mirror of
https://github.com/DarkPlacesEngine/gmqcc.git
synced 2024-11-23 20:33:05 +00:00
334 lines
10 KiB
C++
334 lines
10 KiB
C++
#ifndef GMQCC_IR_HDR
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#define GMQCC_IR_HDR
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#include "gmqcc.h"
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/*
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* Type large enough to hold all the possible IR flags. This should be
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* changed if the static assertion at the end of this file fails.
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*/
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typedef uint8_t ir_flag_t;
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struct ir_value;
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struct ir_instr;
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struct ir_block;
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struct ir_function;
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struct ir_builder;
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struct ir_life_entry_t {
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/* both inclusive */
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size_t start;
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size_t end;
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};
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enum {
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IR_FLAG_HAS_ARRAYS = 1 << 0,
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IR_FLAG_HAS_UNINITIALIZED = 1 << 1,
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IR_FLAG_HAS_GOTO = 1 << 2,
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IR_FLAG_INCLUDE_DEF = 1 << 3,
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IR_FLAG_ERASABLE = 1 << 4,
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IR_FLAG_BLOCK_COVERAGE = 1 << 5,
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IR_FLAG_SPLIT_VECTOR = 1 << 6,
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IR_FLAG_LAST,
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IR_FLAG_MASK_NO_OVERLAP = (IR_FLAG_HAS_ARRAYS | IR_FLAG_HAS_UNINITIALIZED),
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IR_FLAG_MASK_NO_LOCAL_TEMPS = (IR_FLAG_HAS_ARRAYS | IR_FLAG_HAS_UNINITIALIZED)
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};
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struct ir_value {
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ir_value(std::string&& name, store_type storetype, qc_type vtype);
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ir_value(ir_function *owner, std::string&& name, store_type storetype, qc_type vtype);
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~ir_value();
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ir_value *vectorMember(unsigned int member);
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bool GMQCC_WARN setFloat(float);
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bool GMQCC_WARN setFunc(int);
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bool GMQCC_WARN setString(const char*);
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bool GMQCC_WARN setVector(vec3_t);
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bool GMQCC_WARN setField(ir_value*);
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#if 0
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bool GMQCC_WARN setInt(int);
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#endif
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bool lives(size_t at);
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void dumpLife(int (*oprintf)(const char*, ...)) const;
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void setCodeAddress(int32_t gaddr);
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int32_t codeAddress() const;
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bool insertLife(size_t idx, ir_life_entry_t);
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bool setAlive(size_t position);
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bool mergeLife(const ir_value *other);
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std::string m_name;
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qc_type m_vtype;
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store_type m_store;
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lex_ctx_t m_context;
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qc_type m_fieldtype; // even the IR knows the subtype of a field
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qc_type m_outtype; // and the output type of a function
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int m_cvq; // 'const' vs 'var' qualifier
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ir_flag_t m_flags;
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std::vector<ir_instr *> m_reads;
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std::vector<ir_instr *> m_writes;
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// constant values
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bool m_hasvalue;
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union {
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qcfloat_t vfloat;
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int vint;
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vec3_t vvec;
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int32_t ivec[3];
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char *vstring;
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ir_value *vpointer;
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ir_function *vfunc;
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} m_constval;
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struct {
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int32_t globaladdr;
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int32_t name;
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int32_t local; // filled by the local-allocator
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int32_t addroffset; // added for members
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int32_t fieldaddr; // to generate field-addresses early
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} m_code;
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// for accessing vectors
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ir_value *m_members[3];
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ir_value *m_memberof;
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bool m_unique_life; // arrays will never overlap with temps
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bool m_locked; // temps living during a CALL must be locked
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bool m_callparam;
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std::vector<ir_life_entry_t> m_life; // For the temp allocator
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size_t size() const;
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void dump(int (*oprintf)(const char*, ...)) const;
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};
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/* PHI data */
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struct ir_phi_entry_t {
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ir_value *value;
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ir_block *from;
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};
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/* instruction */
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struct ir_instr {
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ir_instr(lex_ctx_t, ir_block *owner, int opcode);
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~ir_instr();
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int m_opcode;
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lex_ctx_t m_context;
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ir_value *(_m_ops[3]) = { nullptr, nullptr, nullptr };
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ir_block *(m_bops[2]) = { nullptr, nullptr };
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std::vector<ir_phi_entry_t> m_phi;
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std::vector<ir_value *> m_params;
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// For the temp-allocation
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size_t m_eid = 0;
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// For IFs
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bool m_likely = true;
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ir_block *m_owner;
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};
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/* block */
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struct ir_block {
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ir_block(ir_function *owner, const std::string& name);
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~ir_block();
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ir_function *m_owner;
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std::string m_label;
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lex_ctx_t m_context;
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bool m_final = false; /* once a jump is added we're done */
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ir_instr **m_instr = nullptr;
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ir_block **m_entries = nullptr;
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ir_block **m_exits = nullptr;
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std::vector<ir_value *> m_living;
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/* For the temp-allocation */
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size_t m_entry_id = 0;
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size_t m_eid = 0;
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bool m_is_return = false;
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bool m_generated = false;
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size_t m_code_start = 0;
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};
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ir_value* ir_block_create_binop(ir_block*, lex_ctx_t, const char *label, int op, ir_value *left, ir_value *right);
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ir_value* ir_block_create_unary(ir_block*, lex_ctx_t, const char *label, int op, ir_value *operand);
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bool GMQCC_WARN ir_block_create_store_op(ir_block*, lex_ctx_t, int op, ir_value *target, ir_value *what);
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bool GMQCC_WARN ir_block_create_storep(ir_block*, lex_ctx_t, ir_value *target, ir_value *what);
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ir_value* ir_block_create_load_from_ent(ir_block*, lex_ctx_t, const char *label, ir_value *ent, ir_value *field, qc_type outype);
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ir_value* ir_block_create_fieldaddress(ir_block*, lex_ctx_t, const char *label, ir_value *entity, ir_value *field);
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bool GMQCC_WARN ir_block_create_state_op(ir_block*, lex_ctx_t, ir_value *frame, ir_value *think);
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/* This is to create an instruction of the form
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* <outtype>%label := opcode a, b
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*/
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ir_instr* ir_block_create_phi(ir_block*, lex_ctx_t, const char *label, qc_type vtype);
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ir_value* ir_phi_value(ir_instr*);
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void ir_phi_add(ir_instr*, ir_block *b, ir_value *v);
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ir_instr* ir_block_create_call(ir_block*, lex_ctx_t, const char *label, ir_value *func, bool noreturn);
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ir_value* ir_call_value(ir_instr*);
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void ir_call_param(ir_instr*, ir_value*);
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bool GMQCC_WARN ir_block_create_return(ir_block*, lex_ctx_t, ir_value *opt_value);
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bool GMQCC_WARN ir_block_create_if(ir_block*, lex_ctx_t, ir_value *cond,
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ir_block *ontrue, ir_block *onfalse);
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/*
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* A 'goto' is an actual 'goto' coded in QC, whereas
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* a 'jump' is a virtual construct which simply names the
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* next block to go to.
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* A goto usually becomes an OP_GOTO in the resulting code,
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* whereas a 'jump' usually doesn't add any actual instruction.
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*/
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bool GMQCC_WARN ir_block_create_jump(ir_block*, lex_ctx_t, ir_block *to);
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bool GMQCC_WARN ir_block_create_goto(ir_block*, lex_ctx_t, ir_block *to);
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/* function */
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struct ir_function {
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ir_function(ir_builder *owner, qc_type returntype);
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~ir_function();
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ir_builder *m_owner;
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std::string m_name;
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qc_type m_outtype;
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int *m_params = nullptr;
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ir_flag_t m_flags = 0;
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int m_builtin = 0;
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std::vector<std::unique_ptr<ir_block>> m_blocks;
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/*
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* values generated from operations
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* which might get optimized away, so anything
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* in there needs to be deleted in the dtor.
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*/
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std::vector<std::unique_ptr<ir_value>> m_values;
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std::vector<std::unique_ptr<ir_value>> m_locals; /* locally defined variables */
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ir_value *m_value = nullptr;
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size_t m_allocated_locals = 0;
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size_t m_globaltemps = 0;
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ir_block* m_first = nullptr;
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ir_block* m_last = nullptr;
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lex_ctx_t m_context;
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/*
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* for prototypes - first we generate all the
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* globals, and we remember teh function-defs
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* so we can later fill in the entry pos
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*
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* remember the ID:
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*/
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qcint_t m_code_function_def = -1;
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/* for temp allocation */
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size_t m_run_id = 0;
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/* vararg support: */
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size_t m_max_varargs = 0;
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};
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ir_value* ir_function_create_local(ir_function *self, const std::string& name, qc_type vtype, bool param);
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bool GMQCC_WARN ir_function_finalize(ir_function*);
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ir_block* ir_function_create_block(lex_ctx_t ctx, ir_function*, const char *label);
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/* builder */
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#define IR_HT_SIZE 1024
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#define IR_MAX_VINSTR_TEMPS 1
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struct ir_builder {
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ir_builder(const std::string& modulename);
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~ir_builder();
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ir_function *createFunction(const std::string &name, qc_type outtype);
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ir_value *createGlobal(const std::string &name, qc_type vtype);
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ir_value *createField(const std::string &name, qc_type vtype);
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ir_value *get_va_count();
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bool generate(const char *filename);
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void dump(int (*oprintf)(const char*, ...)) const;
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ir_value *generateExtparamProto();
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void generateExtparam();
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ir_value *literalFloat(float value, bool add_to_list);
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std::string m_name;
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std::vector<std::unique_ptr<ir_function>> m_functions;
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std::vector<std::unique_ptr<ir_value>> m_globals;
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std::vector<std::unique_ptr<ir_value>> m_fields;
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// for reusing them in vector-splits, TODO: sort this or use a radix-tree
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std::vector<ir_value*> m_const_floats;
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ht m_htfunctions;
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ht m_htglobals;
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ht m_htfields;
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// extparams' ir_values reference the ones from extparam_protos
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std::vector<std::unique_ptr<ir_value>> m_extparam_protos;
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std::vector<ir_value*> m_extparams;
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// the highest func->allocated_locals
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size_t m_max_locals = 0;
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size_t m_max_globaltemps = 0;
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uint32_t m_first_common_local = 0;
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uint32_t m_first_common_globaltemp = 0;
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std::vector<const char*> m_filenames;
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std::vector<qcint_t> m_filestrings;
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// we cache the #IMMEDIATE string here
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qcint_t m_str_immediate = 0;
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// there should just be this one nil
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ir_value *m_nil;
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ir_value *m_reserved_va_count = nullptr;
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ir_value *m_coverage_func = nullptr;
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/* some virtual instructions require temps, and their code is isolated
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* so that we don't need to keep track of their liveness.
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*/
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ir_value *m_vinstr_temp[IR_MAX_VINSTR_TEMPS];
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/* code generator */
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std::unique_ptr<code_t> m_code;
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private:
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qcint_t filestring(const char *filename);
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bool generateGlobal(ir_value*, bool is_local);
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bool generateGlobalFunction(ir_value*);
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bool generateGlobalFunctionCode(ir_value*);
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bool generateFunctionLocals(ir_value*);
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};
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/*
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* This code assumes 32 bit floats while generating binary
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* Blub: don't use extern here, it's annoying and shows up in nm
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* for some reason :P
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*/
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typedef int static_assert_is_32bit_float [(sizeof(int32_t) == 4) ? 1 : -1];
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typedef int static_assert_is_32bit_integer[(sizeof(qcfloat_t) == 4) ? 1 : -1];
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/*
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* If the condition creates a situation where this becomes -1 size it means there are
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* more IR_FLAGs than the type ir_flag_t is capable of holding. So either eliminate
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* the IR flag count or change the ir_flag_t typedef to a type large enough to accomodate
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* all the flags.
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*/
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typedef int static_assert_is_ir_flag_safe [((IR_FLAG_LAST) <= (ir_flag_t)(-1)) ? 1 : -1];
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#endif
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