/* * Copyright (C) 2012 * Wolfgang Bumiller * * 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 THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. */ #ifndef GMQCC_IR_HDR #define GMQCC_IR_HDR /* ir_value */ typedef struct { /* both inclusive */ size_t start; size_t end; } ir_life_entry_t; struct ir_function_s; typedef struct ir_value_s { char *name; int vtype; int store; lex_ctx context; /* even the IR knows the subtype of a field */ int fieldtype; /* and the output type of a function */ int outtype; MEM_VECTOR_MAKE(struct ir_instr_s*, reads); MEM_VECTOR_MAKE(struct ir_instr_s*, writes); /* constantvalues */ bool isconst; union { float vfloat; int vint; vector vvec; char *vstring; struct ir_value_s *vpointer; struct ir_function_s *vfunc; quaternion vquat; matrix vmat; } constval; struct { int32_t globaladdr; int32_t name; /* filled by the local-allocator */ int32_t local; } code; /* For the temp allocator */ MEM_VECTOR_MAKE(ir_life_entry_t, life); } ir_value; /* ir_value can be a variable, or created by an operation */ ir_value* ir_value_var(const char *name, int st, int vtype); /* if a result of an operation: the function should store * it to remember to delete it / garbage collect it */ ir_value* ir_value_out(struct ir_function_s *owner, const char *name, int st, int vtype); void ir_value_delete(ir_value*); void ir_value_set_name(ir_value*, const char *name); MEM_VECTOR_PROTO_ALL(ir_value, struct ir_instr_s*, reads); MEM_VECTOR_PROTO_ALL(ir_value, struct ir_instr_s*, writes); bool GMQCC_WARN ir_value_set_float(ir_value*, float f); bool GMQCC_WARN ir_value_set_func(ir_value*, int f); #if 0 bool GMQCC_WARN ir_value_set_int(ir_value*, int i); #endif bool GMQCC_WARN ir_value_set_string(ir_value*, const char *s); bool GMQCC_WARN ir_value_set_vector(ir_value*, vector v); /*bool ir_value_set_pointer_v(ir_value*, ir_value* p); */ /*bool ir_value_set_pointer_i(ir_value*, int i); */ bool GMQCC_WARN ir_value_set_quaternion(ir_value*, quaternion v); bool GMQCC_WARN ir_value_set_matrix(ir_value*, matrix v); MEM_VECTOR_PROTO(ir_value, ir_life_entry_t, life); /* merge an instruction into the life-range */ /* returns false if the lifepoint was already known */ bool ir_value_life_merge(ir_value*, size_t); bool ir_value_life_merge_into(ir_value*, const ir_value*); /* check if a value lives at a specific point */ bool ir_value_lives(ir_value*, size_t); /* check if the life-range of 2 values overlaps */ bool ir_values_overlap(const ir_value*, const ir_value*); void ir_value_dump(ir_value*, int (*oprintf)(const char*,...)); void ir_value_dump_life(ir_value *self, int (*oprintf)(const char*,...)); /* A vector of IR values */ typedef struct { MEM_VECTOR_MAKE(ir_value*, v); } ir_value_vector; MEM_VECTOR_PROTO(ir_value_vector, ir_value*, v); /* PHI data */ typedef struct ir_phi_entry_s { ir_value *value; struct ir_block_s *from; } ir_phi_entry_t; /* instruction */ typedef struct ir_instr_s { int opcode; lex_ctx context; ir_value* (_ops[3]); struct ir_block_s* (bops[2]); MEM_VECTOR_MAKE(ir_phi_entry_t, phi); MEM_VECTOR_MAKE(ir_value*, params); /* For the temp-allocation */ size_t eid; struct ir_block_s *owner; } ir_instr; ir_instr* ir_instr_new(struct ir_block_s *owner, int opcode); void ir_instr_delete(ir_instr*); MEM_VECTOR_PROTO(ir_value, ir_phi_entry_t, phi); bool GMQCC_WARN ir_instr_op(ir_instr*, int op, ir_value *value, bool writing); MEM_VECTOR_PROTO(ir_value, ir_value*, params); void ir_instr_dump(ir_instr* in, char *ind, int (*oprintf)(const char*,...)); /* block */ typedef struct ir_block_s { char *label; lex_ctx context; bool final; /* once a jump is added we're done */ MEM_VECTOR_MAKE(ir_instr*, instr); MEM_VECTOR_MAKE(struct ir_block_s*, entries); MEM_VECTOR_MAKE(struct ir_block_s*, exits); MEM_VECTOR_MAKE(ir_value*, living); /* For the temp-allocation */ size_t eid; bool is_return; size_t run_id; struct ir_function_s *owner; bool generated; size_t code_start; } ir_block; ir_block* ir_block_new(struct ir_function_s *owner, const char *label); void ir_block_delete(ir_block*); bool ir_block_set_label(ir_block*, const char *label); MEM_VECTOR_PROTO(ir_block, ir_instr*, instr); MEM_VECTOR_PROTO_ALL(ir_block, ir_block*, exits); MEM_VECTOR_PROTO_ALL(ir_block, ir_block*, entries); ir_value* ir_block_create_binop(ir_block*, const char *label, int op, ir_value *left, ir_value *right); ir_value* ir_block_create_unary(ir_block*, const char *label, int op, ir_value *operand); bool GMQCC_WARN ir_block_create_store_op(ir_block*, int op, ir_value *target, ir_value *what); bool GMQCC_WARN ir_block_create_store(ir_block*, ir_value *target, ir_value *what); bool GMQCC_WARN ir_block_create_storep(ir_block*, ir_value *target, ir_value *what); /* field must be of TYPE_FIELD */ ir_value* ir_block_create_load_from_ent(ir_block*, const char *label, ir_value *ent, ir_value *field, int outype); ir_value* ir_block_create_fieldaddress(ir_block*, const char *label, ir_value *entity, ir_value *field); /* This is to create an instruction of the form * %label := opcode a, b */ ir_value* ir_block_create_general_instr(ir_block *self, const char *label, int op, ir_value *a, ir_value *b, int outype); ir_value* ir_block_create_add(ir_block*, const char *label, ir_value *l, ir_value *r); ir_value* ir_block_create_sub(ir_block*, const char *label, ir_value *l, ir_value *r); ir_value* ir_block_create_mul(ir_block*, const char *label, ir_value *l, ir_value *r); ir_value* ir_block_create_div(ir_block*, const char *label, ir_value *l, ir_value *r); ir_instr* ir_block_create_phi(ir_block*, const char *label, int vtype); ir_value* ir_phi_value(ir_instr*); bool GMQCC_WARN ir_phi_add(ir_instr*, ir_block *b, ir_value *v); ir_instr* ir_block_create_call(ir_block*, const char *label, ir_value *func); ir_value* ir_call_value(ir_instr*); bool GMQCC_WARN ir_call_param(ir_instr*, ir_value*); bool GMQCC_WARN ir_block_create_return(ir_block*, ir_value *opt_value); bool GMQCC_WARN ir_block_create_if(ir_block*, ir_value *cond, ir_block *ontrue, ir_block *onfalse); /* A 'goto' is an actual 'goto' coded in QC, whereas * a 'jump' is a virtual construct which simply names the * next block to go to. * A goto usually becomes an OP_GOTO in the resulting code, * whereas a 'jump' usually doesn't add any actual instruction. */ bool GMQCC_WARN ir_block_create_jump(ir_block*, ir_block *to); bool GMQCC_WARN ir_block_create_goto(ir_block*, ir_block *to); MEM_VECTOR_PROTO_ALL(ir_block, ir_value*, living); void ir_block_dump(ir_block*, char *ind, int (*oprintf)(const char*,...)); /* function */ typedef struct ir_function_s { char *name; int outtype; MEM_VECTOR_MAKE(int, params); MEM_VECTOR_MAKE(ir_block*, blocks); int builtin; ir_value *value; /* values generated from operations * which might get optimized away, so anything * in there needs to be deleted in the dtor. */ MEM_VECTOR_MAKE(ir_value*, values); /* locally defined variables */ MEM_VECTOR_MAKE(ir_value*, locals); size_t allocated_locals; ir_block* first; ir_block* last; lex_ctx context; /* for temp allocation */ size_t run_id; struct ir_builder_s *owner; } ir_function; ir_function* ir_function_new(struct ir_builder_s *owner, int returntype); void ir_function_delete(ir_function*); bool GMQCC_WARN ir_function_collect_value(ir_function*, ir_value *value); bool ir_function_set_name(ir_function*, const char *name); MEM_VECTOR_PROTO(ir_function, int, params); MEM_VECTOR_PROTO(ir_function, ir_block*, blocks); ir_value* ir_function_get_local(ir_function *self, const char *name); ir_value* ir_function_create_local(ir_function *self, const char *name, int vtype, bool param); bool GMQCC_WARN ir_function_finalize(ir_function*); /* bool ir_function_naive_phi(ir_function*); bool ir_function_enumerate(ir_function*); bool ir_function_calculate_liferanges(ir_function*); */ ir_block* ir_function_create_block(ir_function*, const char *label); void ir_function_dump(ir_function*, char *ind, int (*oprintf)(const char*,...)); /* builder */ typedef struct ir_builder_s { char *name; MEM_VECTOR_MAKE(ir_function*, functions); MEM_VECTOR_MAKE(ir_value*, globals); MEM_VECTOR_MAKE(ir_value*, fields); } ir_builder; ir_builder* ir_builder_new(const char *modulename); void ir_builder_delete(ir_builder*); bool ir_builder_set_name(ir_builder *self, const char *name); MEM_VECTOR_PROTO(ir_builder, ir_function*, functions); MEM_VECTOR_PROTO(ir_builder, ir_value*, globals); MEM_VECTOR_PROTO(ir_builder, ir_value*, fields); ir_function* ir_builder_get_function(ir_builder*, const char *fun); ir_function* ir_builder_create_function(ir_builder*, const char *name, int outtype); ir_value* ir_builder_get_global(ir_builder*, const char *fun); ir_value* ir_builder_create_global(ir_builder*, const char *name, int vtype); ir_value* ir_builder_get_field(ir_builder*, const char *fun); ir_value* ir_builder_create_field(ir_builder*, const char *name, int vtype); bool ir_builder_generate(ir_builder *self, const char *filename); void ir_builder_dump(ir_builder*, int (*oprintf)(const char*, ...)); /* This code assumes 32 bit floats while generating binary */ extern int check_int_and_float_size [ (sizeof(int32_t) == sizeof(( (ir_value*)(NULL) )->constval.vvec.x)) ? 1 : -1 ]; #endif