL1 }, { "gl_BackSecondaryColor", VERT_RESULT_BFC1 }, { "gl_TexCoord", VERT_RESULT_TEX0 }, { "gl_FogFragCoord", VERT_RESULT_FOGC }, { "gl_PointSize", VERT_RESULT_PSIZ }, { NULL, 0 } }; static const struct output_info fragOutputs[] = { { "gl_FragColor", FRAG_RESULT_COLR }, { "gl_FragDepth", FRAG_RESULT_DEPR }, { "gl_FragData", FRAG_RESULT_DATA0 }, { NULL, 0 } }; GLuint i; const struct output_info *outputs = (target == GL_VERTEX_PROGRAM_ARB) ? vertOutputs : fragOutputs; for (i = 0; outputs[i].Name; i++) { if (strcmp(outputs[i].Name, name) == 0) { /* found */ return outputs[i].Attrib; } } return -1; } /**********************************************************************/ /** * Map "_asm foo" to IR_FOO, etc. */ typedef struct { const char *Name; slang_ir_opcode Opcode; GLuint HaveRetValue, NumParams; } slang_asm_info; static slang_asm_info AsmInfo[] = { /* vec4 binary op */ { "vec4_add", IR_ADD, 1, 2 }, { "vec4_subtract", IR_SUB, 1, 2 }, { "vec4_multiply", IR_MUL, 1, 2 }, { "vec4_dot", IR_DOT4, 1, 2 }, { "vec3_dot", IR_DOT3, 1, 2 }, { "vec2_dot", IR_DOT2, 1, 2 }, { "vec3_nrm", IR_NRM3, 1, 1 }, { "vec4_nrm", IR_NRM4, 1, 1 }, { "vec3_cross", IR_CROSS, 1, 2 }, { "vec4_lrp", IR_LRP, 1, 3 }, { "vec4_min", IR_MIN, 1, 2 }, { "vec4_max", IR_MAX, 1, 2 }, { "vec4_clamp", IR_CLAMP, 1, 3 }, { "vec4_seq", IR_SEQUAL, 1, 2 }, { "vec4_sne", IR_SNEQUAL, 1, 2 }, { "vec4_sge", IR_SGE, 1, 2 }, { "vec4_sgt", IR_SGT, 1, 2 }, { "vec4_sle", IR_SLE, 1, 2 }, { "vec4_slt", IR_SLT, 1, 2 }, /* vec4 unary */ { "vec4_move", IR_MOVE, 1, 1 }, { "vec4_floor", IR_FLOOR, 1, 1 }, { "vec4_frac", IR_FRAC, 1, 1 }, { "vec4_abs", IR_ABS, 1, 1 }, { "vec4_negate", IR_NEG, 1, 1 }, { "vec4_ddx", IR_DDX, 1, 1 }, { "vec4_ddy", IR_DDY, 1, 1 }, /* float binary op */ { "float_power", IR_POW, 1, 2 }, /* texture / sampler */ { "vec4_tex1d", IR_TEX, 1, 2 }, { "vec4_texb1d", IR_TEXB, 1, 2 }, /* 1d w/ bias */ { "vec4_texp1d", IR_TEXP, 1, 2 }, /* 1d w/ projection */ { "vec4_tex2d", IR_TEX, 1, 2 }, { "vec4_texb2d", IR_TEXB, 1, 2 }, /* 2d w/ bias */ { "vec4_texp2d", IR_TEXP, 1, 2 }, /* 2d w/ projection */ { "vec4_tex3d", IR_TEX, 1, 2 }, { "vec4_texb3d", IR_TEXB, 1, 2 }, /* 3d w/ bias */ { "vec4_texp3d", IR_TEXP, 1, 2 }, /* 3d w/ projection */ { "vec4_texcube", IR_TEX, 1, 2 }, /* cubemap */ { "vec4_tex_rect", IR_TEX, 1, 2 }, /* rectangle */ { "vec4_texp_rect", IR_TEX, 1, 2 },/* rectangle w/ projection */ /* unary op */ { "ivec4_to_vec4", IR_I_TO_F, 1, 1 }, /* int[4] to float[4] */ { "vec4_to_ivec4", IR_F_TO_I, 1, 1 }, /* float[4] to int[4] */ { "float_exp", IR_EXP, 1, 1 }, { "float_exp2", IR_EXP2, 1, 1 }, { "float_log2", IR_LOG2, 1, 1 }, { "float_rsq", IR_RSQ, 1, 1 }, { "float_rcp", IR_RCP, 1, 1 }, { "float_sine", IR_SIN, 1, 1 }, { "float_cosine", IR_COS, 1, 1 }, { "float_noise1", IR_NOISE1, 1, 1}, { "float_noise2", IR_NOISE2, 1, 1}, { "float_noise3", IR_NOISE3, 1, 1}, { "float_noise4", IR_NOISE4, 1, 1}, { NULL, IR_NOP, 0, 0 } }; static slang_ir_node * new_node3(slang_ir_opcode op, slang_ir_node *c0, slang_ir_node *c1, slang_ir_node *c2) { slang_ir_node *n = (slang_ir_node *) _slang_alloc(sizeof(slang_ir_node)); if (n) { n->Opcode = op; n->Children[0] = c0; n->Children[1] = c1; n->Children[2] = c2; n->InstLocation = -1; } return n; } static slang_ir_node * new_node2(slang_ir_opcode op, slang_ir_node *c0, slang_ir_node *c1) { return new_node3(op, c0, c1, NULL); } static slang_ir_node * new_node1(slang_ir_opcode op, slang_ir_node *c0) { return new_node3(op, c0, NULL, NULL); } static slang_ir_node * new_node0(slang_ir_opcode op) { return new_node3(op, NULL, NULL, NULL); } /** * Create sequence of two nodes. */ static slang_ir_node * new_seq(slang_ir_node *left, slang_ir_node *right) { if (!left) return right; if (!right) return left; return new_node2(IR_SEQ, left, right); } static slang_ir_node * new_label(slang_label *label) { slang_ir_node *n = new_node0(IR_LABEL); assert(label); if (n) n->Label = label; return n; } static slang_ir_node * new_float_literal(const float v[4], GLuint size) { slang_ir_node *n = new_node0(IR_FLOAT); assert(size <= 4); COPY_4V(n->Value, v); /* allocate a storage object, but compute actual location (Index) later */ n->Store = _slang_new_ir_storage(PROGRAM_CONSTANT, -1, size); return n; } static slang_ir_node * new_not(slang_ir_node *n) { return new_node1(IR_NOT, n); } /** * Non-inlined function call. */ static slang_ir_node * new_function_call(slang_ir_node *code, slang_label *name) { slang_ir_node *n = new_node1(IR_CALL, code); assert(name); if (n) n->Label = name; return n; } /** * Unconditional jump. */ static slang_ir_node * new_return(slang_label *dest) { slang_ir_node *n = new_node0(IR_RETURN); assert(dest); if (n) n->Label = dest; return n; } static slang_ir_node * new_loop(slang_ir_node *body) { return new_node1(IR_LOOP, body); } static slang_ir_node * new_break(slang_ir_node *loopNode) { slang_ir_node *n = new_node0(IR_BREAK); assert(loopNode); assert(loopNode->Opcode == IR_LOOP); if (n) { /* insert this node at head of linked list */ n->List = loopNode->List; loopNode->List = n; } return n; } /** * Make new IR_BREAK_IF_TRUE. */ static slang_ir_node * new_break_if_true(slang_ir_node *loopNode, slang_ir_node *cond) { slang_ir_node *n; assert(loopNode); assert(loopNode->Opcode == IR_LOOP); n = new_node1(IR_BREAK_IF_TRUE, cond); if (n) { /* insert this node at head of linked list */ n->List = loopNode->List; loopNode->List = n; } return n; } /** * Make new IR_CONT_IF_TRUE node. */ static slang_ir_node * new_cont_if_true(slang_ir_node *loopNode, slang_ir_node *cond) { slang_ir_node *n; assert(loopNode); assert(loopNode->Opcode == IR_LOOP); n = new_node1(IR_CONT_IF_TRUE, cond); if (n) { /* insert this node at head of linked list */ n->List = loopNode->List; loopNode->List = n; } return n; } static slang_ir_node * new_cond(slang_ir_node *n) { slang_ir_node *c = new_node1(IR_COND, n); return c; } static slang_ir_node * new_if(slang_ir_node *cond, slang_ir_node *ifPart, slang_ir_node *elsePart) { return new_node3(IR_IF, cond, ifPart, elsePart); } /** * New IR_VAR node - a reference to a previously declared variable. */ static slang_ir_node * new_var(slang_assemble_ctx *A, slang_variable *var) { slang_ir_node *n = new_node0(IR_VAR); if (n) { _slang_attach_storage(n, var); } return n; } /** * Check if the given function is really just a wrapper for a * basic assembly instruction. */ static GLboolean slang_is_asm_function(const slang_function *fun) { if (fun->body->type == SLANG_OPER_BLOCK_NO_NEW_SCOPE && fun->body->num_children == 1 && fun->body->children[0].type == SLANG_OPER_ASM) { return GL_TRUE; } return GL_FALSE; } static GLboolean _slang_is_noop(const slang_operation *oper) { if (!oper || oper->type == SLANG_OPER_VOID || (oper->num_children == 1 && oper->children[0].type == SLANG_OPER_VOID)) return GL_TRUE; else return GL_FALSE; } /** * Recursively search tree for a node of the given type. */ static slang_operation * _slang_find_node_type(slang_operation *oper, slang_operation_type type) { GLuint i; if (oper->type == type) return oper; for (i = 0; i < oper->num_children; i++) { slang_operation *p = _slang_find_node_type(&oper->children[i], type); if (p) return p; } return NULL; } /** * Count the number of operations of the given time rooted at 'oper'. */ static GLuint _slang_count_node_type(slang_operation *oper, slang_operation_type type) { GLuint i, count = 0; if (oper->type == type) { return 1; } for (i = 0; i < oper->num_children; i++) { count += _slang_count_node_type(&oper->children[i], type); } return count; } /** * Check if the 'return' statement found under 'oper' is a "tail return" * that can be no-op'd. For example: * * void func(void) * { * .. do something .. * return; // this is a no-op * } * * This is used when determining if a function can be inlined. If the * 'return' is not the last statement, we can't inline the function since * we still need the semantic behaviour of the 'return' but we don't want * to accidentally return from the _calling_ function. We'd need to use an * unconditional branch, but we don't have such a GPU instruction (not * always, at least). */ static GLboolean _slang_is_tail_return(const slang_operation *oper) { GLuint k = oper->num_children; while (k > 0) { const slang_operation *last = &oper->children[k - 1]; if (last->type == SLANG_OPER_RETURN) return GL_TRUE; else if (last->type == SLANG_OPER_IDENTIFIER || last->type == SLANG_OPER_LABEL) k--; /* try prev child */ else if (last->type == SLANG_OPER_BLOCK_NO_NEW_SCOPE || last->type == SLANG_OPER_BLOCK_NEW_SCOPE) /* try sub-children */ return _slang_is_tail_return(last); else break; } return GL_FALSE; } static void slang_resolve_variable(slang_operation *oper) { if (oper->type == SLANG_OPER_IDENTIFIER && !oper->var) { oper->var = _slang_variable_locate(oper->locals, oper->a_id, GL_TRUE); } } /** * Replace particular variables (SLANG_OPER_IDENTIFIER) with new expressions. */ static void slang_substitute(slang_assemble_ctx *A, slang_operation *oper, GLuint substCount, slang_variable **substOld, slang_operation **substNew, GLboolean isLHS) { switch (oper->type) { case SLANG_OPER_VARIABLE_DECL: { slang_variable *v = _slang_variable_locate(oper->locals, oper->a_id, GL_TRUE); assert(v); if (v->initializer && oper->num_children == 0) { /* set child of oper to copy of initializer */ oper->num_children = 1; oper->children = slang_operation_new(1); slang_operation_copy(&oper->children[0], v->initializer); } if (oper->num_children == 1) { /* the initializer */ slang_substitute(A, &oper->children[0], substCount, substOld, substNew, GL_FALSE); } } break; case SLANG_OPER_IDENTIFIER: assert(oper->num_children == 0); if (1/**!isLHS XXX FIX */) { slang_atom id = oper->a_id; slang_variable *v; GLuint i; v = _slang_variable_locate(oper->locals, id, GL_TRUE); if (!v) { _mesa_problem(NULL, "var %s not found!\n", (char *) oper->a_id); return; } /* look for a substitution */ for (i = 0; i < substCount; i++) { if (v == substOld[i]) { /* OK, replace this SLANG_OPER_IDENTIFIER with a new expr */ #if 0 /* DEBUG only */ if (substNew[i]->type == SLANG_OPER_IDENTIFIER) { assert(substNew[i]->var); assert(substNew[i]->var->a_name); printf("Substitute %s with %s in id node %p\n", (char*)v->a_name, (char*) substNew[i]->var->a_name, (void*) oper); } else { printf("Substitute %s with %f in id node %p\n", (char*)v->a_name, substNew[i]->literal[0], (void*) oper); } #endif slang_operation_copy(oper, substNew[i]); break; } } } break; case SLANG_OPER_RETURN: /* do return replacement here too */ assert(oper->num_children == 0 || oper->num_children == 1); if (oper->num_children == 1 && !_slang_is_noop(&oper->children[0])) { /* replace: * return expr; * with: * __retVal = expr; * return; * then do substitutions on the assignment. */ slang_operation *blockOper, *assignOper, *returnOper; /* check if function actually has a return type */ assert(A->CurFunction); if (A->CurFunction->header.type.specifier.type == SLANG_SPEC_VOID) { slang_info_log_error(A->log, "illegal return expression"); return; } blockOper = slang_operation_new(1); blockOper->type = SLANG_OPER_BLOCK_NO_NEW_SCOPE; blockOper->num_children = 2; blockOper->locals->outer_scope = oper->locals->outer_scope; blockOper->children = slang_operation_new(2); assignOper = blockOper->children + 0; returnOper = blockOper->children + 1; assignOper->type = SLANG_OPER_ASSIGN; assignOper->num_children = 2; assignOper->locals->outer_scope = blockOper->locals; assignOper->children = slang_operation_new(2); assignOper->children[0].type = SLANG_OPER_IDENTIFIER; assignOper->children[0].a_id = slang_atom_pool_atom(A->atoms, "__retVal"); assignOper->children[0].locals->outer_scope = assignOper->locals; slang_operation_copy(&assignOper->children[1], &oper->children[0]); returnOper->type = SLANG_OPER_RETURN; /* return w/ no value */ assert(returnOper->num_children == 0); /* do substitutions on the "__retVal = expr" sub-tree */ slang_substitute(A, assignOper, substCount, substOld, substNew, GL_FALSE); /* install new code */ slang_operation_copy(oper, blockOper); slang_operation_destruct(blockOper); } else { /* check if return value was expected */ assert(A->CurFunction); if (A->CurFunction->header.type.specifier.type != SLANG_SPEC_VOID) { slang_info_log_error(A->log, "return statement requires an expression"); return; } } break; case SLANG_OPER_ASSIGN: case SLANG_OPER_SUBSCRIPT: /* special case: * child[0] can't have substitutions but child[1] can. */ slang_substitute(A, &oper->children[0], substCount, substOld, substNew, GL_TRUE); slang_substitute(A, &oper->children[1], substCount, substOld, substNew, GL_FALSE); break; case SLANG_OPER_FIELD: /* XXX NEW - test */ slang_substitute(A, &oper->children[0], substCount, substOld, substNew, GL_TRUE); break; default: { GLuint i; for (i = 0; i < oper->num_children; i++) slang_substitute(A, &oper->children[i], substCount, substOld, substNew, GL_FALSE); } } } /** * Produce inline code for a call to an assembly instruction. * This is typically used to compile a call to a built-in function like this: * * vec4 mix(const vec4 x, const vec4 y, const vec4 a) * { * __asm vec4_lrp __retVal, a, y, x; * } * * * A call to * r = mix(p1, p2, p3); * * Becomes: * * mov * / \ * r vec4_lrp * / | \ * p3 p2 p1 * * We basically translate a SLANG_OPER_CALL into a SLANG_OPER_ASM. */ static slang_operation * slang_inline_asm_function(slang_assemble_ctx *A, slang_function *fun, slang_operation *oper) { const GLuint numArgs = oper->num_children; GLuint i; slang_operation *inlined; const GLboolean haveRetValue = _slang_function_has_return_value(fun); slang_variable **substOld; slang_operation **substNew; ASSERT(slang_is_asm_function(fun)); ASSERT(fun->param_count == numArgs + haveRetValue); /* printf("Inline %s as %s\n", (char*) fun->header.a_name, (char*) fun->body->children[0].a_id); */ /* * We'll substitute formal params with actual args in the asm call. */ substOld = (slang_variable **) _slang_alloc(numArgs * sizeof(slang_variable *)); substNew = (slang_operation **) _slang_alloc(numArgs * sizeof(slang_operation *)); for (i = 0; i < numArgs; i++) { substOld[i] = fun->parameters->variables[i]; substNew[i] = oper->children + i; } /* make a copy of the code to inline */ inlined = slang_operation_new(1); slang_operation_copy(inlined, &fun->body->children[0]); if (haveRetValue) { /* get rid of the __retVal child */ inlined->num_children--; for (i = 0; i < inlined->num_children; i++) { inlined->children[i] = inlined->children[i + 1]; } } /* now do formal->actual substitutions */ slang_substitute(A, inlined, numArgs, substOld, substNew, GL_FALSE); _slang_free(substOld); _slang_free(substNew); #if 0 printf("+++++++++++++ inlined asm function %s +++++++++++++\n", (char *) fun->header.a_name); slang_print_tree(inlined, 3); printf("+++++++++++++++++++++++++++++++++++++++++++++++++++\n"); #endif return inlined; } /** * Inline the given function call operation. * Return a new slang_operation that corresponds to the inlined code. */ static slang_operation * slang_inline_function_call(slang_assemble_ctx * A, slang_function *fun, slang_operation *oper, slang_operation *returnOper) { typedef enum { SUBST = 1, COPY_IN, COPY_OUT } ParamMode; ParamMode *paramMode; const GLboolean haveRetValue = _slang_function_has_return_value(fun); const GLuint numArgs = oper->num_children; const GLuint totalArgs = numArgs + haveRetValue; slang_operation *args = oper->children; slang_operation *inlined, *top; slang_variable **substOld; slang_operation **substNew; GLuint substCount, numCopyIn, i; slang_function *prevFunction; slang_variable_scope *newScope = NULL; /* save / push */ prevFunction = A->CurFunction; A->CurFunction = fun; /*assert(oper->type == SLANG_OPER_CALL); (or (matrix) multiply, etc) */ assert(fun->param_count == totalArgs); /* allocate temporary arrays */ paramMode = (ParamMode *) _slang_alloc(totalArgs * sizeof(ParamMode)); substOld = (slang_variable **) _slang_alloc(totalArgs * sizeof(slang_variable *)); substNew = (slang_operation **) _slang_alloc(totalArgs * sizeof(slang_operation *)); #if 0 printf("\nInline call to %s (total vars=%d nparams=%d)\n", (char *) fun->header.a_name, fun->parameters->num_variables, numArgs); #endif if (haveRetValue && !returnOper) { /* Create 3-child comma sequence for inlined code: * child[0]: declare __resultTmp * child[1]: inlined function body * child[2]: __resultTmp */ slang_operation *commaSeq; slang_operation *declOper = NULL; slang_variable *resultVar; commaSeq = slang_operation_new(1); commaSeq->type = SLANG_OPER_SEQUENCE; assert(commaSeq->locals); commaSeq->locals->outer_scope = oper->locals->outer_scope; commaSeq->num_children = 3; commaSeq->children = slang_operation_new(3); /* allocate the return var */ resultVar = slang_variable_scope_grow(commaSeq->locals); /* printf("Alloc __resultTmp in scope %p for retval of calling %s\n", (void*)commaSeq->locals, (char *) fun->header.a_name); */ resultVar->a_name = slang_atom_pool_atom(A->atoms, "__resultTmp"); resultVar->type = fun->header.type; /* XXX copy? */ resultVar->isTemp = GL_TRUE; /* child[0] = __resultTmp declaration */ declOper = &commaSeq->children[0]; declOper->type = SLANG_OPER_VARIABLE_DECL; declOper->a_id = resultVar->a_name; declOper->locals->outer_scope = commaSeq->locals; /* child[1] = function body */ inlined = &commaSeq->children[1]; inlined->locals->outer_scope = commaSeq->locals; /* child[2] = __resultTmp reference */ returnOper = &commaSeq->children[2]; returnOper->type = SLANG_OPER_IDENTIFIER; returnOper->a_id = resultVar->a_name; returnOper->locals->outer_scope = commaSeq->locals; top = commaSeq; } else { top = inlined = slang_operation_new(1); /* XXXX this may be inappropriate!!!! */ inlined->locals->outer_scope = oper->locals->outer_scope; } assert(inlined->locals); /* Examine the parameters, look for inout/out params, look for possible * substitutions, etc: * param type behaviour * in copy actual to local * const in substitute param with actual * out copy out */ substCount = 0; for (i = 0; i < totalArgs; i++) { slang_variable *p = fun->parameters->variables[i]; /* printf("Param %d: %s %s \n", i, slang_type_qual_string(p->type.qualifier), (char *) p->a_name); */ if (p->type.qualifier == SLANG_QUAL_INOUT || p->type.qualifier == SLANG_QUAL_OUT) { /* an output param */ slang_operation *arg; if (i < numArgs) arg = &args[i]; else arg = returnOper; paramMode[i] = SUBST; if (arg->type == SLANG_OPER_IDENTIFIER) slang_resolve_variable(arg); /* replace parameter 'p' with argument 'arg' */ substOld[substCount] = p; substNew[substCount] = arg; /* will get copied */ substCount++; } else if (p->type.qualifier == SLANG_QUAL_CONST) { /* a constant input param */ if (args[i].type == SLANG_OPER_IDENTIFIER || args[i].type == SLANG_OPER_LITERAL_FLOAT) { /* replace all occurances of this parameter variable with the * actual argument variable or a literal. */ paramMode[i] = SUBST; slang_resolve_variable(&args[i]); substOld[substCount] = p; substNew[substCount] = &args[i]; /* will get copied */ substCount++; } else { paramMode[i] = COPY_IN; } } else { paramMode[i] = COPY_IN; } assert(paramMode[i]); } /* actual code inlining: */ slang_operation_copy(inlined, fun->body); /*** XXX review this */ assert(inlined->type == SLANG_OPER_BLOCK_NO_NEW_SCOPE || inlined->type == SLANG_OPER_BLOCK_NEW_SCOPE); inlined->type = SLANG_OPER_BLOCK_NEW_SCOPE; #if 0 printf("======================= orig body code ======================\n"); printf("=== params scope = %p\n", (void*) fun->parameters); slang_print_tree(fun->body, 8); printf("======================= copied code =========================\n"); slang_print_tree(inlined, 8); #endif /* do parameter substitution in inlined code: */ slang_substitute(A, inlined, substCount, substOld, substNew, GL_FALSE); #if 0 printf("======================= subst code ==========================\n"); slang_print_tree(inlined, 8); printf("=============================================================\n"); #endif /* New prolog statements: (inserted before the inlined code) * Copy the 'in' arguments. */ numCopyIn = 0; for (i = 0; i < numArgs; i++) { if (paramMode[i] == COPY_IN) { slang_variable *p = fun->parameters->variables[i]; /* declare parameter 'p' */ slang_operation *decl = slang_operation_insert(&inlined->num_children, &inlined->children, numCopyIn); decl->type = SLANG_OPER_VARIABLE_DECL; assert(decl->locals); decl->locals->outer_scope = inlined->locals; decl->a_id = p->a_name; decl->num_children = 1; decl->children = slang_operation_new(1); /* child[0] is the var's initializer */ slang_operation_copy(&decl->children[0], args + i); /* add parameter 'p' to the local variable scope here */ { slang_variable *pCopy = slang_variable_scope_grow(inlined->locals); pCopy->type = p->type; pCopy->a_name = p->a_name; pCopy->array_len = p->array_len; } newScope = inlined->locals; numCopyIn++; } } /* Now add copies of the function's local vars to the new variable scope */ for (i = totalArgs; i < fun->parameters->num_variables; i++) { slang_variable *p = fun->parameters->variables[i]; slang_variable *pCopy = slang_variable_scope_grow(inlined->locals); pCopy->type = p->type; pCopy->a_name = p->a_name; pCopy->array_len = p->array_len; } /* New epilog statements: * 1. Create end of function label to jump to from return statements. * 2. Copy the 'out' parameter vars */ { slang_operation *lab = slang_operation_insert(&inlined->num_children, &inlined->children, inlined->num_children); lab->type = SLANG_OPER_LABEL; lab->label = A->curFuncEndLabel; } for (i = 0; i < totalArgs; i++) { if (paramMode[i] == COPY_OUT) { const slang_variable *p = fun->parameters->variables[i]; /* actualCallVar = outParam */ /*if (i > 0 || !haveRetValue)*/ slang_operation *ass = slang_operation_insert(&inlined->num_children, &inlined->children, inlined->num_children); ass->type = SLANG_OPER_ASSIGN; ass->num_children = 2; ass->locals->outer_scope = inlined->locals; ass->children = slang_operation_new(2); ass->children[0] = args[i]; /*XXX copy */ ass->children[1].type = SLANG_OPER_IDENTIFIER; ass->children[1].a_id = p->a_name; ass->children[1].locals->outer_scope = ass->locals; } } _slang_free(paramMode); _slang_free(substOld); _slang_free(substNew); /* Update scoping to use the new local vars instead of the * original function's vars. This is especially important * for nested inlining. */ if (newScope) slang_replace_scope(inlined, fun->parameters, newScope); #if 0 printf("Done Inline call to %s (total vars=%d nparams=%d)\n\n", (char *) fun->header.a_name, fun->parameters->num_variables, numArgs); slang_print_tree(top, 0); #endif /* pop */ A->CurFunction = prevFunction; return top; } static slang_ir_node * _slang_gen_function_call(slang_assemble_ctx *A, slang_function *fun, slang_operation *oper, slang_operation *dest) { slang_ir_node *n; slang_operation *inlined; slang_label *prevFuncEndLabel; char name[200]; prevFuncEndLabel = A->curFuncEndLabel; sprintf(name, "__endOfFunc_%s_", (char *) fun->header.a_name); A->curFuncEndLabel = _slang_label_new(name); assert(A->curFuncEndLabel); if (slang_is_asm_function(fun) && !dest) { /* assemble assembly function - tree style */ inlined = slang_inline_asm_function(A, fun, oper); } else { /* non-assembly function */ /* We always generate an "inline-able" block of code here. * We may either: * 1. insert the inline code * 2. Generate a call to the "inline" code as a subroutine */ slang_operation *ret = NULL; inlined = slang_inline_function_call(A, fun, oper, dest); if (!inlined) return NULL; ret = _slang_find_node_type(inlined, SLANG_OPER_RETURN); if (ret) { /* check if this is a "tail" return */ if (_slang_count_node_type(inlined, SLANG_OPER_RETURN) == 1 && _slang_is_tail_return(inlined)) { /* The only RETURN is the last stmt in the function, no-op it * and inline the function body. */ ret->type = SLANG_OPER_NONE; } else { slang_operation *callOper; /* The function we're calling has one or more 'return' statements. * So, we can't truly inline this function because we need to * implement 'return' with RET (and CAL). * Nevertheless, we performed "inlining" to make a new instance * of the function body to deal with static register allocation. * * XXX check if there's one 'return' and if it's the very last * statement in the function - we can optimize that case. */ assert(inlined->type == SLANG_OPER_BLOCK_NEW_SCOPE || inlined->type == SLANG_OPER_SEQUENCE); if (_slang_function_has_return_value(fun) && !dest) { assert(inlined->children[0].type == SLANG_OPER_VARIABLE_DECL); assert(inlined->children[2].type == SLANG_OPER_IDENTIFIER); callOper = &inlined->children[1]; } else { callOper = inlined; } callOper->type = SLANG_OPER_NON_INLINED_CALL; callOper->fun = fun; callOper->label = _slang_label_new_unique((char*) fun->header.a_name); } } } if (!inlined) return NULL; /* Replace the function call with the inlined block (or new CALL stmt) */ slang_operation_destruct(oper); *oper = *inlined; _slang_free(inlined); #if 0 assert(inlined->locals); printf("*** Inlined code for call to %s:\n", (char*) fun->header.a_name); slang_print_tree(oper, 10); printf("\n"); #endif n = _slang_gen_operation(A, oper); /*_slang_label_delete(A->curFuncEndLabel);*/ A->curFuncEndLabel = prevFuncEndLabel; return n; } static slang_asm_info * slang_find_asm_info(const char *name) { GLuint i; for (i = 0; AsmInfo[i].Name; i++) { if (_mesa_strcmp(AsmInfo[i].Name, name) == 0) { return AsmInfo + i; } } return NULL; } /** * Some write-masked assignments are simple, but others are hard. * Simple example: * vec3 v; * v.xy = vec2(a, b); * Hard example: * vec3 v; * v.zy = vec2(a, b); * this gets transformed/swizzled into: * v.zy = vec2(a, b).*yx* (* = don't care) * This function helps to determine simple vs. non-simple. */ static GLboolean _slang_simple_writemask(GLuint writemask, GLuint swizzle) { switch (writemask) { case WRITEMASK_X: return GET_SWZ(swizzle, 0) == SWIZZLE_X; case WRITEMASK_Y: return GET_SWZ(swizzle, 1) == SWIZZLE_Y; case WRITEMASK_Z: return GET_SWZ(swizzle, 2) == SWIZZLE_Z; case WRITEMASK_W: return GET_SWZ(swizzle, 3) == SWIZZLE_W; case WRITEMASK_XY: return (GET_SWZ(swizzle, 0) == SWIZZLE_X) && (GET_SWZ(swizzle, 1) == SWIZZLE_Y); case WRITEMASK_XYZ: return (GET_SWZ(swizzle, 0) == SWIZZLE_X) && (GET_SWZ(swizzle, 1) == SWIZZLE_Y) && (GET_SWZ(swizzle, 2) == SWIZZLE_Z); case WRITEMASK_XYZW: return swizzle == SWIZZLE_NOOP; default: return GL_FALSE; } } /** * Convert the given swizzle into a writemask. In some cases this * is trivial, in other cases, we'll need to also swizzle the right * hand side to put components in the right places. * See comment above for more info. * XXX this function could be simplified and should probably be renamed. * \param swizzle the incoming swizzle * \param writemaskOut returns the writemask * \param swizzleOut swizzle to apply to the right-hand-side * \return GL_FALSE for simple writemasks, GL_TRUE for non-simple */ static GLboolean swizzle_to_writemask(slang_assemble_ctx *A, GLuint swizzle, GLuint *writemaskOut, GLuint *swizzleOut) { GLuint mask = 0x0, newSwizzle[4]; GLint i, size; /* make new dst writemask, compute size */ for (i = 0; i < 4; i++) { const GLuint swz = GET_SWZ(swizzle, i); if (swz == SWIZZLE_NIL) { /* end */ break; } assert(swz >= 0 && swz <= 3); if (swizzle != SWIZZLE_XXXX && swizzle != SWIZZLE_YYYY && swizzle != SWIZZLE_ZZZZ && swizzle != SWIZZLE_WWWW && (mask & (1 << swz))) { /* a channel can't be specified twice (ex: ".xyyz") */ slang_info_log_error(A->log, "Invalid writemask '%s'", _mesa_swizzle_string(swizzle, 0, 0)); return GL_FALSE; } mask |= (1 << swz); } assert(mask <= 0xf); size = i; /* number of components in mask/swizzle */ *writemaskOut = mask; /* make new src swizzle, by inversion */ for (i = 0; i < 4; i++) { newSwizzle[i] = i; /*identity*/ } for (i = 0; i < size; i++) { const GLuint swz = GET_SWZ(swizzle, i); newSwizzle[swz] = i; } *swizzleOut = MAKE_SWIZZLE4(newSwizzle[0], newSwizzle[1], newSwizzle[2], newSwizzle[3]); if (_slang_simple_writemask(mask, *swizzleOut)) { if (size >= 1) assert(GET_SWZ(*swizzleOut, 0) == SWIZZLE_X); if (size >= 2) assert(GET_SWZ(*swizzleOut, 1) == SWIZZLE_Y); if (size >= 3) assert(GET_SWZ(*swizzleOut, 2) == SWIZZLE_Z); if (size >= 4) assert(GET_SWZ(*swizzleOut, 3) == SWIZZLE_W); return GL_TRUE; } else return GL_FALSE; } /** * Recursively traverse 'oper' to produce a swizzle mask in the event * of any vector subscripts and swizzle suffixes. * Ex: for "vec4 v", "v[2].x" resolves to v.z */ static GLuint resolve_swizzle(const slang_operation *oper) { if (oper->type == SLANG_OPER_FIELD) { /* writemask from .xyzw suffix */ slang_swizzle swz; if (_slang_is_swizzle((char*) oper->a_id, 4, &swz)) { GLuint swizzle = MAKE_SWIZZLE4(swz.swizzle[0], swz.swizzle[1], swz.swizzle[2], swz.swizzle[3]); GLuint child_swizzle = resolve_swizzle(&oper->children[0]); GLuint s = _slang_swizzle_swizzle(child_swizzle, swizzle); return s; } else return SWIZZLE_XYZW; } else if (oper->type == SLANG_OPER_SUBSCRIPT && oper->children[1].type == SLANG_OPER_LITERAL_INT) { /* writemask from [index] */ GLuint child_swizzle = resolve_swizzle(&oper->children[0]); GLuint i = (GLuint) oper->children[1].literal[0]; GLuint swizzle; GLuint s; switch (i) { case 0: swizzle = SWIZZLE_XXXX; break; case 1: swizzle = SWIZZLE_YYYY; break; case 2: swizzle = SWIZZLE_ZZZZ; break; case 3: swizzle = SWIZZLE_WWWW; break; default: swizzle = SWIZZLE_XYZW; } s = _slang_swizzle_swizzle(child_swizzle, swizzle); return s; } else { return SWIZZLE_XYZW; } } /** * Recursively descend through swizzle nodes to find the node's storage info. */ static slang_ir_storage * get_store(const slang_ir_node *n) { if (n->Opcode == IR_SWIZZLE) { return get_store(n->Children[0]); } return n->Store; } /** * Generate IR tree for an asm instruction/operation such as: * __asm vec4_dot __retVal.x, v1, v2; */ static slang_ir_node * _slang_gen_asm(slang_assemble_ctx *A, slang_operation *oper, slang_operation *dest) { const slang_asm_info *info; slang_ir_node *kids[3], *n; GLuint j, firstOperand; assert(oper->type == SLANG_OPER_ASM); info = slang_find_asm_info((char *) oper->a_id); if (!info) { _mesa_problem(NULL, "undefined __asm function %s\n", (char *) oper->a_id); assert(info); } assert(info->NumParams <= 3); if (info->NumParams == oper->num_children) { /* Storage for result is not specified. * Children[0], [1], [2] are the operands. */ firstOperand = 0; } else { /* Storage for result (child[0]) is specified. * Children[1], [2], [3] are the operands. */ firstOperand = 1; } /* assemble child(ren) */ kids[0] = kids[1] = kids[2] = NULL; for (j = 0; j < info->NumParams; j++) { kids[j] = _slang_gen_operation(A, &oper->children[firstOperand + j]); if (!kids[j]) return NULL; } n = new_node3(info->Opcode, kids[0], kids[1], kids[2]); if (firstOperand) { /* Setup n->Store to be a particular location. Otherwise, storage * for the result (a temporary) will be allocated later. */ slang_operation *dest_oper; slang_ir_node *n0; dest_oper = &oper->children[0]; n0 = _slang_gen_operation(A, dest_oper); if (!n0) return NULL; assert(!n->Store); n->Store = n0->Store; assert(n->Store->File != PROGRAM_UNDEFINED || n->Store->Parent); _slang_free(n0); } return n; } static void print_funcs(struct slang_function_scope_ *scope, const char *name) { GLuint i; for (i = 0; i < scope->num_functions; i++) { slang_function *f = &scope->functions[i]; if (!name || strcmp(name, (char*) f->header.a_name) == 0) printf(" %s (%d args)\n", name, f->param_count); } if (scope->outer_scope) print_funcs(scope->outer_scope, name); } /** * Find a function of the given name, taking 'numArgs' arguments. * This is the function we'll try to call when there is no exact match * between function parameters and call arguments. * * XXX we should really create a list of candidate functions and try * all of them... */ static slang_function * _slang_find_function_by_argc(slang_function_scope *scope, const char *name, int numArgs) { while (scope) { GLuint i; for (i = 0; i < scope->num_functions; i++) { slang_function *f = &scope->functions[i]; if (strcmp(name, (char*) f->header.a_name) == 0) { int haveRetValue = _slang_function_has_return_value(f); if (numArgs == f->param_count - haveRetValue) return f; } } scope = scope->outer_scope; } return NULL; } static slang_function * _slang_find_function_by_max_argc(slang_function_scope *scope, const char *name) { slang_function *maxFunc = NULL; GLuint maxArgs = 0; while (scope) { GLuint i; for (i = 0; i < scope->num_functions; i++) { slang_function *f = &scope->functions[i]; if (strcmp(name, (char*) f->header.a_name) == 0) { if (f->param_count > maxArgs) { maxArgs = f->param_count; maxFunc = f; } } } scope = scope->outer_scope; } return maxFunc; } /** * Generate a new slang_function which is a constructor for a user-defined * struct type. */ static slang_function * _slang_make_struct_constructor(slang_assemble_ctx *A, slang_struct *str) { const GLint numFields = str->fields->num_variables; slang_function *fun = slang_function_new(SLANG_FUNC_CONSTRUCTOR); /* function header (name, return type) */ fun->header.a_name = str->a_name; fun->header.type.qualifier = SLANG_QUAL_NONE; fun->header.type.specifier.type = SLANG_SPEC_STRUCT; fun->header.type.specifier._struct = str; /* function parameters (= struct's fields) */ { GLint i; for (i = 0; i < numFields; i++) { /* printf("Field %d: %s\n", i, (char*) str->fields->variables[i]->a_name); */ slang_variable *p = slang_variable_scope_grow(fun->parameters); *p = *str->fields->variables[i]; /* copy the variable and type */ p->type.qualifier = SLANG_QUAL_CONST; } fun->param_count = fun->parameters->num_variables; } /* Add __retVal to params */ { slang_variable *p = slang_variable_scope_grow(fun->parameters); slang_atom a_retVal = slang_atom_pool_atom(A->atoms, "__retVal"); assert(a_retVal); p->a_name = a_retVal; p->type = fun->header.type; p->type.qualifier = SLANG_QUAL_OUT; fun->param_count++; } /* function body is: * block: * declare T; * T.f1 = p1; * T.f2 = p2; * ... * T.fn = pn; * return T; */ { slang_variable_scope *scope; slang_variable *var; GLint i; fun->body = slang_operation_new(1); fun->body->type = SLANG_OPER_BLOCK_NEW_SCOPE; fun->body->num_children = numFields + 2; fun->body->children = slang_operation_new(numFields + 2); scope = fun->body->locals; scope->outer_scope = fun->parameters; /* create local var 't' */ var = slang_variable_scope_grow(scope); var->a_name = slang_atom_pool_atom(A->atoms, "t"); var->type = fun->header.type; /* declare t */ { slang_operation *decl; decl = &fun->body->children[0]; decl->type = SLANG_OPER_VARIABLE_DECL; decl->locals = _slang_variable_scope_new(scope); decl->a_id = var->a_name; } /* assign params to fields of t */ for (i = 0; i < numFields; i++) { slang_operation *assign = &fun->body->children[1 + i]; assign->type = SLANG_OPER_ASSIGN; assign->locals = _slang_variable_scope_new(scope); assign->num_children = 2; assign->children = slang_operation_new(2); { slang_operation *lhs = &assign->children[0]; lhs->type = SLANG_OPER_FIELD; lhs->locals = _slang_variable_scope_new(scope); lhs->num_children = 1; lhs->children = slang_operation_new(1); lhs->a_id = str->fields->variables[i]->a_name; lhs->children[0].type = SLANG_OPER_IDENTIFIER; lhs->children[0].a_id = var->a_name; lhs->children[0].locals = _slang_variable_scope_new(scope); #if 0 lhs->children[1].num_children = 1; lhs->children[1].children = slang_operation_new(1); lhs->children[1].children[0].type = SLANG_OPER_IDENTIFIER; lhs->children[1].children[0].a_id = str->fields->variables[i]->a_name; lhs->children[1].children->locals = _slang_variable_scope_new(scope); #endif } { slang_operation *rhs = &assign->children[1]; rhs->type = SLANG_OPER_IDENTIFIER; rhs->locals = _slang_variable_scope_new(scope); rhs->a_id = str->fields->variables[i]->a_name; } } /* return t; */ { slang_operation *ret = &fun->body->children[numFields + 1]; ret->type = SLANG_OPER_RETURN; ret->locals = _slang_variable_scope_new(scope); ret->num_children = 1; ret->children = slang_operation_new(1); ret->children[0].type = SLANG_OPER_IDENTIFIER; ret->children[0].a_id = var->a_name; ret->children[0].locals = _slang_variable_scope_new(scope); } } /* slang_print_function(fun, 1); */ return fun; } /** * Find/create a function (constructor) for the given structure name. */ static slang_function * _slang_locate_struct_constructor(slang_assemble_ctx *A, const char *name) { unsigned int i; for (i = 0; i < A->space.structs->num_structs; i++) { slang_struct *str = &A->space.structs->structs[i]; if (strcmp(name, (const char *) str->a_name) == 0) { /* found a structure type that matches the function name */ if (!str->constructor) { /* create the constructor function now */ str->constructor = _slang_make_struct_constructor(A, str); } return str->constructor; } } return NULL; } /** * Generate a new slang_function to satisfy a call to an array constructor. * Ex: float[3](1., 2., 3.) */ static slang_function * _slang_make_array_constructor(slang_assemble_ctx *A, slang_operation *oper) { slang_type_specifier_type baseType; slang_function *fun; int num_elements; fun = slang_function_new(SLANG_FUNC_CONSTRUCTOR); if (!fun) return NULL; baseType = slang_type_specifier_type_from_string((char *) oper->a_id); num_elements = oper->num_children; /* function header, return type */ { fun->header.a_name = oper->a_id; fun->header.type.qualifier = SLANG_QUAL_NONE; fun->header.type.specifier.type = SLANG_SPEC_ARRAY; fun->header.type.specifier._array = slang_type_specifier_new(baseType, NULL, NULL); fun->header.type.array_len = num_elements; } /* function parameters (= number of elements) */ { GLint i; for (i = 0; i < num_elements; i++) { /* printf("Field %d: %s\n", i, (char*) str->fields->variables[i]->a_name); */ slang_variable *p = slang_variable_scope_grow(fun->parameters); char name[10]; _mesa_snprintf(name, sizeof(name), "p%d", i); p->a_name = slang_atom_pool_atom(A->atoms, name); p->type.qualifier = SLANG_QUAL_CONST; p->type.specifier.type = baseType; } fun->param_count = fun->parameters->num_variables; } /* Add __retVal to params */ { slang_variable *p = slang_variable_scope_grow(fun->parameters); slang_atom a_retVal = slang_atom_pool_atom(A->atoms, "__retVal"); assert(a_retVal); p->a_name = a_retVal; p->type = fun->header.type; p->type.qualifier = SLANG_QUAL_OUT; p->type.specifier.type = baseType; fun->param_count++; } /* function body is: * block: * declare T; * T[0] = p0; * T[1] = p1; * ... * T[n] = pn; * return T; */ { slang_variable_scope *scope; slang_variable *var; GLint i; fun->body = slang_operation_new(1); fun->body->type = SLANG_OPER_BLOCK_NEW_SCOPE; fun->body->num_children = num_elements + 2; fun->body->children = slang_operation_new(num_elements + 2); scope = fun->body->locals; scope->outer_scope = fun->parameters; /* create local var 't' */ var = slang_variable_scope_grow(scope); var->a_name = slang_atom_pool_atom(A->atoms, "ttt"); var->type = fun->header.type;/*XXX copy*/ /* declare t */ { slang_operation *decl; decl = &fun->body->children[0]; decl->type = SLANG_OPER_VARIABLE_DECL; decl->locals = _slang_variable_scope_new(scope); decl->a_id = var->a_name; } /* assign params to elements of t */ for (i = 0; i < num_elements; i++) { slang_operation *assign = &fun->body->children[1 + i]; assign->type = SLANG_OPER_ASSIGN; assign->locals = _slang_variable_scope_new(scope); assign->num_children = 2; assign->children = slang_operation_new(2); { slang_operation *lhs = &assign->children[0]; lhs->type = SLANG_OPER_SUBSCRIPT; lhs->locals = _slang_variable_scope_new(scope); lhs->num_children = 2; lhs->children = slang_operation_new(2); lhs->children[0].type = SLANG_OPER_IDENTIFIER; lhs->children[0].a_id = var->a_name; lhs->children[0].locals = _slang_variable_scope_new(scope); lhs->children[1].type = SLANG_OPER_LITERAL_INT; lhs->children[1].literal[0] = (GLfloat) i; } { slang_operation *rhs = &assign->children[1]; rhs->type = SLANG_OPER_IDENTIFIER; rhs->locals = _slang_variable_scope_new(scope); rhs->a_id = fun->parameters->variables[i]->a_name; } } /* return t; */ { slang_operation *ret = &fun->body->children[num_elements + 1]; ret->type = SLANG_OPER_RETURN; ret->locals = _slang_variable_scope_new(scope); ret->num_children = 1; ret->children = slang_operation_new(1); ret->children[0].type = SLANG_OPER_IDENTIFIER; ret->children[0].a_id = var->a_name; ret->children[0].locals = _slang_variable_scope_new(scope); } } /* slang_print_function(fun, 1); */ return fun; } static GLboolean _slang_is_vec_mat_type(const char *name) { static const char *vecmat_types[] = { "float", "int", "bool", "vec2", "vec3", "vec4", "ivec2", "ivec3", "ivec4", "bvec2", "bvec3", "bvec4", "mat2", "mat3", "mat4", "mat2x3", "mat2x4", "mat3x2", "mat3x4", "mat4x2", "mat4x3", NULL }; int i; for (i = 0; vecmat_types[i]; i++) if (_mesa_strcmp(name, vecmat_types[i]) == 0) return GL_TRUE; return GL_FALSE; } /** * Assemble a function call, given a particular function name. * \param name the function's name (operators like '*' are possible). */ static slang_ir_node * _slang_gen_function_call_name(slang_assemble_ctx *A, const char *name, slang_operation *oper, slang_operation *dest) { slang_operation *params = oper->children; const GLuint param_count = oper->num_children; slang_atom atom; slang_function *fun; slang_ir_node *n; atom = slang_atom_pool_atom(A->atoms, name); if (atom == SLANG_ATOM_NULL) return NULL; if (oper->array_constructor) { /* this needs special handling */ fun = _slang_make_array_constructor(A, oper); } else { /* Try to find function by name and exact argument type matching */ GLboolean error = GL_FALSE; fun = _slang_function_locate(A->space.funcs, atom, params, param_count, &A->space, A->atoms, A->log, &error); if (error) { slang_info_log_error(A->log, "Function '%s' not found (check argument types)", name); return NULL; } } if (!fun) { /* Next, try locating a constructor function for a user-defined type */ fun = _slang_locate_struct_constructor(A, name); } /* * At this point, some heuristics are used to try to find a function * that matches the calling signature by means of casting or "unrolling" * of constructors. */ if (!fun && _slang_is_vec_mat_type(name)) { /* Next, if this call looks like a vec() or mat() constructor call, * try "unwinding" the args to satisfy a constructor. */ fun = _slang_find_function_by_max_argc(A->space.funcs, name); if (fun) { if (!_slang_adapt_call(oper, fun, &A->space, A->atoms, A->log)) { slang_info_log_error(A->log, "Function '%s' not found (check argument types)", name); return NULL; } } } if (!fun && _slang_is_vec_mat_type(name)) { /* Next, try casting args to the types of the formal parameters */ int numArgs = oper->num_children; fun = _slang_find_function_by_argc(A->space.funcs, name, numArgs); if (!fun || !_slang_cast_func_params(oper, fun, &A->space, A->atoms, A->log)) { slang_info_log_error(A->log, "Function '%s' not found (check argument types)", name); return NULL; } assert(fun); } if (!fun) { slang_info_log_error(A->log, "Function '%s' not found (check argument types)", name); return NULL; } if (!fun->body) { slang_info_log_error(A->log, "Function '%s' prototyped but not defined. " "Separate compilation units not supported.", name); return NULL; } /* type checking to be sure function's return type matches 'dest' type */ if (dest) { slang_typeinfo t0; slang_typeinfo_construct(&t0); typeof_operation(A, dest, &t0); if (!slang_type_specifier_equal(&t0.spec, &fun->header.type.specifier)) { slang_info_log_error(A->log, "Incompatible type returned by call to '%s'", name); return NULL; } } n = _slang_gen_function_call(A, fun, oper, dest); if (n && !n->Store && !dest && fun->header.type.specifier.type != SLANG_SPEC_VOID) { /* setup n->Store for the result of the function call */ GLint size = _slang_sizeof_type_specifier(&fun->header.type.specifier); n->Store = _slang_new_ir_storage(PROGRAM_TEMPORARY, -1, size); /*printf("Alloc storage for function result, size %d \n", size);*/ } if (oper->array_constructor) { /* free the temporary array constructor function now */ slang_function_destruct(fun); } return n; } static slang_ir_node * _slang_gen_method_call(slang_assemble_ctx *A, slang_operation *oper) { slang_atom *a_length = slang_atom_pool_atom(A->atoms, "length"); slang_ir_node *n; slang_variable *var; /* NOTE: In GLSL 1.20, there's only one kind of method * call: array.length(). Anything else is an error. */ if (oper->a_id != a_length) { slang_info_log_error(A->log, "Undefined method call '%s'", (char *) oper->a_id); return NULL; } /* length() takes no arguments */ if (oper->num_children > 0) { slang_info_log_error(A->log, "Invalid arguments to length() method"); return NULL; } /* lookup the object/variable */ var = _slang_variable_locate(oper->locals, oper->a_obj, GL_TRUE); if (!var || var->type.specifier.type != SLANG_SPEC_ARRAY) { slang_info_log_error(A->log, "Undefined object '%s'", (char *) oper->a_obj); return NULL; } /* Create a float/literal IR node encoding the array length */ n = new_node0(IR_FLOAT); if (n) { n->Value[0] = (float) _slang_array_length(var); n->Store = _slang_new_ir_storage(PROGRAM_CONSTANT, -1, 1); } return n; } static GLboolean _slang_is_constant_cond(const slang_operation *oper, GLboolean *value) { if (oper->type == SLANG_OPER_LITERAL_FLOAT || oper->type == SLANG_OPER_LITERAL_INT || oper->type == SLANG_OPER_LITERAL_BOOL) { if (oper->literal[0]) *value = GL_TRUE; else *value = GL_FALSE; return GL_TRUE; } else if (oper->type == SLANG_OPER_EXPRESSION && oper->num_children == 1) { return _slang_is_constant_cond(&oper->children[0], value); } return GL_FALSE; } /** * Test if an operation is a scalar or boolean. */ static GLboolean _slang_is_scalar_or_boolean(slang_assemble_ctx *A, slang_operation *oper) { slang_typeinfo type; GLint size; slang_typeinfo_construct(&type); typeof_operation(A, oper, &type); size = _slang_sizeof_type_specifier(&type.spec); slang_typeinfo_destruct(&type); return size == 1; } /** * Test if an operation is boolean. */ static GLboolean _slang_is_boolean(slang_assemble_ctx *A, slang_operation *oper) { slang_typeinfo type; GLboolean isBool; slang_typeinfo_construct(&type); typeof_operation(A, oper, &type); isBool = (type.spec.type == SLANG_SPEC_BOOL); slang_typeinfo_destruct(&type); return isBool; } /** * Generate loop code using high-level IR_LOOP instruction */ static slang_ir_node * _slang_gen_while(slang_assemble_ctx * A, const slang_operation *oper) { /* * LOOP: * BREAK if !expr (child[0]) * body code (child[1]) */ slang_ir_node *prevLoop, *loop, *breakIf, *body; GLboolean isConst, constTrue; /* type-check expression */ if (!_slang_is_boolean(A, &oper->children[0])) { slang_info_log_error(A->log, "scalar/boolean expression expected for 'while'"); return NULL; } /* Check if loop condition is a constant */ isConst = _slang_is_constant_cond(&oper->children[0], &constTrue); if (isConst && !constTrue) { /* loop is never executed! */ return new_node0(IR_NOP); } loop = new_loop(NULL); /* save old, push new loop */ prevLoop = A->CurLoop; A->CurLoop = loop; if (isConst && constTrue) { /* while(nonzero constant), no conditional break */ breakIf = NULL; } else { slang_ir_node *cond = new_cond(new_not(_slang_gen_operation(A, &oper->children[0]))); breakIf = new_break_if_true(A->CurLoop, cond); } body = _slang_gen_operation(A, &oper->children[1]); loop->Children[0] = new_seq(breakIf, body); /* Do infinite loop detection */ /* loop->List is head of linked list of break/continue nodes */ if (!loop->List && isConst && constTrue) { /* infinite loop detected */ A->CurLoop = prevLoop; /* clean-up */ slang_info_log_error(A->log, "Infinite loop detected!"); return NULL; } /* pop loop, restore prev */ A->CurLoop = prevLoop; return loop; } /** * Generate IR tree for a do-while loop using high-level LOOP, IF instructions. */ static slang_ir_node * _slang_gen_do(slang_assemble_ctx * A, const slang_operation *oper) { /* * LOOP: * body code (child[0]) * tail code: * BREAK if !expr (child[1]) */ slang_ir_node *prevLoop, *loop; GLboolean isConst, constTrue; /* type-check expression */ if (!_slang_is_boolean(A, &oper->children[1])) { slang_info_log_error(A->log, "scalar/boolean expression expected for 'do/while'"); return NULL; } loop = new_loop(NULL); /* save old, push new loop */ prevLoop = A->CurLoop; A->CurLoop = loop; /* loop body: */ loop->Children[0] = _slang_gen_operation(A, &oper->children[0]); /* Check if loop condition is a constant */ isConst = _slang_is_constant_cond(&oper->children[1], &constTrue); if (isConst && constTrue) { /* do { } while(1) ==> no conditional break */ loop->Children[1] = NULL; /* no tail code */ } else { slang_ir_node *cond = new_cond(new_not(_slang_gen_operation(A, &oper->children[1]))); loop->Children[1] = new_break_if_true(A->CurLoop, cond); } /* XXX we should do infinite loop detection, as above */ /* pop loop, restore prev */ A->CurLoop = prevLoop; return loop; } /** * Recursively count the number of operations rooted at 'oper'. * This gives some kind of indication of the size/complexity of an operation. */ static GLuint sizeof_operation(const slang_operation *oper) { if (oper) { GLuint count = 1; /* me */ GLuint i; for (i = 0; i < oper->num_children; i++) { count += sizeof_operation(&oper->children[i]); } return count; } else { return 0; } } /** * Determine if a for-loop can be unrolled. * At this time, only a rather narrow class of for loops can be unrolled. * See code for details. * When a loop can't be unrolled because it's too large we'll emit a * message to the log. */ static GLboolean _slang_can_unroll_for_loop(slang_assemble_ctx * A, const slang_operation *oper) { GLuint bodySize; GLint start, end; const char *varName; assert(oper->type == SLANG_OPER_FOR); assert(oper->num_children == 4); /* children[0] must be "i=constant" */ if (oper->children[0].type != SLANG_OPER_EXPRESSION) return GL_FALSE; if (oper->children[0].children[0].type != SLANG_OPER_ASSIGN) return GL_FALSE; if (oper->children[0].children[0].children[0].type != SLANG_OPER_IDENTIFIER) return GL_FALSE; if (oper->children[0].children[0].children[1].type != SLANG_OPER_LITERAL_INT) return GL_FALSE; /* children[1] must be "ichildren[1].type != SLANG_OPER_EXPRESSION) return GL_FALSE; if (oper->children[1].children[0].type != SLANG_OPER_LESS) return GL_FALSE; if (oper->children[1].children[0].children[0].type != SLANG_OPER_IDENTIFIER) return GL_FALSE; if (oper->children[1].children[0].children[1].type != SLANG_OPER_LITERAL_INT) return GL_FALSE; /* children[2] must be "i++" or "++i" */ if (oper->children[2].type != SLANG_OPER_POSTINCREMENT && oper->children[2].type != SLANG_OPER_PREINCREMENT) return GL_FALSE; if (oper->children[2].children[0].type != SLANG_OPER_IDENTIFIER) return GL_FALSE; /* make sure the same variable name is used in all places */ if ((oper->children[0].children[0].children[0].a_id != oper->children[1].children[0].children[0].a_id) || (oper->children[0].children[0].children[0].a_id != oper->children[2].children[0].a_id)) return GL_FALSE; varName = (const char *) oper->children[0].children[0].children[0].a_id; /* children[3], the loop body, can't be too large */ bodySize = sizeof_operation(&oper->children[3]); if (bodySize > MAX_FOR_LOOP_UNROLL_BODY_SIZE) { slang_info_log_print(A->log, "Note: 'for (%s ... )' body is too large/complex" " to unroll", varName); return GL_FALSE; } /* get/check loop iteration limits */ start = (GLint) oper->children[0].children[0].children[1].literal[0]; end = (GLint) oper->children[1].children[0].children[1].literal[0]; if (start >= end) return GL_FALSE; /* degenerate case */ if (end - start > MAX_FOR_LOOP_UNROLL_ITERATIONS) { slang_info_log_print(A->log, "Note: 'for (%s=%d; %s<%d; ++%s)' is too" " many iterations to unroll", varName, start, varName, end, varName); return GL_FALSE; } if ((end - start) * bodySize > MAX_FOR_LOOP_UNROLL_COMPLEXITY) { slang_info_log_print(A->log, "Note: 'for (%s=%d; %s<%d; ++%s)' will generate" " too much code to unroll", varName, start, varName, end, varName); return GL_FALSE; } return GL_TRUE; /* we can unroll the loop */ } /** * Unroll a for-loop. * First we determine the number of iterations to unroll. * Then for each iteration: * make a copy of the loop body * replace instances of the loop variable with the current iteration value * generate IR code for the body * \return pointer to generated IR code or NULL if error, out of memory, etc. */ static slang_ir_node * _slang_unroll_for_loop(slang_assemble_ctx * A, const slang_operation *oper) { GLint start, end, iter; slang_ir_node *n, *root = NULL; start = (GLint) oper->children[0].children[0].children[1].literal[0]; end = (GLint) oper->children[1].children[0].children[1].literal[0]; for (iter = start; iter < end; iter++) { slang_operation *body; slang_atom id; /* make a copy of the loop body */ body = slang_operation_new(1); if (!body) return NULL; if (!slang_operation_copy(body, &oper->children[3])) return NULL; id = oper->children[0].children[0].children[0].a_id; /* in body, replace instances of 'id' with literal 'iter' */ { slang_variable *oldVar; slang_operation *newOper; oldVar = _slang_variable_locate(oper->locals, id, GL_TRUE); if (!oldVar) { /* undeclared loop variable */ slang_operation_delete(body); return NULL; } newOper = slang_operation_new(1); newOper->type = SLANG_OPER_LITERAL_INT; newOper->literal_size = 1; newOper->literal[0] = iter; /* replace instances of the loop variable with newOper */ slang_substitute(A, body, 1, &oldVar, &newOper, GL_FALSE); } /* do IR codegen for body */ n = _slang_gen_operation(A, body); root = new_seq(root, n); slang_operation_delete(body); } return root; } /** * Generate IR for a for-loop. Unrolling will be done when possible. */ static slang_ir_node * _slang_gen_for(slang_assemble_ctx * A, const slang_operation *oper) { GLboolean unroll = _slang_can_unroll_for_loop(A, oper); if (unroll) { slang_ir_node *code = _slang_unroll_for_loop(A, oper); if (code) return code; } /* conventional for-loop code generation */ { /* * init code (child[0]) * LOOP: * BREAK if !expr (child[1]) * body code (child[3]) * tail code: * incr code (child[2]) // XXX continue here */ slang_ir_node *prevLoop, *loop, *cond, *breakIf, *body, *init, *incr; init = _slang_gen_operation(A, &oper->children[0]); loop = new_loop(NULL); /* save old, push new loop */ prevLoop = A->CurLoop; A->CurLoop = loop; cond = new_cond(new_not(_slang_gen_operation(A, &oper->children[1]))); breakIf = new_break_if_true(A->CurLoop, cond); body = _slang_gen_operation(A, &oper->children[3]); incr = _slang_gen_operation(A, &oper->children[2]); loop->Children[0] = new_seq(breakIf, body); loop->Children[1] = incr; /* tail code */ /* pop loop, restore prev */ A->CurLoop = prevLoop; return new_seq(init, loop); } } static slang_ir_node * _slang_gen_continue(slang_assemble_ctx * A, const slang_operation *oper) { slang_ir_node *n, *loopNode; assert(oper->type == SLANG_OPER_CONTINUE); loopNode = A->CurLoop; assert(loopNode); assert(loopNode->Opcode == IR_LOOP); n = new_node0(IR_CONT); if (n) { n->Parent = loopNode; /* insert this node at head of linked list */ n->List = loopNode->List; loopNode->List = n; } return n; } /** * Determine if the given operation is of a specific type. */ static GLboolean is_operation_type(const slang_operation *oper, slang_operation_type type) { if (oper->type == type) return GL_TRUE; else if ((oper->type == SLANG_OPER_BLOCK_NEW_SCOPE || oper->type == SLANG_OPER_BLOCK_NO_NEW_SCOPE) && oper->num_children == 1) return is_operation_type(&oper->children[0], type); else return GL_FALSE; } /** * Generate IR tree for an if/then/else conditional using high-level * IR_IF instruction. */ static slang_ir_node * _slang_gen_if(slang_assemble_ctx * A, const slang_operation *oper) { /* * eval expr (child[0]) * IF expr THEN * if-body code * ELSE * else-body code * ENDIF */ const GLboolean haveElseClause = !_slang_is_noop(&oper->children[2]); slang_ir_node *ifNode, *cond, *ifBody, *elseBody; GLboolean isConst, constTrue; /* type-check expression */ if (!_slang_is_boolean(A, &oper->children[0])) { slang_info_log_error(A->log, "boolean expression expected for 'if'"); return NULL; } if (!_slang_is_scalar_or_boolean(A, &oper->children[0])) { slang_info_log_error(A->log, "scalar/boolean expression expected for 'if'"); return NULL; } isConst = _slang_is_constant_cond(&oper->children[0], &constTrue); if (isConst) { if (constTrue) { /* if (true) ... */ return _slang_gen_operation(A, &oper->children[1]); } else { /* if (false) ... */ return _slang_gen_operation(A, &oper->children[2]); } } cond = _slang_gen_operation(A, &oper->children[0]); cond = new_cond(cond); if (is_operation_type(&oper->children[1], SLANG_OPER_BREAK) && !haveElseClause) { /* Special case: generate a conditional break */ ifBody = new_break_if_true(A->CurLoop, cond); return ifBody; } else if (is_operation_type(&oper->children[1], SLANG_OPER_CONTINUE) && !haveElseClause) { /* Special case: generate a conditional break */ ifBody = new_cont_if_true(A->CurLoop, cond); return ifBody; } else { /* general case */ ifBody = _slang_gen_operation(A, &oper->children[1]); if (haveElseClause) elseBody = _slang_gen_operation(A, &oper->children[2]); else elseBody = NULL; ifNode = new_if(cond, ifBody, elseBody); return ifNode; } } static slang_ir_node * _slang_gen_not(slang_assemble_ctx * A, const slang_operation *oper) { slang_ir_node *n; assert(oper->type == SLANG_OPER_NOT); /* type-check expression */ if (!_slang_is_scalar_or_boolean(A, &oper->children[0])) { slang_info_log_error(A->log, "scalar/boolean expression expected for '!'"); return NULL; } n = _slang_gen_operation(A, &oper->children[0]); if (n) return new_not(n); else return NULL; } static slang_ir_node * _slang_gen_xor(slang_assemble_ctx * A, const slang_operation *oper) { slang_ir_node *n1, *n2; assert(oper->type == SLANG_OPER_LOGICALXOR); if (!_slang_is_scalar_or_boolean(A, &oper->children[0]) || !_slang_is_scalar_or_boolean(A, &oper->children[0])) { slang_info_log_error(A->log, "scalar/boolean expressions expected for '^^'"); return NULL; } n1 = _slang_gen_operation(A, &oper->children[0]); if (!n1) return NULL; n2 = _slang_gen_operation(A, &oper->children[1]); if (!n2) return NULL; return new_node2(IR_NOTEQUAL, n1, n2); } /** * Generate IR node for storage of a temporary of given size. */ static slang_ir_node * _slang_gen_temporary(GLint size) { slang_ir_storage *store; slang_ir_node *n = NULL; store = _slang_new_ir_storage(PROGRAM_TEMPORARY, -2, size); if (store) { n = new_node0(IR_VAR_DECL); if (n) { n->Store = store; } else { _slang_free(store); } } return n; } /** * Generate program constants for an array. * Ex: const vec2[3] v = vec2[3](vec2(1,1), vec2(2,2), vec2(3,3)); * This will allocate and initialize three vector constants, storing * the array in constant memory, not temporaries like a non-const array. * This can also be used for uniform array initializers. * \return GL_TRUE for success, GL_FALSE if failure (semantic error, etc). */ static GLboolean make_constant_array(slang_assemble_ctx *A, slang_variable *var, slang_operation *initializer) { struct gl_program *prog = A->program; const GLenum datatype = _slang_gltype_from_specifier(&var->type.specifier); const char *varName = (char *) var->a_name; const GLuint numElements = initializer->num_children; GLint size; GLuint i, j; GLfloat *values; if (!var->store) { var->store = _slang_new_ir_storage(PROGRAM_UNDEFINED, -6, -6); } size = var->store->Size; assert(var->type.qualifier == SLANG_QUAL_CONST || var->type.qualifier == SLANG_QUAL_UNIFORM); assert(initializer->type == SLANG_OPER_CALL); assert(initializer->array_constructor); values = (GLfloat *) _mesa_malloc(numElements * 4 * sizeof(GLfloat)); /* convert constructor params into ordinary floats */ for (i = 0; i < numElements; i++) { const slang_operation *op = &initializer->children[i]; if (op->type != SLANG_OPER_LITERAL_FLOAT) { /* unsupported type for this optimization */ free(values); return GL_FALSE; } for (j = 0; j < op->literal_size; j++) { values[i * 4 + j] = op->literal[j]; } for ( ; j < 4; j++) { values[i * 4 + j] = 0.0f; } } /* slightly different paths for constants vs. uniforms */ if (var->type.qualifier == SLANG_QUAL_UNIFORM) { var->store->File = PROGRAM_UNIFORM; var->store->Index = _mesa_add_uniform(prog->Parameters, varName, size, datatype, values); } else { var->store->File = PROGRAM_CONSTANT; var->store->Index = _mesa_add_named_constant(prog->Parameters, varName, values, size); } assert(var->store->Size == size); _mesa_free(values); return GL_TRUE; } /** * Generate IR node for allocating/declaring a variable (either a local or * a global). * Generally, this involves allocating an slang_ir_storage instance for the * variable, choosing a register file (temporary, constant, etc). * For ordinary variables we do not yet allocate storage though. We do that * when we find the first actual use of the variable to avoid allocating temp * regs that will never get used. * At this time, uniforms are always allocated space in this function. * * \param initializer Optional initializer expression for the variable. */ static slang_ir_node * _slang_gen_var_decl(slang_assemble_ctx *A, slang_variable *var, slang_operation *initializer) { const char *varName = (const char *) var->a_name; const GLenum datatype = _slang_gltype_from_specifier(&var->type.specifier); slang_ir_node *varDecl, *n; slang_ir_storage *store; GLint arrayLen, size, totalSize; /* if array then totalSize > size */ enum register_file file; /*assert(!var->declared);*/ var->declared = GL_TRUE; /* determine GPU register file for simple cases */ if (is_sampler_type(&var->type)) { file = PROGRAM_SAMPLER; } else if (var->type.qualifier == SLANG_QUAL_UNIFORM) { file = PROGRAM_UNIFORM; } else { file = PROGRAM_TEMPORARY; } totalSize = size = _slang_sizeof_type_specifier(&var->type.specifier); if (size <= 0) { slang_info_log_error(A->log, "invalid declaration for '%s'", varName); return NULL; } arrayLen = _slang_array_length(var); totalSize = _slang_array_size(size, arrayLen); /* Allocate IR node for the declaration */ varDecl = new_node0(IR_VAR_DECL); if (!varDecl) return NULL; _slang_attach_storage(varDecl, var); /* undefined storage at first */ assert(var->store); assert(varDecl->Store == var->store); assert(varDecl->Store); assert(varDecl->Store->Index < 0); store = var->store; assert(store == varDecl->Store); /* Fill in storage fields which we now know. store->Index/Swizzle may be * set for some cases below. Otherwise, store->Index/Swizzle will be set * during code emit. */ store->File = file; store->Size = totalSize; /* if there's an initializer, generate IR for the expression */ if (initializer) { slang_ir_node *varRef, *init; if (var->type.qualifier == SLANG_QUAL_CONST) { /* if the variable is const, the initializer must be a const * expression as well. */ #if 0 if (!_slang_is_constant_expr(initializer)) { slang_info_log_error(A->log, "initializer for %s not constant", varName); return NULL; } #endif } /* IR for the variable we're initializing */ varRef = new_var(A, var); if (!varRef) { slang_info_log_error(A->log, "out of memory"); return NULL; } /* constant-folding, etc here */ _slang_simplify(initializer, &A->space, A->atoms); /* look for simple constant-valued variables and uniforms */ if (var->type.qualifier == SLANG_QUAL_CONST || var->type.qualifier == SLANG_QUAL_UNIFORM) { if (initializer->type == SLANG_OPER_CALL && initializer->array_constructor) { /* array initializer */ if (make_constant_array(A, var, initializer)) return varRef; } else if (initializer->type == SLANG_OPER_LITERAL_FLOAT || initializer->type == SLANG_OPER_LITERAL_INT) { /* simple float/vector initializer */ if (store->File == PROGRAM_UNIFORM) { store->Index = _mesa_add_uniform(A->program->Parameters, varName, totalSize, datatype, initializer->literal); store->Swizzle = _slang_var_swizzle(size, 0); return varRef; } #if 0 else { store->File = PROGRAM_CONSTANT; store->Index = _mesa_add_named_constant(A->program->Parameters, varName, initializer->literal, totalSize); store->Swizzle = _slang_var_swizzle(size, 0); return varRef; } #endif } } /* IR for initializer */ init = _slang_gen_operation(A, initializer); if (!init) return NULL; /* XXX remove this when type checking is added above */ if (init->Store && init->Store->Size != totalSize) { slang_info_log_error(A->log, "invalid assignment (wrong types)"); return NULL; } /* assign RHS to LHS */ n = new_node2(IR_COPY, varRef, init); n = new_seq(varDecl, n); } else { /* no initializer */ n = varDecl; } if (store->File == PROGRAM_UNIFORM && store->Index < 0) { /* always need to allocate storage for uniforms at this point */ store->Index = _mesa_add_uniform(A->program->Parameters, varName, totalSize, datatype, NULL); store->Swizzle = _slang_var_swizzle(size, 0); } #if 0 printf("%s var %p %s store=%p index=%d size=%d\n", __FUNCTION__, (void *) var, (char *) varName, (void *) store, store->Index, store->Size); #endif return n; } /** * Generate code for a selection expression: b ? x : y * XXX In some cases we could implement a selection expression * with an LRP instruction (use the boolean as the interpolant). * Otherwise, we use an IF/ELSE/ENDIF construct. */ static slang_ir_node * _slang_gen_select(slang_assemble_ctx *A, slang_operation *oper) { slang_ir_node *cond, *ifNode, *trueExpr, *falseExpr, *trueNode, *falseNode; slang_ir_node *tmpDecl, *tmpVar, *tree; slang_typeinfo type0, type1, type2; int size, isBool, isEqual; assert(oper->type == SLANG_OPER_SELECT); assert(oper->num_children == 3); /* type of children[0] must be boolean */ slang_typeinfo_construct(&type0); typeof_operation(A, &oper->children[0], &type0); isBool = (type0.spec.type == SLANG_SPEC_BOOL); slang_typeinfo_destruct(&type0); if (!isBool) { slang_info_log_error(A->log, "selector type is not boolean"); return NULL; } slang_typeinfo_construct(&type1); slang_typeinfo_construct(&type2); typeof_operation(A, &oper->children[1], &type1); typeof_operation(A, &oper->children[2], &type2); isEqual = slang_type_specifier_equal(&type1.spec, &type2.spec); slang_typeinfo_destruct(&type1); slang_typeinfo_destruct(&type2); if (!isEqual) { slang_info_log_error(A->log, "incompatible types for ?: operator"); return NULL; } /* size of x or y's type */ size = _slang_sizeof_type_specifier(&type1.spec); assert(size > 0); /* temporary var */ tmpDecl = _slang_gen_temporary(size); /* the condition (child 0) */ cond = _slang_gen_operation(A, &oper->children[0]); cond = new_cond(cond); /* if-true body (child 1) */ tmpVar = new_node0(IR_VAR); tmpVar->Store = tmpDecl->Store; trueExpr = _slang_gen_operation(A, &oper->children[1]); trueNode = new_node2(IR_COPY, tmpVar, trueExpr); /* if-false body (child 2) */ tmpVar = new_node0(IR_VAR); tmpVar->Store = tmpDecl->Store; falseExpr = _slang_gen_operation(A, &oper->children[2]); falseNode = new_node2(IR_COPY, tmpVar, falseExpr); ifNode = new_if(cond, trueNode, falseNode); /* tmp var value */ tmpVar = new_node0(IR_VAR); tmpVar->Store = tmpDecl->Store; tree = new_seq(ifNode, tmpVar); tree = new_seq(tmpDecl, tree); /*_slang_print_ir_tree(tree, 10);*/ return tree; } /** * Generate code for &&. */ static slang_ir_node * _slang_gen_logical_and(slang_assemble_ctx *A, slang_operation *oper) { /* rewrite "a && b" as "a ? b : false" */ slang_operation *select; slang_ir_node *n; select = slang_operation_new(1); select->type = SLANG_OPER_SELECT; select->num_children = 3; select->children = slang_operation_new(3); slang_operation_copy(&select->children[0], &oper->children[0]); slang_operation_copy(&select->children[1], &oper->children[1]); select->children[2].type = SLANG_OPER_LITERAL_BOOL; ASSIGN_4V(select->children[2].literal, 0, 0, 0, 0); /* false */ select->children[2].literal_size = 1; n = _slang_gen_select(A, select); return n; } /** * Generate code for ||. */ static slang_ir_node * _slang_gen_logical_or(slang_assemble_ctx *A, slang_operation *oper) { /* rewrite "a || b" as "a ? true : b" */ slang_operation *select; slang_ir_node *n; select = slang_operation_new(1); select->type = SLANG_OPER_SELECT; select->num_children = 3; select->children = slang_operation_new(3); slang_operation_copy(&select->children[0], &oper->children[0]); select->children[1].type = SLANG_OPER_LITERAL_BOOL; ASSIGN_4V(select->children[1].literal, 1, 1, 1, 1); /* true */ select->children[1].literal_size = 1; slang_operation_copy(&select->children[2], &oper->children[1]); n = _slang_gen_select(A, select); return n; } /** * Generate IR tree for a return statement. */ static slang_ir_node * _slang_gen_return(slang_assemble_ctx * A, slang_operation *oper) { const GLboolean haveReturnValue = (oper->num_children == 1 && oper->children[0].type != SLANG_OPER_VOID); /* error checking */ assert(A->CurFunction); if (haveReturnValue && A->CurFunction->header.type.specifier.type == SLANG_SPEC_VOID) { slang_info_log_error(A->log, "illegal return expression"); return NULL; } else if (!haveReturnValue && A->CurFunction->header.type.specifier.type != SLANG_SPEC_VOID) { slang_info_log_error(A->log, "return statement requires an expression"); return NULL; } if (!haveReturnValue) { return new_return(A->curFuncEndLabel); } else { /* * Convert from: * return expr; * To: * __retVal = expr; * return; // goto __endOfFunction */ slang_operation *assign; slang_atom a_retVal; slang_ir_node *n; a_retVal = slang_atom_pool_atom(A->atoms, "__retVal"); assert(a_retVal); #if 1 /* DEBUG */ { slang_variable *v = _slang_variable_locate(oper->locals, a_retVal, GL_TRUE); if (!v) { /* trying to return a value in a void-valued function */ return NULL; } } #endif assign = slang_operation_new(1); assign->type = SLANG_OPER_ASSIGN; assign->num_children = 2; assign->children = slang_operation_new(2); /* lhs (__retVal) */ assign->children[0].type = SLANG_OPER_IDENTIFIER; assign->children[0].a_id = a_retVal; assign->children[0].locals->outer_scope = assign->locals; /* rhs (expr) */ /* XXX we might be able to avoid this copy someday */ slang_operation_copy(&assign->children[1], &oper->children[0]); /* assemble the new code */ n = new_seq(_slang_gen_operation(A, assign), new_return(A->curFuncEndLabel)); slang_operation_delete(assign); return n; } } /** * Determine if the given operation/expression is const-valued. */ static GLboolean _slang_is_constant_expr(const slang_operation *oper) { slang_variable *var; GLuint i; switch (oper->type) { case SLANG_OPER_IDENTIFIER: var = _slang_variable_locate(oper->locals, oper->a_id, GL_TRUE); if (var && var->type.qualifier == SLANG_QUAL_CONST) return GL_TRUE; return GL_FALSE; default: for (i = 0; i < oper->num_children; i++) { if (!_slang_is_constant_expr(&oper->children[i])) return GL_FALSE; } return GL_TRUE; } } /** * Check if an assignment of type t1 to t0 is legal. * XXX more cases needed. */ static GLboolean _slang_assignment_compatible(slang_assemble_ctx *A, slang_operation *op0, slang_operation *op1) { slang_typeinfo t0, t1; GLuint sz0, sz1; if (op0->type == SLANG_OPER_POSTINCREMENT || op0->type == SLANG_OPER_POSTDECREMENT) { return GL_FALSE; } slang_typeinfo_construct(&t0); typeof_operation(A, op0, &t0); slang_typeinfo_construct(&t1); typeof_operation(A, op1, &t1); sz0 = _slang_sizeof_type_specifier(&t0.spec); sz1 = _slang_sizeof_type_specifier(&t1.spec); #if 1 if (sz0 != sz1) { /*printf("assignment size mismatch %u vs %u\n", sz0, sz1);*/ return GL_FALSE; } #endif if (t0.spec.type == SLANG_SPEC_STRUCT && t1.spec.type == SLANG_SPEC_STRUCT && t0.spec._struct->a_name != t1.spec._struct->a_name) return GL_FALSE; if (t0.spec.type == SLANG_SPEC_FLOAT && t1.spec.type == SLANG_SPEC_BOOL) return GL_FALSE; #if 0 /* not used just yet - causes problems elsewhere */ if (t0.spec.type == SLANG_SPEC_INT && t1.spec.type == SLANG_SPEC_FLOAT) return GL_FALSE; #endif if (t0.spec.type == SLANG_SPEC_BOOL && t1.spec.type == SLANG_SPEC_FLOAT) return GL_FALSE; if (t0.spec.type == SLANG_SPEC_BOOL && t1.spec.type == SLANG_SPEC_INT) return GL_FALSE; return GL_TRUE; } /** * Generate IR tree for a local variable declaration. * Basically do some error checking and call _slang_gen_var_decl(). */ static slang_ir_node * _slang_gen_declaration(slang_assemble_ctx *A, slang_operation *oper) { const char *varName = (char *) oper->a_id; slang_variable *var; slang_ir_node *varDecl; slang_operation *initializer; assert(oper->type == SLANG_OPER_VARIABLE_DECL); assert(oper->num_children <= 1); /* lookup the variable by name */ var = _slang_variable_locate(oper->locals, oper->a_id, GL_TRUE); if (!var) return NULL; /* "shouldn't happen" */ if (var->type.qualifier == SLANG_QUAL_ATTRIBUTE || var->type.qualifier == SLANG_QUAL_VARYING || var->type.qualifier == SLANG_QUAL_UNIFORM) { /* can't declare attribute/uniform vars inside functions */ slang_info_log_error(A->log, "local variable '%s' cannot be an attribute/uniform/varying", varName); return NULL; } #if 0 if (v->declared) { slang_info_log_error(A->log, "variable '%s' redeclared", varName); return NULL; } #endif /* check if the var has an initializer */ if (oper->num_children > 0) { assert(oper->num_children == 1); initializer = &oper->children[0]; } else if (var->initializer) { initializer = var->initializer; } else { initializer = NULL; } if (initializer) { /* check/compare var type and initializer type */ if (!_slang_assignment_compatible(A, oper, initializer)) { slang_info_log_error(A->log, "incompatible types in assignment"); return NULL; } } else { if (var->type.qualifier == SLANG_QUAL_CONST) { slang_info_log_error(A->log, "const-qualified variable '%s' requires initializer", varName); return NULL; } } /* Generate IR node */ varDecl = _slang_gen_var_decl(A, var, initializer); if (!varDecl) return NULL; return varDecl; } /** * Generate IR tree for a reference to a variable (such as in an expression). * This is different from a variable declaration. */ static slang_ir_node * _slang_gen_variable(slang_assemble_ctx * A, slang_operation *oper) { /* If there's a variable associated with this oper (from inlining) * use it. Otherwise, use the oper's var id. */ slang_atom name = oper->var ? oper->var->a_name : oper->a_id; slang_variable *var = _slang_variable_locate(oper->locals, name, GL_TRUE); slang_ir_node *n; if (!var) { slang_info_log_error(A->log, "undefined variable '%s'", (char *) name); return NULL; } assert(var->declared); n = new_var(A, var); return n; } /** * Return the number of components actually named by the swizzle. * Recall that swizzles may have undefined/don't-care values. */ static GLuint swizzle_size(GLuint swizzle) { GLuint size = 0, i; for (i = 0; i < 4; i++) { GLuint swz = GET_SWZ(swizzle, i); size += (swz >= 0 && swz <= 3); } return size; } static slang_ir_node * _slang_gen_swizzle(slang_ir_node *child, GLuint swizzle) { slang_ir_node *n = new_node1(IR_SWIZZLE, child); assert(child); if (n) { assert(!n->Store); n->Store = _slang_new_ir_storage_relative(0, swizzle_size(swizzle), child->Store); n->Store->Swizzle = swizzle; } return n; } static GLboolean is_store_writable(const slang_assemble_ctx *A, const slang_ir_storage *store) { while (store->Parent) store = store->Parent; if (!(store->File == PROGRAM_OUTPUT || store->File == PROGRAM_TEMPORARY || (store->File == PROGRAM_VARYING && A->program->Target == GL_VERTEX_PROGRAM_ARB))) { return GL_FALSE; } else { return GL_TRUE; } } /** * Walk up an IR storage path to compute the final swizzle. * This is used when we find an expression such as "foo.xz.yx". */ static GLuint root_swizzle(const slang_ir_storage *st) { GLuint swizzle = st->Swizzle; while (st->Parent) { st = st->Parent; swizzle = _slang_swizzle_swizzle(st->Swizzle, swizzle); } return swizzle; } /** * Generate IR tree for an assignment (=). */ static slang_ir_node * _slang_gen_assignment(slang_assemble_ctx * A, slang_operation *oper) { if (oper->children[0].type == SLANG_OPER_IDENTIFIER) { /* Check that var is writeable */ slang_variable *var = _slang_variable_locate(oper->children[0].locals, oper->children[0].a_id, GL_TRUE); if (!var) { slang_info_log_error(A->log, "undefined variable '%s'", (char *) oper->children[0].a_id); return NULL; } if (var->type.qualifier == SLANG_QUAL_CONST || var->type.qualifier == SLANG_QUAL_ATTRIBUTE || var->type.qualifier == SLANG_QUAL_UNIFORM || (var->type.qualifier == SLANG_QUAL_VARYING && A->program->Target == GL_FRAGMENT_PROGRAM_ARB)) { slang_info_log_error(A->log, "illegal assignment to read-only variable '%s'", (char *) oper->children[0].a_id); return NULL; } } if (oper->children[0].type == SLANG_OPER_IDENTIFIER && oper->children[1].type == SLANG_OPER_CALL) { /* Special case of: x = f(a, b) * Replace with f(a, b, x) (where x == hidden __retVal out param) * * XXX this could be even more effective if we could accomodate * cases such as "v.x = f();" - would help with typical vertex * transformation. */ slang_ir_node *n; n = _slang_gen_function_call_name(A, (const char *) oper->children[1].a_id, &oper->children[1], &oper->children[0]); return n; } else { slang_ir_node *n, *lhs, *rhs; /* lhs and rhs type checking */ if (!_slang_assignment_compatible(A, &oper->children[0], &oper->children[1])) { slang_info_log_error(A->log, "incompatible types in assignment"); return NULL; } lhs = _slang_gen_operation(A, &oper->children[0]); if (!lhs) { return NULL; } if (!lhs->Store) { slang_info_log_error(A->log, "invalid left hand side for assignment"); return NULL; } /* check that lhs is writable */ if (!is_store_writable(A, lhs->Store)) { slang_info_log_error(A->log, "illegal assignment to read-only l-value"); return NULL; } rhs = _slang_gen_operation(A, &oper->children[1]); if (lhs && rhs) { /* convert lhs swizzle into writemask */ const GLuint swizzle = root_swizzle(lhs->Store); GLuint writemask, newSwizzle; if (!swizzle_to_writemask(A, swizzle, &writemask, &newSwizzle)) { /* Non-simple writemask, need to swizzle right hand side in * order to put components into the right place. */ rhs = _slang_gen_swizzle(rhs, newSwizzle); } n = new_node2(IR_COPY, lhs, rhs); return n; } else { return NULL; } } } /** * Generate IR tree for referencing a field in a struct (or basic vector type) */ static slang_ir_node * _slang_gen_struct_field(slang_assemble_ctx * A, slang_operation *oper) { slang_typeinfo ti; /* type of struct */ slang_typeinfo_construct(&ti); typeof_operation(A, &oper->children[0], &ti); if (_slang_type_is_vector(ti.spec.type)) { /* the field should be a swizzle */ const GLuint rows = _slang_type_dim(ti.spec.type); slang_swizzle swz; slang_ir_node *n; GLuint swizzle; if (!_slang_is_swizzle((char *) oper->a_id, rows, &swz)) { slang_info_log_error(A->log, "Bad swizzle"); return NULL; } swizzle = MAKE_SWIZZLE4(swz.swizzle[0], swz.swizzle[1], swz.swizzle[2], swz.swizzle[3]); n = _slang_gen_operation(A, &oper->children[0]); /* create new parent node with swizzle */ if (n) n = _slang_gen_swizzle(n, swizzle); return n; } else if ( ti.spec.type == SLANG_SPEC_FLOAT || ti.spec.type == SLANG_SPEC_INT || ti.spec.type == SLANG_SPEC_BOOL) { const GLuint rows = 1; slang_swizzle swz; slang_ir_node *n; GLuint swizzle; if (!_slang_is_swizzle((char *) oper->a_id, rows, &swz)) { slang_info_log_error(A->log, "Bad swizzle"); } swizzle = MAKE_SWIZZLE4(swz.swizzle[0], swz.swizzle[1], swz.swizzle[2], swz.swizzle[3]); n = _slang_gen_operation(A, &oper->children[0]); /* create new parent node with swizzle */ n = _slang_gen_swizzle(n, swizzle); return n; } else { /* the field is a structure member (base.field) */ /* oper->children[0] is the base */ /* oper->a_id is the field name */ slang_ir_node *base, *n; slang_typeinfo field_ti; GLint fieldSize, fieldOffset = -1; /* type of field */ slang_typeinfo_construct(&field_ti); typeof_operation(A, oper, &field_ti); fieldSize = _slang_sizeof_type_specifier(&field_ti.spec); if (fieldSize > 0) fieldOffset = _slang_field_offset(&ti.spec, oper->a_id); if (fieldSize == 0 || fieldOffset < 0) { const char *structName; if (ti.spec._struct) structName = (char *) ti.spec._struct->a_name; else structName = "unknown"; slang_info_log_error(A->log, "\"%s\" is not a member of struct \"%s\"", (char *) oper->a_id, structName); return NULL; } assert(fieldSize >= 0); base = _slang_gen_operation(A, &oper->children[0]); if (!base) { /* error msg should have already been logged */ return NULL; } n = new_node1(IR_FIELD, base); if (!n) return NULL; n->Field = (char *) oper->a_id; /* Store the field's offset in storage->Index */ n->Store = _slang_new_ir_storage(base->Store->File, fieldOffset, fieldSize); return n; } } /** * Gen code for array indexing. */ static slang_ir_node * _slang_gen_array_element(slang_assemble_ctx * A, slang_operation *oper) { slang_typeinfo array_ti; /* get array's type info */ slang_typeinfo_construct(&array_ti); typeof_operation(A, &oper->children[0], &array_ti); if (_slang_type_is_vector(array_ti.spec.type)) { /* indexing a simple vector type: "vec4 v; v[0]=p;" */ /* translate the index into a swizzle/writemask: "v.x=p" */ const GLuint max = _slang_type_dim(array_ti.spec.type); GLint index; slang_ir_node *n; index = (GLint) oper->children[1].literal[0]; if (oper->children[1].type != SLANG_OPER_LITERAL_INT || index >= (GLint) max) { #if 0 slang_info_log_error(A->log, "Invalid array index for vector type"); printf("type = %d\n", oper->children[1].type); printf("index = %d, max = %d\n", index, max); printf("array = %s\n", (char*)oper->children[0].a_id); printf("index = %s\n", (char*)oper->children[1].a_id); return NULL; #else index = 0; #endif } n = _slang_gen_operation(A, &oper->children[0]); if (n) { /* use swizzle to access the element */ GLuint swizzle = MAKE_SWIZZLE4(SWIZZLE_X + index, SWIZZLE_NIL, SWIZZLE_NIL, SWIZZLE_NIL); n = _slang_gen_swizzle(n, swizzle); } assert(n->Store); return n; } else { /* conventional array */ slang_typeinfo elem_ti; slang_ir_node *elem, *array, *index; GLint elemSize, arrayLen; /* size of array element */ slang_typeinfo_construct(&elem_ti); typeof_operation(A, oper, &elem_ti); elemSize = _slang_sizeof_type_specifier(&elem_ti.spec); if (_slang_type_is_matrix(array_ti.spec.type)) arrayLen = _slang_type_dim(array_ti.spec.type); else arrayLen = array_ti.array_len; slang_typeinfo_destruct(&array_ti); slang_typeinfo_destruct(&elem_ti); if (elemSize <= 0) { /* unknown var or type */ slang_info_log_error(A->log, "Undefined variable or type"); return NULL; } array = _slang_gen_operation(A, &oper->children[0]); index = _slang_gen_operation(A, &oper->children[1]); if (array && index) { /* bounds check */ GLint constIndex = -1; if (index->Opcode == IR_FLOAT) { constIndex = (int) index->Value[0]; if (constIndex < 0 || constIndex >= arrayLen) { slang_info_log_error(A->log, "Array index out of bounds (index=%d size=%d)", constIndex, arrayLen); _slang_free_ir_tree(array); _slang_free_ir_tree(index); return NULL; } } if (!array->Store) { slang_info_log_error(A->log, "Invalid array"); return NULL; } elem = new_node2(IR_ELEMENT, array, index); /* The storage info here will be updated during code emit */ elem->Store = _slang_new_ir_storage(array->Store->File, array->Store->Index, elemSize); elem->Store->Swizzle = _slang_var_swizzle(elemSize, 0); return elem; } else { _slang_free_ir_tree(array); _slang_free_ir_tree(index); return NULL; } } } static slang_ir_node * _slang_gen_compare(slang_assemble_ctx *A, slang_operation *oper, slang_ir_opcode opcode) { slang_typeinfo t0, t1; slang_ir_node *n; slang_typeinfo_construct(&t0); typeof_operation(A, &oper->children[0], &t0); slang_typeinfo_construct(&t1); typeof_operation(A, &oper->children[0], &t1); if (t0.spec.type == SLANG_SPEC_ARRAY || t1.spec.type == SLANG_SPEC_ARRAY) { slang_info_log_error(A->log, "Illegal array comparison"); return NULL; } if (oper->type != SLANG_OPER_EQUAL && oper->type != SLANG_OPER_NOTEQUAL) { /* <, <=, >, >= can only be used with scalars */ if ((t0.spec.type != SLANG_SPEC_INT && t0.spec.type != SLANG_SPEC_FLOAT) || (t1.spec.type != SLANG_SPEC_INT && t1.spec.type != SLANG_SPEC_FLOAT)) { slang_info_log_error(A->log, "Incompatible type(s) for inequality operator"); return NULL; } } n = new_node2(opcode, _slang_gen_operation(A, &oper->children[0]), _slang_gen_operation(A, &oper->children[1])); /* result is a bool (size 1) */ n->Store = _slang_new_ir_storage(PROGRAM_TEMPORARY, -1, 1); return n; } #if 0 static void print_vars(slang_variable_scope *s) { int i; printf("vars: "); for (i = 0; i < s->num_variables; i++) { printf("%s %d, \n", (char*) s->variables[i]->a_name, s->variables[i]->declared); } printf("\n"); } #endif #if 0 static void _slang_undeclare_vars(slang_variable_scope *locals) { if (locals->num_variables > 0) { int i; for (i = 0; i < locals->num_variables; i++) { slang_variable *v = locals->variables[i]; printf("undeclare %s at %p\n", (char*) v->a_name, v); v->declared = GL_FALSE; } } } #endif /** * Generate IR tree for a slang_operation (AST node) */ static slang_ir_node * _slang_gen_operation(slang_assemble_ctx * A, slang_operation *oper) { switch (oper->type) { case SLANG_OPER_BLOCK_NEW_SCOPE: { slang_ir_node *n; _slang_push_var_table(A->vartable); oper->type = SLANG_OPER_BLOCK_NO_NEW_SCOPE; /* temp change */ n = _slang_gen_operation(A, oper); oper->type = SLANG_OPER_BLOCK_NEW_SCOPE; /* restore */ _slang_pop_var_table(A->vartable); /*_slang_undeclare_vars(oper->locals);*/ /*print_vars(oper->locals);*/ if (n) n = new_node1(IR_SCOPE, n); return n; } break; case SLANG_OPER_BLOCK_NO_NEW_SCOPE: /* list of operations */ if (oper->num_children > 0) { slang_ir_node *n, *tree = NULL; GLuint i; for (i = 0; i < oper->num_children; i++) { n = _slang_gen_operation(A, &oper->children[i]); if (!n) { _slang_free_ir_tree(tree); return NULL; /* error must have occured */ } tree = new_seq(tree, n); } return tree; } else { return new_node0(IR_NOP); } case SLANG_OPER_EXPRESSION: return _slang_gen_operation(A, &oper->children[0]); case SLANG_OPER_FOR: return _slang_gen_for(A, oper); case SLANG_OPER_DO: return _slang_gen_do(A, oper); case SLANG_OPER_WHILE: return _slang_gen_while(A, oper); case SLANG_OPER_BREAK: if (!A->CurLoop) { slang_info_log_error(A->log, "'break' not in loop"); return NULL; } return new_break(A->CurLoop); case SLANG_OPER_CONTINUE: if (!A->CurLoop) { slang_info_log_error(A->log, "'continue' not in loop"); return NULL; } return _slang_gen_continue(A, oper); case SLANG_OPER_DISCARD: return new_node0(IR_KILL); case SLANG_OPER_EQUAL: return _slang_gen_compare(A, oper, IR_EQUAL); case SLANG_OPER_NOTEQUAL: return _slang_gen_compare(A, oper, IR_NOTEQUAL); case SLANG_OPER_GREATER: return _slang_gen_compare(A, oper, IR_SGT); case SLANG_OPER_LESS: return _slang_gen_compare(A, oper, IR_SLT); case SLANG_OPER_GREATEREQUAL: return _slang_gen_compare(A, oper, IR_SGE); case SLANG_OPER_LESSEQUAL: return _slang_gen_compare(A, oper, IR_SLE); case SLANG_OPER_ADD: { slang_ir_node *n; assert(oper->num_children == 2); n = _slang_gen_function_call_name(A, "+", oper, NULL); return n; } case SLANG_OPER_SUBTRACT: { slang_ir_node *n; assert(oper->num_children == 2); n = _slang_gen_function_call_name(A, "-", oper, NULL); return n; } case SLANG_OPER_MULTIPLY: { slang_ir_node *n; assert(oper->num_children == 2); n = _slang_gen_function_call_name(A, "*", oper, NULL); return n; } case SLANG_OPER_DIVIDE: { slang_ir_node *n; assert(oper->num_children == 2); n = _slang_gen_function_call_name(A, "/", oper, NULL); return n; } case SLANG_OPER_MINUS: { slang_ir_node *n; assert(oper->num_children == 1); n = _slang_gen_function_call_name(A, "-", oper, NULL); return n; } case SLANG_OPER_PLUS: /* +expr --> do nothing */ return _slang_gen_operation(A, &oper->children[0]); case SLANG_OPER_VARIABLE_DECL: return _slang_gen_declaration(A, oper); case SLANG_OPER_ASSIGN: return _slang_gen_assignment(A, oper); case SLANG_OPER_ADDASSIGN: { slang_ir_node *n; assert(oper->num_children == 2); n = _slang_gen_function_call_name(A, "+=", oper, NULL); return n; } case SLANG_OPER_SUBASSIGN: { slang_ir_node *n; assert(oper->num_children == 2); n = _slang_gen_function_call_name(A, "-=", oper, NULL); return n; } break; case SLANG_OPER_MULASSIGN: { slang_ir_node *n; assert(oper->num_children == 2); n = _slang_gen_function_call_name(A, "*=", oper, NULL); return n; } case SLANG_OPER_DIVASSIGN: { slang_ir_node *n; assert(oper->num_children == 2); n = _slang_gen_function_call_name(A, "/=", oper, NULL); return n; } case SLANG_OPER_LOGICALAND: { slang_ir_node *n; assert(oper->num_children == 2); n = _slang_gen_logical_and(A, oper); return n; } case SLANG_OPER_LOGICALOR: { slang_ir_node *n; assert(oper->num_children == 2); n = _slang_gen_logical_or(A, oper); return n; } case SLANG_OPER_LOGICALXOR: return _slang_gen_xor(A, oper); case SLANG_OPER_NOT: return _slang_gen_not(A, oper); case SLANG_OPER_SELECT: /* b ? x : y */ { slang_ir_node *n; assert(oper->num_children == 3); n = _slang_gen_select(A, oper); return n; } case SLANG_OPER_ASM: return _slang_gen_asm(A, oper, NULL); case SLANG_OPER_CALL: return _slang_gen_function_call_name(A, (const char *) oper->a_id, oper, NULL); case SLANG_OPER_METHOD: return _slang_gen_method_call(A, oper); case SLANG_OPER_RETURN: return _slang_gen_return(A, oper); case SLANG_OPER_LABEL: return new_label(oper->label); case SLANG_OPER_IDENTIFIER: return _slang_gen_variable(A, oper); case SLANG_OPER_IF: return _slang_gen_if(A, oper); case SLANG_OPER_FIELD: return _slang_gen_struct_field(A, oper); case SLANG_OPER_SUBSCRIPT: return _slang_gen_array_element(A, oper); case SLANG_OPER_LITERAL_FLOAT: /* fall-through */ case SLANG_OPER_LITERAL_INT: /* fall-through */ case SLANG_OPER_LITERAL_BOOL: return new_float_literal(oper->literal, oper->literal_size); case SLANG_OPER_POSTINCREMENT: /* var++ */ { slang_ir_node *n; assert(oper->num_children == 1); n = _slang_gen_function_call_name(A, "__postIncr", oper, NULL); return n; } case SLANG_OPER_POSTDECREMENT: /* var-- */ { slang_ir_node *n; assert(oper->num_children == 1); n = _slang_gen_function_call_name(A, "__postDecr", oper, NULL); return n; } case SLANG_OPER_PREINCREMENT: /* ++var */ { slang_ir_node *n; assert(oper->num_children == 1); n = _slang_gen_function_call_name(A, "++", oper, NULL); return n; } case SLANG_OPER_PREDECREMENT: /* --var */ { slang_ir_node *n; assert(oper->num_children == 1); n = _slang_gen_function_call_name(A, "--", oper, NULL); return n; } case SLANG_OPER_NON_INLINED_CALL: case SLANG_OPER_SEQUENCE: { slang_ir_node *tree = NULL; GLuint i; for (i = 0; i < oper->num_children; i++) { slang_ir_node *n = _slang_gen_operation(A, &oper->children[i]); tree = new_seq(tree, n); if (n) tree->Store = n->Store; } if (oper->type == SLANG_OPER_NON_INLINED_CALL) { tree = new_function_call(tree, oper->label); } return tree; } case SLANG_OPER_NONE: case SLANG_OPER_VOID: /* returning NULL here would generate an error */ return new_node0(IR_NOP); default: _mesa_problem(NULL, "bad node type %d in _slang_gen_operation", oper->type); return new_node0(IR_NOP); } return NULL; } /** * Called by compiler when a global variable has been parsed/compiled. * Here we examine the variable's type to determine what kind of register * storage will be used. * * A uniform such as "gl_Position" will become the register specification * (PROGRAM_OUTPUT, VERT_RESULT_HPOS). Or, uniform "gl_FogFragCoord" * will be (PROGRAM_INPUT, FRAG_ATTRIB_FOGC). * * Samplers are interesting. For "uniform sampler2D tex;" we'll specify * (PROGRAM_SAMPLER, index) where index is resolved at link-time to an * actual texture unit (as specified by the user calling glUniform1i()). */ GLboolean _slang_codegen_global_variable(slang_assemble_ctx *A, slang_variable *var, slang_unit_type type) { struct gl_program *prog = A->program; const char *varName = (char *) var->a_name; GLboolean success = GL_TRUE; slang_ir_storage *store = NULL; int dbg = 0; const GLenum datatype = _slang_gltype_from_specifier(&var->type.specifier); const GLint texIndex = sampler_to_texture_index(var->type.specifier.type); const GLint size = _slang_sizeof_type_specifier(&var->type.specifier); const GLint arrayLen = _slang_array_length(var); const GLint totalSize = _slang_array_size(size, arrayLen); if (texIndex != -1) { /* This is a texture sampler variable... * store->File = PROGRAM_SAMPLER * store->Index = sampler number (0..7, typically) * store->Size = texture type index (1D, 2D, 3D, cube, etc) */ if (var->initializer) { slang_info_log_error(A->log, "illegal assignment to '%s'", varName); return GL_FALSE; } #if FEATURE_es2_glsl /* XXX should use FEATURE_texture_rect */ /* disallow rect samplers */ if (var->type.specifier.type == SLANG_SPEC_SAMPLER2DRECT || var->type.specifier.type == SLANG_SPEC_SAMPLER2DRECTSHADOW) { slang_info_log_error(A->log, "invalid sampler type for '%s'", varName); return GL_FALSE; } #endif { GLint sampNum = _mesa_add_sampler(prog->Parameters, varName, datatype); store = _slang_new_ir_storage(PROGRAM_SAMPLER, sampNum, texIndex); } if (dbg) printf("SAMPLER "); } else if (var->type.qualifier == SLANG_QUAL_UNIFORM) { /* Uniform variable */ const GLuint swizzle = _slang_var_swizzle(totalSize, 0); if (prog) { /* user-defined uniform */ if (datatype == GL_NONE) { if (var->type.specifier.type == SLANG_SPEC_STRUCT) { /* temporary work-around */ GLenum datatype = GL_FLOAT; GLint uniformLoc = _mesa_add_uniform(prog->Parameters, varName, totalSize, datatype, NULL); store = _slang_new_ir_storage_swz(PROGRAM_UNIFORM, uniformLoc, totalSize, swizzle); /* XXX what we need to do is unroll the struct into its * basic types, creating a uniform variable for each. * For example: * struct foo { * vec3 a; * vec4 b; * }; * uniform foo f; * * Should produce uniforms: * "f.a" (GL_FLOAT_VEC3) * "f.b" (GL_FLOAT_VEC4) */ if (var->initializer) { slang_info_log_error(A->log, "unsupported initializer for uniform '%s'", varName); return GL_FALSE; } } else { slang_info_log_error(A->log, "invalid datatype for uniform variable %s", varName); return GL_FALSE; } } else { /* non-struct uniform */ if (!_slang_gen_var_decl(A, var, var->initializer)) return GL_FALSE; store = var->store; } } else { /* pre-defined uniform, like gl_ModelviewMatrix */ /* We know it's a uniform, but don't allocate storage unless * it's really used. */ store = _slang_new_ir_storage_swz(PROGRAM_STATE_VAR, -1, totalSize, swizzle); } if (dbg) printf("UNIFORM (sz %d) ", totalSize); } else if (var->type.qualifier == SLANG_QUAL_VARYING) { /* varyings must be float, vec or mat */ if (!_slang_type_is_float_vec_mat(var->type.specifier.type) && var->type.specifier.type != SLANG_SPEC_ARRAY) { slang_info_log_error(A->log, "varying '%s' must be float/vector/matrix", varName); return GL_FALSE; } if (var->initializer) { slang_info_log_error(A->log, "illegal initializer for varying '%s'", varName); return GL_FALSE; } if (prog) { /* user-defined varying */ GLbitfield flags; GLint varyingLoc; GLuint swizzle; flags = 0x0; if (var->type.centroid == SLANG_CENTROID) flags |= PROG_PARAM_BIT_CENTROID; if (var->type.variant == SLANG_INVARIANT) flags |= PROG_PARAM_BIT_INVARIANT; varyingLoc = _mesa_add_varying(prog->Varying, varName, totalSize, flags); swizzle = _slang_var_swizzle(size, 0); store = _slang_new_ir_storage_swz(PROGRAM_VARYING, varyingLoc, totalSize, swizzle); } else { /* pre-defined varying, like gl_Color or gl_TexCoord */ if (type == SLANG_UNIT_FRAGMENT_BUILTIN) { /* fragment program input */ GLuint swizzle; GLint index = _slang_input_index(varName, GL_FRAGMENT_PROGRAM_ARB, &swizzle); assert(index >= 0); assert(index < FRAG_ATTRIB_MAX); store = _slang_new_ir_storage_swz(PROGRAM_INPUT, index, size, swizzle); } else { /* vertex program output */ GLint index = _slang_output_index(varName, GL_VERTEX_PROGRAM_ARB); GLuint swizzle = _slang_var_swizzle(size, 0); assert(index >= 0); assert(index < VERT_RESULT_MAX); assert(type == SLANG_UNIT_VERTEX_BUILTIN); store = _slang_new_ir_storage_swz(PROGRAM_OUTPUT, index, size, swizzle); } if (dbg) printf("V/F "); } if (dbg) printf("VARYING "); } else if (var->type.qualifier == SLANG_QUAL_ATTRIBUTE) { GLuint swizzle; GLint index; /* attributes must be float, vec or mat */ if (!_slang_type_is_float_vec_mat(var->type.specifier.type)) { slang_info_log_error(A->log, "attribute '%s' must be float/vector/matrix", varName); return GL_FALSE; } if (prog) { /* user-defined vertex attribute */ const GLint attr = -1; /* unknown */ swizzle = _slang_var_swizzle(size, 0); index = _mesa_add_attribute(prog->Attributes, varName, size, datatype, attr); assert(index >= 0); index = VERT_ATTRIB_GENERIC0 + index; } else { /* pre-defined vertex attrib */ index = _slang_input_index(varName, GL_VERTEX_PROGRAM_ARB, &swizzle); assert(index >= 0); } store = _slang_new_ir_storage_swz(PROGRAM_INPUT, index, size, swizzle); if (dbg) printf("ATTRIB "); } else if (var->type.qualifier == SLANG_QUAL_FIXEDINPUT) { GLuint swizzle = SWIZZLE_XYZW; /* silence compiler warning */ GLint index = _slang_input_index(varName, GL_FRAGMENT_PROGRAM_ARB, &swizzle); store = _slang_new_ir_storage_swz(PROGRAM_INPUT, index, size, swizzle); if (dbg) printf("INPUT "); } else if (var->type.qualifier == SLANG_QUAL_FIXEDOUTPUT) { if (type == SLANG_UNIT_VERTEX_BUILTIN) { GLint index = _slang_output_index(varName, GL_VERTEX_PROGRAM_ARB); store = _slang_new_ir_storage(PROGRAM_OUTPUT, index, size); } else { GLint index = _slang_output_index(varName, GL_FRAGMENT_PROGRAM_ARB); GLint specialSize = 4; /* treat all fragment outputs as float[4] */ assert(type == SLANG_UNIT_FRAGMENT_BUILTIN); store = _slang_new_ir_storage(PROGRAM_OUTPUT, index, specialSize); } if (dbg) printf("OUTPUT "); } else if (var->type.qualifier == SLANG_QUAL_CONST && !prog) { /* pre-defined global constant, like gl_MaxLights */ store = _slang_new_ir_storage(PROGRAM_CONSTANT, -1, size); if (dbg) printf("CONST "); } else { /* ordinary variable (may be const) */ slang_ir_node *n; /* IR node to declare the variable */ n = _slang_gen_var_decl(A, var, var->initializer); /* emit GPU instructions */ success = _slang_emit_code(n, A->vartable, A->program, GL_FALSE, A->log); _slang_free_ir_tree(n); } if (dbg) printf("GLOBAL VAR %s idx %d\n", (char*) var->a_name, store ? store->Index : -2); if (store) var->store = store; /* save var's storage info */ var->declared = GL_TRUE; return success; } /** * Produce an IR tree from a function AST (fun->body). * Then call the code emitter to convert the IR tree into gl_program * instructions. */ GLboolean _slang_codegen_function(slang_assemble_ctx * A, slang_function * fun) { slang_ir_node *n; GLboolean success = GL_TRUE; if (_mesa_strcmp((char *) fun->header.a_name, "main") != 0) { /* we only really generate code for main, all other functions get * inlined or codegen'd upon an actual call. */ #if 0 /* do some basic error checking though */ if (fun->header.type.specifier.type != SLANG_SPEC_VOID) { /* check that non-void functions actually return something */ slang_operation *op = _slang_find_node_type(fun->body, SLANG_OPER_RETURN); if (!op) { slang_info_log_error(A->log, "function \"%s\" has no return statement", (char *) fun->header.a_name); printf( "function \"%s\" has no return statement\n", (char *) fun->header.a_name); return GL_FALSE; } } #endif return GL_TRUE; /* not an error */ } #if 0 printf("\n*********** codegen_function %s\n", (char *) fun->header.a_name); slang_print_function(fun, 1); #endif /* should have been allocated earlier: */ assert(A->program->Parameters ); assert(A->program->Varying); assert(A->vartable); A->CurLoop = NULL; A->CurFunction = fun; /* fold constant expressions, etc. */ _slang_simplify(fun->body, &A->space, A->atoms); #if 0 printf("\n*********** simplified %s\n", (char *) fun->header.a_name); slang_print_function(fun, 1); #endif /* Create an end-of-function label */ A->curFuncEndLabel = _slang_label_new("__endOfFunc__main"); /* push new vartable scope */ _slang_push_var_table(A->vartable); /* Generate IR tree for the function body code */ n = _slang_gen_operation(A, fun->body); if (n) n = new_node1(IR_SCOPE, n); /* pop vartable, restore previous */ _slang_pop_var_table(A->vartable); if (!n) { /* XXX record error */ return GL_FALSE; } /* append an end-of-function-label to IR tree */ n = new_seq(n, new_label(A->curFuncEndLabel)); /*_slang_label_delete(A->curFuncEndLabel);*/ A->curFuncEndLabel = NULL; #if 0 printf("************* New AST for %s *****\n", (char*)fun->header.a_name); slang_print_function(fun, 1); #endif #if 0 printf("************* IR for %s *******\n", (char*)fun->header.a_name); _slang_print_ir_tree(n, 0); #endif #if 0 printf("************* End codegen function ************\n\n"); #endif /* Emit program instructions */ success = _slang_emit_code(n, A->vartable, A->program, GL_TRUE, A->log); _slang_free_ir_tree(n); /* free codegen context */ /* _mesa_free(A->codegen); */ return success; }