struct irProcedure; struct irBlock; struct irValue; struct irDebugInfo; struct irModule { CheckerInfo * info; gbArena arena; gbArena tmp_arena; gbAllocator allocator; gbAllocator tmp_allocator; // bool generate_debug_info; u32 stmt_state_flags; // String source_filename; String layout; // String triple; Map min_dep_map; // Key: Entity * Map values; // Key: Entity * Map members; // Key: String Map entity_names; // Key: Entity * of the typename Map debug_info; // Key: Unique pointer i32 global_string_index; i32 global_array_index; // For ConstantSlice i32 global_generated_index; irValue * global_default_context; // NOTE(bill): To prevent strings from being copied a lot // Mainly used for file names Map const_strings; // Key: String Entity * entry_point_entity; Array procs; // NOTE(bill): All procedures with bodies Array procs_to_generate; // NOTE(bill): Procedures to generate Array foreign_library_paths; // Only the ones that were used }; // NOTE(bill): For more info, see https://en.wikipedia.org/wiki/Dominator_(graph_theory) struct irDomNode { irBlock * idom; // Parent (Immediate Dominator) Array children; i32 pre, post; // Ordering in tree }; struct irBlock { i32 index; String label; irProcedure *parent; AstNode * node; // Can be NULL Scope * scope; isize scope_index; irDomNode dom; i32 gaps; Array instrs; Array locals; Array preds; Array succs; }; struct irTargetList { irTargetList *prev; irBlock * break_; irBlock * continue_; irBlock * fallthrough_; }; enum irDeferExitKind { irDeferExit_Default, irDeferExit_Return, irDeferExit_Branch, }; enum irDeferKind { irDefer_Node, irDefer_Instr, }; struct irDefer { irDeferKind kind; isize scope_index; irBlock * block; union { AstNode *stmt; // NOTE(bill): `instr` will be copied every time to create a new one irValue *instr; }; }; struct irBranchBlocks { AstNode *label; irBlock *break_; irBlock *continue_; }; struct irProcedure { irProcedure * parent; Array children; Entity * entity; irModule * module; String name; Type * type; AstNode * type_expr; AstNode * body; u64 tags; irValue * return_ptr; Array params; Array defer_stmts; Array blocks; i32 scope_index; irBlock * decl_block; irBlock * entry_block; irBlock * curr_block; irTargetList * target_list; Array referrers; Array context_stack; Array branch_blocks; i32 local_count; i32 instr_count; i32 block_count; }; #define IR_STARTUP_RUNTIME_PROC_NAME "__$startup_runtime" #define IR_TYPE_INFO_DATA_NAME "__$type_info_data" #define IR_TYPE_INFO_TYPES_NAME "__$type_info_types_data" #define IR_TYPE_INFO_NAMES_NAME "__$type_info_names_data" #define IR_TYPE_INFO_OFFSETS_NAME "__$type_info_offsets_data" #define IR_TYPE_INFO_USINGS_NAME "__$type_info_usings_data" #define IR_INSTR_KINDS \ IR_INSTR_KIND(Comment, struct { String text; }) \ IR_INSTR_KIND(Local, struct { \ Entity * entity; \ Type * type; \ bool zero_initialized; \ Array referrers; \ i64 alignment; \ }) \ IR_INSTR_KIND(ZeroInit, struct { irValue *address; }) \ IR_INSTR_KIND(Store, struct { \ irValue *address, *value; bool atomic; \ }) \ IR_INSTR_KIND(Load, struct { Type *type; irValue *address; }) \ IR_INSTR_KIND(PtrOffset, struct { \ irValue *address; \ irValue *offset; \ }) \ IR_INSTR_KIND(ArrayElementPtr, struct { \ irValue *address; \ Type * result_type; \ irValue *elem_index; \ }) \ IR_INSTR_KIND(StructElementPtr, struct { \ irValue *address; \ Type * result_type; \ i32 elem_index; \ }) \ IR_INSTR_KIND(StructExtractValue, struct { \ irValue *address; \ Type * result_type; \ i32 index; \ }) \ IR_INSTR_KIND(UnionTagPtr, struct { \ irValue *address; \ Type *type; /* ^int */ \ }) \ IR_INSTR_KIND(UnionTagValue, struct { \ irValue *address; \ Type *type; /* int */ \ }) \ IR_INSTR_KIND(Conv, struct { \ irConvKind kind; \ irValue *value; \ Type *from, *to; \ }) \ IR_INSTR_KIND(Jump, struct { irBlock *block; }) \ IR_INSTR_KIND(If, struct { \ irValue *cond; \ irBlock *true_block; \ irBlock *false_block; \ }) \ IR_INSTR_KIND(Return, struct { irValue *value; }) \ IR_INSTR_KIND(Select, struct { \ irValue *cond; \ irValue *true_value; \ irValue *false_value; \ }) \ IR_INSTR_KIND(Phi, struct { Array edges; Type *type; })\ IR_INSTR_KIND(Unreachable, i32) \ IR_INSTR_KIND(UnaryOp, struct { \ Type * type; \ TokenKind op; \ irValue * expr; \ }) \ IR_INSTR_KIND(BinaryOp, struct { \ Type * type; \ TokenKind op; \ irValue * left, *right; \ }) \ IR_INSTR_KIND(Call, struct { \ Type * type; /* return type */ \ irValue * value; \ irValue * return_ptr; \ irValue **args; \ isize arg_count; \ irValue * context_ptr; \ }) \ IR_INSTR_KIND(StartupRuntime, i32) \ IR_INSTR_KIND(DebugDeclare, struct { \ irDebugInfo *debug_info; \ AstNode * expr; \ Entity * entity; \ bool is_addr; \ irValue * value; \ }) \ // IR_INSTR_KIND(BoundsCheck, struct { \ // TokenPos pos; \ // irValue *index; \ // irValue *len; \ // }) \ // IR_INSTR_KIND(SliceBoundsCheck, struct { \ // TokenPos pos; \ // irValue *low; \ // irValue *high; \ // irValue *max; \ // bool is_substring; \ // }) \ #define IR_CONV_KINDS \ IR_CONV_KIND(trunc) \ IR_CONV_KIND(zext) \ IR_CONV_KIND(sext) \ IR_CONV_KIND(fptrunc) \ IR_CONV_KIND(fpext) \ IR_CONV_KIND(fptoui) \ IR_CONV_KIND(fptosi) \ IR_CONV_KIND(uitofp) \ IR_CONV_KIND(sitofp) \ IR_CONV_KIND(ptrtoint) \ IR_CONV_KIND(inttoptr) \ IR_CONV_KIND(bitcast) enum irInstrKind { irInstr_Invalid, #define IR_INSTR_KIND(x, ...) GB_JOIN2(irInstr_, x), IR_INSTR_KINDS #undef IR_INSTR_KIND }; String const ir_instr_strings[] = { {cast(u8 *)"Invalid", gb_size_of("Invalid")-1}, #define IR_INSTR_KIND(x, ...) {cast(u8 *)#x, gb_size_of(#x)-1}, IR_INSTR_KINDS #undef IR_INSTR_KIND }; enum irConvKind { irConv_Invalid, #define IR_CONV_KIND(x) GB_JOIN2(irConv_, x), IR_CONV_KINDS #undef IR_CONV_KIND }; String const ir_conv_strings[] = { {cast(u8 *)"Invalid", gb_size_of("Invalid")-1}, #define IR_CONV_KIND(x) {cast(u8 *)#x, gb_size_of(#x)-1}, IR_CONV_KINDS #undef IR_CONV_KIND }; #define IR_INSTR_KIND(k, ...) typedef __VA_ARGS__ GB_JOIN2(irInstr, k); IR_INSTR_KINDS #undef IR_INSTR_KIND struct irInstr { irInstrKind kind; irBlock *parent; Type *type; union { #define IR_INSTR_KIND(k, ...) GB_JOIN2(irInstr, k) k; IR_INSTR_KINDS #undef IR_INSTR_KIND }; }; enum irValueKind { irValue_Invalid, irValue_Constant, irValue_ConstantSlice, irValue_Nil, irValue_Undef, irValue_TypeName, irValue_Global, irValue_Param, irValue_Proc, irValue_Block, irValue_Instr, irValue_Count, }; struct irValueConstant { Type * type; ExactValue value; }; struct irValueConstantSlice { Type * type; irValue *backing_array; i64 count; }; struct irValueNil { Type *type; }; struct irValueUndef { Type *type; }; struct irValueTypeName { Type * type; String name; }; struct irValueGlobal { String name; Entity * entity; Type * type; irValue * value; Array referrers; bool is_constant; bool is_private; bool is_thread_local; bool is_foreign; bool is_unnamed_addr; }; enum irParamPasskind { irParamPass_Value, // Pass by value irParamPass_Pointer, // Pass as a pointer rather than by value irParamPass_Integer, // Pass as an integer of the same size }; struct irValueParam { irParamPasskind kind; irProcedure * parent; Entity * entity; Type * type; Type * original_type; Array referrers; }; struct irValue { irValueKind kind; i32 index; bool index_set; union { irValueConstant Constant; irValueConstantSlice ConstantSlice; irValueNil Nil; irValueUndef Undef; irValueTypeName TypeName; irValueGlobal Global; irValueParam Param; irProcedure Proc; irBlock Block; irInstr Instr; }; }; gb_global irValue *v_zero = NULL; gb_global irValue *v_one = NULL; gb_global irValue *v_zero32 = NULL; gb_global irValue *v_one32 = NULL; gb_global irValue *v_two32 = NULL; gb_global irValue *v_false = NULL; gb_global irValue *v_true = NULL; gb_global irValue *v_raw_nil = NULL; enum irAddrKind { irAddr_Default, // irAddr_Vector, irAddr_Map, irAddr_BitField, }; struct irAddr { irAddrKind kind; irValue * addr; union { struct { irValue *map_key; Type * map_type; Type * map_result; }; struct { i32 bit_field_value_index; }; }; // union { // struct { irValue *index; } Vector; // }; }; irAddr ir_addr(irValue *addr) { irAddr v = {irAddr_Default, addr}; return v; } irAddr ir_addr_map(irValue *addr, irValue *map_key, Type *map_type, Type *map_result) { irAddr v = {irAddr_Map, addr}; v.map_key = map_key; v.map_type = map_type; v.map_result = map_result; return v; } irAddr ir_addr_bit_field(irValue *addr, isize bit_field_value_index) { irAddr v = {irAddr_BitField, addr}; v.bit_field_value_index = bit_field_value_index; return v; } enum irDebugEncoding { irDebugBasicEncoding_Invalid = 0, irDebugBasicEncoding_address = 1, irDebugBasicEncoding_boolean = 2, irDebugBasicEncoding_float = 3, irDebugBasicEncoding_signed = 4, irDebugBasicEncoding_signed_char = 5, irDebugBasicEncoding_unsigned = 6, irDebugBasicEncoding_unsigned_char = 7, irDebugBasicEncoding_member = 13, irDebugBasicEncoding_pointer_type = 15, irDebugBasicEncoding_typedef = 22, irDebugBasicEncoding_array_type = 1, irDebugBasicEncoding_enumeration_type = 4, irDebugBasicEncoding_structure_type = 19, irDebugBasicEncoding_union_type = 23, }; enum irDebugInfoKind { irDebugInfo_Invalid, irDebugInfo_CompileUnit, irDebugInfo_File, irDebugInfo_Scope, irDebugInfo_Proc, irDebugInfo_AllProcs, irDebugInfo_BasicType, // basic types irDebugInfo_ProcType, irDebugInfo_DerivedType, // pointer, typedef irDebugInfo_CompositeType, // array, struct, enum, (raw_)union irDebugInfo_Enumerator, // For irDebugInfo_CompositeType if enum irDebugInfo_GlobalVariable, irDebugInfo_LocalVariable, irDebugInfo_Count, }; struct irDebugInfo { irDebugInfoKind kind; i32 id; union { struct { AstFile * file; String producer; irDebugInfo *all_procs; } CompileUnit; struct { AstFile *file; String filename; String directory; } File; struct { irDebugInfo *parent; irDebugInfo *file; TokenPos pos; Scope * scope; // Actual scope } Scope; struct { Entity * entity; String name; irDebugInfo *file; TokenPos pos; } Proc; struct { Array procs; } AllProcs; struct { String name; i32 size; i32 align; irDebugEncoding encoding; } BasicType; struct { irDebugInfo * return_type; Array param_types; } ProcType; struct { irDebugInfo * base_type; irDebugEncoding encoding; } DerivedType; struct { irDebugEncoding encoding; String name; String identifier; irDebugInfo * file; TokenPos pos; i32 size; i32 align; Array elements; } CompositeType; struct { String name; i64 value; } Enumerator; struct { String name; String linkage_name; irDebugInfo *scope; irDebugInfo *file; TokenPos pos; irValue *variable; irDebugInfo *declaration; } GlobalVariable; struct { String name; irDebugInfo *scope; irDebugInfo *file; TokenPos pos; i32 arg; // Non-zero if proc parameter irDebugInfo *type; } LocalVariable; }; }; struct irGen { irModule module; gbFile output_file; bool opt_called; String output_base; String output_name; }; Type *ir_type(irValue *value); Type *ir_instr_type(irInstr *instr) { switch (instr->kind) { case irInstr_Local: return instr->Local.type; case irInstr_Load: return instr->Load.type; case irInstr_StructElementPtr: return instr->StructElementPtr.result_type; case irInstr_ArrayElementPtr: return instr->ArrayElementPtr.result_type; case irInstr_PtrOffset: return ir_type(instr->PtrOffset.address); case irInstr_Phi: return instr->Phi.type; case irInstr_StructExtractValue: return instr->StructExtractValue.result_type; case irInstr_UnionTagPtr: return instr->UnionTagPtr.type; case irInstr_UnionTagValue: return instr->UnionTagValue.type; case irInstr_UnaryOp: return instr->UnaryOp.type; case irInstr_BinaryOp: return instr->BinaryOp.type; case irInstr_Conv: return instr->Conv.to; case irInstr_Select: return ir_type(instr->Select.true_value); case irInstr_Call: { Type *pt = base_type(instr->Call.type); if (pt != NULL) { if (pt->kind == Type_Tuple && pt->Tuple.variable_count == 1) { return pt->Tuple.variables[0]->type; } return pt; } return NULL; } break; } return NULL; } Type *ir_type(irValue *value) { switch (value->kind) { case irValue_Constant: return value->Constant.type; case irValue_ConstantSlice: return value->ConstantSlice.type; case irValue_Nil: return value->Nil.type; case irValue_Undef: return value->Undef.type; case irValue_TypeName: return value->TypeName.type; case irValue_Global: return value->Global.type; case irValue_Param: return value->Param.type; case irValue_Proc: return value->Proc.type; case irValue_Instr: return ir_instr_type(&value->Instr); } return NULL; } bool ir_is_blank_ident(AstNode *node) { if (node->kind == AstNode_Ident) { ast_node(i, Ident, node); return is_blank_ident(i->token.string); } return false; } irInstr *ir_get_last_instr(irBlock *block) { if (block != NULL) { isize len = block->instrs.count; if (len > 0) { irValue *v = block->instrs[len-1]; GB_ASSERT(v->kind == irValue_Instr); return &v->Instr; } } return NULL; } bool ir_is_instr_terminating(irInstr *i) { if (i != NULL) { switch (i->kind) { case irInstr_Return: case irInstr_Unreachable: return true; } } return false; } void ir_add_edge(irBlock *from, irBlock *to) { GB_ASSERT(from->instrs.count > 0); if (!ir_is_instr_terminating(ir_get_last_instr(from))) { array_add(&from->succs, to); array_add(&to->preds, from); } } void ir_set_instr_parent(irValue *instr, irBlock *parent) { if (instr->kind == irValue_Instr) { instr->Instr.parent = parent; } } Array *ir_value_referrers(irValue *v) { switch (v->kind) { case irValue_Global: return &v->Global.referrers; case irValue_Param: return &v->Param.referrers; case irValue_Proc: { if (v->Proc.parent != NULL) { return &v->Proc.referrers; } return NULL; } case irValue_Instr: { irInstr *i = &v->Instr; switch (i->kind) { case irInstr_Local: return &i->Local.referrers; } } break; } return NULL; } //////////////////////////////////////////////////////////////// // // @Make // //////////////////////////////////////////////////////////////// void ir_module_add_value (irModule *m, Entity *e, irValue *v); irValue *ir_emit_zero_init (irProcedure *p, irValue *address); irValue *ir_emit_comment (irProcedure *p, String text); irValue *ir_emit_store (irProcedure *p, irValue *address, irValue *value); irValue *ir_emit_load (irProcedure *p, irValue *address); void ir_emit_jump (irProcedure *proc, irBlock *block); irValue *ir_emit_conv (irProcedure *proc, irValue *value, Type *t); irValue *ir_type_info (irProcedure *proc, Type *type); irValue *ir_build_expr (irProcedure *proc, AstNode *expr); void ir_build_stmt (irProcedure *proc, AstNode *node); irValue *ir_build_cond (irProcedure *proc, AstNode *cond, irBlock *true_block, irBlock *false_block); void ir_build_defer_stmt (irProcedure *proc, irDefer d); irAddr ir_build_addr (irProcedure *proc, AstNode *expr); void ir_build_proc (irValue *value, irProcedure *parent); void ir_gen_global_type_name(irModule *m, Entity *e, String name); irValue *ir_get_type_info_ptr (irProcedure *proc, Type *type); irValue *ir_alloc_value(gbAllocator a, irValueKind kind) { irValue *v = gb_alloc_item(a, irValue); v->kind = kind; return v; } irValue *ir_alloc_instr(irProcedure *proc, irInstrKind kind) { irValue *v = ir_alloc_value(proc->module->allocator, irValue_Instr); v->Instr.kind = kind; proc->instr_count++; return v; } irDebugInfo *ir_alloc_debug_info(gbAllocator a, irDebugInfoKind kind) { irDebugInfo *di = gb_alloc_item(a, irDebugInfo); di->kind = kind; return di; } irValue *ir_value_type_name(gbAllocator a, String name, Type *type) { irValue *v = ir_alloc_value(a, irValue_TypeName); v->TypeName.name = name; v->TypeName.type = type; return v; } irValue *ir_value_global(gbAllocator a, Entity *e, irValue *value) { irValue *v = ir_alloc_value(a, irValue_Global); v->Global.entity = e; v->Global.type = make_type_pointer(a, e->type); v->Global.value = value; array_init(&v->Global.referrers, heap_allocator()); // TODO(bill): Replace heap allocator here return v; } irValue *ir_value_param(gbAllocator a, irProcedure *parent, Entity *e, Type *abi_type) { irValue *v = ir_alloc_value(a, irValue_Param); v->Param.kind = irParamPass_Value; v->Param.parent = parent; v->Param.entity = e; v->Param.original_type = e->type; v->Param.type = abi_type; if (abi_type != e->type) { if (is_type_pointer(abi_type)) { v->Param.kind = irParamPass_Pointer; } else if (is_type_integer(abi_type)) { v->Param.kind = irParamPass_Integer; } else { GB_PANIC("Invalid abi type pass kind"); } } array_init(&v->Param.referrers, heap_allocator()); // TODO(bill): Replace heap allocator here return v; } irValue *ir_value_nil(gbAllocator a, Type *type) { irValue *v = ir_alloc_value(a, irValue_Nil); v->Nil.type = type; return v; } irValue *ir_value_undef(gbAllocator a, Type *type) { irValue *v = ir_alloc_value(a, irValue_Undef); v->Undef.type = type; return v; } String ir_get_global_name(irModule *m, irValue *v) { if (v->kind != irValue_Global) { return str_lit(""); } irValueGlobal *g = &v->Global; Entity *e = g->entity; String name = e->token.string; String *found = map_get(&m->entity_names, hash_entity(e)); if (found != NULL) { name = *found; } return name; } irValue *ir_instr_local(irProcedure *p, Entity *e, bool zero_initialized) { irValue *v = ir_alloc_instr(p, irInstr_Local); irInstr *i = &v->Instr; i->Local.entity = e; i->Local.type = make_type_pointer(p->module->allocator, e->type); i->Local.zero_initialized = zero_initialized; i->Local.alignment = type_align_of(p->module->allocator, e->type); array_init(&i->Local.referrers, heap_allocator()); // TODO(bill): Replace heap allocator here ir_module_add_value(p->module, e, v); return v; } irValue *ir_instr_store(irProcedure *p, irValue *address, irValue *value, bool atomic) { irValue *v = ir_alloc_instr(p, irInstr_Store); irInstr *i = &v->Instr; i->Store.address = address; i->Store.value = value; i->Store.atomic = atomic; return v; } irValue *ir_instr_zero_init(irProcedure *p, irValue *address) { irValue *v = ir_alloc_instr(p, irInstr_ZeroInit); irInstr *i = &v->Instr; i->ZeroInit.address = address; return v; } irValue *ir_instr_load(irProcedure *p, irValue *address) { irValue *v = ir_alloc_instr(p, irInstr_Load); irInstr *i = &v->Instr; i->Load.address = address; i->Load.type = type_deref(ir_type(address)); return v; } irValue *ir_instr_array_element_ptr(irProcedure *p, irValue *address, irValue *elem_index) { irValue *v = ir_alloc_instr(p, irInstr_ArrayElementPtr); irInstr *i = &v->Instr; Type *t = ir_type(address); GB_ASSERT_MSG(is_type_pointer(t), "%s", type_to_string(t)); t = base_type(type_deref(t)); GB_ASSERT(is_type_array(t) || is_type_vector(t)); Type *result_type = make_type_pointer(p->module->allocator, t->Array.elem); i->ArrayElementPtr.address = address; i->ArrayElementPtr.elem_index = elem_index; i->ArrayElementPtr.result_type = result_type; GB_ASSERT_MSG(is_type_pointer(ir_type(address)), "%s", type_to_string(ir_type(address))); return v; } irValue *ir_instr_struct_element_ptr(irProcedure *p, irValue *address, i32 elem_index, Type *result_type) { irValue *v = ir_alloc_instr(p, irInstr_StructElementPtr); irInstr *i = &v->Instr; i->StructElementPtr.address = address; i->StructElementPtr.elem_index = elem_index; i->StructElementPtr.result_type = result_type; GB_ASSERT_MSG(is_type_pointer(ir_type(address)), "%s", type_to_string(ir_type(address))); return v; } irValue *ir_instr_ptr_offset(irProcedure *p, irValue *address, irValue *offset) { irValue *v = ir_alloc_instr(p, irInstr_PtrOffset); irInstr *i = &v->Instr; i->PtrOffset.address = address; i->PtrOffset.offset = offset; GB_ASSERT_MSG(is_type_pointer(ir_type(address)), "%s", type_to_string(ir_type(address))); GB_ASSERT_MSG(is_type_integer(ir_type(offset)), "%s", type_to_string(ir_type(address))); return v; } irValue *ir_instr_struct_extract_value(irProcedure *p, irValue *address, i32 index, Type *result_type) { irValue *v = ir_alloc_instr(p, irInstr_StructExtractValue); irInstr *i = &v->Instr; i->StructExtractValue.address = address; i->StructExtractValue.index = index; i->StructExtractValue.result_type = result_type; return v; } irValue *ir_instr_union_tag_ptr(irProcedure *p, irValue *address) { irValue *v = ir_alloc_instr(p, irInstr_UnionTagPtr); irInstr *i = &v->Instr; i->UnionTagPtr.address = address; i->UnionTagPtr.type = t_int_ptr; return v; } irValue *ir_instr_union_tag_value(irProcedure *p, irValue *address) { irValue *v = ir_alloc_instr(p, irInstr_UnionTagValue); irInstr *i = &v->Instr; i->UnionTagValue.address = address; i->UnionTagValue.type = t_int; return v; } irValue *ir_instr_unary_op(irProcedure *p, TokenKind op, irValue *expr, Type *type) { irValue *v = ir_alloc_instr(p, irInstr_UnaryOp); irInstr *i = &v->Instr; i->UnaryOp.op = op; i->UnaryOp.expr = expr; i->UnaryOp.type = type; return v; } irValue *ir_instr_binary_op(irProcedure *p, TokenKind op, irValue *left, irValue *right, Type *type) { irValue *v = ir_alloc_instr(p, irInstr_BinaryOp); irInstr *i = &v->Instr; i->BinaryOp.op = op; i->BinaryOp.left = left; i->BinaryOp.right = right; i->BinaryOp.type = type; return v; } irValue *ir_instr_jump(irProcedure *p, irBlock *block) { irValue *v = ir_alloc_instr(p, irInstr_Jump); irInstr *i = &v->Instr; i->Jump.block = block; return v; } irValue *ir_instr_if(irProcedure *p, irValue *cond, irBlock *true_block, irBlock *false_block) { irValue *v = ir_alloc_instr(p, irInstr_If); irInstr *i = &v->Instr; i->If.cond = cond; i->If.true_block = true_block; i->If.false_block = false_block; return v; } irValue *ir_instr_phi(irProcedure *p, Array edges, Type *type) { irValue *v = ir_alloc_instr(p, irInstr_Phi); irInstr *i = &v->Instr; i->Phi.edges = edges; i->Phi.type = type; return v; } irValue *ir_instr_unreachable(irProcedure *p) { irValue *v = ir_alloc_instr(p, irInstr_Unreachable); return v; } irValue *ir_instr_return(irProcedure *p, irValue *value) { irValue *v = ir_alloc_instr(p, irInstr_Return); v->Instr.Return.value = value; return v; } irValue *ir_instr_select(irProcedure *p, irValue *cond, irValue *t, irValue *f) { irValue *v = ir_alloc_instr(p, irInstr_Select); v->Instr.Select.cond = cond; v->Instr.Select.true_value = t; v->Instr.Select.false_value = f; return v; } irValue *ir_instr_call(irProcedure *p, irValue *value, irValue *return_ptr, irValue **args, isize arg_count, Type *result_type, irValue *context_ptr) { irValue *v = ir_alloc_instr(p, irInstr_Call); v->Instr.Call.value = value; v->Instr.Call.return_ptr = return_ptr; v->Instr.Call.args = args; v->Instr.Call.arg_count = arg_count; v->Instr.Call.type = result_type; v->Instr.Call.context_ptr = context_ptr; return v; } irValue *ir_instr_conv(irProcedure *p, irConvKind kind, irValue *value, Type *from, Type *to) { irValue *v = ir_alloc_instr(p, irInstr_Conv); v->Instr.Conv.kind = kind; v->Instr.Conv.value = value; v->Instr.Conv.from = from; v->Instr.Conv.to = to; return v; } irValue *ir_instr_comment(irProcedure *p, String text) { irValue *v = ir_alloc_instr(p, irInstr_Comment); v->Instr.Comment.text = text; return v; } irValue *ir_instr_debug_declare(irProcedure *p, irDebugInfo *debug_info, AstNode *expr, Entity *entity, bool is_addr, irValue *value) { irValue *v = ir_alloc_instr(p, irInstr_DebugDeclare); v->Instr.DebugDeclare.debug_info = debug_info; v->Instr.DebugDeclare.expr = expr; v->Instr.DebugDeclare.entity = entity; v->Instr.DebugDeclare.is_addr = is_addr; v->Instr.DebugDeclare.value = value; return v; } irValue *ir_value_constant(gbAllocator a, Type *type, ExactValue value) { irValue *v = ir_alloc_value(a, irValue_Constant); v->Constant.type = type; v->Constant.value = value; return v; } irValue *ir_value_constant_slice(gbAllocator a, Type *type, irValue *backing_array, i64 count) { irValue *v = ir_alloc_value(a, irValue_ConstantSlice); v->ConstantSlice.type = type; v->ConstantSlice.backing_array = backing_array; v->ConstantSlice.count = count; return v; } irValue *ir_emit(irProcedure *proc, irValue *instr) { GB_ASSERT(instr->kind == irValue_Instr); irBlock *b = proc->curr_block; instr->Instr.parent = b; if (b != NULL) { irInstr *i = ir_get_last_instr(b); if (!ir_is_instr_terminating(i)) { array_add(&b->instrs, instr); } } else if (instr->Instr.kind != irInstr_Unreachable) { GB_PANIC("ir_emit: Instruction missing parent block"); } return instr; } irValue *ir_const_int(gbAllocator a, i64 i) { return ir_value_constant(a, t_int, exact_value_i64(i)); } irValue *ir_const_i32(gbAllocator a, i32 i) { return ir_value_constant(a, t_i32, exact_value_i64(i)); } irValue *ir_const_u32(gbAllocator a, u32 i) { return ir_value_constant(a, t_u32, exact_value_i64(i)); } irValue *ir_const_i64(gbAllocator a, i64 i) { return ir_value_constant(a, t_i64, exact_value_i64(i)); } irValue *ir_const_u64(gbAllocator a, u64 i) { return ir_value_constant(a, t_u64, exact_value_i64(i)); } irValue *ir_const_f32(gbAllocator a, f32 f) { return ir_value_constant(a, t_f32, exact_value_float(f)); } irValue *ir_const_f64(gbAllocator a, f64 f) { return ir_value_constant(a, t_f64, exact_value_float(f)); } irValue *ir_const_bool(gbAllocator a, bool b) { return ir_value_constant(a, t_bool, exact_value_bool(b != 0)); } irValue *ir_const_string(gbAllocator a, String s) { return ir_value_constant(a, t_string, exact_value_string(s)); } irValue *ir_value_procedure(gbAllocator a, irModule *m, Entity *entity, Type *type, AstNode *type_expr, AstNode *body, String name) { irValue *v = ir_alloc_value(a, irValue_Proc); v->Proc.module = m; v->Proc.entity = entity; v->Proc.type = type; v->Proc.type_expr = type_expr; v->Proc.body = body; v->Proc.name = name; array_init(&v->Proc.referrers, heap_allocator()); // TODO(bill): replace heap allocator Type *t = base_type(type); GB_ASSERT(is_type_proc(t)); array_init(&v->Proc.params, heap_allocator(), t->Proc.param_count); return v; } irValue *ir_generate_array(irModule *m, Type *elem_type, i64 count, String prefix, i64 id) { gbAllocator a = m->allocator; Token token = {Token_Ident}; isize name_len = prefix.len + 10; token.string.text = gb_alloc_array(a, u8, name_len); token.string.len = gb_snprintf(cast(char *)token.string.text, name_len, "%.*s-%llx", LIT(prefix), cast(unsigned long long)id)-1; Entity *e = make_entity_variable(a, NULL, token, make_type_array(a, elem_type, count), false); irValue *value = ir_value_global(a, e, NULL); value->Global.is_private = true; ir_module_add_value(m, e, value); map_set(&m->members, hash_string(token.string), value); return value; } irBlock *ir_new_block(irProcedure *proc, AstNode *node, char *label) { Scope *scope = NULL; if (node != NULL) { scope = scope_of_node(proc->module->info, node); GB_ASSERT_MSG(scope != NULL, "Block scope not found for %.*s", LIT(ast_node_strings[node->kind])); } irValue *v = ir_alloc_value(proc->module->allocator, irValue_Block); v->Block.label = make_string_c(label); v->Block.node = node; v->Block.scope = scope; v->Block.parent = proc; // TODO(bill): Is this correct or even needed? v->Block.scope_index = proc->scope_index; array_init(&v->Block.instrs, heap_allocator()); array_init(&v->Block.locals, heap_allocator()); array_init(&v->Block.preds, heap_allocator()); array_init(&v->Block.succs, heap_allocator()); irBlock *block = &v->Block; return block; } void ir_add_block_to_proc(irProcedure *proc, irBlock *b) { for_array(i, proc->blocks) { if (proc->blocks[i] == b) { return; } } array_add(&proc->blocks, b); b->index = proc->block_count++; } void ir_start_block(irProcedure *proc, irBlock *block) { proc->curr_block = block; if (block != NULL) { ir_add_block_to_proc(proc, block); } } irDefer ir_add_defer_node(irProcedure *proc, isize scope_index, AstNode *stmt) { irDefer d = {irDefer_Node}; d.scope_index = scope_index; d.block = proc->curr_block; d.stmt = stmt; array_add(&proc->defer_stmts, d); return d; } irDefer ir_add_defer_instr(irProcedure *proc, isize scope_index, irValue *instr) { irDefer d = {irDefer_Instr}; d.scope_index = proc->scope_index; d.block = proc->curr_block; d.instr = instr; // NOTE(bill): It will make a copy everytime it is called array_add(&proc->defer_stmts, d); return d; } irValue *ir_add_module_constant(irModule *m, Type *type, ExactValue value) { gbAllocator a = m->allocator; // gbAllocator a = gb_heap_allocator(); if (is_type_slice(type)) { ast_node(cl, CompoundLit, value.value_compound); isize count = cl->elems.count; if (count == 0) { return ir_value_nil(a, type); } Type *elem = base_type(type)->Slice.elem; Type *t = make_type_array(a, elem, count); irValue *backing_array = ir_add_module_constant(m, t, value); isize max_len = 7+8+1; u8 *str = cast(u8 *)gb_alloc_array(a, u8, max_len); isize len = gb_snprintf(cast(char *)str, max_len, "__csba$%x", m->global_array_index); m->global_array_index++; String name = make_string(str, len-1); Entity *e = make_entity_constant(a, NULL, make_token_ident(name), t, value); irValue *g = ir_value_global(a, e, backing_array); ir_module_add_value(m, e, g); map_set(&m->members, hash_string(name), g); return ir_value_constant_slice(a, type, g, count); } return ir_value_constant(a, type, value); } irValue *ir_add_global_string_array(irModule *m, String string) { // TODO(bill): Should this use the arena allocator or the heap allocator? // Strings could be huge! gbAllocator a = m->allocator; // gbAllocator a = gb_heap_allocator(); isize max_len = 6+8+1; u8 *str = cast(u8 *)gb_alloc_array(a, u8, max_len); isize len = gb_snprintf(cast(char *)str, max_len, "__str$%x", m->global_string_index); m->global_string_index++; String name = make_string(str, len-1); Token token = {Token_String}; token.string = name; Type *type = make_type_array(a, t_u8, string.len); ExactValue ev = exact_value_string(string); Entity *entity = make_entity_constant(a, NULL, token, type, ev); irValue *g = ir_value_global(a, entity, ir_add_module_constant(m, type, ev)); g->Global.is_private = true; // g->Global.is_unnamed_addr = true; // g->Global.is_constant = true; ir_module_add_value(m, entity, g); map_set(&m->members, hash_string(name), g); return g; } irValue *ir_add_local(irProcedure *proc, Entity *e, AstNode *expr, bool zero_initialized) { irBlock *b = proc->decl_block; // all variables must be in the first block irValue *instr = ir_instr_local(proc, e, true); instr->Instr.parent = b; array_add(&b->instrs, instr); array_add(&b->locals, instr); proc->local_count++; if (zero_initialized) { ir_emit_zero_init(proc, instr); } if (expr != NULL && proc->entity != NULL) { irDebugInfo *di = *map_get(&proc->module->debug_info, hash_entity(proc->entity)); ir_emit(proc, ir_instr_debug_declare(proc, di, expr, e, true, instr)); } return instr; } irValue *ir_add_local_for_identifier(irProcedure *proc, AstNode *name, bool zero_initialized) { Entity *e = entity_of_ident(proc->module->info, name); if (e != NULL) { ir_emit_comment(proc, e->token.string); if (e->kind == Entity_Variable && e->Variable.is_foreign) { HashKey key = hash_string(e->token.string); irValue **prev_value = map_get(&proc->module->members, key); if (prev_value == NULL) { // NOTE(bill): Don't do mutliple declarations in the IR irValue *g = ir_value_global(proc->module->allocator, e, NULL); g->Global.name = e->token.string; g->Global.is_foreign = true; ir_module_add_value(proc->module, e, g); map_set(&proc->module->members, key, g); return g; } else { return *prev_value; } } return ir_add_local(proc, e, name, zero_initialized); } return NULL; } irValue *ir_add_local_generated(irProcedure *proc, Type *type) { GB_ASSERT(type != NULL); Scope *scope = NULL; if (proc->curr_block) { scope = proc->curr_block->scope; } Entity *e = make_entity_variable(proc->module->allocator, scope, empty_token, type, false); return ir_add_local(proc, e, NULL, true); } irValue *ir_add_global_generated(irModule *m, Type *type, irValue *value) { GB_ASSERT(type != NULL); gbAllocator a = m->allocator; isize max_len = 7+8+1; u8 *str = cast(u8 *)gb_alloc_array(a, u8, max_len); isize len = gb_snprintf(cast(char *)str, max_len, "__ggv$%x", m->global_generated_index); m->global_generated_index++; String name = make_string(str, len-1); Scope *scope = NULL; Entity *e = make_entity_variable(a, scope, make_token_ident(name), type, false); irValue *g = ir_value_global(a, e, value); ir_module_add_value(m, e, g); map_set(&m->members, hash_string(name), g); return g; } irValue *ir_add_param(irProcedure *proc, Entity *e, AstNode *expr, Type *abi_type) { irValue *v = ir_value_param(proc->module->allocator, proc, e, abi_type); irValueParam *p = &v->Param; switch (p->kind) { case irParamPass_Value: { irValue *l = ir_add_local(proc, e, expr, false); ir_emit_store(proc, l, v); return v; } case irParamPass_Pointer: { ir_module_add_value(proc->module, e, v); return ir_emit_load(proc, v); } case irParamPass_Integer: { irValue *l = ir_add_local(proc, e, expr, false); irValue *iptr = ir_emit_conv(proc, l, make_type_pointer(proc->module->allocator, p->type)); ir_emit_store(proc, iptr, v); return ir_emit_load(proc, l); } } GB_PANIC("Unreachable"); return NULL; } //////////////////////////////////////////////////////////////// // // @Debug // //////////////////////////////////////////////////////////////// irDebugInfo *ir_add_debug_info_file(irProcedure *proc, AstFile *file) { // if (!proc->module->generate_debug_info) { // return NULL; // } GB_ASSERT(file != NULL); irDebugInfo *di = ir_alloc_debug_info(proc->module->allocator, irDebugInfo_File); di->File.file = file; String filename = file->tokenizer.fullpath; String directory = filename; isize slash_index = 0; for (isize i = filename.len-1; i >= 0; i--) { if (filename[i] == '\\' || filename[i] == '/') { break; } slash_index = i; } directory.len = slash_index-1; filename.text = filename.text + slash_index; filename.len -= slash_index; di->File.filename = filename; di->File.directory = directory; map_set(&proc->module->debug_info, hash_ast_file(file), di); return di; } irDebugInfo *ir_add_debug_info_proc(irProcedure *proc, Entity *entity, String name, irDebugInfo *file) { // if (!proc->module->generate_debug_info) { // return NULL; // } GB_ASSERT(entity != NULL); irDebugInfo *di = ir_alloc_debug_info(proc->module->allocator, irDebugInfo_Proc); di->Proc.entity = entity; di->Proc.name = name; di->Proc.file = file; di->Proc.pos = entity->token.pos; map_set(&proc->module->debug_info, hash_entity(entity), di); return di; } //////////////////////////////////////////////////////////////// // // @Emit // //////////////////////////////////////////////////////////////// irValue *ir_emit_store(irProcedure *p, irValue *address, irValue *value) { #if 1 // NOTE(bill): Sanity check Type *a = type_deref(ir_type(address)); Type *b = ir_type(value); if (!is_type_untyped(b)) { GB_ASSERT_MSG(are_types_identical(core_type(a), core_type(b)), "%s %s", type_to_string(a), type_to_string(b)); } #endif return ir_emit(p, ir_instr_store(p, address, value, is_type_atomic(a))); } irValue *ir_emit_load(irProcedure *p, irValue *address) { GB_ASSERT(address != NULL); return ir_emit(p, ir_instr_load(p, address)); } irValue *ir_emit_select(irProcedure *p, irValue *cond, irValue *t, irValue *f) { return ir_emit(p, ir_instr_select(p, cond, t, f)); } irValue *ir_emit_zero_init(irProcedure *p, irValue *address) { return ir_emit(p, ir_instr_zero_init(p, address)); } irValue *ir_emit_comment(irProcedure *p, String text) { return ir_emit(p, ir_instr_comment(p, text)); } irValue *ir_copy_value_to_ptr(irProcedure *proc, irValue *val, Type *new_type, i64 alignment) { i64 type_alignment = type_align_of(proc->module->allocator, new_type); if (alignment < type_alignment) { alignment = type_alignment; } irValue *ptr = ir_add_local_generated(proc, new_type); ptr->Instr.Local.alignment = alignment; ir_emit_store(proc, ptr, val); return ptr; } irValue *ir_emit_bitcast(irProcedure *proc, irValue *data, Type *type) { return ir_emit(proc, ir_instr_conv(proc, irConv_bitcast, data, ir_type(data), type)); } irValue *ir_emit_transmute(irProcedure *proc, irValue *value, Type *t); irValue *ir_emit_global_call(irProcedure *proc, char *name_, irValue **args, isize arg_count); irValue *ir_find_or_generate_context_ptr(irProcedure *proc) { if (proc->context_stack.count > 0) { return proc->context_stack[proc->context_stack.count-1]; } irValue *c = ir_add_local_generated(proc, t_context); ir_emit_store(proc, c, ir_emit_load(proc, proc->module->global_default_context)); array_add(&proc->context_stack, c); return c; } irValue *ir_emit_call(irProcedure *p, irValue *value, irValue **args, isize arg_count) { Type *pt = base_type(ir_type(value)); GB_ASSERT(pt->kind == Type_Proc); Type *results = pt->Proc.results; irValue *context_ptr = NULL; if (pt->Proc.calling_convention == ProcCC_Odin) { context_ptr = ir_find_or_generate_context_ptr(p); } isize param_count = pt->Proc.param_count; if (pt->Proc.c_vararg) { GB_ASSERT(param_count-1 <= arg_count); } else { GB_ASSERT(param_count == arg_count); } for (isize i = 0; i < param_count; i++) { Entity *e = pt->Proc.params->Tuple.variables[i]; if (e->kind != Entity_Variable) { continue; } Type *original_type = e->type; Type *new_type = pt->Proc.abi_compat_params[i]; if (original_type != new_type) { if (is_type_pointer(new_type)) { args[i] = ir_copy_value_to_ptr(p, args[i], original_type, 16); } else if (is_type_integer(new_type)) { args[i] = ir_emit_transmute(p, args[i], new_type); } } } Type *abi_rt = pt->Proc.abi_compat_result_type; Type *rt = reduce_tuple_to_single_type(results); if (pt->Proc.return_by_pointer) { irValue *return_ptr = ir_add_local_generated(p, rt); GB_ASSERT(is_type_pointer(ir_type(return_ptr))); ir_emit(p, ir_instr_call(p, value, return_ptr, args, arg_count, NULL, context_ptr)); return ir_emit_load(p, return_ptr); } irValue *result = ir_emit(p, ir_instr_call(p, value, NULL, args, arg_count, abi_rt, context_ptr)); if (abi_rt != results) { result = ir_emit_transmute(p, result, rt); } return result; } irValue *ir_emit_global_call(irProcedure *proc, char *name_, irValue **args, isize arg_count) { String name = make_string_c(name_); irValue **found = map_get(&proc->module->members, hash_string(name)); GB_ASSERT_MSG(found != NULL, "%.*s", LIT(name)); irValue *gp = *found; return ir_emit_call(proc, gp, args, arg_count); } void ir_emit_defer_stmts(irProcedure *proc, irDeferExitKind kind, irBlock *block) { isize count = proc->defer_stmts.count; isize i = count; while (i --> 0) { irDefer d = proc->defer_stmts[i]; if (kind == irDeferExit_Default) { if (proc->scope_index == d.scope_index && d.scope_index > 1) { ir_build_defer_stmt(proc, d); array_pop(&proc->defer_stmts); continue; } else { break; } } else if (kind == irDeferExit_Return) { ir_build_defer_stmt(proc, d); } else if (kind == irDeferExit_Branch) { GB_ASSERT(block != NULL); isize lower_limit = block->scope_index+1; if (lower_limit < d.scope_index) { ir_build_defer_stmt(proc, d); } } } } void ir_open_scope(irProcedure *proc) { proc->scope_index++; } void ir_close_scope(irProcedure *proc, irDeferExitKind kind, irBlock *block) { ir_emit_defer_stmts(proc, kind, block); GB_ASSERT(proc->scope_index > 0); proc->scope_index--; } void ir_emit_unreachable(irProcedure *proc) { ir_emit(proc, ir_instr_unreachable(proc)); } void ir_emit_return(irProcedure *proc, irValue *v) { ir_emit_defer_stmts(proc, irDeferExit_Return, NULL); if (proc->type->Proc.return_by_pointer) { ir_emit_store(proc, proc->return_ptr, v); ir_emit(proc, ir_instr_return(proc, NULL)); } else { Type *abi_rt = proc->type->Proc.abi_compat_result_type; if (abi_rt != proc->type->Proc.results) { v = ir_emit_transmute(proc, v, abi_rt); } ir_emit(proc, ir_instr_return(proc, v)); } } void ir_emit_jump(irProcedure *proc, irBlock *target_block) { irBlock *b = proc->curr_block; if (b == NULL) { return; } ir_emit(proc, ir_instr_jump(proc, target_block)); ir_add_edge(b, target_block); ir_start_block(proc, NULL); } void ir_emit_if(irProcedure *proc, irValue *cond, irBlock *true_block, irBlock *false_block) { irBlock *b = proc->curr_block; if (b == NULL) { return; } ir_emit(proc, ir_instr_if(proc, cond, true_block, false_block)); ir_add_edge(b, true_block); ir_add_edge(b, false_block); ir_start_block(proc, NULL); } void ir_emit_startup_runtime(irProcedure *proc) { GB_ASSERT(proc->parent == NULL && proc->name == "main"); ir_emit(proc, ir_alloc_instr(proc, irInstr_StartupRuntime)); } irValue *ir_emit_struct_ep(irProcedure *proc, irValue *s, i32 index); irValue *ir_emit_comp(irProcedure *proc, TokenKind op_kind, irValue *left, irValue *right); irValue *ir_gen_map_header(irProcedure *proc, irValue *map_val, Type *map_type) { GB_ASSERT_MSG(is_type_pointer(ir_type(map_val)), "%s", type_to_string(ir_type(map_val))); gbAllocator a = proc->module->allocator; irValue *h = ir_add_local_generated(proc, t_map_header); map_type = base_type(map_type); Type *key_type = map_type->Map.key; Type *val_type = map_type->Map.value; // NOTE(bill): Removes unnecessary allocation if split gep irValue *gep0 = ir_emit_struct_ep(proc, h, 0); irValue *m = ir_emit_conv(proc, map_val, type_deref(ir_type(gep0))); ir_emit_store(proc, gep0, m); if (is_type_string(key_type)) { ir_emit_store(proc, ir_emit_struct_ep(proc, h, 1), v_true); } i64 entry_size = type_size_of(a, map_type->Map.entry_type); i64 entry_align = type_align_of(a, map_type->Map.entry_type); i64 value_offset = type_offset_of(a, map_type->Map.entry_type, 2); i64 value_size = type_size_of(a, map_type->Map.value); ir_emit_store(proc, ir_emit_struct_ep(proc, h, 2), ir_const_int(a, entry_size)); ir_emit_store(proc, ir_emit_struct_ep(proc, h, 3), ir_const_int(a, entry_align)); ir_emit_store(proc, ir_emit_struct_ep(proc, h, 4), ir_const_int(a, value_offset)); ir_emit_store(proc, ir_emit_struct_ep(proc, h, 5), ir_const_int(a, value_size)); return ir_emit_load(proc, h); } irValue *ir_gen_map_key(irProcedure *proc, irValue *key, Type *key_type) { Type *hash_type = t_u128; irValue *v = ir_add_local_generated(proc, t_map_key); Type *t = base_type(ir_type(key)); key = ir_emit_conv(proc, key, key_type); if (is_type_integer(t)) { ir_emit_store(proc, ir_emit_struct_ep(proc, v, 0), ir_emit_conv(proc, key, hash_type)); } else if (is_type_pointer(t)) { irValue *p = ir_emit_conv(proc, key, t_uint); ir_emit_store(proc, ir_emit_struct_ep(proc, v, 0), ir_emit_conv(proc, p, hash_type)); } else if (is_type_float(t)) { irValue *bits = NULL; i64 size = type_size_of(proc->module->allocator, t); switch (8*size) { case 32: bits = ir_emit_transmute(proc, key, t_u32); break; case 64: bits = ir_emit_transmute(proc, key, t_u64); break; default: GB_PANIC("Unhandled float size: %lld bits", size); break; } ir_emit_store(proc, ir_emit_struct_ep(proc, v, 0), ir_emit_conv(proc, bits, hash_type)); } else if (is_type_string(t)) { irValue *str = ir_emit_conv(proc, key, t_string); irValue *hashed_str = NULL; if (str->kind == irValue_Constant) { ExactValue ev = str->Constant.value; GB_ASSERT(ev.kind == ExactValue_String); u128 hs = fnv128a(ev.value_string.text, ev.value_string.len); hashed_str = ir_value_constant(proc->module->allocator, t_u128, exact_value_u128(hs)); } else { irValue **args = gb_alloc_array(proc->module->allocator, irValue *, 1); args[0] = str; hashed_str = ir_emit_global_call(proc, "__default_hash_string", args, 1); } ir_emit_store(proc, ir_emit_struct_ep(proc, v, 0), hashed_str); ir_emit_store(proc, ir_emit_struct_ep(proc, v, 1), str); } else { GB_PANIC("Unhandled map key type"); } return ir_emit_load(proc, v); } // NOTE(bill): Returns NULL if not possible irValue *ir_address_from_load_or_generate_local(irProcedure *proc, irValue *val) { if (val->kind == irValue_Instr) { if (val->Instr.kind == irInstr_Load) { return val->Instr.Load.address; } } Type *type = ir_type(val); irValue *local = ir_add_local_generated(proc, type); ir_emit_store(proc, local, val); return local; } Type *ir_addr_type(irAddr addr) { if (addr.addr == NULL) { return NULL; } if (addr.kind == irAddr_Map) { Type *t = base_type(addr.map_type); GB_ASSERT(is_type_map(t)); return t->Map.value; } Type *t = ir_type(addr.addr); GB_ASSERT(is_type_pointer(t)); return type_deref(t); } irValue *ir_insert_dynamic_map_key_and_value(irProcedure *proc, irValue *addr, Type *map_type, irValue *map_key, irValue *map_value) { map_type = base_type(map_type); irValue *h = ir_gen_map_header(proc, addr, map_type); irValue *key = ir_gen_map_key(proc, map_key, map_type->Map.key); irValue *v = ir_emit_conv(proc, map_value, map_type->Map.value); irValue *ptr = ir_add_local_generated(proc, ir_type(v)); ir_emit_store(proc, ptr, v); irValue **args = gb_alloc_array(proc->module->allocator, irValue *, 3); args[0] = h; args[1] = key; args[2] = ir_emit_conv(proc, ptr, t_rawptr); return ir_emit_global_call(proc, "__dynamic_map_set", args, 3); } irValue *ir_emit_ptr_offset(irProcedure *proc, irValue *ptr, irValue *offset); irValue *ir_emit_arith(irProcedure *proc, TokenKind op, irValue *left, irValue *right, Type *type); irValue *ir_addr_store(irProcedure *proc, irAddr addr, irValue *value) { if (addr.addr == NULL) { return NULL; } if (addr.kind == irAddr_Map) { return ir_insert_dynamic_map_key_and_value(proc, addr.addr, addr.map_type, addr.map_key, value); } else if (addr.kind == irAddr_BitField) { gbAllocator a = proc->module->allocator; Type *bft = base_type(type_deref(ir_type(addr.addr))); GB_ASSERT(is_type_bit_field(bft)); i32 value_index = addr.bit_field_value_index; i32 offset = bft->BitField.offsets[value_index]; i32 size_in_bits = bft->BitField.fields[value_index]->type->BitFieldValue.bits; i32 byte_index = offset / 8; i32 bit_inset = offset % 8; i32 size_in_bytes = next_pow2((size_in_bits+7)/8); if (size_in_bytes == 0) { GB_ASSERT(size_in_bits == 0); return NULL; } Type *int_type = NULL; switch (size_in_bytes) { case 1: int_type = t_u8; break; case 2: int_type = t_u16; break; case 4: int_type = t_u32; break; case 8: int_type = t_u64; break; case 16: int_type = t_u128; break; } GB_ASSERT(int_type != NULL); value = ir_emit_conv(proc, value, int_type); irValue *bytes = ir_emit_conv(proc, addr.addr, t_u8_ptr); bytes = ir_emit_ptr_offset(proc, bytes, ir_const_int(a, byte_index)); if (bit_inset == 0) { irValue *v = value; i32 sa = 8*size_in_bytes - size_in_bits; if (sa > 0) { irValue *shift_amount = ir_const_int(a, sa); v = ir_emit_arith(proc, Token_Shl, v, shift_amount, int_type); v = ir_emit_arith(proc, Token_Shr, v, shift_amount, int_type); } irValue *ptr = ir_emit_conv(proc, bytes, make_type_pointer(a, int_type)); v = ir_emit_arith(proc, Token_Or, ir_emit_load(proc, ptr), v, int_type); return ir_emit_store(proc, ptr, v); } // First byte { i32 sa = 8 - bit_inset; irValue *shift_amount = ir_const_int(a, sa); irValue *v = ir_emit_conv(proc, value, t_u8); v = ir_emit_arith(proc, Token_Shl, v, shift_amount, int_type); v = ir_emit_arith(proc, Token_Or, ir_emit_load(proc, bytes), v, int_type); ir_emit_store(proc, bytes, v); } // Remaining bytes { irValue *shift_amount = ir_const_int(a, bit_inset); irValue *ptr = ir_emit_conv(proc, ir_emit_ptr_offset(proc, bytes, v_one), make_type_pointer(a, int_type)); irValue *v = ir_emit_arith(proc, Token_Shr, value, shift_amount, int_type); v = ir_emit_arith(proc, Token_Or, ir_emit_load(proc, ptr), v, int_type); return ir_emit_store(proc, ptr, v); } } irValue *v = ir_emit_conv(proc, value, ir_addr_type(addr)); return ir_emit_store(proc, addr.addr, v); } irValue *ir_addr_load(irProcedure *proc, irAddr addr) { if (addr.addr == NULL) { GB_PANIC("Illegal addr load"); return NULL; } if (addr.kind == irAddr_Map) { // TODO(bill): map lookup Type *map_type = base_type(addr.map_type); irValue *v = ir_add_local_generated(proc, map_type->Map.lookup_result_type); irValue *h = ir_gen_map_header(proc, addr.addr, map_type); irValue *key = ir_gen_map_key(proc, addr.map_key, map_type->Map.key); irValue **args = gb_alloc_array(proc->module->allocator, irValue *, 2); args[0] = h; args[1] = key; irValue *ptr = ir_emit_global_call(proc, "__dynamic_map_get", args, 2); irValue *ok = ir_emit_comp(proc, Token_NotEq, ptr, v_raw_nil); ir_emit_store(proc, ir_emit_struct_ep(proc, v, 1), ok); irBlock *then = ir_new_block(proc, NULL, "map.get.then"); irBlock *done = ir_new_block(proc, NULL, "map.get.done"); ir_emit_if(proc, ok, then, done); ir_start_block(proc, then); { // TODO(bill): mem copy it instead? irValue *gep0 = ir_emit_struct_ep(proc, v, 0); irValue *value = ir_emit_conv(proc, ptr, ir_type(gep0)); ir_emit_store(proc, gep0, ir_emit_load(proc, value)); } ir_emit_jump(proc, done); ir_start_block(proc, done); if (is_type_tuple(addr.map_result)) { return ir_emit_load(proc, v); } else { irValue *single = ir_emit_struct_ep(proc, v, 0); return ir_emit_load(proc, single); } } else if (addr.kind == irAddr_BitField) { gbAllocator a = proc->module->allocator; Type *bft = base_type(type_deref(ir_type(addr.addr))); GB_ASSERT(is_type_bit_field(bft)); i32 value_index = addr.bit_field_value_index; i32 offset = bft->BitField.offsets[value_index]; i32 size_in_bits = bft->BitField.fields[value_index]->type->BitFieldValue.bits; i32 byte_index = offset / 8; i32 bit_inset = offset % 8; i32 size_in_bytes = next_pow2((size_in_bits+7)/8); if (size_in_bytes == 0) { GB_ASSERT(size_in_bits == 0); return ir_const_i32(a, 0); } Type *int_type = NULL; switch (size_in_bytes) { case 1: int_type = t_u8; break; case 2: int_type = t_u16; break; case 4: int_type = t_u32; break; case 8: int_type = t_u64; break; case 16: int_type = t_u128; break; } GB_ASSERT(int_type != NULL); irValue *bytes = ir_emit_conv(proc, addr.addr, t_u8_ptr); bytes = ir_emit_ptr_offset(proc, bytes, ir_const_int(a, byte_index)); Type *int_ptr = make_type_pointer(a, int_type); if (bit_inset == 0) { irValue *v = ir_emit_load(proc, ir_emit_conv(proc, bytes, int_ptr)); i32 sa = 8*size_in_bytes - size_in_bits; if (sa > 0) { irValue *shift_amount = ir_const_int(a, sa); v = ir_emit_arith(proc, Token_Shl, v, shift_amount, int_type); v = ir_emit_arith(proc, Token_Shr, v, shift_amount, int_type); } return v; } GB_ASSERT(8 > bit_inset); irValue *shift_amount = ir_value_constant(a, int_type, exact_value_i64(bit_inset)); irValue *first_byte = ir_emit_load(proc, bytes); irValue *res = ir_emit_arith(proc, Token_Shr, first_byte, shift_amount, int_type); irValue *remaining_bytes = ir_emit_load(proc, ir_emit_conv(proc, ir_emit_ptr_offset(proc, bytes, v_one), int_ptr)); remaining_bytes = ir_emit_arith(proc, Token_Shl, remaining_bytes, shift_amount, int_type); return ir_emit_arith(proc, Token_Or, res, remaining_bytes, int_type); } Type *t = base_type(ir_type(addr.addr)); if (t->kind == Type_Proc) { // NOTE(bill): Imported procedures don't require a load as they are pointers return addr.addr; } return ir_emit_load(proc, addr.addr); } irValue *ir_emit_array_epi(irProcedure *proc, irValue *s, i32 index); irValue *ir_emit_struct_ev(irProcedure *proc, irValue *s, i32 index); irValue *ir_emit_ptr_offset(irProcedure *proc, irValue *ptr, irValue *offset) { offset = ir_emit_conv(proc, offset, t_int); return ir_emit(proc, ir_instr_ptr_offset(proc, ptr, offset)); } irValue *ir_emit_unary_arith(irProcedure *proc, TokenKind op, irValue *x, Type *type) { switch (op) { case Token_Add: return x; case Token_Not: // Boolean not case Token_Xor: // Bitwise not case Token_Sub: // Bitwise Not break; case Token_Pointer: GB_PANIC("This should be handled elsewhere"); break; } if (is_type_vector(ir_type(x))) { ir_emit_comment(proc, str_lit("vector.arith.begin")); // IMPORTANT TODO(bill): This is very wasteful with regards to stack memory Type *tl = base_type(ir_type(x)); irValue *val = ir_address_from_load_or_generate_local(proc, x); GB_ASSERT(is_type_vector(type)); Type *elem_type = base_type(type)->Vector.elem; irValue *res = ir_add_local_generated(proc, type); for (i32 i = 0; i < tl->Vector.count; i++) { irValue *e = ir_emit_load(proc, ir_emit_array_epi(proc, val, i)); irValue *z = ir_emit_unary_arith(proc, op, e, elem_type); ir_emit_store(proc, ir_emit_array_epi(proc, res, i), z); } ir_emit_comment(proc, str_lit("vector.arith.end")); return ir_emit_load(proc, res); } return ir_emit(proc, ir_instr_unary_op(proc, op, x, type)); } irValue *ir_emit_arith(irProcedure *proc, TokenKind op, irValue *left, irValue *right, Type *type) { Type *t_left = ir_type(left); Type *t_right = ir_type(right); if (is_type_vector(t_left) || is_type_vector(t_right)) { ir_emit_comment(proc, str_lit("vector.arith.begin")); // IMPORTANT TODO(bill): This is very wasteful with regards to stack memory left = ir_emit_conv(proc, left, type); right = ir_emit_conv(proc, right, type); irValue *lhs = ir_address_from_load_or_generate_local(proc, left); irValue *rhs = ir_address_from_load_or_generate_local(proc, right); GB_ASSERT(is_type_vector(type)); Type *elem_type = base_type(type)->Vector.elem; irValue *res = ir_add_local_generated(proc, type); i64 count = base_type(type)->Vector.count; for (i32 i = 0; i < count; i++) { irValue *x = ir_emit_load(proc, ir_emit_array_epi(proc, lhs, i)); irValue *y = ir_emit_load(proc, ir_emit_array_epi(proc, rhs, i)); irValue *z = ir_emit_arith(proc, op, x, y, elem_type); ir_emit_store(proc, ir_emit_array_epi(proc, res, i), z); } ir_emit_comment(proc, str_lit("vector.arith.end")); return ir_emit_load(proc, res); } if (is_type_complex(t_left)) { ir_emit_comment(proc, str_lit("complex.arith.begin")); Type *ft = base_complex_elem_type(t_left); irValue *res = ir_add_local_generated(proc, type); irValue *a = ir_emit_struct_ev(proc, left, 0); irValue *b = ir_emit_struct_ev(proc, left, 1); irValue *c = ir_emit_struct_ev(proc, right, 0); irValue *d = ir_emit_struct_ev(proc, right, 1); irValue *real = NULL; irValue *imag = NULL; switch (op) { case Token_Add: real = ir_emit_arith(proc, Token_Add, a, c, ft); imag = ir_emit_arith(proc, Token_Add, b, d, ft); break; case Token_Sub: real = ir_emit_arith(proc, Token_Sub, a, c, ft); imag = ir_emit_arith(proc, Token_Sub, b, d, ft); break; case Token_Mul: { irValue *x = ir_emit_arith(proc, Token_Mul, a, c, ft); irValue *y = ir_emit_arith(proc, Token_Mul, b, d, ft); real = ir_emit_arith(proc, Token_Sub, x, y, ft); irValue *z = ir_emit_arith(proc, Token_Mul, b, c, ft); irValue *w = ir_emit_arith(proc, Token_Mul, a, d, ft); imag = ir_emit_arith(proc, Token_Add, z, w, ft); } break; case Token_Quo: { irValue *s1 = ir_emit_arith(proc, Token_Mul, c, c, ft); irValue *s2 = ir_emit_arith(proc, Token_Mul, d, d, ft); irValue *s = ir_emit_arith(proc, Token_Add, s1, s2, ft); irValue *x = ir_emit_arith(proc, Token_Mul, a, c, ft); irValue *y = ir_emit_arith(proc, Token_Mul, b, d, ft); real = ir_emit_arith(proc, Token_Add, x, y, ft); real = ir_emit_arith(proc, Token_Quo, real, s, ft); irValue *z = ir_emit_arith(proc, Token_Mul, b, c, ft); irValue *w = ir_emit_arith(proc, Token_Mul, a, d, ft); imag = ir_emit_arith(proc, Token_Sub, z, w, ft); imag = ir_emit_arith(proc, Token_Quo, imag, s, ft); } break; } ir_emit_store(proc, ir_emit_struct_ep(proc, res, 0), real); ir_emit_store(proc, ir_emit_struct_ep(proc, res, 1), imag); ir_emit_comment(proc, str_lit("complex.end.begin")); return ir_emit_load(proc, res); } if (op == Token_Add) { if (is_type_pointer(t_left)) { irValue *ptr = ir_emit_conv(proc, left, type); irValue *offset = right; return ir_emit_ptr_offset(proc, ptr, offset); } else if (is_type_pointer(ir_type(right))) { irValue *ptr = ir_emit_conv(proc, right, type); irValue *offset = left; return ir_emit_ptr_offset(proc, ptr, offset); } } else if (op == Token_Sub) { if (is_type_pointer(t_left) && is_type_integer(t_right)) { // ptr - int irValue *ptr = ir_emit_conv(proc, left, type); irValue *offset = ir_emit_unary_arith(proc, Token_Sub, right, t_int); return ir_emit_ptr_offset(proc, ptr, offset); } else if (is_type_pointer(t_left) && is_type_pointer(t_right)) { GB_ASSERT(is_type_integer(type)); irModule *m = proc->module; Type *ptr_type = base_type(t_left); GB_ASSERT(!is_type_rawptr(ptr_type)); irValue *elem_size = ir_const_int(m->allocator, type_size_of(m->allocator, ptr_type->Pointer.elem)); irValue *x = ir_emit_conv(proc, left, type); irValue *y = ir_emit_conv(proc, right, type); irValue *diff = ir_emit_arith(proc, op, x, y, type); return ir_emit_arith(proc, Token_Quo, diff, elem_size, type); } } switch (op) { case Token_Shl: case Token_Shr: left = ir_emit_conv(proc, left, type); right = ir_emit_conv(proc, right, type); break; case Token_AndNot: { // NOTE(bill): x &~ y == x & (~y) == x & (y ~ -1) // NOTE(bill): "not" `x` == `x` "xor" `-1` irValue *neg = ir_add_module_constant(proc->module, type, exact_value_i64(-1)); op = Token_Xor; right = ir_emit_arith(proc, op, right, neg, type); GB_ASSERT(right->Instr.kind == irInstr_BinaryOp); right->Instr.BinaryOp.type = type; op = Token_And; } /* fallthrough */ case Token_Add: case Token_Sub: case Token_Mul: case Token_Quo: case Token_Mod: case Token_ModMod: case Token_And: case Token_Or: case Token_Xor: left = ir_emit_conv(proc, left, type); right = ir_emit_conv(proc, right, type); break; } if (op == Token_ModMod) { irValue *n = left; irValue *m = right; if (is_type_unsigned(type)) { return ir_emit_arith(proc, Token_Mod, n, m, type); } irValue *a = ir_emit_arith(proc, Token_Mod, n, m, type); irValue *b = ir_emit_arith(proc, Token_Add, a, m, type); return ir_emit_arith(proc, Token_Mod, b, m, type); } if (is_type_i128_or_u128(type)) { // IMPORTANT NOTE(bill): LLVM is goddamn buggy! bool is_unsigned = is_type_unsigned(type); char *name = NULL; if (op == Token_Quo) { name = cast(char *)(is_unsigned ? "__udivti3" : "__divti3"); } else if (op == Token_Mod) { name = cast(char *)(is_unsigned ? "__umodti3" : "__modti3"); } if (name != NULL) { irValue **args = gb_alloc_array(proc->module->allocator, irValue *, 2); args[0] = left; args[1] = right; return ir_emit_global_call(proc, name, args, 2); } } return ir_emit(proc, ir_instr_binary_op(proc, op, left, right, type)); } irValue *ir_emit_union_tag_ptr(irProcedure *proc, irValue *u) { Type *t = ir_type(u); GB_ASSERT_MSG(is_type_pointer(t) && is_type_union(type_deref(t)), "%s", type_to_string(t)); irValue *tag_ptr = ir_emit(proc, ir_instr_union_tag_ptr(proc, u)); Type *tpt = ir_type(tag_ptr); GB_ASSERT(is_type_pointer(tpt)); tpt = base_type(type_deref(tpt)); GB_ASSERT(tpt == t_int); return tag_ptr; } irValue *ir_emit_union_tag_value(irProcedure *proc, irValue *u) { Type *t = ir_type(u); GB_ASSERT(is_type_union(t)); GB_ASSERT(are_types_identical(t, ir_type(u))); return ir_emit(proc, ir_instr_union_tag_value(proc, u)); } irValue *ir_emit_comp(irProcedure *proc, TokenKind op_kind, irValue *left, irValue *right); irValue *ir_emit_comp_against_nil(irProcedure *proc, TokenKind op_kind, irValue *x) { Type *t = ir_type(x); if (is_type_any(t)) { irValue *data = ir_emit_struct_ev(proc, x, 0); irValue *ti = ir_emit_struct_ev(proc, x, 1); if (op_kind == Token_CmpEq) { irValue *a = ir_emit_comp(proc, Token_CmpEq, data, v_raw_nil); irValue *b = ir_emit_comp(proc, Token_CmpEq, ti, v_raw_nil); return ir_emit_arith(proc, Token_Or, a, b, t_bool); } else if (op_kind == Token_NotEq) { irValue *a = ir_emit_comp(proc, Token_NotEq, data, v_raw_nil); irValue *b = ir_emit_comp(proc, Token_NotEq, ti, v_raw_nil); return ir_emit_arith(proc, Token_And, a, b, t_bool); } } else if (is_type_slice(t)) { irValue *data = ir_emit_struct_ev(proc, x, 0); irValue *cap = ir_emit_struct_ev(proc, x, 2); if (op_kind == Token_CmpEq) { irValue *a = ir_emit_comp(proc, Token_CmpEq, data, v_raw_nil); irValue *b = ir_emit_comp(proc, Token_CmpEq, cap, v_zero); return ir_emit_arith(proc, Token_Or, a, b, t_bool); } else if (op_kind == Token_NotEq) { irValue *a = ir_emit_comp(proc, Token_NotEq, data, v_raw_nil); irValue *b = ir_emit_comp(proc, Token_NotEq, cap, v_zero); return ir_emit_arith(proc, Token_And, a, b, t_bool); } } else if (is_type_dynamic_array(t)) { irValue *data = ir_emit_struct_ev(proc, x, 0); irValue *cap = ir_emit_struct_ev(proc, x, 2); if (op_kind == Token_CmpEq) { irValue *a = ir_emit_comp(proc, Token_CmpEq, data, v_raw_nil); irValue *b = ir_emit_comp(proc, Token_CmpEq, cap, v_zero); return ir_emit_arith(proc, Token_Or, a, b, t_bool); } else if (op_kind == Token_NotEq) { irValue *a = ir_emit_comp(proc, Token_NotEq, data, v_raw_nil); irValue *b = ir_emit_comp(proc, Token_NotEq, cap, v_zero); return ir_emit_arith(proc, Token_And, a, b, t_bool); } } else if (is_type_map(t)) { irValue *hashes = ir_emit_struct_ev(proc, x, 0); irValue *entries = ir_emit_struct_ev(proc, x, 1); irValue *a = ir_emit_comp_against_nil(proc, op_kind, hashes); irValue *b = ir_emit_comp_against_nil(proc, op_kind, entries); if (op_kind == Token_CmpEq) { return ir_emit_arith(proc, Token_Or, a, b, t_bool); } else if (op_kind == Token_NotEq) { return ir_emit_arith(proc, Token_And, a, b, t_bool); } } else if (is_type_union(t)) { irValue *tag = ir_emit_union_tag_value(proc, x); return ir_emit_comp(proc, op_kind, tag, v_zero); } return NULL; } irValue *ir_emit_comp(irProcedure *proc, TokenKind op_kind, irValue *left, irValue *right) { Type *a = base_type(ir_type(left)); Type *b = base_type(ir_type(right)); GB_ASSERT(gb_is_between(op_kind, Token__ComparisonBegin+1, Token__ComparisonEnd-1)); irValue *nil_check = NULL; if (left->kind == irValue_Nil) { nil_check = ir_emit_comp_against_nil(proc, op_kind, right); } else if (right->kind == irValue_Nil) { nil_check = ir_emit_comp_against_nil(proc, op_kind, left); } if (nil_check != NULL) { return nil_check; } if (are_types_identical(a, b)) { // NOTE(bill): No need for a conversion } else if (left->kind == irValue_Constant || left->kind == irValue_Nil) { left = ir_emit_conv(proc, left, ir_type(right)); } else if (right->kind == irValue_Constant || right->kind == irValue_Nil) { right = ir_emit_conv(proc, right, ir_type(left)); } else { gbAllocator a = proc->module->allocator; i64 ls = type_size_of(a, ir_type(left)); i64 rs = type_size_of(a, ir_type(right)); if (ls < rs) { left = ir_emit_conv(proc, left, ir_type(right)); } else if (ls > rs) { right = ir_emit_conv(proc, right, ir_type(left)); } else { right = ir_emit_conv(proc, right, ir_type(left)); } } Type *result = t_bool; if (is_type_vector(a)) { result = make_type_vector(proc->module->allocator, t_bool, a->Vector.count); } if (is_type_vector(a)) { ir_emit_comment(proc, str_lit("vector.comp.begin")); Type *tl = base_type(a); irValue *lhs = ir_address_from_load_or_generate_local(proc, left); irValue *rhs = ir_address_from_load_or_generate_local(proc, right); GB_ASSERT(is_type_vector(result)); Type *elem_type = base_type(result)->Vector.elem; irValue *res = ir_add_local_generated(proc, result); for (i32 i = 0; i < tl->Vector.count; i++) { irValue *x = ir_emit_load(proc, ir_emit_array_epi(proc, lhs, i)); irValue *y = ir_emit_load(proc, ir_emit_array_epi(proc, rhs, i)); irValue *z = ir_emit_comp(proc, op_kind, x, y); ir_emit_store(proc, ir_emit_array_epi(proc, res, i), z); } ir_emit_comment(proc, str_lit("vector.comp.end")); return ir_emit_load(proc, res); } return ir_emit(proc, ir_instr_binary_op(proc, op_kind, left, right, result)); } irValue *ir_emit_array_ep(irProcedure *proc, irValue *s, irValue *index) { GB_ASSERT(index != NULL); Type *t = ir_type(s); GB_ASSERT(is_type_pointer(t)); Type *st = base_type(type_deref(t)); GB_ASSERT_MSG(is_type_array(st) || is_type_vector(st), "%s", type_to_string(st)); // NOTE(bill): For some weird legacy reason in LLVM, structure elements must be accessed as an i32 index = ir_emit_conv(proc, index, t_i32); return ir_emit(proc, ir_instr_array_element_ptr(proc, s, index)); } irValue *ir_emit_array_epi(irProcedure *proc, irValue *s, i32 index) { return ir_emit_array_ep(proc, s, ir_const_i32(proc->module->allocator, index)); } irValue *ir_emit_struct_ep(irProcedure *proc, irValue *s, i32 index) { gbAllocator a = proc->module->allocator; Type *t = base_type(type_deref(ir_type(s))); Type *result_type = NULL; if (is_type_struct(t)) { GB_ASSERT(t->Record.field_count > 0); GB_ASSERT(gb_is_between(index, 0, t->Record.field_count-1)); result_type = make_type_pointer(a, t->Record.fields[index]->type); } else if (is_type_union(t)) { type_set_offsets(a, t); GB_ASSERT(t->Record.field_count > 0); if (index == -1) { index = t->Record.field_count+1; result_type = t_int_ptr; } else { GB_ASSERT(gb_is_between(index, 0, t->Record.field_count-1)); result_type = make_type_pointer(a, t->Record.fields[index]->type); } } else if (is_type_tuple(t)) { GB_ASSERT(t->Tuple.variable_count > 0); GB_ASSERT(gb_is_between(index, 0, t->Tuple.variable_count-1)); result_type = make_type_pointer(a, t->Tuple.variables[index]->type); } else if (is_type_complex(t)) { Type *ft = base_complex_elem_type(t); switch (index) { case 0: result_type = make_type_pointer(a, ft); break; case 1: result_type = make_type_pointer(a, ft); break; } } else if (is_type_slice(t)) { switch (index) { case 0: result_type = make_type_pointer(a, make_type_pointer(a, t->Slice.elem)); break; case 1: result_type = make_type_pointer(a, t_int); break; case 2: result_type = make_type_pointer(a, t_int); break; } } else if (is_type_string(t)) { switch (index) { case 0: result_type = make_type_pointer(a, t_u8_ptr); break; case 1: result_type = make_type_pointer(a, t_int); break; } } else if (is_type_any(t)) { switch (index) { case 0: result_type = make_type_pointer(a, t_rawptr); break; case 1: result_type = make_type_pointer(a, t_type_info_ptr); break; } } else if (is_type_dynamic_array(t)) { switch (index) { case 0: result_type = make_type_pointer(a, make_type_pointer(a, t->DynamicArray.elem)); break; case 1: result_type = t_int_ptr; break; case 2: result_type = t_int_ptr; break; case 3: result_type = t_allocator_ptr; break; } } else if (is_type_dynamic_map(t)) { Type *gst = t->Map.generated_struct_type; switch (index) { case 0: result_type = make_type_pointer(a, gst->Record.fields[0]->type); break; case 1: result_type = make_type_pointer(a, gst->Record.fields[1]->type); break; } }else { GB_PANIC("TODO(bill): struct_gep type: %s, %d", type_to_string(ir_type(s)), index); } GB_ASSERT(result_type != NULL); return ir_emit(proc, ir_instr_struct_element_ptr(proc, s, index, result_type)); } irValue *ir_emit_struct_ev(irProcedure *proc, irValue *s, i32 index) { // NOTE(bill): For some weird legacy reason in LLVM, structure elements must be accessed as an i32 gbAllocator a = proc->module->allocator; Type *t = base_type(ir_type(s)); Type *result_type = NULL; if (is_type_struct(t)) { GB_ASSERT(t->Record.field_count > 0); GB_ASSERT(gb_is_between(index, 0, t->Record.field_count-1)); result_type = t->Record.fields[index]->type; } else if (is_type_union(t)) { type_set_offsets(a, t); if (index == -1) { index = t->Record.field_count+1; result_type = t_int_ptr; } else { GB_ASSERT(gb_is_between(index, 0, t->Record.field_count-1)); } result_type = t->Record.fields[index]->type; } else if (is_type_tuple(t)) { GB_ASSERT(t->Tuple.variable_count > 0); GB_ASSERT(gb_is_between(index, 0, t->Tuple.variable_count-1)); result_type = t->Tuple.variables[index]->type; } else if (is_type_complex(t)) { Type *ft = base_complex_elem_type(t); switch (index) { case 0: result_type = ft; break; case 1: result_type = ft; break; } } else if (is_type_slice(t)) { switch (index) { case 0: result_type = make_type_pointer(a, t->Slice.elem); break; case 1: result_type = t_int; break; case 2: result_type = t_int; break; } } else if (is_type_string(t)) { switch (index) { case 0: result_type = t_u8_ptr; break; case 1: result_type = t_int; break; } } else if (is_type_any(t)) { switch (index) { case 0: result_type = t_rawptr; break; case 1: result_type = t_type_info_ptr; break; } } else if (is_type_dynamic_array(t)) { switch (index) { case 0: result_type = make_type_pointer(a, t->DynamicArray.elem); break; case 1: result_type = t_int; break; case 2: result_type = t_int; break; case 3: result_type = t_allocator; break; } } else if (is_type_dynamic_map(t)) { Type *gst = t->Map.generated_struct_type; switch (index) { case 0: result_type = gst->Record.fields[0]->type; break; case 1: result_type = gst->Record.fields[1]->type; break; } } else { GB_PANIC("TODO(bill): struct_ev type: %s, %d", type_to_string(ir_type(s)), index); } GB_ASSERT(result_type != NULL); return ir_emit(proc, ir_instr_struct_extract_value(proc, s, index, result_type)); } irValue *ir_emit_deep_field_gep(irProcedure *proc, irValue *e, Selection sel) { GB_ASSERT(sel.index.count > 0); Type *type = type_deref(ir_type(e)); for_array(i, sel.index) { i32 index = cast(i32)sel.index[i]; if (is_type_pointer(type)) { type = type_deref(type); e = ir_emit_load(proc, e); e = ir_emit_ptr_offset(proc, e, v_zero); // TODO(bill): Do I need these copies? } type = core_type(type); if (is_type_raw_union(type)) { type = type->Record.fields[index]->type; e = ir_emit_conv(proc, e, make_type_pointer(proc->module->allocator, type)); } else if (type->kind == Type_Record) { if (index == -1) { type = t_int; } else { type = type->Record.fields[index]->type; } e = ir_emit_struct_ep(proc, e, index); } else if (type->kind == Type_Tuple) { type = type->Tuple.variables[index]->type; e = ir_emit_struct_ep(proc, e, index); }else if (type->kind == Type_Basic) { switch (type->Basic.kind) { case Basic_any: { if (index == 0) { type = t_rawptr; } else if (index == 1) { type = t_type_info_ptr; } e = ir_emit_struct_ep(proc, e, index); } break; case Basic_string: e = ir_emit_struct_ep(proc, e, index); break; default: GB_PANIC("un-gep-able type"); break; } } else if (type->kind == Type_Slice) { e = ir_emit_struct_ep(proc, e, index); } else if (type->kind == Type_DynamicArray) { e = ir_emit_struct_ep(proc, e, index); } else if (type->kind == Type_Vector) { e = ir_emit_array_epi(proc, e, index); } else if (type->kind == Type_Array) { e = ir_emit_array_epi(proc, e, index); } else if (type->kind == Type_Map) { e = ir_emit_struct_ep(proc, e, 1); switch (index) { case 0: e = ir_emit_struct_ep(proc, e, 1); break; // count case 1: e = ir_emit_struct_ep(proc, e, 2); break; // capacity case 2: e = ir_emit_struct_ep(proc, e, 3); break; // allocator } } else { GB_PANIC("un-gep-able type %s", type_to_string(type)); } } return e; } irValue *ir_emit_deep_field_ev(irProcedure *proc, irValue *e, Selection sel) { GB_ASSERT(sel.index.count > 0); Type *type = ir_type(e); for_array(i, sel.index) { i32 index = cast(i32)sel.index[i]; if (is_type_pointer(type)) { type = type_deref(type); e = ir_emit_load(proc, e); e = ir_emit_ptr_offset(proc, e, v_zero); // TODO(bill): Do I need these copies? } type = base_type(type); if (is_type_raw_union(type)) { GB_PANIC("TODO(bill): IS THIS EVEN CORRECT?"); type = type->Record.fields[index]->type; e = ir_emit_conv(proc, e, type); } else if (type->kind == Type_Map) { e = ir_emit_struct_ev(proc, e, 1); switch (index) { case 0: e = ir_emit_struct_ev(proc, e, 1); break; // count case 1: e = ir_emit_struct_ev(proc, e, 2); break; // capacity case 2: e = ir_emit_struct_ev(proc, e, 3); break; // allocator } } else { e = ir_emit_struct_ev(proc, e, index); } } return e; } irValue *ir_array_elem(irProcedure *proc, irValue *array) { return ir_emit_array_ep(proc, array, v_zero32); } irValue *ir_array_len(irProcedure *proc, irValue *array) { Type *t = base_type(ir_type(array)); GB_ASSERT(t->kind == Type_Array); return ir_const_int(proc->module->allocator, t->Array.count); } irValue *ir_vector_elem(irProcedure *proc, irValue *vector) { return ir_emit_array_ep(proc, vector, v_one32); } irValue *ir_slice_elem(irProcedure *proc, irValue *slice) { Type *t = base_type(ir_type(slice)); GB_ASSERT(t->kind == Type_Slice); return ir_emit_struct_ev(proc, slice, 0); } irValue *ir_slice_count(irProcedure *proc, irValue *slice) { Type *t = base_type(ir_type(slice)); GB_ASSERT(t->kind == Type_Slice); return ir_emit_struct_ev(proc, slice, 1); } irValue *ir_slice_capacity(irProcedure *proc, irValue *slice) { Type *t = base_type(ir_type(slice)); GB_ASSERT(t->kind == Type_Slice); return ir_emit_struct_ev(proc, slice, 2); } irValue *ir_dynamic_array_elem(irProcedure *proc, irValue *da) { Type *t = ir_type(da); GB_ASSERT(t->kind == Type_DynamicArray); return ir_emit_struct_ev(proc, da, 0); } irValue *ir_dynamic_array_count(irProcedure *proc, irValue *da) { Type *t = base_type(ir_type(da)); GB_ASSERT_MSG(t->kind == Type_DynamicArray, "%s", type_to_string(t)); return ir_emit_struct_ev(proc, da, 1); } irValue *ir_dynamic_array_capacity(irProcedure *proc, irValue *da) { Type *t = base_type(ir_type(da)); GB_ASSERT(t->kind == Type_DynamicArray); return ir_emit_struct_ev(proc, da, 2); } irValue *ir_dynamic_array_allocator(irProcedure *proc, irValue *da) { Type *t = base_type(ir_type(da)); GB_ASSERT(t->kind == Type_DynamicArray); return ir_emit_struct_ev(proc, da, 3); } irValue *ir_string_elem(irProcedure *proc, irValue *string) { Type *t = base_type(ir_type(string)); GB_ASSERT(t->kind == Type_Basic && t->Basic.kind == Basic_string); return ir_emit_struct_ev(proc, string, 0); } irValue *ir_string_len(irProcedure *proc, irValue *string) { Type *t = base_type(ir_type(string)); GB_ASSERT_MSG(t->kind == Type_Basic && t->Basic.kind == Basic_string, "%s", type_to_string(t)); return ir_emit_struct_ev(proc, string, 1); } void ir_fill_slice(irProcedure *proc, irValue *slice_ptr, irValue *data, irValue *len, irValue *cap) { Type *t = ir_type(slice_ptr); GB_ASSERT(is_type_pointer(t)); t = type_deref(t); GB_ASSERT(is_type_slice(t)); ir_emit_store(proc, ir_emit_struct_ep(proc, slice_ptr, 0), data); ir_emit_store(proc, ir_emit_struct_ep(proc, slice_ptr, 1), len); ir_emit_store(proc, ir_emit_struct_ep(proc, slice_ptr, 2), cap); } void ir_fill_string(irProcedure *proc, irValue *string_ptr, irValue *data, irValue *len) { Type *t = ir_type(string_ptr); GB_ASSERT(is_type_pointer(t)); t = type_deref(t); GB_ASSERT(is_type_string(t)); ir_emit_store(proc, ir_emit_struct_ep(proc, string_ptr, 0), data); ir_emit_store(proc, ir_emit_struct_ep(proc, string_ptr, 1), len); } irValue *ir_emit_string(irProcedure *proc, irValue *elem, irValue *len) { irValue *str = ir_add_local_generated(proc, t_string); ir_fill_string(proc, str, elem, len); return ir_emit_load(proc, str); } irValue *ir_add_local_slice(irProcedure *proc, Type *slice_type, irValue *base, irValue *low, irValue *high, irValue *max) { // TODO(bill): array bounds checking for slice creation // TODO(bill): check that low < high <= max gbAllocator a = proc->module->allocator; Type *bt = base_type(ir_type(base)); if (low == NULL) { low = v_zero; } if (high == NULL) { switch (bt->kind) { case Type_Array: high = ir_array_len(proc, base); break; case Type_Slice: high = ir_slice_count(proc, base); break; case Type_Pointer: high = v_one; break; } } if (max == NULL) { switch (bt->kind) { case Type_Array: high = ir_array_len(proc, base); break; case Type_Slice: high = ir_slice_capacity(proc, base); break; case Type_Pointer: high = v_one; break; } } irValue *len = ir_emit_arith(proc, Token_Sub, high, low, t_int); irValue *cap = ir_emit_arith(proc, Token_Sub, max, low, t_int); irValue *elem = NULL; switch (bt->kind) { case Type_Array: elem = ir_array_elem(proc, base); break; case Type_Slice: elem = ir_slice_elem(proc, base); break; case Type_Pointer: elem = ir_emit_load(proc, base); break; } elem = ir_emit_ptr_offset(proc, elem, low); irValue *slice = ir_add_local_generated(proc, slice_type); ir_fill_slice(proc, slice, elem, len, cap); return slice; } irValue *ir_find_or_add_entity_string(irModule *m, String str) { irValue **found = map_get(&m->const_strings, hash_string(str)); if (found != NULL) { return *found; } irValue *v = ir_const_string(m->allocator, str); map_set(&m->const_strings, hash_string(str), v); return v; } String ir_lookup_subtype_polymorphic_field(CheckerInfo *info, Type *dst, Type *src) { Type *prev_src = src; // Type *prev_dst = dst; src = base_type(type_deref(src)); // dst = base_type(type_deref(dst)); bool src_is_ptr = src != prev_src; // bool dst_is_ptr = dst != prev_dst; GB_ASSERT(is_type_struct(src) || is_type_union(src)); for (isize i = 0; i < src->Record.field_count; i++) { Entity *f = src->Record.fields[i]; if (f->kind == Entity_Variable && f->flags & EntityFlag_Using) { if (are_types_identical(dst, f->type)) { return f->token.string; } if (src_is_ptr && is_type_pointer(dst)) { if (are_types_identical(type_deref(dst), f->type)) { return f->token.string; } } if (is_type_struct(f->type)) { String name = ir_lookup_subtype_polymorphic_field(info, dst, f->type); if (name.len > 0) { return name; } } } } return str_lit(""); } irValue *ir_emit_ptr_to_int(irProcedure *proc, irValue *value, Type *t, bool allow_type_type = false) { Type *vt = core_type(ir_type(value)); GB_ASSERT(is_type_pointer(vt)); if (allow_type_type) { GB_ASSERT(is_type_int_or_uint(core_type(t))); } else { GB_ASSERT(is_type_int_or_uint(core_type(t))); } return ir_emit(proc, ir_instr_conv(proc, irConv_ptrtoint, value, vt, t)); } irValue *ir_emit_int_to_ptr(irProcedure *proc, irValue *value, Type *t) { Type *vt = core_type(ir_type(value)); GB_ASSERT(is_type_int_or_uint(vt)); GB_ASSERT(is_type_pointer(core_type(t))); return ir_emit(proc, ir_instr_conv(proc, irConv_inttoptr, value, vt, t)); } irValue *ir_emit_conv(irProcedure *proc, irValue *value, Type *t) { Type *src_type = ir_type(value); if (are_types_identical(t, src_type)) { return value; } Type *src = core_type(src_type); Type *dst = core_type(t); // if (is_type_untyped_nil(src) && type_has_nil(dst)) { if (is_type_untyped_nil(src)) { return ir_value_nil(proc->module->allocator, t); } if (is_type_untyped_undef(src)) { return ir_value_undef(proc->module->allocator, t); } if (value->kind == irValue_Constant) { if (is_type_any(dst)) { irValue *default_value = ir_add_local_generated(proc, default_type(src_type)); ir_emit_store(proc, default_value, value); return ir_emit_conv(proc, ir_emit_load(proc, default_value), t_any); } else if (dst->kind == Type_Basic) { ExactValue ev = value->Constant.value; if (is_type_float(dst)) { ev = exact_value_to_float(ev); } else if (is_type_complex(dst)) { ev = exact_value_to_complex(ev); } else if (is_type_string(dst)) { // Handled elsewhere GB_ASSERT_MSG(ev.kind == ExactValue_String, "%d", ev.kind); } else if (is_type_integer(dst)) { ev = exact_value_to_integer(ev); } else if (is_type_pointer(dst)) { // IMPORTANT NOTE(bill): LLVM doesn't support pointer constants expect `null` irValue *i = ir_add_module_constant(proc->module, t_uint, ev); return ir_emit(proc, ir_instr_conv(proc, irConv_inttoptr, i, t_uint, dst)); } return ir_add_module_constant(proc->module, t, ev); } } if (are_types_identical(src, dst)) { return value; } // integer -> integer if (is_type_integer(src) && is_type_integer(dst)) { GB_ASSERT(src->kind == Type_Basic && dst->kind == Type_Basic); i64 sz = type_size_of(proc->module->allocator, default_type(src)); i64 dz = type_size_of(proc->module->allocator, default_type(dst)); irConvKind kind = irConv_trunc; if (dz < sz) { kind = irConv_trunc; } else if (dz == sz) { // NOTE(bill): In LLVM, all integers are signed and rely upon 2's compliment // NOTE(bill): Copy the value just for type correctness kind = irConv_bitcast; } else if (dz > sz) { if (is_type_unsigned(src)) { kind = irConv_zext; // zero extent } else { kind = irConv_sext; // sign extent } } return ir_emit(proc, ir_instr_conv(proc, kind, value, src_type, t)); } // boolean -> integer if (is_type_boolean(src) && is_type_integer(dst)) { return ir_emit(proc, ir_instr_conv(proc, irConv_zext, value, src_type, t)); } // integer -> boolean if (is_type_integer(src) && is_type_boolean(dst)) { return ir_emit_comp(proc, Token_NotEq, value, v_zero); } // float -> float if (is_type_float(src) && is_type_float(dst)) { gbAllocator a = proc->module->allocator; i64 sz = type_size_of(proc->module->allocator, src); i64 dz = type_size_of(proc->module->allocator, dst); if (sz == 2) { switch (dz) { case 2: return value; case 4: { irValue **args = gb_alloc_array(a, irValue *, 1); args[0] = value; return ir_emit_global_call(proc, "__gnu_h2f_ieee", args, 1); } break; case 8: { irValue **args = gb_alloc_array(a, irValue *, 1); args[0] = value; return ir_emit_global_call(proc, "__f16_to_f64", args, 1); } break; } } else if (dz == 2) { switch (sz) { case 2: return value; case 4: { irValue **args = gb_alloc_array(a, irValue *, 1); args[0] = value; return ir_emit_global_call(proc, "__gnu_f2h_ieee", args, 1); } break; case 8: { irValue **args = gb_alloc_array(a, irValue *, 1); args[0] = value; return ir_emit_global_call(proc, "__truncdfhf2", args, 1); } break; } } irConvKind kind = irConv_fptrunc; if (dz >= sz) { kind = irConv_fpext; } return ir_emit(proc, ir_instr_conv(proc, kind, value, src_type, t)); } if (is_type_complex(src) && is_type_complex(dst)) { Type *ft = base_complex_elem_type(dst); irValue *gen = ir_add_local_generated(proc, dst); irValue *real = ir_emit_conv(proc, ir_emit_struct_ev(proc, value, 0), ft); irValue *imag = ir_emit_conv(proc, ir_emit_struct_ev(proc, value, 1), ft); ir_emit_store(proc, ir_emit_struct_ep(proc, gen, 0), real); ir_emit_store(proc, ir_emit_struct_ep(proc, gen, 1), imag); return ir_emit_load(proc, gen); } // float <-> integer if (is_type_float(src) && is_type_integer(dst)) { irConvKind kind = irConv_fptosi; if (is_type_unsigned(dst)) { kind = irConv_fptoui; } return ir_emit(proc, ir_instr_conv(proc, kind, value, src_type, t)); } if (is_type_integer(src) && is_type_float(dst)) { irConvKind kind = irConv_sitofp; if (is_type_unsigned(src)) { kind = irConv_uitofp; } return ir_emit(proc, ir_instr_conv(proc, kind, value, src_type, t)); } // Pointer <-> int if (is_type_pointer(src) && is_type_int_or_uint(dst)) { return ir_emit_ptr_to_int(proc, value, t); } if (is_type_int_or_uint(src) && is_type_pointer(dst)) { return ir_emit_int_to_ptr(proc, value, t); } if (is_type_union(dst)) { for (isize i = 1; i < dst->Record.variant_count; i++) { Entity *f = dst->Record.variants[i]; if (are_types_identical(f->type, src_type)) { ir_emit_comment(proc, str_lit("union - child to parent")); gbAllocator a = proc->module->allocator; irValue *parent = ir_add_local_generated(proc, t); irValue *underlying = ir_emit_conv(proc, parent, make_type_pointer(a, f->type)); ir_emit_store(proc, underlying, value); irValue *tag_ptr = ir_emit_union_tag_ptr(proc, parent); ir_emit_store(proc, tag_ptr, ir_const_int(a, i)); return ir_emit_load(proc, parent); } } } // NOTE(bill): This has to be done before `Pointer <-> Pointer` as it's // subtype polymorphism casting if (check_is_assignable_to_using_subtype(src_type, t)) { Type *st = type_deref(src_type); Type *pst = st; st = type_deref(st); bool st_is_ptr = st != pst; st = base_type(st); Type *dt = t; bool dt_is_ptr = is_type_pointer(dt); GB_ASSERT(is_type_struct(st) || is_type_union(st)); String field_name = ir_lookup_subtype_polymorphic_field(proc->module->info, t, st); // gb_printf("field_name: %.*s\n", LIT(field_name)); if (field_name.len > 0) { // NOTE(bill): It can be casted Selection sel = lookup_field(proc->module->allocator, st, field_name, false); if (sel.entity != NULL) { ir_emit_comment(proc, str_lit("cast - polymorphism")); if (st_is_ptr) { irValue *res = ir_emit_deep_field_gep(proc, value, sel); if (!dt_is_ptr) { res = ir_emit_load(proc, res); } return res; } else { if (is_type_pointer(ir_type(value))) { if (!dt_is_ptr) { value = ir_emit_load(proc, value); } else { value = ir_emit_deep_field_gep(proc, value, sel); return ir_emit_load(proc, value); } } return ir_emit_deep_field_ev(proc, value, sel); } } } } // Pointer <-> Pointer if (is_type_pointer(src) && is_type_pointer(dst)) { return ir_emit_bitcast(proc, value, t); } // proc <-> proc if (is_type_proc(src) && is_type_proc(dst)) { return ir_emit_bitcast(proc, value, t); } // pointer -> proc if (is_type_pointer(src) && is_type_proc(dst)) { return ir_emit_bitcast(proc, value, t); } // proc -> pointer if (is_type_proc(src) && is_type_pointer(dst)) { return ir_emit_bitcast(proc, value, t); } // []byte/[]u8 <-> string if (is_type_u8_slice(src) && is_type_string(dst)) { irValue *elem = ir_slice_elem(proc, value); irValue *len = ir_slice_count(proc, value); return ir_emit_string(proc, elem, len); } if (is_type_string(src) && is_type_u8_slice(dst)) { irValue *elem = ir_string_elem(proc, value); irValue *elem_ptr = ir_add_local_generated(proc, ir_type(elem)); ir_emit_store(proc, elem_ptr, elem); irValue *len = ir_string_len(proc, value); irValue *cap = len; irValue *slice = ir_add_local_slice(proc, t, elem_ptr, v_zero, len, cap); return ir_emit_load(proc, slice); } if (is_type_vector(dst)) { Type *dst_elem = dst->Vector.elem; value = ir_emit_conv(proc, value, dst_elem); irValue *v = ir_add_local_generated(proc, t); isize index_count = dst->Vector.count; for (i32 i = 0; i < index_count; i++) { irValue *elem = ir_emit_array_epi(proc, v, i); ir_emit_store(proc, elem, value); } return ir_emit_load(proc, v); } if (is_type_any(dst)) { irValue *result = ir_add_local_generated(proc, t_any); if (is_type_untyped_nil(src)) { return ir_emit_load(proc, result); } Type *st = default_type(src_type); irValue *data = NULL; if (value->kind == irValue_Instr && value->Instr.kind == irInstr_Load) { // NOTE(bill): Addreirble value data = value->Instr.Load.address; } else { // NOTE(bill): Non-addreirble value data = ir_add_local_generated(proc, st); ir_emit_store(proc, data, value); } GB_ASSERT(is_type_pointer(ir_type(data))); GB_ASSERT_MSG(is_type_typed(st), "%s", type_to_string(st)); data = ir_emit_conv(proc, data, t_rawptr); irValue *ti = ir_type_info(proc, st); ir_emit_store(proc, ir_emit_struct_ep(proc, result, 0), data); ir_emit_store(proc, ir_emit_struct_ep(proc, result, 1), ti); return ir_emit_load(proc, result); } gb_printf_err("ir_emit_conv: src -> dst\n"); gb_printf_err("Not Identical %s != %s\n", type_to_string(src_type), type_to_string(t)); gb_printf_err("Not Identical %s != %s\n", type_to_string(src), type_to_string(dst)); GB_PANIC("Invalid type conversion: `%s` to `%s` for procedure `%.*s`", type_to_string(src_type), type_to_string(t), LIT(proc->name)); return NULL; } bool ir_is_type_aggregate(Type *t) { t = base_type(t); switch (t->kind) { case Type_Basic: switch (t->Basic.kind) { case Basic_string: case Basic_any: return true; // case Basic_complex32: case Basic_complex64: case Basic_complex128: return true; } break; case Type_Pointer: return false; case Type_Vector: case Type_Array: case Type_Slice: case Type_Record: case Type_Tuple: case Type_DynamicArray: case Type_Map: case Type_BitField: return true; case Type_Named: return ir_is_type_aggregate(t->Named.base); } return false; } irValue *ir_emit_transmute(irProcedure *proc, irValue *value, Type *t) { Type *src_type = ir_type(value); if (are_types_identical(t, src_type)) { return value; } Type *src = base_type(src_type); Type *dst = base_type(t); #if 0 if (are_types_identical(t, src_type)) { return value; } #endif irModule *m = proc->module; i64 sz = type_size_of(m->allocator, src); i64 dz = type_size_of(m->allocator, dst); GB_ASSERT_MSG(sz == dz, "Invalid transmute conversion: `%s` to `%s`", type_to_string(src_type), type_to_string(t)); if (ir_is_type_aggregate(src) || ir_is_type_aggregate(dst)) { irValue *s = ir_address_from_load_or_generate_local(proc, value); irValue *d = ir_emit_bitcast(proc, s, make_type_pointer(m->allocator, t)); return ir_emit_load(proc, d); } // TODO(bill): Actually figure out what the conversion needs to be correctly 'cause LLVM return ir_emit_bitcast(proc, value, dst); } irValue *ir_emit_down_cast(irProcedure *proc, irValue *value, Type *t) { GB_ASSERT(is_type_pointer(ir_type(value))); gbAllocator allocator = proc->module->allocator; String field_name = check_down_cast_name(t, type_deref(ir_type(value))); GB_ASSERT(field_name.len > 0); Selection sel = lookup_field(proc->module->allocator, t, field_name, false); irValue *bytes = ir_emit_conv(proc, value, t_u8_ptr); i64 offset_ = type_offset_of_from_selection(allocator, type_deref(t), sel); irValue *offset = ir_const_int(allocator, -offset_); irValue *head = ir_emit_ptr_offset(proc, bytes, offset); return ir_emit_conv(proc, head, t); } irValue *ir_emit_union_cast(irProcedure *proc, irValue *value, Type *type, TokenPos pos) { gbAllocator a = proc->module->allocator; Type *src_type = ir_type(value); bool is_ptr = is_type_pointer(src_type); bool is_tuple = true; Type *tuple = type; if (type->kind != Type_Tuple) { is_tuple = false; tuple = make_optional_ok_type(a, type); } irValue *v = ir_add_local_generated(proc, tuple); if (is_ptr) { Type *src = base_type(type_deref(src_type)); Type *src_ptr = src_type; GB_ASSERT(is_type_union(src)); Type *dst_ptr = tuple->Tuple.variables[0]->type; Type *dst = type_deref(dst_ptr); irValue *tag = ir_emit_load(proc, ir_emit_union_tag_ptr(proc, value)); irValue *dst_tag = NULL; for (isize i = 1; i < src->Record.variant_count; i++) { Entity *f = src->Record.variants[i]; if (are_types_identical(f->type, dst)) { dst_tag = ir_const_int(a, i); break; } } GB_ASSERT(dst_tag != NULL); irBlock *ok_block = ir_new_block(proc, NULL, "union_cast.ok"); irBlock *end_block = ir_new_block(proc, NULL, "union_cast.end"); irValue *cond = ir_emit_comp(proc, Token_CmpEq, tag, dst_tag); ir_emit_if(proc, cond, ok_block, end_block); ir_start_block(proc, ok_block); irValue *gep0 = ir_emit_struct_ep(proc, v, 0); irValue *gep1 = ir_emit_struct_ep(proc, v, 1); irValue *data = ir_emit_conv(proc, value, dst_ptr); ir_emit_store(proc, gep0, data); ir_emit_store(proc, gep1, v_true); ir_emit_jump(proc, end_block); ir_start_block(proc, end_block); } else { Type *src = base_type(src_type); GB_ASSERT(is_type_union(src)); Type *dst = tuple->Tuple.variables[0]->type; Type *dst_ptr = make_type_pointer(a, dst); irValue *value_ = ir_address_from_load_or_generate_local(proc, value); irValue *tag = ir_emit_load(proc, ir_emit_union_tag_ptr(proc, value_)); irValue *dst_tag = NULL; for (isize i = 1; i < src->Record.variant_count; i++) { Entity *f = src->Record.variants[i]; if (are_types_identical(f->type, dst)) { dst_tag = ir_const_int(a, i); break; } } GB_ASSERT(dst_tag != NULL); irBlock *ok_block = ir_new_block(proc, NULL, "union_cast.ok"); irBlock *end_block = ir_new_block(proc, NULL, "union_cast.end"); irValue *cond = ir_emit_comp(proc, Token_CmpEq, tag, dst_tag); ir_emit_if(proc, cond, ok_block, end_block); ir_start_block(proc, ok_block); irValue *gep0 = ir_emit_struct_ep(proc, v, 0); irValue *gep1 = ir_emit_struct_ep(proc, v, 1); irValue *data = ir_emit_load(proc, ir_emit_conv(proc, value_, ir_type(gep0))); ir_emit_store(proc, gep0, data); ir_emit_store(proc, gep1, v_true); ir_emit_jump(proc, end_block); ir_start_block(proc, end_block); } if (!is_tuple) { // NOTE(bill): Panic on invalid conversion Type *dst_type = tuple->Tuple.variables[0]->type; irValue *ok = ir_emit_load(proc, ir_emit_struct_ep(proc, v, 1)); irValue **args = gb_alloc_array(a, irValue *, 6); args[0] = ok; args[1] = ir_find_or_add_entity_string(proc->module, pos.file); args[2] = ir_const_int(a, pos.line); args[3] = ir_const_int(a, pos.column); args[4] = ir_type_info(proc, src_type); args[5] = ir_type_info(proc, dst_type); ir_emit_global_call(proc, "__type_assertion_check", args, 6); return ir_emit_load(proc, ir_emit_struct_ep(proc, v, 0)); } return ir_emit_load(proc, v); } irAddr ir_emit_any_cast_addr(irProcedure *proc, irValue *value, Type *type, TokenPos pos) { gbAllocator a = proc->module->allocator; Type *src_type = ir_type(value); bool is_tuple = true; Type *tuple = type; if (type->kind != Type_Tuple) { is_tuple = false; tuple = make_optional_ok_type(a, type); } Type *dst_type = tuple->Tuple.variables[0]->type; irValue *v = ir_add_local_generated(proc, tuple); irValue *ti_ptr = ir_type_info(proc, dst_type); irValue *any_ti = ir_emit_struct_ev(proc, value, 1); irBlock *ok_block = ir_new_block(proc, NULL, "any_cast.ok"); irBlock *end_block = ir_new_block(proc, NULL, "any_cast.end"); irValue *cond = ir_emit_comp(proc, Token_CmpEq, any_ti, ti_ptr); ir_emit_if(proc, cond, ok_block, end_block); ir_start_block(proc, ok_block); irValue *gep0 = ir_emit_struct_ep(proc, v, 0); irValue *gep1 = ir_emit_struct_ep(proc, v, 1); irValue *any_data = ir_emit_struct_ev(proc, value, 0); irValue *ptr = ir_emit_conv(proc, any_data, make_type_pointer(a, dst_type)); ir_emit_store(proc, gep0, ir_emit_load(proc, ptr)); ir_emit_store(proc, gep1, v_true); ir_emit_jump(proc, end_block); ir_start_block(proc, end_block); if (!is_tuple) { // NOTE(bill): Panic on invalid conversion irValue *ok = ir_emit_load(proc, ir_emit_struct_ep(proc, v, 1)); irValue **args = gb_alloc_array(a, irValue *, 6); args[0] = ok; args[1] = ir_find_or_add_entity_string(proc->module, pos.file); args[2] = ir_const_int(a, pos.line); args[3] = ir_const_int(a, pos.column); args[4] = any_ti; args[5] = ti_ptr; ir_emit_global_call(proc, "__type_assertion_check", args, 6); return ir_addr(ir_emit_struct_ep(proc, v, 0)); } return ir_addr(v); } irValue *ir_emit_any_cast(irProcedure *proc, irValue *value, Type *type, TokenPos pos) { return ir_addr_load(proc, ir_emit_any_cast_addr(proc, value, type, pos)); } // TODO(bill): Try and make a lot of this constant aggregate literals in LLVM IR gb_global irValue *ir_global_type_info_data = NULL; gb_global irValue *ir_global_type_info_member_types = NULL; gb_global irValue *ir_global_type_info_member_names = NULL; gb_global irValue *ir_global_type_info_member_offsets = NULL; gb_global irValue *ir_global_type_info_member_usings = NULL; gb_global i32 ir_global_type_info_data_index = 0; gb_global i32 ir_global_type_info_member_types_index = 0; gb_global i32 ir_global_type_info_member_names_index = 0; gb_global i32 ir_global_type_info_member_offsets_index = 0; gb_global i32 ir_global_type_info_member_usings_index = 0; irValue *ir_type_info(irProcedure *proc, Type *type) { CheckerInfo *info = proc->module->info; type = default_type(type); i32 entry_index = type_info_index(info, type); // gb_printf_err("%d %s\n", entry_index, type_to_string(type)); return ir_emit_array_ep(proc, ir_global_type_info_data, ir_const_i32(proc->module->allocator, entry_index)); } irValue *ir_emit_logical_binary_expr(irProcedure *proc, AstNode *expr) { ast_node(be, BinaryExpr, expr); #if 0 irBlock *true_ = ir_new_block(proc, NULL, "logical.cmp.true"); irBlock *false_ = ir_new_block(proc, NULL, "logical.cmp.false"); irBlock *done = ir_new_block(proc, NULL, "logical.cmp.done"); irValue *result = ir_add_local_generated(proc, t_bool); ir_build_cond(proc, expr, true_, false_); ir_start_block(proc, true_); ir_emit_store(proc, result, v_true); ir_emit_jump(proc, done); ir_start_block(proc, false_); ir_emit_store(proc, result, v_false); ir_emit_jump(proc, done); ir_start_block(proc, done); return ir_emit_load(proc, result); #else irBlock *rhs = ir_new_block(proc, NULL, "logical.cmp.rhs"); irBlock *done = ir_new_block(proc, NULL, "logical.cmp.done"); Type *type = type_of_expr(proc->module->info, expr); type = default_type(type); irValue *short_circuit = NULL; if (be->op.kind == Token_CmpAnd) { ir_build_cond(proc, be->left, rhs, done); short_circuit = v_false; } else if (be->op.kind == Token_CmpOr) { ir_build_cond(proc, be->left, done, rhs); short_circuit = v_true; } if (rhs->preds.count == 0) { ir_start_block(proc, done); return short_circuit; } if (done->preds.count == 0) { ir_start_block(proc, rhs); return ir_build_expr(proc, be->right); } Array edges = {}; array_init(&edges, proc->module->allocator, done->preds.count+1); for_array(i, done->preds) { array_add(&edges, short_circuit); } ir_start_block(proc, rhs); array_add(&edges, ir_build_expr(proc, be->right)); ir_emit_jump(proc, done); ir_start_block(proc, done); return ir_emit(proc, ir_instr_phi(proc, edges, type)); #endif } void ir_emit_bounds_check(irProcedure *proc, Token token, irValue *index, irValue *len) { if ((proc->module->stmt_state_flags & StmtStateFlag_no_bounds_check) != 0) { return; } index = ir_emit_conv(proc, index, t_int); len = ir_emit_conv(proc, len, t_int); gbAllocator a = proc->module->allocator; irValue *file = ir_find_or_add_entity_string(proc->module, token.pos.file); irValue *line = ir_const_int(a, token.pos.line); irValue *column = ir_const_int(a, token.pos.column); irValue **args = gb_alloc_array(a, irValue *, 5); args[0] = file; args[1] = line; args[2] = column; args[3] = index; args[4] = len; ir_emit_global_call(proc, "__bounds_check_error", args, 5); // ir_emit(proc, ir_instr_bounds_check(proc, token.pos, index, len)); } void ir_emit_slice_bounds_check(irProcedure *proc, Token token, irValue *low, irValue *high, irValue *max, bool is_substring) { if ((proc->module->stmt_state_flags & StmtStateFlag_no_bounds_check) != 0) { return; } gbAllocator a = proc->module->allocator; irValue *file = ir_find_or_add_entity_string(proc->module, token.pos.file); irValue *line = ir_const_int(a, token.pos.line); irValue *column = ir_const_int(a, token.pos.column); low = ir_emit_conv(proc, low, t_int); high = ir_emit_conv(proc, high, t_int); irValue **args = gb_alloc_array(a, irValue *, 6); args[0] = file; args[1] = line; args[2] = column; args[3] = low; args[4] = high; args[5] = max; if (is_substring) { ir_emit_global_call(proc, "__substring_expr_error", args, 5); } else { ir_emit_global_call(proc, "__slice_expr_error", args, 6); } // ir_emit(proc, ir_instr_slice_bounds_check(proc, token.pos, low, high, max, is_substring)); } //////////////////////////////////////////////////////////////// // // @Build // //////////////////////////////////////////////////////////////// String ir_mangle_name(irGen *s, String path, Entity *e) { // NOTE(bill): prefix names not in the init scope // TODO(bill): make robust and not just rely on the file's name String name = e->token.string; irModule *m = &s->module; CheckerInfo *info = m->info; gbAllocator a = m->allocator; AstFile *file = ast_file_of_filename(info, path); char *str = gb_alloc_array(a, char, path.len+1); gb_memmove(str, path.text, path.len); str[path.len] = 0; for (isize i = 0; i < path.len; i++) { if (str[i] == '\\') { str[i] = '/'; } } char const *base = gb_path_base_name(str); char const *ext = gb_path_extension(base); isize base_len = ext-1-base; isize max_len = base_len + 1 + 1 + 10 + 1 + name.len; bool require_suffix_id = check_is_entity_overloaded(e) || is_type_poly_proc(e->type); if (require_suffix_id) { max_len += 21; } u8 *new_name = gb_alloc_array(a, u8, max_len); isize new_name_len = 0; if ((base_len > 0 && gb_char_is_digit(base[0])) || base_len == 0) { new_name_len = gb_snprintf( cast(char *)new_name, max_len, "_%.*s-%u.%.*s", cast(int)base_len, base, file->id, LIT(name)); } else { new_name_len = gb_snprintf( cast(char *)new_name, max_len, "%.*s-%u.%.*s", cast(int)base_len, base, file->id, LIT(name)); } if (require_suffix_id) { char *str = cast(char *)new_name + new_name_len-1; isize len = max_len-new_name_len; isize extra = gb_snprintf(str, len, "-%llu", cast(unsigned long long)e->id); new_name_len += extra-1; } return make_string(new_name, new_name_len-1); } void ir_mangle_add_sub_type_name(irModule *m, Entity *field, String parent) { if (field->kind != Entity_TypeName) { return; } String cn = field->token.string; isize len = parent.len + 1 + 16 + 1 + cn.len; u8 *text = gb_alloc_array(m->allocator, u8, len); isize new_name_len = gb_snprintf(cast(char *)text, len, "%.*s.%.*s", LIT(parent), LIT(cn)); String child = {text, new_name_len-1}; map_set(&m->entity_names, hash_entity(field), child); ir_gen_global_type_name(m, field, child); } irBranchBlocks ir_lookup_branch_blocks(irProcedure *proc, AstNode *ident) { GB_ASSERT(ident->kind == AstNode_Ident); Entity *e = entity_of_ident(proc->module->info, ident); GB_ASSERT(e->kind == Entity_Label); for_array(i, proc->branch_blocks) { irBranchBlocks *b = &proc->branch_blocks[i]; if (b->label == e->Label.node) { return *b; } } GB_PANIC("Unreachable"); irBranchBlocks empty = {}; return empty; } void ir_push_target_list(irProcedure *proc, AstNode *label, irBlock *break_, irBlock *continue_, irBlock *fallthrough_) { irTargetList *tl = gb_alloc_item(proc->module->allocator, irTargetList); tl->prev = proc->target_list; tl->break_ = break_; tl->continue_ = continue_; tl->fallthrough_ = fallthrough_; proc->target_list = tl; if (label != NULL) { // Set label blocks GB_ASSERT(label->kind == AstNode_Label); for_array(i, proc->branch_blocks) { irBranchBlocks *b = &proc->branch_blocks[i]; GB_ASSERT(b->label != NULL && label != NULL); GB_ASSERT(b->label->kind == AstNode_Label); if (b->label == label) { b->break_ = break_; b->continue_ = continue_; return; } } GB_PANIC("ir_set_label_blocks: Unreachable"); } } void ir_pop_target_list(irProcedure *proc) { proc->target_list = proc->target_list->prev; } void ir_gen_global_type_name(irModule *m, Entity *e, String name) { irValue *t = ir_value_type_name(m->allocator, name, e->type); ir_module_add_value(m, e, t); map_set(&m->members, hash_string(name), t); if (is_type_union(e->type)) { Type *bt = base_type(e->type); // NOTE(bill): Zeroth entry is null (for `match type` stmts) for (isize j = 1; j < bt->Record.variant_count; j++) { ir_mangle_add_sub_type_name(m, bt->Record.variants[j], name); } } } void ir_build_defer_stmt(irProcedure *proc, irDefer d) { irBlock *b = ir_new_block(proc, NULL, "defer"); // NOTE(bill): The prev block may defer injection before it's terminator irInstr *last_instr = ir_get_last_instr(proc->curr_block); if (last_instr == NULL || !ir_is_instr_terminating(last_instr)) { ir_emit_jump(proc, b); } ir_start_block(proc, b); ir_emit_comment(proc, str_lit("defer")); if (d.kind == irDefer_Node) { ir_build_stmt(proc, d.stmt); } else if (d.kind == irDefer_Instr) { // NOTE(bill): Need to make a new copy irValue *instr = cast(irValue *)gb_alloc_copy(proc->module->allocator, d.instr, gb_size_of(irValue)); ir_emit(proc, instr); } } irValue *ir_emit_clamp(irProcedure *proc, Type *t, irValue *x, irValue *min, irValue *max) { irValue *cond = NULL; ir_emit_comment(proc, str_lit("clamp")); x = ir_emit_conv(proc, x, t); min = ir_emit_conv(proc, min, t); max = ir_emit_conv(proc, max, t); cond = ir_emit_comp(proc, Token_Gt, min, x); x = ir_emit_select(proc, cond, min, x); cond = ir_emit_comp(proc, Token_Lt, max, x); x = ir_emit_select(proc, cond, max, x); return x; } irValue *ir_find_global_variable(irProcedure *proc, String name) { irValue **value = map_get(&proc->module->members, hash_string(name)); GB_ASSERT_MSG(value != NULL, "Unable to find global variable `%.*s`", LIT(name)); return *value; } void ir_build_stmt_list(irProcedure *proc, Array stmts); bool is_double_pointer(Type *t) { if (!is_type_pointer(t)) { return false; } Type *td = type_deref(t); if (td == NULL || td == t) { return false; } return is_type_pointer(td); } irValue *ir_emit_source_code_location(irProcedure *proc, String procedure, TokenPos pos) { gbAllocator a = proc->module->allocator; irValue **args = gb_alloc_array(a, irValue *, 4); args[0] = ir_find_or_add_entity_string(proc->module, pos.file); args[1] = ir_const_i64(a, pos.line); args[2] = ir_const_i64(a, pos.column); args[3] = ir_find_or_add_entity_string(proc->module, procedure); return ir_emit_global_call(proc, "make_source_code_location", args, 4); } irValue *ir_build_builtin_proc(irProcedure *proc, AstNode *expr, TypeAndValue tv, BuiltinProcId id) { ast_node(ce, CallExpr, expr); switch (id) { case BuiltinProc_DIRECTIVE: { ast_node(bd, BasicDirective, ce->proc); String name = bd->name; GB_ASSERT(name == "location"); String procedure = proc->entity->token.string; TokenPos pos = ast_node_token(ce->proc).pos; if (ce->args.count > 0) { AstNode *ident = ce->args[0];; while (ident->kind == AstNode_SelectorExpr) { ident = ident->SelectorExpr.selector; } Entity *e = entity_of_ident(proc->module->info, ident); GB_ASSERT(e != NULL); if (e->parent_proc_decl != NULL && e->parent_proc_decl->entity_count > 0) { procedure = e->parent_proc_decl->entities[0]->token.string; } else { procedure = str_lit(""); } pos = e->token.pos; } return ir_emit_source_code_location(proc, procedure, pos); } break; case BuiltinProc_type_info: { Type *t = default_type(type_of_expr(proc->module->info, ce->args[0])); return ir_type_info(proc, t); } break; case BuiltinProc_transmute: { irValue *x = ir_build_expr(proc, ce->args[1]); return ir_emit_transmute(proc, x, tv.type); } case BuiltinProc_len: { irValue *v = ir_build_expr(proc, ce->args[0]); Type *t = base_type(ir_type(v)); if (is_type_pointer(t)) { // IMPORTANT TODO(bill): Should there be a nil pointer check? v = ir_emit_load(proc, v); t = type_deref(t); } if (is_type_string(t)) { return ir_string_len(proc, v); } else if (is_type_array(t)) { GB_PANIC("Array lengths are constant"); } else if (is_type_vector(t)) { GB_PANIC("Vector lengths are constant"); } else if (is_type_slice(t)) { return ir_slice_count(proc, v); } else if (is_type_dynamic_array(t)) { return ir_dynamic_array_count(proc, v); } else if (is_type_dynamic_map(t)) { ir_emit_comment(proc, str_lit("len: map")); irValue *entries = ir_emit_struct_ev(proc, v, 1); return ir_dynamic_array_count(proc, entries); } GB_PANIC("Unreachable"); } break; case BuiltinProc_cap: { irValue *v = ir_build_expr(proc, ce->args[0]); Type *t = base_type(ir_type(v)); if (is_type_pointer(t)) { // IMPORTANT TODO(bill): Should there be a nil pointer check? v = ir_emit_load(proc, v); t = type_deref(t); } if (is_type_string(t)) { GB_PANIC("Unreachable"); } else if (is_type_array(t)) { GB_PANIC("Array lengths are constant"); } else if (is_type_vector(t)) { GB_PANIC("Unreachable"); } else if (is_type_slice(t)) { return ir_slice_capacity(proc, v); } else if (is_type_dynamic_array(t)) { return ir_dynamic_array_capacity(proc, v); } else if (is_type_map(t)) { irValue *entries = ir_emit_struct_ev(proc, v, 1); return ir_dynamic_array_capacity(proc, entries); } GB_PANIC("Unreachable"); } break; #if 0 case BuiltinProc_new: { ir_emit_comment(proc, str_lit("new")); // proc new(Type) -> ^Type gbAllocator a = proc->module->allocator; Type *type = type_of_expr(proc->module->info, ce->args[0]); Type *allocation_type = type; i32 variant_index = 0; if (is_type_struct(type)) { Type *st = base_type(type); if (st->Record.variant_parent != NULL) { allocation_type = st->Record.variant_parent; variant_index = st->Record.variant_index; GB_ASSERT(allocation_type != NULL); } } Type *ptr_type = make_type_pointer(a, type); i64 size = type_size_of(a, allocation_type); i64 align = type_align_of(a, allocation_type); irValue **args = gb_alloc_array(a, irValue *, 2); args[0] = ir_const_int(a, size); args[1] = ir_const_int(a, align); irValue *call = ir_emit_global_call(proc, "alloc", args, 2); irValue *v = ir_emit_conv(proc, call, ptr_type); if (type != allocation_type) { Type *u = base_type(allocation_type); Type *uptr_type = make_type_pointer(a, u); irValue *parent = ir_emit_conv(proc, call, uptr_type); irValue *tag_ptr = ir_emit_union_tag_ptr(proc, parent); ir_emit_store(proc, tag_ptr, ir_const_int(a, variant_index)); } return v; } break; #endif case BuiltinProc_make: { ir_emit_comment(proc, str_lit("make")); gbAllocator a = proc->module->allocator; Type *type = type_of_expr(proc->module->info, ce->args[0]); if (is_type_slice(type)) { Type *elem_type = core_type(type)->Slice.elem; Type *elem_ptr_type = make_type_pointer(a, elem_type); irValue *elem_size = ir_const_int(a, type_size_of(a, elem_type)); irValue *elem_align = ir_const_int(a, type_align_of(a, elem_type)); irValue *count = ir_emit_conv(proc, ir_build_expr(proc, ce->args[1]), t_int); irValue *capacity = count; if (ce->args.count == 3) { capacity = ir_emit_conv(proc, ir_build_expr(proc, ce->args[2]), t_int); } ir_emit_slice_bounds_check(proc, ast_node_token(ce->args[1]), v_zero, count, capacity, false); irValue *slice_size = ir_emit_arith(proc, Token_Mul, elem_size, capacity, t_int); irValue **args = gb_alloc_array(a, irValue *, 2); args[0] = slice_size; args[1] = elem_align; irValue *call = ir_emit_global_call(proc, "alloc", args, 2); irValue *ptr = ir_emit_conv(proc, call, elem_ptr_type); irValue *slice = ir_add_local_generated(proc, type); ir_fill_slice(proc, slice, ptr, count, capacity); return ir_emit_load(proc, slice); } else if (is_type_dynamic_map(type)) { irValue *int_16 = ir_const_int(a, 16); irValue *cap = int_16; if (ce->args.count == 2) { cap = ir_emit_conv(proc, ir_build_expr(proc, ce->args[1]), t_int); } irValue *cond = ir_emit_comp(proc, Token_Gt, cap, v_zero); cap = ir_emit_select(proc, cond, cap, int_16); irValue *map = ir_add_local_generated(proc, type); irValue *header = ir_gen_map_header(proc, map, base_type(type)); irValue **args = gb_alloc_array(a, irValue *, 2); args[0] = header; args[1] = cap; ir_emit_global_call(proc, "__dynamic_map_reserve", args, 2); return ir_emit_load(proc, map); } else if (is_type_dynamic_array(type)) { Type *elem_type = base_type(type)->DynamicArray.elem; irValue *len = v_zero; if (ce->args.count > 1) { len = ir_emit_conv(proc, ir_build_expr(proc, ce->args[1]), t_int); } irValue *cap = len; if (ce->args.count > 2) { cap = ir_emit_conv(proc, ir_build_expr(proc, ce->args[2]), t_int); } ir_emit_slice_bounds_check(proc, ast_node_token(ce->args[0]), v_zero, len, cap, false); irValue *array = ir_add_local_generated(proc, type); irValue **args = gb_alloc_array(a, irValue *, 5); args[0] = ir_emit_conv(proc, array, t_rawptr); args[1] = ir_const_int(a, type_size_of(a, elem_type)); args[2] = ir_const_int(a, type_align_of(a, elem_type));; args[3] = len; args[4] = cap; ir_emit_global_call(proc, "__dynamic_array_make", args, 5); return ir_emit_load(proc, array); } } break; case BuiltinProc_free: { ir_emit_comment(proc, str_lit("free")); gbAllocator a = proc->module->allocator; AstNode *node = ce->args[0]; TypeAndValue tav = type_and_value_of_expr(proc->module->info, node); Type *type = base_type(tav.type); if (is_type_dynamic_array(type)) { irValue *val = ir_build_expr(proc, node); irValue *da_allocator = ir_emit_struct_ev(proc, val, 3); irValue *ptr = ir_emit_struct_ev(proc, val, 0); ptr = ir_emit_conv(proc, ptr, t_rawptr); irValue **args = gb_alloc_array(a, irValue *, 1); args[0] = da_allocator; args[1] = ptr; return ir_emit_global_call(proc, "free_ptr_with_allocator", args, 2); } else if (is_type_dynamic_map(type)) { irValue *map = ir_build_expr(proc, node); irValue *map_ptr = ir_address_from_load_or_generate_local(proc, map); { irValue *array = ir_emit_struct_ep(proc, map_ptr, 0); irValue *da_allocator = ir_emit_load(proc, ir_emit_struct_ep(proc, array, 3)); irValue *da_ptr = ir_emit_load(proc, ir_emit_struct_ep(proc, array, 0)); da_ptr = ir_emit_conv(proc, da_ptr, t_rawptr); irValue **args = gb_alloc_array(a, irValue *, 1); args[0] = da_allocator; args[1] = da_ptr; ir_emit_global_call(proc, "free_ptr_with_allocator", args, 2); } { irValue *array = ir_emit_struct_ep(proc, map_ptr, 1); irValue *da_allocator = ir_emit_load(proc, ir_emit_struct_ep(proc, array, 3)); irValue *da_ptr = ir_emit_load(proc, ir_emit_struct_ep(proc, array, 0)); da_ptr = ir_emit_conv(proc, da_ptr, t_rawptr); irValue **args = gb_alloc_array(a, irValue *, 1); args[0] = da_allocator; args[1] = da_ptr; ir_emit_global_call(proc, "free_ptr_with_allocator", args, 2); } return NULL; } irValue *val = ir_build_expr(proc, node); irValue *ptr = NULL; if (is_type_pointer(type)) { ptr = val; } else if (is_type_slice(type)) { ptr = ir_slice_elem(proc, val); } else if (is_type_string(type)) { ptr = ir_string_elem(proc, val); } else { GB_PANIC("Invalid type to `free`"); } if (ptr == NULL) { return NULL; } ptr = ir_emit_conv(proc, ptr, t_rawptr); irValue **args = gb_alloc_array(a, irValue *, 1); args[0] = ptr; return ir_emit_global_call(proc, "free_ptr", args, 1); } break; case BuiltinProc_reserve: { ir_emit_comment(proc, str_lit("reserve")); gbAllocator a = proc->module->allocator; irValue *ptr = ir_build_addr(proc, ce->args[0]).addr; Type *type = ir_type(ptr); GB_ASSERT(is_type_pointer(type)); type = base_type(type_deref(type)); irValue *capacity = ir_emit_conv(proc, ir_build_expr(proc, ce->args[1]), t_int); if (is_type_dynamic_array(type)) { Type *elem = type->DynamicArray.elem; irValue *elem_size = ir_const_int(a, type_size_of(a, elem)); irValue *elem_align = ir_const_int(a, type_align_of(a, elem)); ptr = ir_emit_conv(proc, ptr, t_rawptr); irValue **args = gb_alloc_array(a, irValue *, 4); args[0] = ptr; args[1] = elem_size; args[2] = elem_align; args[3] = capacity; return ir_emit_global_call(proc, "__dynamic_array_reserve", args, 4); } else if (is_type_dynamic_map(type)) { irValue **args = gb_alloc_array(a, irValue *, 2); args[0] = ir_gen_map_header(proc, ptr, type); args[1] = capacity; return ir_emit_global_call(proc, "__dynamic_map_reserve", args, 2); } else { GB_PANIC("Unknown type for `reserve`"); } } break; case BuiltinProc_clear: { ir_emit_comment(proc, str_lit("clear")); Type *original_type = type_of_expr(proc->module->info, ce->args[0]); irAddr addr = ir_build_addr(proc, ce->args[0]); irValue *ptr = addr.addr; if (is_double_pointer(ir_type(ptr))) { ptr = ir_addr_load(proc, addr); } Type *t = base_type(type_deref(original_type)); if (is_type_dynamic_array(t)) { irValue *count_ptr = ir_emit_struct_ep(proc, ptr, 1); ir_emit_store(proc, count_ptr, v_zero); } else if (is_type_dynamic_map(t)) { irValue *ha = ir_emit_struct_ep(proc, ptr, 0); irValue *ea = ir_emit_struct_ep(proc, ptr, 1); ir_emit_store(proc, ir_emit_struct_ep(proc, ha, 1), v_zero); ir_emit_store(proc, ir_emit_struct_ep(proc, ea, 1), v_zero); } else if (is_type_slice(t)) { irValue *count_ptr = ir_emit_struct_ep(proc, ptr, 1); ir_emit_store(proc, count_ptr, v_zero); } else { GB_PANIC("TODO(bill): ir clear for `%s`", type_to_string(t)); } return NULL; } break; case BuiltinProc_append: { ir_emit_comment(proc, str_lit("append")); gbAllocator a = proc->module->allocator; Type *value_type = type_of_expr(proc->module->info, ce->args[0]); irAddr array_addr = ir_build_addr(proc, ce->args[0]); irValue *array_ptr = array_addr.addr; if (is_double_pointer(ir_type(array_ptr))) { array_ptr = ir_addr_load(proc, array_addr); } Type *type = ir_type(array_ptr); { TokenPos pos = ast_node_token(ce->args[0]).pos; GB_ASSERT_MSG(is_type_pointer(type), "%.*s(%td) %s", LIT(pos.file), pos.line, type_to_string(type)); } type = base_type(type_deref(type)); Type *elem_type = NULL; bool is_slice = false; if (is_type_dynamic_array(type)) { elem_type = type->DynamicArray.elem; } else if (is_type_slice(type)) { is_slice = true; elem_type = type->Slice.elem; } else { GB_PANIC("Invalid type to append"); } irValue *elem_size = ir_const_int(a, type_size_of(a, elem_type)); irValue *elem_align = ir_const_int(a, type_align_of(a, elem_type)); array_ptr = ir_emit_conv(proc, array_ptr, t_rawptr); isize arg_index = 0; isize arg_count = 0; for_array(i, ce->args) { AstNode *a = ce->args[i]; Type *at = base_type(type_of_expr(proc->module->info, a)); if (at->kind == Type_Tuple) { arg_count += at->Tuple.variable_count; } else { arg_count++; } } irValue **args = gb_alloc_array(proc->module->allocator, irValue *, arg_count); bool vari_expand = ce->ellipsis.pos.line != 0; for_array(i, ce->args) { irValue *a = ir_build_expr(proc, ce->args[i]); Type *at = ir_type(a); if (at->kind == Type_Tuple) { for (isize i = 0; i < at->Tuple.variable_count; i++) { Entity *e = at->Tuple.variables[i]; irValue *v = ir_emit_struct_ev(proc, a, i); args[arg_index++] = v; } } else { args[arg_index++] = a; } } if (!vari_expand) { for (isize i = 1; i < arg_count; i++) { args[i] = ir_emit_conv(proc, args[i], elem_type); } } if (!vari_expand) { ir_emit_comment(proc, str_lit("variadic call argument generation")); Type *slice_type = make_type_slice(a, elem_type); irValue *slice = ir_add_local_generated(proc, slice_type); isize slice_len = arg_count-1; if (slice_len > 0) { irValue *base_array = ir_add_local_generated(proc, make_type_array(a, elem_type, slice_len)); for (isize i = 1; i < arg_count; i++) { irValue *addr = ir_emit_array_epi(proc, base_array, i-1); ir_emit_store(proc, addr, args[i]); } irValue *base_elem = ir_emit_array_epi(proc, base_array, 0); irValue *len = ir_const_int(a, slice_len); ir_fill_slice(proc, slice, base_elem, len, len); } arg_count = 2; args[arg_count-1] = ir_emit_load(proc, slice); } irValue *item_slice = args[1]; irValue *items = ir_slice_elem(proc, item_slice); irValue *item_count = ir_slice_count(proc, item_slice); irValue **daa_args = gb_alloc_array(a, irValue *, 5); daa_args[0] = array_ptr; daa_args[1] = elem_size; daa_args[2] = elem_align; daa_args[3] = ir_emit_conv(proc, items, t_rawptr); daa_args[4] = ir_emit_conv(proc, item_count, t_int); if (is_slice) { return ir_emit_global_call(proc, "__slice_append", daa_args, 5); } return ir_emit_global_call(proc, "__dynamic_array_append", daa_args, 5); } break; case BuiltinProc_delete: { ir_emit_comment(proc, str_lit("delete")); irValue *map = ir_build_expr(proc, ce->args[0]); irValue *key = ir_build_expr(proc, ce->args[1]); Type *map_type = ir_type(map); GB_ASSERT(is_type_dynamic_map(map_type)); Type *key_type = base_type(map_type)->Map.key; irValue *addr = ir_address_from_load_or_generate_local(proc, map); gbAllocator a = proc->module->allocator; irValue **args = gb_alloc_array(a, irValue *, 2); args[0] = ir_gen_map_header(proc, addr, map_type); args[1] = ir_gen_map_key(proc, key, key_type); return ir_emit_global_call(proc, "__dynamic_map_delete", args, 2); } break; case BuiltinProc_copy: { ir_emit_comment(proc, str_lit("copy")); // proc copy(dst, src: []Type) -> int AstNode *dst_node = ce->args[0]; AstNode *src_node = ce->args[1]; irValue *dst_slice = ir_build_expr(proc, dst_node); irValue *src_slice = ir_build_expr(proc, src_node); Type *slice_type = base_type(ir_type(dst_slice)); GB_ASSERT(slice_type->kind == Type_Slice); Type *elem_type = slice_type->Slice.elem; i64 size_of_elem = type_size_of(proc->module->allocator, elem_type); irValue *dst = ir_emit_conv(proc, ir_slice_elem(proc, dst_slice), t_rawptr); irValue *src = ir_emit_conv(proc, ir_slice_elem(proc, src_slice), t_rawptr); irValue *len_dst = ir_slice_count(proc, dst_slice); irValue *len_src = ir_slice_count(proc, src_slice); irValue *cond = ir_emit_comp(proc, Token_Lt, len_dst, len_src); irValue *len = ir_emit_select(proc, cond, len_dst, len_src); irValue *elem_size = ir_const_int(proc->module->allocator, size_of_elem); irValue *byte_count = ir_emit_arith(proc, Token_Mul, len, elem_size, t_int); irValue **args = gb_alloc_array(proc->module->allocator, irValue *, 3); args[0] = dst; args[1] = src; args[2] = byte_count; ir_emit_global_call(proc, "__mem_copy", args, 3); return len; } break; case BuiltinProc_swizzle: { ir_emit_comment(proc, str_lit("swizzle.begin")); irAddr vector_addr = ir_build_addr(proc, ce->args[0]); isize index_count = ce->args.count-1; if (index_count == 0) { return ir_addr_load(proc, vector_addr); } irValue *src = vector_addr.addr; irValue *dst = ir_add_local_generated(proc, tv.type); for (i32 i = 1; i < ce->args.count; i++) { TypeAndValue tv = type_and_value_of_expr(proc->module->info, ce->args[i]); GB_ASSERT(is_type_integer(tv.type)); GB_ASSERT(tv.value.kind == ExactValue_Integer); i32 src_index = cast(i32)i128_to_i64(tv.value.value_integer); i32 dst_index = i-1; irValue *src_elem = ir_emit_array_epi(proc, src, src_index); irValue *dst_elem = ir_emit_array_epi(proc, dst, dst_index); ir_emit_store(proc, dst_elem, ir_emit_load(proc, src_elem)); } ir_emit_comment(proc, str_lit("swizzle.end")); return ir_emit_load(proc, dst); // return ir_emit(proc, ir_instr_vector_shuffle(proc, vector, indices, index_count)); } break; case BuiltinProc_complex: { ir_emit_comment(proc, str_lit("complex")); irValue *real = ir_build_expr(proc, ce->args[0]); irValue *imag = ir_build_expr(proc, ce->args[1]); irValue *dst = ir_add_local_generated(proc, tv.type); Type *ft = base_complex_elem_type(tv.type); real = ir_emit_conv(proc, real, ft); imag = ir_emit_conv(proc, imag, ft); ir_emit_store(proc, ir_emit_struct_ep(proc, dst, 0), real); ir_emit_store(proc, ir_emit_struct_ep(proc, dst, 1), imag); return ir_emit_load(proc, dst); } break; case BuiltinProc_real: { ir_emit_comment(proc, str_lit("real")); irValue *val = ir_build_expr(proc, ce->args[0]); irValue *real = ir_emit_struct_ev(proc, val, 0); return ir_emit_conv(proc, real, tv.type); } break; case BuiltinProc_imag: { ir_emit_comment(proc, str_lit("imag")); irValue *val = ir_build_expr(proc, ce->args[0]); irValue *imag = ir_emit_struct_ev(proc, val, 1); return ir_emit_conv(proc, imag, tv.type); } break; case BuiltinProc_conj: { ir_emit_comment(proc, str_lit("conj")); irValue *val = ir_build_expr(proc, ce->args[0]); irValue *res = NULL; Type *t = ir_type(val); if (is_type_complex(t)) { res = ir_add_local_generated(proc, tv.type); irValue *real = ir_emit_struct_ev(proc, val, 0); irValue *imag = ir_emit_struct_ev(proc, val, 1); imag = ir_emit_unary_arith(proc, Token_Sub, imag, ir_type(imag)); ir_emit_store(proc, ir_emit_struct_ep(proc, res, 0), real); ir_emit_store(proc, ir_emit_struct_ep(proc, res, 1), imag); } return ir_emit_load(proc, res); } break; case BuiltinProc_slice_ptr: { ir_emit_comment(proc, str_lit("slice_ptr")); irValue *ptr = ir_build_expr(proc, ce->args[0]); irValue *count = ir_build_expr(proc, ce->args[1]); count = ir_emit_conv(proc, count, t_int); irValue *capacity = count; if (ce->args.count > 2) { capacity = ir_build_expr(proc, ce->args[2]); capacity = ir_emit_conv(proc, capacity, t_int); } Type *slice_type = make_type_slice(proc->module->allocator, type_deref(ir_type(ptr))); irValue *slice = ir_add_local_generated(proc, slice_type); ir_fill_slice(proc, slice, ptr, count, capacity); return ir_emit_load(proc, slice); } break; case BuiltinProc_slice_to_bytes: { ir_emit_comment(proc, str_lit("slice_to_bytes")); irValue *s = ir_build_expr(proc, ce->args[0]); Type *t = base_type(ir_type(s)); if (is_type_u8_slice(t)) { return ir_emit_conv(proc, s, tv.type); } irValue *slice = ir_add_local_generated(proc, tv.type); i64 elem_size = type_size_of(proc->module->allocator, t->Slice.elem); irValue *ptr = ir_emit_conv(proc, ir_slice_elem(proc, s), t_u8_ptr); irValue *count = ir_slice_count(proc, s); irValue *capacity = ir_slice_capacity(proc, s); count = ir_emit_arith(proc, Token_Mul, count, ir_const_int(proc->module->allocator, elem_size), t_int); capacity = ir_emit_arith(proc, Token_Mul, capacity, ir_const_int(proc->module->allocator, elem_size), t_int); ir_fill_slice(proc, slice, ptr, count, capacity); return ir_emit_load(proc, slice); } break; case BuiltinProc_expand_to_tuple: { ir_emit_comment(proc, str_lit("expand_to_tuple")); irValue *s = ir_build_expr(proc, ce->args[0]); Type *t = base_type(ir_type(s)); GB_ASSERT(t->kind == Type_Record); GB_ASSERT(is_type_tuple(tv.type)); irValue *tuple = ir_add_local_generated(proc, tv.type); for (isize src_index = 0; src_index < t->Record.field_count; src_index++) { Entity *field = t->Record.fields_in_src_order[src_index]; i32 field_index = field->Variable.field_index; irValue *f = ir_emit_struct_ev(proc, s, field_index); irValue *ep = ir_emit_struct_ep(proc, tuple, src_index); ir_emit_store(proc, ep, f); } return ir_emit_load(proc, tuple); } break; case BuiltinProc_min: { ir_emit_comment(proc, str_lit("min")); Type *t = type_of_expr(proc->module->info, expr); irValue *x = ir_emit_conv(proc, ir_build_expr(proc, ce->args[0]), t); irValue *y = ir_emit_conv(proc, ir_build_expr(proc, ce->args[1]), t); irValue *cond = ir_emit_comp(proc, Token_Lt, x, y); return ir_emit_select(proc, cond, x, y); } break; case BuiltinProc_max: { ir_emit_comment(proc, str_lit("max")); Type *t = type_of_expr(proc->module->info, expr); irValue *x = ir_emit_conv(proc, ir_build_expr(proc, ce->args[0]), t); irValue *y = ir_emit_conv(proc, ir_build_expr(proc, ce->args[1]), t); irValue *cond = ir_emit_comp(proc, Token_Gt, x, y); return ir_emit_select(proc, cond, x, y); } break; case BuiltinProc_abs: { ir_emit_comment(proc, str_lit("abs")); irValue *x = ir_build_expr(proc, ce->args[0]); Type *t = ir_type(x); if (is_type_complex(t)) { gbAllocator a = proc->module->allocator; i64 sz = 8*type_size_of(a, t); irValue **args = gb_alloc_array(a, irValue *, 1); args[0] = x; switch (sz) { case 64: return ir_emit_global_call(proc, "__abs_complex64", args, 1); case 128: return ir_emit_global_call(proc, "__abs_complex128", args, 1); } GB_PANIC("Unknown complex type"); } irValue *zero = ir_emit_conv(proc, v_zero, t); irValue *cond = ir_emit_comp(proc, Token_Lt, x, zero); irValue *neg = ir_emit(proc, ir_instr_unary_op(proc, Token_Sub, x, t)); return ir_emit_select(proc, cond, neg, x); } break; case BuiltinProc_clamp: { ir_emit_comment(proc, str_lit("clamp")); Type *t = type_of_expr(proc->module->info, expr); return ir_emit_clamp(proc, t, ir_build_expr(proc, ce->args[0]), ir_build_expr(proc, ce->args[1]), ir_build_expr(proc, ce->args[2])); } break; } GB_PANIC("Unhandled built-in procedure"); return NULL; } irValue *ir_build_expr(irProcedure *proc, AstNode *expr) { expr = unparen_expr(expr); TypeAndValue tv = type_and_value_of_expr(proc->module->info, expr); GB_ASSERT(tv.mode != Addressing_Invalid); if (tv.mode == Addressing_Type) { // // TODO(bill): Handle this correctly // i32 entry_index = type_info_index(proc->module->info, tv.type, false); // if (entry_index >= 0) { // irValue *ptr = ir_get_type_info_ptr(proc, tv.type); // return ir_emit_ptr_to_int(proc, ptr, t_type, true); // // i32 id = entry_index+1; // // return ir_value_constant(proc->module->allocator, t_int, exact_value_i64(id)); // } // return v_raw_nil; return ir_value_nil(proc->module->allocator, tv.type); } if (tv.value.kind != ExactValue_Invalid) { // NOTE(bill): Edge case if (tv.value.kind != ExactValue_Compound && is_type_vector(tv.type)) { Type *elem = base_vector_type(tv.type); ExactValue value = convert_exact_value_for_type(tv.value, elem); irValue *x = ir_add_module_constant(proc->module, elem, value); return ir_emit_conv(proc, x, tv.type); } return ir_add_module_constant(proc->module, tv.type, tv.value); } if (tv.mode == Addressing_Variable) { return ir_addr_load(proc, ir_build_addr(proc, expr)); } switch (expr->kind) { case_ast_node(bl, BasicLit, expr); TokenPos pos = bl->pos; GB_PANIC("Non-constant basic literal %.*s(%td:%td) - %.*s", LIT(pos.file), pos.line, pos.column, LIT(token_strings[bl->kind])); case_end; case_ast_node(bd, BasicDirective, expr); TokenPos pos = bd->token.pos; GB_PANIC("Non-constant basic literal %.*s(%td:%td) - %.*s", LIT(pos.file), pos.line, pos.column, LIT(bd->name)); case_end; case_ast_node(i, Implicit, expr); return ir_addr_load(proc, ir_build_addr(proc, expr)); case_end; case_ast_node(u, Undef, expr); return ir_value_undef(proc->module->allocator, tv.type); case_end; case_ast_node(i, Ident, expr); Entity *e = entity_of_ident(proc->module->info, expr); if (e->kind == Entity_Builtin) { Token token = ast_node_token(expr); GB_PANIC("TODO(bill): ir_build_single_expr Entity_Builtin `%.*s`\n" "\t at %.*s(%td:%td)", LIT(builtin_procs[e->Builtin.id].name), LIT(token.pos.file), token.pos.line, token.pos.column); return NULL; } else if (e->kind == Entity_Nil) { return ir_value_nil(proc->module->allocator, tv.type); } irValue **found = map_get(&proc->module->values, hash_entity(e)); if (found) { irValue *v = *found; if (v->kind == irValue_Proc) { return v; } // if (e->kind == Entity_Variable && e->Variable.param) { // return v; // } return ir_emit_load(proc, v); } else if (e != NULL && e->kind == Entity_Variable) { return ir_addr_load(proc, ir_build_addr(proc, expr)); } GB_PANIC("NULL value for expression from identifier: %.*s @ %p", LIT(i->token.string), expr); return NULL; case_end; case_ast_node(re, RunExpr, expr); // TODO(bill): Run Expression return ir_build_expr(proc, re->expr); case_end; case_ast_node(de, DerefExpr, expr); return ir_addr_load(proc, ir_build_addr(proc, expr)); case_end; case_ast_node(se, SelectorExpr, expr); TypeAndValue tav = type_and_value_of_expr(proc->module->info, expr); GB_ASSERT(tav.mode != Addressing_Invalid); return ir_addr_load(proc, ir_build_addr(proc, expr)); case_end; case_ast_node(te, TernaryExpr, expr); ir_emit_comment(proc, str_lit("TernaryExpr")); Array edges = {}; array_init(&edges, proc->module->allocator, 2); GB_ASSERT(te->y != NULL); irBlock *then = ir_new_block(proc, NULL, "if.then"); irBlock *done = ir_new_block(proc, NULL, "if.done"); // NOTE(bill): Append later irBlock *else_ = ir_new_block(proc, NULL, "if.else"); irValue *cond = ir_build_cond(proc, te->cond, then, else_); ir_start_block(proc, then); Type *type = type_of_expr(proc->module->info, expr); ir_open_scope(proc); array_add(&edges, ir_emit_conv(proc, ir_build_expr(proc, te->x), type)); ir_close_scope(proc, irDeferExit_Default, NULL); ir_emit_jump(proc, done); ir_start_block(proc, else_); ir_open_scope(proc); array_add(&edges, ir_emit_conv(proc, ir_build_expr(proc, te->y), type)); ir_close_scope(proc, irDeferExit_Default, NULL); ir_emit_jump(proc, done); ir_start_block(proc, done); return ir_emit(proc, ir_instr_phi(proc, edges, type)); case_end; #if 0 case_ast_node(ie, IfExpr, expr); ir_emit_comment(proc, str_lit("IfExpr")); if (ie->init != NULL) { irBlock *init = ir_new_block(proc, expr, "if.init"); ir_emit_jump(proc, init); ir_start_block(proc, init); ir_build_stmt(proc, ie->init); } Array edges = {}; array_init(&edges, proc->module->allocator, 2); GB_ASSERT(ie->else_expr != NULL); irBlock *then = ir_new_block(proc, expr, "if.then"); irBlock *done = ir_new_block(proc, expr, "if.done"); // NOTE(bill): Append later irBlock *else_ = ir_new_block(proc, ie->else_expr, "if.else"); irValue *cond = ir_build_cond(proc, ie->cond, then, else_); ir_start_block(proc, then); ir_open_scope(proc); array_add(&edges, ir_build_expr(proc, ie->body)); ir_close_scope(proc, irDeferExit_Default, NULL); ir_emit_jump(proc, done); ir_start_block(proc, else_); ir_open_scope(proc); array_add(&edges, ir_build_expr(proc, ie->else_expr)); ir_close_scope(proc, irDeferExit_Default, NULL); ir_emit_jump(proc, done); ir_start_block(proc, done); Type *type = type_of_expr(proc->module->info, expr); return ir_emit(proc, ir_instr_phi(proc, edges, type)); case_end; #endif case_ast_node(ta, TypeAssertion, expr); TokenPos pos = ast_node_token(expr).pos; Type *type = tv.type; irValue *e = ir_build_expr(proc, ta->expr); Type *t = type_deref(ir_type(e)); if (is_type_union(t)) { ir_emit_comment(proc, str_lit("cast - union_cast")); return ir_emit_union_cast(proc, e, type, pos); } else if (is_type_any(t)) { ir_emit_comment(proc, str_lit("cast - any_cast")); return ir_emit_any_cast(proc, e, type, pos); } else { GB_PANIC("TODO(bill): type assertion %s", type_to_string(ir_type(e))); } case_end; case_ast_node(ue, UnaryExpr, expr); switch (ue->op.kind) { case Token_And: return ir_emit_ptr_offset(proc, ir_build_addr(proc, ue->expr).addr, v_zero); // Make a copy of the pointer default: return ir_emit_unary_arith(proc, ue->op.kind, ir_build_expr(proc, ue->expr), tv.type); } case_end; case_ast_node(be, BinaryExpr, expr); irValue *left = ir_build_expr(proc, be->left); Type *type = default_type(tv.type); switch (be->op.kind) { case Token_Add: case Token_Sub: case Token_Mul: case Token_Quo: case Token_Mod: case Token_ModMod: case Token_And: case Token_Or: case Token_Xor: case Token_AndNot: case Token_Shl: case Token_Shr: { irValue *right = ir_build_expr(proc, be->right); return ir_emit_arith(proc, be->op.kind, left, right, type); } case Token_CmpEq: case Token_NotEq: case Token_Lt: case Token_LtEq: case Token_Gt: case Token_GtEq: { irValue *right = ir_build_expr(proc, be->right); irValue *cmp = ir_emit_comp(proc, be->op.kind, left, right); return ir_emit_conv(proc, cmp, type); } break; case Token_CmpAnd: case Token_CmpOr: return ir_emit_logical_binary_expr(proc, expr); default: GB_PANIC("Invalid binary expression"); break; } case_end; case_ast_node(pl, ProcLit, expr); // NOTE(bill): Generate a new name // parent$count isize name_len = proc->name.len + 1 + 8 + 1; u8 *name_text = gb_alloc_array(proc->module->allocator, u8, name_len); name_len = gb_snprintf(cast(char *)name_text, name_len, "%.*s$%d", LIT(proc->name), cast(i32)proc->children.count); String name = make_string(name_text, name_len-1); Type *type = type_of_expr(proc->module->info, expr); irValue *value = ir_value_procedure(proc->module->allocator, proc->module, NULL, type, pl->type, pl->body, name); value->Proc.tags = pl->tags; value->Proc.parent = proc; array_add(&proc->children, &value->Proc); array_add(&proc->module->procs_to_generate, value); return value; case_end; case_ast_node(cl, CompoundLit, expr); return ir_addr_load(proc, ir_build_addr(proc, expr)); case_end; case_ast_node(ce, CallExpr, expr); TypeAndValue proc_tv = type_and_value_of_expr(proc->module->info, ce->proc); AddressingMode proc_mode = proc_tv.mode; if (proc_mode == Addressing_Type) { GB_ASSERT(ce->args.count == 1); irValue *x = ir_build_expr(proc, ce->args[0]); irValue *y = ir_emit_conv(proc, x, tv.type); return y; } AstNode *p = unparen_expr(ce->proc); if (proc_mode == Addressing_Builtin) { Entity *e = entity_of_ident(proc->module->info, p); BuiltinProcId id = cast(BuiltinProcId)(e != NULL ? e->Builtin.id : BuiltinProc_DIRECTIVE); return ir_build_builtin_proc(proc, expr, tv, id); } // NOTE(bill): Regular call irValue *value = ir_build_expr(proc, ce->proc); GB_ASSERT(value != NULL); Type *proc_type_ = base_type(ir_type(value)); GB_ASSERT(proc_type_->kind == Type_Proc); TypeProc *type = &proc_type_->Proc; if (is_call_expr_field_value(ce)) { isize param_count = type->param_count; irValue **args = gb_alloc_array(proc->module->allocator, irValue *, param_count); for_array(arg_index, ce->args) { AstNode *arg = ce->args[arg_index]; ast_node(fv, FieldValue, arg); GB_ASSERT(fv->field->kind == AstNode_Ident); String name = fv->field->Ident.token.string; isize index = lookup_procedure_parameter(type, name); GB_ASSERT(index >= 0); irValue *expr = ir_build_expr(proc, fv->value); args[index] = expr; } TypeTuple *pt = &type->params->Tuple; for (isize i = 0; i < param_count; i++) { Entity *e = pt->variables[i]; if (e->kind == Entity_TypeName) { args[i] = ir_value_nil(proc->module->allocator, e->type); } else { GB_ASSERT(e->kind == Entity_Variable); if (args[i] == NULL) { if (e->Variable.default_value.kind != ExactValue_Invalid) { args[i] = ir_value_constant(proc->module->allocator, e->type, e->Variable.default_value); } else { args[i] = ir_value_nil(proc->module->allocator, e->type); } } else { args[i] = ir_emit_conv(proc, args[i], e->type); } } } return ir_emit_call(proc, value, args, param_count); } isize arg_index = 0; isize arg_count = 0; for_array(i, ce->args) { AstNode *a = ce->args[i]; Type *at = base_type(type_of_expr(proc->module->info, a)); if (at->kind == Type_Tuple) { arg_count += at->Tuple.variable_count; } else { arg_count++; } } irValue **args = gb_alloc_array(proc->module->allocator, irValue *, gb_max(type->param_count, arg_count)); bool variadic = type->variadic; bool vari_expand = ce->ellipsis.pos.line != 0; bool is_c_vararg = type->c_vararg; for_array(i, ce->args) { irValue *a = ir_build_expr(proc, ce->args[i]); Type *at = ir_type(a); if (at->kind == Type_Tuple) { for (isize i = 0; i < at->Tuple.variable_count; i++) { Entity *e = at->Tuple.variables[i]; irValue *v = ir_emit_struct_ev(proc, a, i); args[arg_index++] = v; } } else { args[arg_index++] = a; } } TypeTuple *pt = &type->params->Tuple; if (arg_count < type->param_count) { String procedure = {}; if (proc->entity != NULL) { procedure = proc->entity->token.string; } TokenPos pos = ast_node_token(ce->proc).pos; isize end = type->param_count; if (variadic) { end--; } while (arg_index < end) { Entity *e = pt->variables[arg_index]; GB_ASSERT(e->kind == Entity_Variable); if (e->Variable.default_value.kind != ExactValue_Invalid) { args[arg_index++] = ir_value_constant(proc->module->allocator, e->type, e->Variable.default_value); } else if (e->Variable.default_is_location) { args[arg_index++] = ir_emit_source_code_location(proc, procedure, pos); } else { args[arg_index++] = ir_value_nil(proc->module->allocator, e->type); } } } if (is_c_vararg) { GB_ASSERT(variadic); GB_ASSERT(!vari_expand); isize i = 0; for (; i < type->param_count-1; i++) { Entity *e = pt->variables[i]; if (e->kind == Entity_Variable) { args[i] = ir_emit_conv(proc, args[i], e->type); } } Type *variadic_type = pt->variables[i]->type; GB_ASSERT(is_type_slice(variadic_type)); variadic_type = base_type(variadic_type)->Slice.elem; if (!is_type_any(variadic_type)) { for (; i < arg_count; i++) { args[i] = ir_emit_conv(proc, args[i], variadic_type); } } else { for (; i < arg_count; i++) { args[i] = ir_emit_conv(proc, args[i], default_type(ir_type(args[i]))); } } } else if (variadic) { isize i = 0; for (; i < type->param_count-1; i++) { Entity *e = pt->variables[i]; if (e->kind == Entity_Variable) { args[i] = ir_emit_conv(proc, args[i], e->type); } } if (!vari_expand) { Type *variadic_type = pt->variables[i]->type; GB_ASSERT(is_type_slice(variadic_type)); variadic_type = base_type(variadic_type)->Slice.elem; for (; i < arg_count; i++) { args[i] = ir_emit_conv(proc, args[i], variadic_type); } } } else { for (isize i = 0; i < type->param_count; i++) { Entity *e = pt->variables[i]; if (e->kind == Entity_Variable) { args[i] = ir_emit_conv(proc, args[i], e->type); } } } i64 final_count = type->param_count; if (is_c_vararg) { final_count = arg_count; } if (variadic && !vari_expand && !is_c_vararg) { ir_emit_comment(proc, str_lit("variadic call argument generation")); gbAllocator allocator = proc->module->allocator; Type *slice_type = pt->variables[type->param_count-1]->type; Type *elem_type = base_type(slice_type)->Slice.elem; irValue *slice = ir_add_local_generated(proc, slice_type); isize slice_len = arg_count+1 - type->param_count; if (slice_len > 0) { irValue *base_array = ir_add_local_generated(proc, make_type_array(allocator, elem_type, slice_len)); for (isize i = type->param_count-1, j = 0; i < arg_count; i++, j++) { irValue *addr = ir_emit_array_epi(proc, base_array, j); ir_emit_store(proc, addr, args[i]); } irValue *base_elem = ir_emit_array_epi(proc, base_array, 0); irValue *len = ir_const_int(allocator, slice_len); ir_fill_slice(proc, slice, base_elem, len, len); } arg_count = type->param_count; args[arg_count-1] = ir_emit_load(proc, slice); } return ir_emit_call(proc, value, args, final_count); case_end; case_ast_node(se, SliceExpr, expr); return ir_addr_load(proc, ir_build_addr(proc, expr)); case_end; case_ast_node(ie, IndexExpr, expr); return ir_addr_load(proc, ir_build_addr(proc, expr)); case_end; } GB_PANIC("Unexpected expression: %.*s", LIT(ast_node_strings[expr->kind])); return NULL; } irValue *ir_get_using_variable(irProcedure *proc, Entity *e) { GB_ASSERT(e->kind == Entity_Variable && e->flags & EntityFlag_Using); String name = e->token.string; Entity *parent = e->using_parent; Selection sel = lookup_field(proc->module->allocator, parent->type, name, false); GB_ASSERT(sel.entity != NULL); irValue **pv = map_get(&proc->module->values, hash_entity(parent)); irValue *v = NULL; if (pv != NULL) { v = *pv; } else { GB_ASSERT_MSG(e->using_expr != NULL, "%.*s", LIT(name)); v = ir_build_addr(proc, e->using_expr).addr; } GB_ASSERT(v != NULL); GB_ASSERT(parent->type == type_deref(ir_type(v))); return ir_emit_deep_field_gep(proc, v, sel); } bool ir_is_elem_const(irModule *m, AstNode *elem, Type *elem_type) { if (base_type(elem_type) == t_any) { return false; } if (elem->kind == AstNode_FieldValue) { elem = elem->FieldValue.value; } TypeAndValue tav = type_and_value_of_expr(m->info, elem); GB_ASSERT(tav.mode != Addressing_Invalid); return tav.value.kind != ExactValue_Invalid; } irAddr ir_build_addr_from_entity(irProcedure *proc, Entity *e, AstNode *expr) { GB_ASSERT(e != NULL); GB_ASSERT(e->kind != Entity_Constant); irValue *v = NULL; irValue **found = map_get(&proc->module->values, hash_entity(e)); if (found) { v = *found; } else if (e->kind == Entity_Variable && e->flags & EntityFlag_Using) { // NOTE(bill): Calculate the using variable every time v = ir_get_using_variable(proc, e); } if (v == NULL) { GB_PANIC("Unknown value: %.*s, entity: %p %.*s\n", LIT(e->token.string), e, LIT(entity_strings[e->kind])); } return ir_addr(v); } irAddr ir_build_addr(irProcedure *proc, AstNode *expr) { switch (expr->kind) { case_ast_node(i, Implicit, expr); irValue *v = NULL; switch (i->kind) { case Token_context: v = ir_find_or_generate_context_ptr(proc); // v = ir_find_global_variable(proc, str_lit("__context")); break; } GB_ASSERT(v != NULL); return ir_addr(v); case_end; case_ast_node(i, Ident, expr); if (ir_is_blank_ident(expr)) { irAddr val = {}; return val; } Entity *e = entity_of_ident(proc->module->info, expr); return ir_build_addr_from_entity(proc, e, expr); case_end; case_ast_node(pe, ParenExpr, expr); return ir_build_addr(proc, unparen_expr(expr)); case_end; case_ast_node(se, SelectorExpr, expr); ir_emit_comment(proc, str_lit("SelectorExpr")); AstNode *sel = unparen_expr(se->selector); if (sel->kind == AstNode_Ident) { String selector = sel->Ident.token.string; TypeAndValue tav = type_and_value_of_expr(proc->module->info, se->expr); if (tav.mode == Addressing_Invalid) { // NOTE(bill): Imports Entity *imp = entity_of_ident(proc->module->info, se->expr); if (imp != NULL) { GB_ASSERT(imp->kind == Entity_ImportName); } return ir_build_addr(proc, unparen_expr(se->selector)); } Type *type = base_type(tav.type); if (tav.mode == Addressing_Type) { // Addressing_Type Selection sel = lookup_field(proc->module->allocator, type, selector, true); Entity *e = sel.entity; GB_ASSERT(e->kind == Entity_Variable); GB_ASSERT(e->flags & EntityFlag_TypeField); String name = e->token.string; if (name == "names") { irValue *ti_ptr = ir_type_info(proc, type); irValue *names_ptr = NULL; if (is_type_enum(type)) { irValue *enum_info = ir_emit_conv(proc, ti_ptr, t_type_info_enum_ptr); names_ptr = ir_emit_struct_ep(proc, enum_info, 3); } else if (type->kind == Type_Record) { irValue *record_info = ir_emit_conv(proc, ti_ptr, t_type_info_record_ptr); names_ptr = ir_emit_struct_ep(proc, record_info, 3); } return ir_addr(names_ptr); } else { GB_PANIC("Unhandled TypeField %.*s", LIT(name)); } GB_PANIC("Unreachable"); } Selection sel = lookup_field(proc->module->allocator, type, selector, false); GB_ASSERT(sel.entity != NULL); if (sel.entity->type->kind == Type_BitFieldValue) { irAddr addr = ir_build_addr(proc, se->expr); Type *bft = type_deref(ir_addr_type(addr)); if (sel.index.count == 1) { GB_ASSERT(is_type_bit_field(bft)); i32 index = sel.index[0]; return ir_addr_bit_field(addr.addr, index); } else { Selection s = sel; s.index.count--; i32 index = s.index[s.index.count-1]; irValue *a = addr.addr; a = ir_emit_deep_field_gep(proc, a, s); return ir_addr_bit_field(a, index); } } else { irValue *a = ir_build_addr(proc, se->expr).addr; a = ir_emit_deep_field_gep(proc, a, sel); return ir_addr(a); } } else { Type *type = type_deref(type_of_expr(proc->module->info, se->expr)); Type *selector_type = base_type(type_of_expr(proc->module->info, se->selector)); GB_ASSERT_MSG(is_type_integer(selector_type), "%s", type_to_string(selector_type)); ExactValue val = type_and_value_of_expr(proc->module->info, sel).value; i64 index = i128_to_i64(val.value_integer); Selection sel = lookup_field_from_index(proc->module->allocator, type, index); GB_ASSERT(sel.entity != NULL); irValue *a = ir_build_addr(proc, se->expr).addr; a = ir_emit_deep_field_gep(proc, a, sel); return ir_addr(a); } case_end; case_ast_node(ta, TypeAssertion, expr); gbAllocator a = proc->module->allocator; TokenPos pos = ast_node_token(expr).pos; irValue *e = ir_build_expr(proc, ta->expr); Type *t = type_deref(ir_type(e)); if (is_type_union(t)) { Type *type = type_of_expr(proc->module->info, expr); irValue *v = ir_add_local_generated(proc, type); ir_emit_comment(proc, str_lit("cast - union_cast")); ir_emit_store(proc, v, ir_emit_union_cast(proc, ir_build_expr(proc, ta->expr), type, pos)); return ir_addr(v); } else if (is_type_any(t)) { ir_emit_comment(proc, str_lit("cast - any_cast")); Type *type = type_of_expr(proc->module->info, expr); return ir_emit_any_cast_addr(proc, ir_build_expr(proc, ta->expr), type, pos); } else { GB_PANIC("TODO(bill): type assertion %s", type_to_string(ir_type(e))); } case_end; case_ast_node(ue, UnaryExpr, expr); switch (ue->op.kind) { case Token_And: { return ir_build_addr(proc, ue->expr); } default: GB_PANIC("Invalid unary expression for ir_build_addr"); } case_end; case_ast_node(be, BinaryExpr, expr); GB_PANIC("Invalid binary expression for ir_build_addr: %.*s\n", LIT(be->op.string)); case_end; case_ast_node(ie, IndexExpr, expr); ir_emit_comment(proc, str_lit("IndexExpr")); Type *t = base_type(type_of_expr(proc->module->info, ie->expr)); gbAllocator a = proc->module->allocator; bool deref = is_type_pointer(t); t = base_type(type_deref(t)); if (is_type_map(t)) { irAddr map_addr = ir_build_addr(proc, ie->expr); irValue *map_val = map_addr.addr; irValue *key = ir_build_expr(proc, ie->index); key = ir_emit_conv(proc, key, t->Map.key); Type *result_type = type_of_expr(proc->module->info, expr); return ir_addr_map(map_val, key, t, result_type); } irValue *using_addr = NULL; if (!is_type_indexable(t)) { // Using index expression Entity *using_field = find_using_index_expr(t); if (using_field != NULL) { Selection sel = lookup_field(a, t, using_field->token.string, false); irValue *e = ir_build_addr(proc, ie->expr).addr; using_addr = ir_emit_deep_field_gep(proc, e, sel); t = using_field->type; } } switch (t->kind) { case Type_Vector: { irValue *vector = NULL; if (using_addr != NULL) { vector = using_addr; } else { vector = ir_build_addr(proc, ie->expr).addr; if (deref) { vector = ir_emit_load(proc, vector); } } irValue *index = ir_emit_conv(proc, ir_build_expr(proc, ie->index), t_int); irValue *elem = ir_emit_array_ep(proc, vector, index); irValue *len = ir_const_int(a, t->Vector.count); ir_emit_bounds_check(proc, ast_node_token(ie->index), index, len); return ir_addr(elem); } break; case Type_Array: { irValue *array = NULL; if (using_addr != NULL) { array = using_addr; } else { array = ir_build_addr(proc, ie->expr).addr; if (deref) { array = ir_emit_load(proc, array); } } irValue *index = ir_emit_conv(proc, ir_build_expr(proc, ie->index), t_int); irValue *elem = ir_emit_array_ep(proc, array, index); irValue *len = ir_const_int(a, t->Vector.count); ir_emit_bounds_check(proc, ast_node_token(ie->index), index, len); return ir_addr(elem); } break; case Type_Slice: { irValue *slice = NULL; if (using_addr != NULL) { slice = ir_emit_load(proc, using_addr); } else { slice = ir_build_expr(proc, ie->expr); if (deref) { slice = ir_emit_load(proc, slice); } } irValue *elem = ir_slice_elem(proc, slice); irValue *len = ir_slice_count(proc, slice); irValue *index = ir_emit_conv(proc, ir_build_expr(proc, ie->index), t_int); ir_emit_bounds_check(proc, ast_node_token(ie->index), index, len); irValue *v = ir_emit_ptr_offset(proc, elem, index); return ir_addr(v); } break; case Type_DynamicArray: { irValue *dynamic_array = NULL; if (using_addr != NULL) { dynamic_array = ir_emit_load(proc, using_addr); } else { dynamic_array = ir_build_expr(proc, ie->expr); if (deref) { dynamic_array = ir_emit_load(proc, dynamic_array); } } irValue *elem = ir_dynamic_array_elem(proc, dynamic_array); irValue *len = ir_dynamic_array_count(proc, dynamic_array); irValue *index = ir_emit_conv(proc, ir_build_expr(proc, ie->index), t_int); ir_emit_bounds_check(proc, ast_node_token(ie->index), index, len); irValue *v = ir_emit_ptr_offset(proc, elem, index); return ir_addr(v); } break; case Type_Basic: { // Basic_string irValue *str; irValue *elem; irValue *len; irValue *index; if (using_addr != NULL) { str = ir_emit_load(proc, using_addr); } else { str = ir_build_expr(proc, ie->expr); if (deref) { str = ir_emit_load(proc, str); } } elem = ir_string_elem(proc, str); len = ir_string_len(proc, str); index = ir_emit_conv(proc, ir_build_expr(proc, ie->index), t_int); ir_emit_bounds_check(proc, ast_node_token(ie->index), index, len); return ir_addr(ir_emit_ptr_offset(proc, elem, index)); } break; } case_end; case_ast_node(se, SliceExpr, expr); ir_emit_comment(proc, str_lit("SliceExpr")); gbAllocator a = proc->module->allocator; irValue *low = v_zero; irValue *high = NULL; irValue *max = NULL; if (se->low != NULL) low = ir_build_expr(proc, se->low); if (se->high != NULL) high = ir_build_expr(proc, se->high); if (se->max != NULL) max = ir_build_expr(proc, se->max); if (high != NULL && se->interval0.kind == Token_Ellipsis) { high = ir_emit_arith(proc, Token_Add, high, v_one, t_int); } if (max != NULL && se->interval1.kind == Token_Ellipsis) { max = ir_emit_arith(proc, Token_Add, max, v_one, t_int); } irValue *addr = ir_build_addr(proc, se->expr).addr; irValue *base = ir_emit_load(proc, addr); Type *type = base_type(ir_type(base)); if (is_type_pointer(type)) { type = type_deref(type); addr = base; base = ir_emit_load(proc, base); } // TODO(bill): Cleanup like mad! switch (type->kind) { case Type_Slice: { Type *slice_type = type; if (high == NULL) high = ir_slice_count(proc, base); if (max == NULL) max = ir_slice_capacity(proc, base); ir_emit_slice_bounds_check(proc, se->open, low, high, max, false); irValue *elem = ir_emit_ptr_offset(proc, ir_slice_elem(proc, base), low); irValue *len = ir_emit_arith(proc, Token_Sub, high, low, t_int); irValue *cap = ir_emit_arith(proc, Token_Sub, max, low, t_int); irValue *slice = ir_add_local_generated(proc, slice_type); ir_fill_slice(proc, slice, elem, len, cap); return ir_addr(slice); } case Type_DynamicArray: { Type *elem_type = type->DynamicArray.elem; Type *slice_type = make_type_slice(a, elem_type); if (high == NULL) high = ir_dynamic_array_count(proc, base); if (max == NULL) max = ir_dynamic_array_capacity(proc, base); ir_emit_slice_bounds_check(proc, se->open, low, high, max, false); irValue *elem = ir_emit_ptr_offset(proc, ir_dynamic_array_elem(proc, base), low); irValue *len = ir_emit_arith(proc, Token_Sub, high, low, t_int); irValue *cap = ir_emit_arith(proc, Token_Sub, max, low, t_int); irValue *slice = ir_add_local_generated(proc, slice_type); ir_fill_slice(proc, slice, elem, len, cap); return ir_addr(slice); } case Type_Array: { Type *slice_type = make_type_slice(a, type->Array.elem); if (high == NULL) high = ir_array_len(proc, base); if (max == NULL) max = ir_array_len(proc, base); ir_emit_slice_bounds_check(proc, se->open, low, high, max, false); irValue *elem = ir_emit_ptr_offset(proc, ir_array_elem(proc, addr), low); irValue *len = ir_emit_arith(proc, Token_Sub, high, low, t_int); irValue *cap = ir_emit_arith(proc, Token_Sub, max, low, t_int); irValue *slice = ir_add_local_generated(proc, slice_type); ir_fill_slice(proc, slice, elem, len, cap); return ir_addr(slice); } case Type_Basic: { GB_ASSERT(type == t_string); if (high == NULL) high = ir_string_len(proc, base); // if (max == NULL) max = ir_string_len(proc, base); ir_emit_slice_bounds_check(proc, se->open, low, high, NULL, true); irValue *elem = ir_emit_ptr_offset(proc, ir_string_elem(proc, base), low); irValue *len = ir_emit_arith(proc, Token_Sub, high, low, t_int); irValue *str = ir_add_local_generated(proc, t_string); ir_fill_string(proc, str, elem, len); return ir_addr(str); } break; } GB_PANIC("Unknown slicable type"); case_end; case_ast_node(de, DerefExpr, expr); // TODO(bill): Is a ptr copy needed? irValue *addr = ir_build_expr(proc, de->expr); addr = ir_emit_ptr_offset(proc, addr, v_zero); return ir_addr(addr); case_end; case_ast_node(ce, CallExpr, expr); // NOTE(bill): This is make sure you never need to have an `array_ev` irValue *e = ir_build_expr(proc, expr); irValue *v = ir_add_local_generated(proc, ir_type(e)); ir_emit_store(proc, v, e); return ir_addr(v); case_end; case_ast_node(cl, CompoundLit, expr); ir_emit_comment(proc, str_lit("CompoundLit")); Type *type = type_of_expr(proc->module->info, expr); Type *bt = base_type(type); irValue *v = ir_add_local_generated(proc, type); Type *et = NULL; switch (bt->kind) { case Type_Vector: et = bt->Vector.elem; break; case Type_Array: et = bt->Array.elem; break; case Type_Slice: et = bt->Slice.elem; break; } switch (bt->kind) { default: GB_PANIC("Unknown CompoundLit type: %s", type_to_string(type)); break; case Type_Vector: { if (cl->elems.count == 1 && bt->Vector.count > 1) { isize index_count = bt->Vector.count; irValue *elem_val = ir_build_expr(proc, cl->elems[0]); for (isize i = 0; i < index_count; i++) { ir_emit_store(proc, ir_emit_array_epi(proc, v, i), elem_val); } } else if (cl->elems.count > 0) { ir_emit_store(proc, v, ir_add_module_constant(proc->module, type, exact_value_compound(expr))); for_array(i, cl->elems) { AstNode *elem = cl->elems[i]; if (ir_is_elem_const(proc->module, elem, et)) { continue; } irValue *field_expr = ir_build_expr(proc, elem); Type *t = ir_type(field_expr); GB_ASSERT(t->kind != Type_Tuple); irValue *ev = ir_emit_conv(proc, field_expr, et); irValue *gep = ir_emit_array_epi(proc, v, i); ir_emit_store(proc, gep, ev); } } } break; case Type_Record: { // TODO(bill): "constant" unions are not initialized constantly at the moment. // NOTE(bill): This is due to the layout of the unions when printed to LLVM-IR bool is_union = is_type_union(bt); GB_ASSERT(is_type_struct(bt) || is_type_union(bt)); TypeRecord *st = &bt->Record; if (cl->elems.count > 0) { ir_emit_store(proc, v, ir_add_module_constant(proc->module, type, exact_value_compound(expr))); for_array(field_index, cl->elems) { AstNode *elem = cl->elems[field_index]; irValue *field_expr = NULL; Entity *field = NULL; isize index = field_index; if (elem->kind == AstNode_FieldValue) { ast_node(fv, FieldValue, elem); String name = fv->field->Ident.token.string; Selection sel = lookup_field(proc->module->allocator, bt, name, false); index = sel.index[0]; elem = fv->value; } else { TypeAndValue tav = type_and_value_of_expr(proc->module->info, elem); Selection sel = lookup_field_from_index(proc->module->allocator, bt, st->fields_in_src_order[field_index]->Variable.field_src_index); index = sel.index[0]; } field = st->fields[index]; Type *ft = field->type; if (!is_union && !is_type_union(ft) && ir_is_elem_const(proc->module, elem, ft)) { continue; } field_expr = ir_build_expr(proc, elem); GB_ASSERT(ir_type(field_expr)->kind != Type_Tuple); irValue *fv = ir_emit_conv(proc, field_expr, ft); irValue *gep = ir_emit_struct_ep(proc, v, index); ir_emit_store(proc, gep, fv); } } } break; case Type_DynamicArray: { if (cl->elems.count == 0) { break; } Type *elem = bt->DynamicArray.elem; gbAllocator a = proc->module->allocator; irValue *size = ir_const_int(a, type_size_of(a, elem)); irValue *align = ir_const_int(a, type_align_of(a, elem)); { irValue **args = gb_alloc_array(a, irValue *, 4); args[0] = ir_emit_conv(proc, v, t_rawptr); args[1] = size; args[2] = align; args[3] = ir_const_int(a, 2*cl->elems.count); ir_emit_global_call(proc, "__dynamic_array_reserve", args, 4); } i64 item_count = cl->elems.count; irValue *items = ir_generate_array(proc->module, elem, item_count, str_lit("__dacl$"), cast(i64)cast(intptr)expr); for_array(field_index, cl->elems) { AstNode *f = cl->elems[field_index]; irValue *value = ir_emit_conv(proc, ir_build_expr(proc, f), elem); irValue *ep = ir_emit_array_epi(proc, items, field_index); ir_emit_store(proc, ep, value); } { irValue **args = gb_alloc_array(a, irValue *, 5); args[0] = ir_emit_conv(proc, v, t_rawptr); args[1] = size; args[2] = align; args[3] = ir_emit_conv(proc, items, t_rawptr); args[4] = ir_const_int(a, item_count); ir_emit_global_call(proc, "__dynamic_array_append", args, 5); } } break; case Type_Map: { if (cl->elems.count == 0) { break; } gbAllocator a = proc->module->allocator; { irValue **args = gb_alloc_array(a, irValue *, 2); args[0] = ir_gen_map_header(proc, v, type); args[1] = ir_const_int(a, 2*cl->elems.count); ir_emit_global_call(proc, "__dynamic_map_reserve", args, 2); } for_array(field_index, cl->elems) { AstNode *elem = cl->elems[field_index]; ast_node(fv, FieldValue, elem); irValue *key = ir_build_expr(proc, fv->field); irValue *value = ir_build_expr(proc, fv->value); ir_insert_dynamic_map_key_and_value(proc, v, type, key, value); } } break; case Type_Array: { if (cl->elems.count > 0) { ir_emit_store(proc, v, ir_add_module_constant(proc->module, type, exact_value_compound(expr))); for_array(i, cl->elems) { AstNode *elem = cl->elems[i]; if (ir_is_elem_const(proc->module, elem, et)) { continue; } irValue *field_expr = ir_build_expr(proc, elem); Type *t = ir_type(field_expr); GB_ASSERT(t->kind != Type_Tuple); irValue *ev = ir_emit_conv(proc, field_expr, et); irValue *gep = ir_emit_array_epi(proc, v, i); ir_emit_store(proc, gep, ev); } } } break; case Type_Slice: { if (cl->elems.count > 0) { Type *elem_type = bt->Slice.elem; Type *elem_ptr_type = make_type_pointer(proc->module->allocator, elem_type); Type *elem_ptr_ptr_type = make_type_pointer(proc->module->allocator, elem_ptr_type); irValue *slice = ir_add_module_constant(proc->module, type, exact_value_compound(expr)); GB_ASSERT(slice->kind == irValue_ConstantSlice); irValue *data = ir_emit_array_ep(proc, slice->ConstantSlice.backing_array, v_zero32); for_array(i, cl->elems) { AstNode *elem = cl->elems[i]; if (ir_is_elem_const(proc->module, elem, et)) { continue; } irValue *field_expr = ir_build_expr(proc, elem); Type *t = ir_type(field_expr); GB_ASSERT(t->kind != Type_Tuple); irValue *ev = ir_emit_conv(proc, field_expr, elem_type); irValue *offset = ir_emit_ptr_offset(proc, data, ir_const_int(proc->module->allocator, i)); ir_emit_store(proc, offset, ev); } irValue *count = ir_const_int(proc->module->allocator, slice->ConstantSlice.count); ir_fill_slice(proc, v, data, count, count); } } break; case Type_Basic: { GB_ASSERT(is_type_any(bt)); if (cl->elems.count > 0) { ir_emit_store(proc, v, ir_add_module_constant(proc->module, type, exact_value_compound(expr))); String field_names[2] = { str_lit("data"), str_lit("type_info"), }; Type *field_types[2] = { t_rawptr, t_type_info_ptr, }; for_array(field_index, cl->elems) { AstNode *elem = cl->elems[field_index]; irValue *field_expr = NULL; isize index = field_index; if (elem->kind == AstNode_FieldValue) { ast_node(fv, FieldValue, elem); Selection sel = lookup_field(proc->module->allocator, bt, fv->field->Ident.token.string, false); index = sel.index[0]; elem = fv->value; } else { TypeAndValue tav = type_and_value_of_expr(proc->module->info, elem); Selection sel = lookup_field(proc->module->allocator, bt, field_names[field_index], false); index = sel.index[0]; } field_expr = ir_build_expr(proc, elem); GB_ASSERT(ir_type(field_expr)->kind != Type_Tuple); Type *ft = field_types[index]; irValue *fv = ir_emit_conv(proc, field_expr, ft); irValue *gep = ir_emit_struct_ep(proc, v, index); ir_emit_store(proc, gep, fv); } } } } return ir_addr(v); case_end; } TokenPos token_pos = ast_node_token(expr).pos; GB_PANIC("Unexpected address expression\n" "\tAstNode: %.*s @ " "%.*s(%td:%td)\n", LIT(ast_node_strings[expr->kind]), LIT(token_pos.file), token_pos.line, token_pos.column); return ir_addr(NULL); } void ir_build_assign_op(irProcedure *proc, irAddr lhs, irValue *value, TokenKind op) { irValue *old_value = ir_addr_load(proc, lhs); Type *type = ir_type(old_value); irValue *change = value; if (is_type_pointer(type) && is_type_integer(ir_type(value))) { change = ir_emit_conv(proc, value, default_type(ir_type(value))); } else { change = ir_emit_conv(proc, value, type); } irValue *new_value = ir_emit_arith(proc, op, old_value, change, type); ir_addr_store(proc, lhs, new_value); } irValue *ir_build_cond(irProcedure *proc, AstNode *cond, irBlock *true_block, irBlock *false_block) { switch (cond->kind) { case_ast_node(pe, ParenExpr, cond); return ir_build_cond(proc, pe->expr, true_block, false_block); case_end; case_ast_node(ue, UnaryExpr, cond); if (ue->op.kind == Token_Not) { return ir_build_cond(proc, ue->expr, false_block, true_block); } case_end; case_ast_node(be, BinaryExpr, cond); if (be->op.kind == Token_CmpAnd) { irBlock *block = ir_new_block(proc, NULL, "cmp.and"); ir_build_cond(proc, be->left, block, false_block); ir_start_block(proc, block); return ir_build_cond(proc, be->right, true_block, false_block); } else if (be->op.kind == Token_CmpOr) { irBlock *block = ir_new_block(proc, NULL, "cmp.or"); ir_build_cond(proc, be->left, true_block, block); ir_start_block(proc, block); return ir_build_cond(proc, be->right, true_block, false_block); } case_end; } irValue *v = ir_build_expr(proc, cond); v = ir_emit_conv(proc, v, t_bool); ir_emit_if(proc, v, true_block, false_block); return v; } void ir_build_stmt_list(irProcedure *proc, Array stmts) { for_array(i, stmts) { ir_build_stmt(proc, stmts[i]); } } void ir_build_stmt_internal(irProcedure *proc, AstNode *node); void ir_build_stmt(irProcedure *proc, AstNode *node) { u32 prev_stmt_state_flags = proc->module->stmt_state_flags; if (node->stmt_state_flags != 0) { u32 in = node->stmt_state_flags; u32 out = proc->module->stmt_state_flags; if (in & StmtStateFlag_bounds_check) { out |= StmtStateFlag_bounds_check; out &= ~StmtStateFlag_no_bounds_check; } else if (in & StmtStateFlag_no_bounds_check) { out |= StmtStateFlag_no_bounds_check; out &= ~StmtStateFlag_bounds_check; } proc->module->stmt_state_flags = out; } ir_build_stmt_internal(proc, node); proc->module->stmt_state_flags = prev_stmt_state_flags; } void ir_build_when_stmt(irProcedure *proc, AstNodeWhenStmt *ws) { irValue *cond = ir_build_expr(proc, ws->cond); GB_ASSERT(cond->kind == irValue_Constant && is_type_boolean(ir_type(cond))); GB_ASSERT(cond->Constant.value.kind == ExactValue_Bool); if (cond->Constant.value.value_bool) { ir_build_stmt_list(proc, ws->body->BlockStmt.stmts); } else if (ws->else_stmt) { switch (ws->else_stmt->kind) { case AstNode_BlockStmt: ir_build_stmt_list(proc, ws->else_stmt->BlockStmt.stmts); break; case AstNode_WhenStmt: ir_build_when_stmt(proc, &ws->else_stmt->WhenStmt); break; default: GB_PANIC("Invalid `else` statement in `when` statement"); break; } } } void ir_emit_increment(irProcedure *proc, irValue *addr) { GB_ASSERT(is_type_pointer(ir_type(addr))); Type *type = type_deref(ir_type(addr)); ir_emit_store(proc, addr, ir_emit_arith(proc, Token_Add, ir_emit_load(proc, addr), v_one, type)); } void ir_build_range_indexed(irProcedure *proc, irValue *expr, Type *val_type, irValue *count_ptr, irValue **val_, irValue **idx_, irBlock **loop_, irBlock **done_) { irValue *count = NULL; Type *expr_type = base_type(type_deref(ir_type(expr))); switch (expr_type->kind) { case Type_Array: count = ir_const_int(proc->module->allocator, expr_type->Array.count); break; case Type_Vector: count = ir_const_int(proc->module->allocator, expr_type->Vector.count); break; } irValue *val = NULL; irValue *idx = NULL; irBlock *loop = NULL; irBlock *done = NULL; irBlock *body = NULL; irValue *key = NULL; if (expr_type->kind == Type_Map) { key = ir_add_local_generated(proc, expr_type->Map.key); } irValue *index = ir_add_local_generated(proc, t_int); ir_emit_store(proc, index, ir_const_int(proc->module->allocator, -1)); loop = ir_new_block(proc, NULL, "for.index.loop"); ir_emit_jump(proc, loop); ir_start_block(proc, loop); irValue *incr = ir_emit_arith(proc, Token_Add, ir_emit_load(proc, index), v_one, t_int); ir_emit_store(proc, index, incr); body = ir_new_block(proc, NULL, "for.index.body"); done = ir_new_block(proc, NULL, "for.index.done"); if (count == NULL) { count = ir_emit_load(proc, count_ptr); } irValue *cond = ir_emit_comp(proc, Token_Lt, incr, count); ir_emit_if(proc, cond, body, done); ir_start_block(proc, body); idx = ir_emit_load(proc, index); if (val_type != NULL) { switch (expr_type->kind) { case Type_Array: { val = ir_emit_load(proc, ir_emit_array_ep(proc, expr, idx)); } break; case Type_Vector: { val = ir_emit_load(proc, ir_emit_array_ep(proc, expr, idx)); } break; case Type_Slice: { irValue *elem = ir_slice_elem(proc, expr); val = ir_emit_load(proc, ir_emit_ptr_offset(proc, elem, idx)); } break; case Type_DynamicArray: { irValue *elem = ir_emit_struct_ep(proc, expr, 0); elem = ir_emit_load(proc, elem); val = ir_emit_load(proc, ir_emit_ptr_offset(proc, elem, idx)); } break; case Type_Map: { irValue *entries = ir_emit_struct_ep(proc, expr, 1); irValue *elem = ir_emit_struct_ep(proc, entries, 0); elem = ir_emit_load(proc, elem); irValue *entry = ir_emit_ptr_offset(proc, elem, idx); val = ir_emit_load(proc, ir_emit_struct_ep(proc, entry, 2)); irValue *hash = ir_emit_struct_ep(proc, entry, 0); if (is_type_string(expr_type->Map.key)) { irValue *str = ir_emit_struct_ep(proc, hash, 1); ir_emit_store(proc, key, ir_emit_load(proc, str)); } else { irValue *hash_ptr = ir_emit_struct_ep(proc, hash, 0); hash_ptr = ir_emit_conv(proc, hash_ptr, ir_type(key)); ir_emit_store(proc, key, ir_emit_load(proc, hash_ptr)); } } break; default: GB_PANIC("Cannot do range_indexed of %s", type_to_string(expr_type)); break; } } if (key != NULL) { idx = ir_emit_load(proc, key); } if (val_) *val_ = val; if (idx_) *idx_ = idx; if (loop_) *loop_ = loop; if (done_) *done_ = done; } void ir_build_range_string(irProcedure *proc, irValue *expr, Type *val_type, irValue **val_, irValue **idx_, irBlock **loop_, irBlock **done_) { irValue *count = v_zero; Type *expr_type = base_type(ir_type(expr)); switch (expr_type->kind) { case Type_Basic: count = ir_string_len(proc, expr); break; default: GB_PANIC("Cannot do range_string of %s", type_to_string(expr_type)); break; } irValue *val = NULL; irValue *idx = NULL; irBlock *loop = NULL; irBlock *done = NULL; irBlock *body = NULL; irValue *offset_ = ir_add_local_generated(proc, t_int); ir_emit_store(proc, offset_, v_zero); loop = ir_new_block(proc, NULL, "for.string.loop"); ir_emit_jump(proc, loop); ir_start_block(proc, loop); body = ir_new_block(proc, NULL, "for.string.body"); done = ir_new_block(proc, NULL, "for.string.done"); irValue *offset = ir_emit_load(proc, offset_); irValue *cond = ir_emit_comp(proc, Token_Lt, offset, count); ir_emit_if(proc, cond, body, done); ir_start_block(proc, body); irValue *str_elem = ir_emit_ptr_offset(proc, ir_string_elem(proc, expr), offset); irValue *str_len = ir_emit_arith(proc, Token_Sub, count, offset, t_int); irValue **args = gb_alloc_array(proc->module->allocator, irValue *, 1); args[0] = ir_emit_string(proc, str_elem, str_len); irValue *rune_and_len = ir_emit_global_call(proc, "__string_decode_rune", args, 1); irValue *len = ir_emit_struct_ev(proc, rune_and_len, 1); ir_emit_store(proc, offset_, ir_emit_arith(proc, Token_Add, offset, len, t_int)); idx = offset; if (val_type != NULL) { val = ir_emit_struct_ev(proc, rune_and_len, 0); } if (val_) *val_ = val; if (idx_) *idx_ = idx; if (loop_) *loop_ = loop; if (done_) *done_ = done; } void ir_build_range_interval(irProcedure *proc, AstNodeBinaryExpr *node, Type *val_type, irValue **val_, irValue **idx_, irBlock **loop_, irBlock **done_) { // TODO(bill): How should the behaviour work for lower and upper bounds checking for iteration? // If `lower` is changed, should `val` do so or is that not typical behaviour? irValue *lower = ir_build_expr(proc, node->left); irValue *upper = NULL; irValue *val = NULL; irValue *idx = NULL; irBlock *loop = NULL; irBlock *done = NULL; irBlock *body = NULL; if (val_type == NULL) { val_type = ir_type(lower); } irValue *value = ir_add_local_generated(proc, val_type); ir_emit_store(proc, value, lower); irValue *index = ir_add_local_generated(proc, t_int); ir_emit_store(proc, index, ir_const_int(proc->module->allocator, 0)); loop = ir_new_block(proc, NULL, "for.interval.loop"); ir_emit_jump(proc, loop); ir_start_block(proc, loop); body = ir_new_block(proc, NULL, "for.interval.body"); done = ir_new_block(proc, NULL, "for.interval.done"); TokenKind op = Token_Lt; switch (node->op.kind) { case Token_Ellipsis: op = Token_LtEq; break; case Token_HalfClosed: op = Token_Lt; break; default: GB_PANIC("Invalid interval operator"); break; } upper = ir_build_expr(proc, node->right); irValue *cond = ir_emit_comp(proc, op, ir_emit_load(proc, value), upper); ir_emit_if(proc, cond, body, done); ir_start_block(proc, body); if (value != NULL) { val = ir_emit_load(proc, value); } idx = ir_emit_load(proc, index); ir_emit_increment(proc, value); ir_emit_increment(proc, index); if (val_) *val_ = val; if (idx_) *idx_ = idx; if (loop_) *loop_ = loop; if (done_) *done_ = done; } void ir_store_type_case_implicit(irProcedure *proc, AstNode *clause, irValue *value) { Entity *e = implicit_entity_of_node(proc->module->info, clause); GB_ASSERT(e != NULL); irValue *x = ir_add_local(proc, e, NULL, false); ir_emit_store(proc, x, value); } void ir_type_case_body(irProcedure *proc, AstNode *label, AstNode *clause, irBlock *body, irBlock *done) { ast_node(cc, CaseClause, clause); ir_push_target_list(proc, label, done, NULL, NULL); ir_open_scope(proc); ir_build_stmt_list(proc, cc->stmts); ir_close_scope(proc, irDeferExit_Default, body); ir_pop_target_list(proc); ir_emit_jump(proc, done); } void ir_build_poly_proc(irProcedure *proc, AstNodeProcLit *pd, Entity *e) { GB_ASSERT(pd->body != NULL); if (is_entity_in_dependency_map(&proc->module->min_dep_map, e) == false) { // NOTE(bill): Nothing depends upon it so doesn't need to be built return; } // NOTE(bill): Generate a new name // parent.name-guid String original_name = e->token.string; String pd_name = original_name; if (pd->link_name.len > 0) { pd_name = pd->link_name; } isize name_len = proc->name.len + 1 + pd_name.len + 1 + 10 + 1; u8 *name_text = gb_alloc_array(proc->module->allocator, u8, name_len); i32 guid = cast(i32)proc->children.count; name_len = gb_snprintf(cast(char *)name_text, name_len, "%.*s.%.*s-%d", LIT(proc->name), LIT(pd_name), guid); String name = make_string(name_text, name_len-1); irValue *value = ir_value_procedure(proc->module->allocator, proc->module, e, e->type, pd->type, pd->body, name); value->Proc.tags = pd->tags; value->Proc.parent = proc; ir_module_add_value(proc->module, e, value); array_add(&proc->children, &value->Proc); array_add(&proc->module->procs_to_generate, value); } void ir_build_stmt_internal(irProcedure *proc, AstNode *node) { switch (node->kind) { case_ast_node(bs, EmptyStmt, node); case_end; case_ast_node(fb, ForeignBlockDecl, node); for_array(i, fb->decls) { ir_build_stmt(proc, fb->decls[i]); } case_end; case_ast_node(us, UsingStmt, node); for_array(i, us->list) { AstNode *decl = unparen_expr(us->list[i]); if (decl->kind == AstNode_GenDecl) { ir_build_stmt(proc, decl); } } case_end; case_ast_node(ws, WhenStmt, node); ir_build_when_stmt(proc, ws); case_end; case_ast_node(s, IncDecStmt, node); TokenKind op = Token_Add; if (s->op.kind == Token_Dec) { op = Token_Sub; } irAddr addr = ir_build_addr(proc, s->expr); ir_build_assign_op(proc, addr, v_one, op); case_end; case_ast_node(vd, ValueDecl, node); if (vd->is_mutable) { irModule *m = proc->module; gbTempArenaMemory tmp = gb_temp_arena_memory_begin(&m->tmp_arena); if (vd->values.count == 0) { // declared and zero-initialized for_array(i, vd->names) { AstNode *name = vd->names[i]; if (!ir_is_blank_ident(name)) { ir_add_local_for_identifier(proc, name, true); } } } else { // Tuple(s) Array lvals = {}; Array inits = {}; array_init(&lvals, m->tmp_allocator, vd->names.count); array_init(&inits, m->tmp_allocator, vd->names.count); for_array(i, vd->names) { AstNode *name = vd->names[i]; irAddr lval = ir_addr(NULL); if (!ir_is_blank_ident(name)) { ir_add_local_for_identifier(proc, name, false); lval = ir_build_addr(proc, name); } array_add(&lvals, lval); } for_array(i, vd->values) { irValue *init = ir_build_expr(proc, vd->values[i]); Type *t = ir_type(init); if (t->kind == Type_Tuple) { for (isize i = 0; i < t->Tuple.variable_count; i++) { Entity *e = t->Tuple.variables[i]; irValue *v = ir_emit_struct_ev(proc, init, i); array_add(&inits, v); } } else { array_add(&inits, init); } } for_array(i, inits) { ir_addr_store(proc, lvals[i], inits[i]); } } gb_temp_arena_memory_end(tmp); } else { for_array(i, vd->names) { AstNode *ident = vd->names[i]; GB_ASSERT(ident->kind == AstNode_Ident); Entity *e = entity_of_ident(proc->module->info, ident); GB_ASSERT(e != NULL); if (e->kind == Entity_TypeName) { // NOTE(bill): Generate a new name // parent_proc.name-guid String ts_name = e->token.string; isize name_len = proc->name.len + 1 + ts_name.len + 1 + 10 + 1; u8 *name_text = gb_alloc_array(proc->module->allocator, u8, name_len); i32 guid = cast(i32)proc->module->members.entries.count; name_len = gb_snprintf(cast(char *)name_text, name_len, "%.*s.%.*s-%d", LIT(proc->name), LIT(ts_name), guid); String name = make_string(name_text, name_len-1); irValue *value = ir_value_type_name(proc->module->allocator, name, e->type); map_set(&proc->module->entity_names, hash_entity(e), name); ir_gen_global_type_name(proc->module, e, name); } else if (e->kind == Entity_Procedure) { CheckerInfo *info = proc->module->info; DeclInfo *decl = decl_info_of_entity(info, e); ast_node(pl, ProcLit, decl->proc_lit); if (pl->body != NULL) { if (is_type_poly_proc(e->type)) { auto found = *map_get(&info->gen_procs, hash_pointer(ident)); for_array(i, found) { Entity *e = found[i]; DeclInfo *d = decl_info_of_entity(info, e); ir_build_poly_proc(proc, &d->proc_lit->ProcLit, e); } } else { ir_build_poly_proc(proc, pl, e); } } else { // FFI - Foreign function interace String original_name = e->token.string; String name = original_name; if (pl->link_name.len > 0) { name = pl->link_name; } irValue *value = ir_value_procedure(proc->module->allocator, proc->module, e, e->type, pl->type, pl->body, name); value->Proc.tags = pl->tags; ir_module_add_value(proc->module, e, value); ir_build_proc(value, proc); if (value->Proc.tags & ProcTag_foreign) { HashKey key = hash_string(name); irValue **prev_value = map_get(&proc->module->members, key); if (prev_value == NULL) { // NOTE(bill): Don't do mutliple declarations in the IR map_set(&proc->module->members, key, value); } } else { array_add(&proc->children, &value->Proc); } } } } } case_end; case_ast_node(as, AssignStmt, node); ir_emit_comment(proc, str_lit("AssignStmt")); irModule *m = proc->module; gbTempArenaMemory tmp = gb_temp_arena_memory_begin(&m->tmp_arena); switch (as->op.kind) { case Token_Eq: { Array lvals; array_init(&lvals, m->tmp_allocator); for_array(i, as->lhs) { AstNode *lhs = as->lhs[i]; irAddr lval = {}; if (!ir_is_blank_ident(lhs)) { lval = ir_build_addr(proc, lhs); } array_add(&lvals, lval); } if (as->lhs.count == as->rhs.count) { if (as->lhs.count == 1) { AstNode *rhs = as->rhs[0]; irValue *init = ir_build_expr(proc, rhs); ir_addr_store(proc, lvals[0], init); } else { Array inits; array_init(&inits, m->tmp_allocator, lvals.count); for_array(i, as->rhs) { irValue *init = ir_build_expr(proc, as->rhs[i]); array_add(&inits, init); } for_array(i, inits) { ir_addr_store(proc, lvals[i], inits[i]); } } } else { Array inits; array_init(&inits, m->tmp_allocator, lvals.count); for_array(i, as->rhs) { irValue *init = ir_build_expr(proc, as->rhs[i]); Type *t = ir_type(init); // TODO(bill): refactor for code reuse as this is repeated a bit if (t->kind == Type_Tuple) { for (isize i = 0; i < t->Tuple.variable_count; i++) { Entity *e = t->Tuple.variables[i]; irValue *v = ir_emit_struct_ev(proc, init, i); array_add(&inits, v); } } else { array_add(&inits, init); } } for_array(i, inits) { ir_addr_store(proc, lvals[i], inits[i]); } } } break; default: { // NOTE(bill): Only 1 += 1 is allowed, no tuples // +=, -=, etc i32 op = cast(i32)as->op.kind; op += Token_Add - Token_AddEq; // Convert += to + irAddr lhs = ir_build_addr(proc, as->lhs[0]); irValue *value = ir_build_expr(proc, as->rhs[0]); ir_build_assign_op(proc, lhs, value, cast(TokenKind)op); } break; } gb_temp_arena_memory_end(tmp); case_end; case_ast_node(es, ExprStmt, node); // NOTE(bill): No need to use return value ir_build_expr(proc, es->expr); case_end; case_ast_node(bs, BlockStmt, node); ir_open_scope(proc); ir_build_stmt_list(proc, bs->stmts); ir_close_scope(proc, irDeferExit_Default, NULL); case_end; case_ast_node(ds, DeferStmt, node); ir_emit_comment(proc, str_lit("DeferStmt")); isize scope_index = proc->scope_index; if (ds->stmt->kind == AstNode_BlockStmt) { scope_index--; } ir_add_defer_node(proc, scope_index, ds->stmt); case_end; case_ast_node(rs, ReturnStmt, node); ir_emit_comment(proc, str_lit("ReturnStmt")); irValue *v = NULL; TypeTuple *tuple = &proc->type->Proc.results->Tuple; isize return_count = proc->type->Proc.result_count; isize res_count = rs->results.count; if (res_count > 0 && rs->results[0]->kind == AstNode_FieldValue) { gbTempArenaMemory tmp = gb_temp_arena_memory_begin(&proc->module->tmp_arena); defer (gb_temp_arena_memory_end(tmp)); Array results; array_init_count(&results, proc->module->tmp_allocator, return_count); for_array(arg_index, rs->results) { AstNode *arg = rs->results[arg_index]; ast_node(fv, FieldValue, arg); GB_ASSERT(fv->field->kind == AstNode_Ident); String name = fv->field->Ident.token.string; isize index = lookup_procedure_result(&proc->type->Proc, name); GB_ASSERT(index >= 0); irValue *expr = ir_build_expr(proc, fv->value); results[index] = expr; } for (isize i = 0; i < return_count; i++) { Entity *e = tuple->variables[i]; GB_ASSERT(e->kind == Entity_Variable); if (results[i] == NULL) { if (e->Variable.default_value.kind != ExactValue_Invalid) { results[i] = ir_value_constant(proc->module->allocator, e->type, e->Variable.default_value); } else { results[i] = ir_value_nil(proc->module->allocator, e->type); } } else { results[i] = ir_emit_conv(proc, results[i], e->type); } } if (results.count == 1) { v = results[0]; } else { GB_ASSERT(results.count == return_count); Type *ret_type = proc->type->Proc.results; v = ir_add_local_generated(proc, ret_type); for_array(i, results) { irValue *field = ir_emit_struct_ep(proc, v, i); irValue *res = results[i]; ir_emit_store(proc, field, res); } v = ir_emit_load(proc, v); } } else if (return_count == 0) { // No return values } else if (return_count == 1) { Entity *e = tuple->variables[0]; if (res_count == 0) { if (e->Variable.default_value.kind != ExactValue_Invalid) { v = ir_value_constant(proc->module->allocator, e->type, e->Variable.default_value); } else { v = ir_value_nil(proc->module->allocator, e->type); } } else { v = ir_build_expr(proc, rs->results[0]); v = ir_emit_conv(proc, v, e->type); } } else { gbTempArenaMemory tmp = gb_temp_arena_memory_begin(&proc->module->tmp_arena); defer (gb_temp_arena_memory_end(tmp)); Array results; array_init(&results, proc->module->tmp_allocator, return_count); isize total_index = 0; isize res_index = 0; for (; res_index < res_count; res_index++) { irValue *res = ir_build_expr(proc, rs->results[res_index]); Type *t = ir_type(res); if (t->kind == Type_Tuple) { for (isize i = 0; i < t->Tuple.variable_count; i++) { Entity *e = t->Tuple.variables[i]; irValue *v = ir_emit_struct_ev(proc, res, i); array_add(&results, v); total_index++; } } else { array_add(&results, res); total_index++; } } while (total_index < return_count) { Entity *e = tuple->variables[total_index]; irValue *res = NULL; if (e->Variable.default_value.kind != ExactValue_Invalid) { res = ir_value_constant(proc->module->allocator, e->type, e->Variable.default_value); } else { res = ir_value_nil(proc->module->allocator, e->type); } array_add(&results, res); total_index++; } GB_ASSERT(results.count == return_count); Type *ret_type = proc->type->Proc.results; v = ir_add_local_generated(proc, ret_type); for_array(i, results) { Entity *e = tuple->variables[i]; irValue *res = ir_emit_conv(proc, results[i], e->type); irValue *field = ir_emit_struct_ep(proc, v, i); ir_emit_store(proc, field, res); } v = ir_emit_load(proc, v); } ir_emit_return(proc, v); case_end; case_ast_node(is, IfStmt, node); ir_emit_comment(proc, str_lit("IfStmt")); if (is->init != NULL) { irBlock *init = ir_new_block(proc, node, "if.init"); ir_emit_jump(proc, init); ir_start_block(proc, init); ir_build_stmt(proc, is->init); } irBlock *then = ir_new_block(proc, node, "if.then"); irBlock *done = ir_new_block(proc, node, "if.done"); irBlock *else_ = done; if (is->else_stmt != NULL) { else_ = ir_new_block(proc, is->else_stmt, "if.else"); } ir_build_cond(proc, is->cond, then, else_); ir_start_block(proc, then); ir_open_scope(proc); ir_build_stmt(proc, is->body); ir_close_scope(proc, irDeferExit_Default, NULL); ir_emit_jump(proc, done); if (is->else_stmt != NULL) { ir_start_block(proc, else_); ir_open_scope(proc); ir_build_stmt(proc, is->else_stmt); ir_close_scope(proc, irDeferExit_Default, NULL); ir_emit_jump(proc, done); } ir_start_block(proc, done); case_end; case_ast_node(fs, ForStmt, node); ir_emit_comment(proc, str_lit("ForStmt")); if (fs->init != NULL) { irBlock *init = ir_new_block(proc, node, "for.init"); ir_emit_jump(proc, init); ir_start_block(proc, init); ir_build_stmt(proc, fs->init); } irBlock *body = ir_new_block(proc, node, "for.body"); irBlock *done = ir_new_block(proc, node, "for.done"); // NOTE(bill): Append later irBlock *loop = body; if (fs->cond != NULL) { loop = ir_new_block(proc, node, "for.loop"); } irBlock *post = loop; if (fs->post != NULL) { post = ir_new_block(proc, node, "for.post"); } ir_emit_jump(proc, loop); ir_start_block(proc, loop); if (loop != body) { ir_build_cond(proc, fs->cond, body, done); ir_start_block(proc, body); } ir_push_target_list(proc, fs->label, done, post, NULL); ir_open_scope(proc); ir_build_stmt(proc, fs->body); ir_close_scope(proc, irDeferExit_Default, NULL); ir_pop_target_list(proc); ir_emit_jump(proc, post); if (fs->post != NULL) { ir_start_block(proc, post); ir_build_stmt(proc, fs->post); ir_emit_jump(proc, loop); } ir_start_block(proc, done); case_end; case_ast_node(rs, RangeStmt, node); ir_emit_comment(proc, str_lit("RangeStmt")); Type *val_type = NULL; Type *idx_type = NULL; if (rs->value != NULL && !ir_is_blank_ident(rs->value)) { val_type = type_of_expr(proc->module->info, rs->value); } if (rs->index != NULL && !ir_is_blank_ident(rs->index)) { idx_type = type_of_expr(proc->module->info, rs->index); } if (val_type != NULL) { ir_add_local_for_identifier(proc, rs->value, true); } if (idx_type != NULL) { ir_add_local_for_identifier(proc, rs->index, true); } irValue *val = NULL; irValue *index = NULL; irBlock *loop = NULL; irBlock *done = NULL; AstNode *expr = unparen_expr(rs->expr); TypeAndValue tav = type_and_value_of_expr(proc->module->info, expr); if (is_ast_node_a_range(expr)) { ir_build_range_interval(proc, &expr->BinaryExpr, val_type, &val, &index, &loop, &done); } else if (tav.mode == Addressing_Type) { TokenPos pos = ast_node_token(expr).pos; gbAllocator a = proc->module->allocator; Type *t = tav.type; GB_ASSERT(is_type_enum(t)); Type *enum_ptr = make_type_pointer(a, t); t = base_type(t); Type *core_elem = core_type(t); i64 enum_count = t->Record.field_count; irValue *max_count = ir_const_int(a, enum_count); irValue *eti = ir_emit_union_cast(proc, ir_type_info(proc, t), t_type_info_enum_ptr, pos); irValue *values = ir_emit_load(proc, ir_emit_struct_ep(proc, eti, 4)); irValue *values_data = ir_slice_elem(proc, values); irValue *offset_ = ir_add_local_generated(proc, t_int); ir_emit_store(proc, offset_, v_zero); loop = ir_new_block(proc, NULL, "for.enum.loop"); ir_emit_jump(proc, loop); ir_start_block(proc, loop); irBlock *body = ir_new_block(proc, NULL, "for.enum.body"); done = ir_new_block(proc, NULL, "for.enum.done"); irValue *offset = ir_emit_load(proc, offset_); irValue *cond = ir_emit_comp(proc, Token_Lt, offset, max_count); ir_emit_if(proc, cond, body, done); ir_start_block(proc, body); irValue *val_ptr = ir_emit_ptr_offset(proc, values_data, offset); ir_emit_increment(proc, offset_); index = offset; if (val_type != NULL) { if (is_type_float(core_elem)) { irValue *f = ir_emit_load(proc, ir_emit_conv(proc, val_ptr, t_f64_ptr)); val = ir_emit_conv(proc, f, t); } else if (is_type_integer(core_elem)) { irValue *i = ir_emit_load(proc, ir_emit_conv(proc, val_ptr, t_i64_ptr)); val = ir_emit_conv(proc, i, t); } else { GB_PANIC("TODO(bill): enum core type %s", type_to_string(core_elem)); } } } else { Type *expr_type = type_of_expr(proc->module->info, rs->expr); Type *et = base_type(type_deref(expr_type)); switch (et->kind) { case Type_Map: { irAddr addr = ir_build_addr(proc, rs->expr); irValue *map = addr.addr; if (is_type_pointer(type_deref(ir_addr_type(addr)))) { map = ir_addr_load(proc, addr); } irValue *entries_ptr = ir_emit_struct_ep(proc, map, 1); irValue *count_ptr = ir_emit_struct_ep(proc, entries_ptr, 1); ir_build_range_indexed(proc, map, val_type, count_ptr, &val, &index, &loop, &done); } break; case Type_Array: { irValue *count_ptr = NULL; irValue *array = ir_build_addr(proc, rs->expr).addr; if (is_type_pointer(type_deref(ir_type(array)))) { array = ir_emit_load(proc, array); } count_ptr = ir_add_local_generated(proc, t_int); ir_emit_store(proc, count_ptr, ir_const_int(proc->module->allocator, et->Array.count)); ir_build_range_indexed(proc, array, val_type, count_ptr, &val, &index, &loop, &done); } break; case Type_Vector: { irValue *count_ptr = NULL; irValue *vector = ir_build_addr(proc, rs->expr).addr; if (is_type_pointer(type_deref(ir_type(vector)))) { vector = ir_emit_load(proc, vector); } count_ptr = ir_add_local_generated(proc, t_int); ir_emit_store(proc, count_ptr, ir_const_int(proc->module->allocator, et->Vector.count)); ir_build_range_indexed(proc, vector, val_type, count_ptr, &val, &index, &loop, &done); } break; case Type_DynamicArray: { irValue *count_ptr = NULL; irValue *array = ir_build_addr(proc, rs->expr).addr; if (is_type_pointer(type_deref(ir_type(array)))) { array = ir_emit_load(proc, array); } count_ptr = ir_emit_struct_ep(proc, array, 1); ir_build_range_indexed(proc, array, val_type, count_ptr, &val, &index, &loop, &done); } break; case Type_Slice: { irValue *count_ptr = NULL; irValue *slice = ir_build_expr(proc, rs->expr); if (is_type_pointer(ir_type(slice))) { count_ptr = ir_emit_struct_ep(proc, slice, 1); slice = ir_emit_load(proc, slice); } else { count_ptr = ir_add_local_generated(proc, t_int); ir_emit_store(proc, count_ptr, ir_slice_count(proc, slice)); } ir_build_range_indexed(proc, slice, val_type, count_ptr, &val, &index, &loop, &done); } break; case Type_Basic: { irValue *string = ir_build_expr(proc, rs->expr); if (is_type_pointer(ir_type(string))) { string = ir_emit_load(proc, string); } if (is_type_untyped(expr_type)) { irValue *s = ir_add_local_generated(proc, t_string); ir_emit_store(proc, s, string); string = ir_emit_load(proc, s); } ir_build_range_string(proc, string, val_type, &val, &index, &loop, &done); } break; default: GB_PANIC("Cannot range over %s", type_to_string(expr_type)); break; } } irAddr val_addr = {}; irAddr idx_addr = {}; if (val_type != NULL) { val_addr = ir_build_addr(proc, rs->value); } if (idx_type != NULL) { idx_addr = ir_build_addr(proc, rs->index); } if (val_type != NULL) { ir_addr_store(proc, val_addr, val); } if (idx_type != NULL) { ir_addr_store(proc, idx_addr, index); } ir_push_target_list(proc, rs->label, done, loop, NULL); ir_open_scope(proc); ir_build_stmt(proc, rs->body); ir_close_scope(proc, irDeferExit_Default, NULL); ir_pop_target_list(proc); ir_emit_jump(proc, loop); ir_start_block(proc, done); case_end; case_ast_node(ms, MatchStmt, node); ir_emit_comment(proc, str_lit("MatchStmt")); if (ms->init != NULL) { ir_build_stmt(proc, ms->init); } irValue *tag = v_true; if (ms->tag != NULL) { tag = ir_build_expr(proc, ms->tag); } irBlock *done = ir_new_block(proc, node, "match.done"); // NOTE(bill): Append later ast_node(body, BlockStmt, ms->body); Array default_stmts = {}; irBlock *default_fall = NULL; irBlock *default_block = NULL; irBlock *fall = NULL; bool append_fall = false; isize case_count = body->stmts.count; for_array(i, body->stmts) { AstNode *clause = body->stmts[i]; irBlock *body = fall; ast_node(cc, CaseClause, clause); if (body == NULL) { if (cc->list.count == 0) { body = ir_new_block(proc, clause, "match.dflt.body"); } else { body = ir_new_block(proc, clause, "match.case.body"); } } if (append_fall && body == fall) { append_fall = false; } fall = done; if (i+1 < case_count) { append_fall = true; fall = ir_new_block(proc, clause, "match.fall.body"); } if (cc->list.count == 0) { // default case default_stmts = cc->stmts; default_fall = fall; default_block = body; continue; } irBlock *next_cond = NULL; for_array(j, cc->list) { AstNode *expr = unparen_expr(cc->list[j]); next_cond = ir_new_block(proc, clause, "match.case.next"); irValue *cond = v_false; if (is_ast_node_a_range(expr)) { ast_node(ie, BinaryExpr, expr); TokenKind op = Token_Invalid; switch (ie->op.kind) { case Token_Ellipsis: op = Token_LtEq; break; case Token_HalfClosed: op = Token_Lt; break; default: GB_PANIC("Invalid interval operator"); break; } irValue *lhs = ir_build_expr(proc, ie->left); irValue *rhs = ir_build_expr(proc, ie->right); // TODO(bill): do short circuit here irValue *cond_lhs = ir_emit_comp(proc, Token_LtEq, lhs, tag); irValue *cond_rhs = ir_emit_comp(proc, op, tag, rhs); cond = ir_emit_arith(proc, Token_And, cond_lhs, cond_rhs, t_bool); } else { cond = ir_emit_comp(proc, Token_CmpEq, tag, ir_build_expr(proc, expr)); } ir_emit_if(proc, cond, body, next_cond); ir_start_block(proc, next_cond); } ir_start_block(proc, body); ir_push_target_list(proc, ms->label, done, NULL, fall); ir_open_scope(proc); ir_build_stmt_list(proc, cc->stmts); ir_close_scope(proc, irDeferExit_Default, body); ir_pop_target_list(proc); ir_emit_jump(proc, done); proc->curr_block = next_cond; // ir_start_block(proc, next_cond); } if (default_block != NULL) { ir_emit_jump(proc, default_block); ir_start_block(proc, default_block); ir_push_target_list(proc, ms->label, done, NULL, default_fall); ir_open_scope(proc); ir_build_stmt_list(proc, default_stmts); ir_close_scope(proc, irDeferExit_Default, default_block); ir_pop_target_list(proc); } ir_emit_jump(proc, done); ir_start_block(proc, done); case_end; case_ast_node(ms, TypeMatchStmt, node); ir_emit_comment(proc, str_lit("TypeMatchStmt")); gbAllocator allocator = proc->module->allocator; ast_node(as, AssignStmt, ms->tag); GB_ASSERT(as->lhs.count == 1); GB_ASSERT(as->rhs.count == 1); irValue *parent = ir_build_expr(proc, as->rhs[0]); Type *parent_type = ir_type(parent); bool is_parent_ptr = is_type_pointer(ir_type(parent)); MatchTypeKind match_type_kind = check_valid_type_match_type(ir_type(parent)); GB_ASSERT(match_type_kind != MatchType_Invalid); irValue *parent_value = parent; irValue *parent_ptr = parent; if (!is_parent_ptr) { parent_ptr = ir_address_from_load_or_generate_local(proc, parent_ptr); } irValue *tag_index = NULL; irValue *union_data = NULL; if (match_type_kind == MatchType_Union) { ir_emit_comment(proc, str_lit("get union's tag")); tag_index = ir_emit_load(proc, ir_emit_union_tag_ptr(proc, parent_ptr)); union_data = ir_emit_conv(proc, parent_ptr, t_rawptr); } irBlock *start_block = ir_new_block(proc, node, "typematch.case.first"); ir_emit_jump(proc, start_block); ir_start_block(proc, start_block); // NOTE(bill): Append this later irBlock *done = ir_new_block(proc, node, "typematch.done"); AstNode *default_ = NULL; ast_node(body, BlockStmt, ms->body); gb_local_persist i32 weird_count = 0; for_array(i, body->stmts) { AstNode *clause = body->stmts[i]; ast_node(cc, CaseClause, clause); if (cc->list.count == 0) { default_ = clause; continue; } irBlock *body = ir_new_block(proc, clause, "typematch.body"); irBlock *next = NULL; Type *case_type = NULL; for_array(type_index, cc->list) { next = ir_new_block(proc, NULL, "typematch.next"); case_type = type_of_expr(proc->module->info, cc->list[type_index]); irValue *cond = NULL; if (match_type_kind == MatchType_Union) { Type *bt = type_deref(case_type); irValue *index = NULL; Type *ut = base_type(type_deref(parent_type)); GB_ASSERT(ut->Record.kind == TypeRecord_Union); for (isize variant_index = 1; variant_index < ut->Record.variant_count; variant_index++) { Entity *f = ut->Record.variants[variant_index]; if (are_types_identical(f->type, bt)) { index = ir_const_int(allocator, variant_index); break; } } GB_ASSERT(index != NULL); cond = ir_emit_comp(proc, Token_CmpEq, tag_index, index); } else if (match_type_kind == MatchType_Any) { irValue *any_ti = ir_emit_load(proc, ir_emit_struct_ep(proc, parent_ptr, 1)); irValue *case_ti = ir_type_info(proc, case_type); cond = ir_emit_comp(proc, Token_CmpEq, any_ti, case_ti); } GB_ASSERT(cond != NULL); ir_emit_if(proc, cond, body, next); ir_start_block(proc, next); } Entity *case_entity = implicit_entity_of_node(proc->module->info, clause); irValue *value = parent_value; ir_start_block(proc, body); if (cc->list.count == 1) { bool any_or_not_ptr = is_type_any(type_deref(parent_type)) || !is_parent_ptr; Type *ct = case_entity->type; if (any_or_not_ptr) { ct = make_type_pointer(proc->module->allocator, ct); } GB_ASSERT_MSG(is_type_pointer(ct), "%s", type_to_string(ct)); irValue *data = NULL; if (match_type_kind == MatchType_Union) { data = union_data; } else if (match_type_kind == MatchType_Any) { irValue *any_data = ir_emit_load(proc, ir_emit_struct_ep(proc, parent_ptr, 0)); data = any_data; } value = ir_emit_conv(proc, data, ct); if (any_or_not_ptr) { value = ir_emit_load(proc, value); } } ir_store_type_case_implicit(proc, clause, value); ir_type_case_body(proc, ms->label, clause, body, done); ir_start_block(proc, next); } if (default_ != NULL) { ir_store_type_case_implicit(proc, default_, parent_value); ir_type_case_body(proc, ms->label, default_, proc->curr_block, done); } else { ir_emit_jump(proc, done); } ir_start_block(proc, done); case_end; case_ast_node(bs, BranchStmt, node); irBlock *block = NULL; if (bs->label != NULL) { irBranchBlocks bb = ir_lookup_branch_blocks(proc, bs->label); switch (bs->token.kind) { case Token_break: block = bb.break_; break; case Token_continue: block = bb.continue_; break; case Token_fallthrough: GB_PANIC("fallthrough cannot have a label"); break; } } else { switch (bs->token.kind) { case Token_break: for (irTargetList *t = proc->target_list; t != NULL && block == NULL; t = t->prev) { block = t->break_; } break; case Token_continue: for (irTargetList *t = proc->target_list; t != NULL && block == NULL; t = t->prev) { block = t->continue_; } break; case Token_fallthrough: for (irTargetList *t = proc->target_list; t != NULL && block == NULL; t = t->prev) { block = t->fallthrough_; } break; } } if (block != NULL) { ir_emit_defer_stmts(proc, irDeferExit_Branch, block); } switch (bs->token.kind) { case Token_break: ir_emit_comment(proc, str_lit("break")); break; case Token_continue: ir_emit_comment(proc, str_lit("continue")); break; case Token_fallthrough: ir_emit_comment(proc, str_lit("fallthrough")); break; } ir_emit_jump(proc, block); ir_emit_unreachable(proc); case_end; case_ast_node(pa, PushAllocator, node); ir_emit_comment(proc, str_lit("PushAllocator")); ir_open_scope(proc); irValue *prev = ir_find_or_generate_context_ptr(proc); irValue *next = ir_add_local_generated(proc, t_context); ir_emit_store(proc, next, ir_emit_load(proc, prev)); array_add(&proc->context_stack, next); defer (array_pop(&proc->context_stack)); irValue *gep = ir_emit_struct_ep(proc, next, 1); ir_emit_store(proc, gep, ir_build_expr(proc, pa->expr)); ir_build_stmt(proc, pa->body); ir_close_scope(proc, irDeferExit_Default, NULL); case_end; case_ast_node(pc, PushContext, node); ir_emit_comment(proc, str_lit("PushContext")); ir_open_scope(proc); irValue *prev = ir_find_or_generate_context_ptr(proc); irValue *next = ir_add_local_generated(proc, t_context); array_add(&proc->context_stack, next); defer (array_pop(&proc->context_stack)); ir_emit_store(proc, next, ir_build_expr(proc, pc->expr)); ir_build_stmt(proc, pc->body); ir_close_scope(proc, irDeferExit_Default, NULL); case_end; } } //////////////////////////////////////////////////////////////// // // @Procedure // //////////////////////////////////////////////////////////////// void ir_number_proc_registers(irProcedure *proc) { i32 reg_index = 0; for_array(i, proc->blocks) { irBlock *b = proc->blocks[i]; b->index = i; for_array(j, b->instrs) { irValue *value = b->instrs[j]; GB_ASSERT_MSG(value->kind == irValue_Instr, "%.*s", LIT(proc->name)); irInstr *instr = &value->Instr; if (ir_instr_type(instr) == NULL) { // NOTE(bill): Ignore non-returning instructions value->index = -1; continue; } value->index = reg_index; value->index_set = true; reg_index++; } } } void ir_begin_procedure_body(irProcedure *proc) { gbAllocator a = proc->module->allocator; array_add(&proc->module->procs, proc); array_init(&proc->blocks, heap_allocator()); array_init(&proc->defer_stmts, heap_allocator()); array_init(&proc->children, heap_allocator()); array_init(&proc->branch_blocks, heap_allocator()); array_init(&proc->context_stack, heap_allocator()); DeclInfo *decl = decl_info_of_entity(proc->module->info, proc->entity); if (decl != NULL) { for_array(i, decl->labels) { BlockLabel bl = decl->labels[i]; irBranchBlocks bb = {bl.label, NULL, NULL}; array_add(&proc->branch_blocks, bb); } } proc->decl_block = ir_new_block(proc, proc->type_expr, "decls"); ir_start_block(proc, proc->decl_block); proc->entry_block = ir_new_block(proc, proc->type_expr, "entry"); ir_start_block(proc, proc->entry_block); if (proc->type->Proc.return_by_pointer) { // NOTE(bill): this must be the first parameter stored Type *ptr_type = make_type_pointer(a, reduce_tuple_to_single_type(proc->type->Proc.results)); Entity *e = make_entity_param(a, NULL, make_token_ident(str_lit("agg.result")), ptr_type, false, false); e->flags |= EntityFlag_Sret | EntityFlag_NoAlias; irValue *param = ir_value_param(a, proc, e, ptr_type); param->Param.kind = irParamPass_Pointer; ir_module_add_value(proc->module, e, param); proc->return_ptr = param; } if (proc->type->Proc.params != NULL) { ast_node(pt, ProcType, proc->type_expr); isize param_index = 0; isize q_index = 0; TypeTuple *params = &proc->type->Proc.params->Tuple; for (isize i = 0; i < params->variable_count; i++) { ast_node(fl, FieldList, pt->params); GB_ASSERT(fl->list.count > 0); GB_ASSERT(fl->list[0]->kind == AstNode_Field); if (q_index == fl->list[param_index]->Field.names.count) { q_index = 0; param_index++; } ast_node(field, Field, fl->list[param_index]); AstNode *name = field->names[q_index++]; Entity *e = params->variables[i]; if (e->kind != Entity_Variable) { continue; } Type *abi_type = proc->type->Proc.abi_compat_params[i]; if (e->token.string != "" && e->token.string != "_") { irValue *param = ir_add_param(proc, e, name, abi_type); array_add(&proc->params, param); } } } if (proc->type->Proc.calling_convention == ProcCC_Odin) { Entity *e = make_entity_param(a, NULL, make_token_ident(str_lit("__.context_ptr")), t_context_ptr, false, false); e->flags |= EntityFlag_NoAlias; irValue *param = ir_value_param(a, proc, e, e->type); ir_module_add_value(proc->module, e, param); array_add(&proc->context_stack, param); } } void ir_end_procedure_body(irProcedure *proc) { if (proc->type->Proc.result_count == 0) { ir_emit_return(proc, NULL); } if (proc->curr_block->instrs.count == 0) { ir_emit_unreachable(proc); } proc->curr_block = proc->decl_block; ir_emit_jump(proc, proc->entry_block); proc->curr_block = NULL; ir_number_proc_registers(proc); } void ir_insert_code_before_proc(irProcedure* proc, irProcedure *parent) { if (parent == NULL) { if (proc->name == "main") { ir_emit_startup_runtime(proc); } } } void ir_build_proc(irValue *value, irProcedure *parent) { irProcedure *proc = &value->Proc; proc->parent = parent; if (proc->entity != NULL) { irModule *m = proc->module; CheckerInfo *info = m->info; Entity *e = proc->entity; String filename = e->token.pos.file; AstFile *f = ast_file_of_filename(info, filename); irDebugInfo *di_file = NULL; irDebugInfo **di_file_found = map_get(&m->debug_info, hash_ast_file(f)); if (di_file_found) { di_file = *di_file_found; GB_ASSERT(di_file->kind == irDebugInfo_File); } else { di_file = ir_add_debug_info_file(proc, f); } ir_add_debug_info_proc(proc, e, proc->name, di_file); } if (proc->body != NULL) { u32 prev_stmt_state_flags = proc->module->stmt_state_flags; if (proc->tags != 0) { u32 in = proc->tags; u32 out = proc->module->stmt_state_flags; if (in & ProcTag_bounds_check) { out |= StmtStateFlag_bounds_check; out &= ~StmtStateFlag_no_bounds_check; } else if (in & ProcTag_no_bounds_check) { out |= StmtStateFlag_no_bounds_check; out &= ~StmtStateFlag_bounds_check; } proc->module->stmt_state_flags = out; } ir_begin_procedure_body(proc); ir_insert_code_before_proc(proc, parent); ir_build_stmt(proc, proc->body); ir_end_procedure_body(proc); proc->module->stmt_state_flags = prev_stmt_state_flags; } } //////////////////////////////////////////////////////////////// // // @Module // //////////////////////////////////////////////////////////////// void ir_module_add_value(irModule *m, Entity *e, irValue *v) { map_set(&m->values, hash_entity(e), v); } void ir_init_module(irModule *m, Checker *c) { // TODO(bill): Determine a decent size for the arena isize token_count = c->parser->total_token_count; isize arena_size = 4 * token_count * gb_size_of(irValue); gb_arena_init_from_allocator(&m->arena, heap_allocator(), arena_size); gb_arena_init_from_allocator(&m->tmp_arena, heap_allocator(), arena_size); m->allocator = gb_arena_allocator(&m->arena); m->tmp_allocator = gb_arena_allocator(&m->tmp_arena); m->info = &c->info; map_init(&m->values, heap_allocator()); map_init(&m->members, heap_allocator()); map_init(&m->debug_info, heap_allocator()); map_init(&m->entity_names, heap_allocator()); array_init(&m->procs, heap_allocator()); array_init(&m->procs_to_generate, heap_allocator()); array_init(&m->foreign_library_paths, heap_allocator()); map_init(&m->const_strings, heap_allocator()); // Default states m->stmt_state_flags = 0; m->stmt_state_flags |= StmtStateFlag_bounds_check; { // Add type info data { isize max_index = -1; for_array(type_info_map_index, m->info->type_info_map.entries) { auto *entry = &m->info->type_info_map.entries[type_info_map_index]; Type *t = cast(Type *)entry->key.ptr; t = default_type(t); isize entry_index = type_info_index(m->info, t); if (max_index < entry_index) { max_index = entry_index; } } isize max_type_info_count = max_index+1; String name = str_lit(IR_TYPE_INFO_DATA_NAME); Entity *e = make_entity_variable(m->allocator, NULL, make_token_ident(name), make_type_array(m->allocator, t_type_info, max_type_info_count), false); irValue *g = ir_value_global(m->allocator, e, NULL); g->Global.is_private = true; ir_module_add_value(m, e, g); map_set(&m->members, hash_string(name), g); ir_global_type_info_data = g; } // Type info member buffer { // NOTE(bill): Removes need for heap allocation by making it global memory isize count = 0; for_array(entry_index, m->info->type_info_map.entries) { auto *entry = &m->info->type_info_map.entries[entry_index]; Type *t = cast(Type *)entry->key.ptr; switch (t->kind) { case Type_Record: switch (t->Record.kind) { case TypeRecord_Struct: case TypeRecord_RawUnion: count += t->Record.field_count; break; case TypeRecord_Union: count += t->Record.field_count; count += t->Record.variant_count; break; } break; case Type_Tuple: count += t->Tuple.variable_count; break; } } { String name = str_lit(IR_TYPE_INFO_TYPES_NAME); Entity *e = make_entity_variable(m->allocator, NULL, make_token_ident(name), make_type_array(m->allocator, t_type_info_ptr, count), false); irValue *g = ir_value_global(m->allocator, e, NULL); ir_module_add_value(m, e, g); map_set(&m->members, hash_string(name), g); ir_global_type_info_member_types = g; } { String name = str_lit(IR_TYPE_INFO_NAMES_NAME); Entity *e = make_entity_variable(m->allocator, NULL, make_token_ident(name), make_type_array(m->allocator, t_string, count), false); irValue *g = ir_value_global(m->allocator, e, NULL); ir_module_add_value(m, e, g); map_set(&m->members, hash_string(name), g); ir_global_type_info_member_names = g; } { String name = str_lit(IR_TYPE_INFO_OFFSETS_NAME); Entity *e = make_entity_variable(m->allocator, NULL, make_token_ident(name), make_type_array(m->allocator, t_int, count), false); irValue *g = ir_value_global(m->allocator, e, NULL); ir_module_add_value(m, e, g); map_set(&m->members, hash_string(name), g); ir_global_type_info_member_offsets = g; } { String name = str_lit(IR_TYPE_INFO_USINGS_NAME); Entity *e = make_entity_variable(m->allocator, NULL, make_token_ident(name), make_type_array(m->allocator, t_bool, count), false); irValue *g = ir_value_global(m->allocator, e, NULL); ir_module_add_value(m, e, g); map_set(&m->members, hash_string(name), g); ir_global_type_info_member_usings = g; } } } { irDebugInfo *di = ir_alloc_debug_info(m->allocator, irDebugInfo_CompileUnit); di->CompileUnit.file = m->info->files.entries[0].value; // Zeroth is the init file di->CompileUnit.producer = str_lit("odin"); map_set(&m->debug_info, hash_pointer(m), di); } } void ir_destroy_module(irModule *m) { map_destroy(&m->values); map_destroy(&m->members); map_destroy(&m->entity_names); map_destroy(&m->debug_info); map_destroy(&m->const_strings); array_free(&m->procs); array_free(&m->procs_to_generate); array_free(&m->foreign_library_paths); gb_arena_free(&m->arena); } //////////////////////////////////////////////////////////////// // // @Code Generation // //////////////////////////////////////////////////////////////// bool ir_gen_init(irGen *s, Checker *c) { if (global_error_collector.count != 0) { return false; } isize tc = c->parser->total_token_count; if (tc < 2) { return false; } ir_init_module(&s->module, c); // s->module.generate_debug_info = false; String init_fullpath = c->parser->init_fullpath; // TODO(bill): generate appropriate output name int pos = cast(int)string_extension_position(init_fullpath); int dir_pos = cast(int)string_extension_position(init_fullpath); s->output_name = filename_from_path(init_fullpath); s->output_base = make_string(init_fullpath.text, pos); gbFileError err = gb_file_create(&s->output_file, gb_bprintf("%.*s.ll", pos, init_fullpath.text)); if (err != gbFileError_None) { return false; } return true; } void ir_gen_destroy(irGen *s) { ir_destroy_module(&s->module); gb_file_close(&s->output_file); } // // Type Info stuff // irValue *ir_get_type_info_ptr(irProcedure *proc, Type *type) { i32 index = cast(i32)type_info_index(proc->module->info, type); // gb_printf_err("%d %s\n", index, type_to_string(type)); irValue *ptr = ir_emit_array_epi(proc, ir_global_type_info_data, index); return ir_emit_bitcast(proc, ptr, t_type_info_ptr); } irValue *ir_type_info_member_types_offset(irProcedure *proc, isize count) { irValue *offset = ir_emit_array_epi(proc, ir_global_type_info_member_types, ir_global_type_info_member_types_index); ir_global_type_info_member_types_index += count; return offset; } irValue *ir_type_info_member_names_offset(irProcedure *proc, isize count) { irValue *offset = ir_emit_array_epi(proc, ir_global_type_info_member_names, ir_global_type_info_member_names_index); ir_global_type_info_member_names_index += count; return offset; } irValue *ir_type_info_member_offsets_offset(irProcedure *proc, isize count) { irValue *offset = ir_emit_array_epi(proc, ir_global_type_info_member_offsets, ir_global_type_info_member_offsets_index); ir_global_type_info_member_offsets_index += count; return offset; } irValue *ir_type_info_member_usings_offset(irProcedure *proc, isize count) { irValue *offset = ir_emit_array_epi(proc, ir_global_type_info_member_usings, ir_global_type_info_member_usings_index); ir_global_type_info_member_usings_index += count; return offset; } void ir_add_foreign_library_path(irModule *m, Entity *e) { GB_ASSERT(e != NULL); String library_path = e->LibraryName.path; if (library_path.len == 0) { return; } for_array(path_index, m->foreign_library_paths) { String path = m->foreign_library_paths[path_index]; #if defined(GB_SYSTEM_WINDOWS) if (str_eq_ignore_case(path, library_path)) { #else if (str_eq(path, library_path)) { #endif return; } } array_add(&m->foreign_library_paths, library_path); } void ir_gen_tree(irGen *s) { irModule *m = &s->module; CheckerInfo *info = m->info; gbAllocator a = m->allocator; if (v_zero == NULL) { v_zero = ir_const_int (m->allocator, 0); v_one = ir_const_int (m->allocator, 1); v_zero32 = ir_const_i32 (m->allocator, 0); v_one32 = ir_const_i32 (m->allocator, 1); v_two32 = ir_const_i32 (m->allocator, 2); v_false = ir_const_bool(m->allocator, false); v_true = ir_const_bool(m->allocator, true); v_raw_nil = ir_value_constant(m->allocator, t_rawptr, exact_value_pointer(0)); } isize global_variable_max_count = 0; Entity *entry_point = NULL; bool has_dll_main = false; bool has_win_main = false; for_array(i, info->entities.entries) { auto *entry = &info->entities.entries[i]; Entity *e = cast(Entity *)entry->key.ptr; String name = e->token.string; if (e->kind == Entity_Variable) { global_variable_max_count++; } else if (e->kind == Entity_Procedure && !e->scope->is_global) { if (e->scope->is_init && name == "main") { entry_point = e; } if ((e->Procedure.tags & ProcTag_export) != 0 || (e->Procedure.link_name.len > 0) || (e->scope->is_file && e->Procedure.link_name.len > 0)) { if (!has_dll_main && name == "DllMain") { has_dll_main = true; } else if (!has_win_main && name == "WinMain") { has_win_main = true; } } } } { // Add global default context m->global_default_context = ir_add_global_generated(m, t_context, NULL); } struct irGlobalVariable { irValue *var, *init; DeclInfo *decl; }; Array global_variables; array_init(&global_variables, m->tmp_allocator, global_variable_max_count); m->entry_point_entity = entry_point; m->min_dep_map = generate_minimum_dependency_map(info, entry_point); for_array(i, info->entities.entries) { auto *entry = &info->entities.entries[i]; Entity *e = cast(Entity *)entry->key.ptr; String name = e->token.string; DeclInfo *decl = entry->value; Scope *scope = e->scope; if (!scope->is_file) { continue; } if (map_get(&m->min_dep_map, hash_pointer(e)) == NULL) { // NOTE(bill): Nothing depends upon it so doesn't need to be built continue; } if (!scope->is_global || is_type_poly_proc(e->type)) { if (e->kind == Entity_Procedure && (e->Procedure.tags & ProcTag_export) != 0) { } else if (e->kind == Entity_Procedure && e->Procedure.link_name.len > 0) { // Handle later } else if (scope->is_init && e->kind == Entity_Procedure && name == "main") { } else { name = ir_mangle_name(s, e->token.pos.file, e); } } map_set(&m->entity_names, hash_pointer(e), name); switch (e->kind) { case Entity_TypeName: GB_ASSERT(e->type->kind == Type_Named); ir_gen_global_type_name(m, e, name); break; case Entity_Variable: { irValue *g = ir_value_global(a, e, NULL); g->Global.name = name; g->Global.is_thread_local = e->Variable.is_thread_local; irGlobalVariable var = {}; var.var = g; var.decl = decl; if (decl->init_expr != NULL) { if (is_type_any(e->type)) { } else { TypeAndValue tav = type_and_value_of_expr(info, decl->init_expr); if (tav.mode != Addressing_Invalid) { if (tav.value.kind != ExactValue_Invalid) { ExactValue v = tav.value; // if (v.kind != ExactValue_String) { g->Global.value = ir_add_module_constant(m, tav.type, v); // } } } } } if (g->Global.value == NULL) { array_add(&global_variables, var); } ir_module_add_value(m, e, g); map_set(&m->members, hash_string(name), g); } break; case Entity_Procedure: { ast_node(pl, ProcLit, decl->proc_lit); String original_name = name; AstNode *body = pl->body; if (e->Procedure.is_foreign) { name = e->token.string; // NOTE(bill): Don't use the mangled name ir_add_foreign_library_path(m, e->Procedure.foreign_library); } if (pl->link_name.len > 0) { name = pl->link_name; } AstNode *type_expr = pl->type; irValue *p = ir_value_procedure(a, m, e, e->type, type_expr, body, name); p->Proc.tags = pl->tags; ir_module_add_value(m, e, p); HashKey hash_name = hash_string(name); if (map_get(&m->members, hash_name) == NULL) { multi_map_insert(&m->members, hash_name, p); } } break; } } for_array(i, m->members.entries) { auto *entry = &m->members.entries[i]; irValue *v = entry->value; if (v->kind == irValue_Proc) { ir_build_proc(v, NULL); } } irDebugInfo *compile_unit = m->debug_info.entries[0].value; GB_ASSERT(compile_unit->kind == irDebugInfo_CompileUnit); irDebugInfo *all_procs = ir_alloc_debug_info(m->allocator, irDebugInfo_AllProcs); isize all_proc_max_count = 0; for_array(i, m->debug_info.entries) { auto *entry = &m->debug_info.entries[i]; irDebugInfo *di = entry->value; di->id = i; if (di->kind == irDebugInfo_Proc) { all_proc_max_count++; } } array_init(&all_procs->AllProcs.procs, m->allocator, all_proc_max_count); map_set(&m->debug_info, hash_pointer(all_procs), all_procs); // NOTE(bill): This doesn't need to be mapped compile_unit->CompileUnit.all_procs = all_procs; for_array(i, m->debug_info.entries) { auto *entry = &m->debug_info.entries[i]; irDebugInfo *di = entry->value; if (di->kind == irDebugInfo_Proc) { array_add(&all_procs->AllProcs.procs, di); } } #if defined(GB_SYSTEM_WINDOWS) if (build_context.is_dll && !has_dll_main) { // proc DllMain(inst: rawptr, reason: u32, reserved: rawptr) -> i32 String name = str_lit("DllMain"); Type *proc_params = make_type_tuple(a); Type *proc_results = make_type_tuple(a); Scope *proc_scope = gb_alloc_item(a, Scope); proc_params->Tuple.variables = gb_alloc_array(a, Entity *, 3); proc_params->Tuple.variable_count = 3; proc_results->Tuple.variables = gb_alloc_array(a, Entity *, 1); proc_results->Tuple.variable_count = 1; proc_params->Tuple.variables[0] = make_entity_param(a, proc_scope, blank_token, t_rawptr, false, false); proc_params->Tuple.variables[1] = make_entity_param(a, proc_scope, make_token_ident(str_lit("reason")), t_i32, false, false); proc_params->Tuple.variables[2] = make_entity_param(a, proc_scope, blank_token, t_rawptr, false, false); proc_results->Tuple.variables[0] = make_entity_param(a, proc_scope, empty_token, t_i32, false, false); Type *proc_type = make_type_proc(a, proc_scope, proc_params, 3, proc_results, 1, false, ProcCC_Std); AstNode *body = gb_alloc_item(a, AstNode); Entity *e = make_entity_procedure(a, NULL, make_token_ident(name), proc_type, 0); irValue *p = ir_value_procedure(a, m, e, proc_type, NULL, body, name); map_set(&m->values, hash_pointer(e), p); map_set(&m->members, hash_string(name), p); irProcedure *proc = &p->Proc; proc->tags = ProcTag_no_inline; // TODO(bill): is no_inline a good idea? e->Procedure.link_name = name; ir_begin_procedure_body(proc); // NOTE(bill): https://msdn.microsoft.com/en-us/library/windows/desktop/ms682583(v=vs.85).aspx // DLL_PROCESS_ATTACH == 1 irAddr reason_addr = ir_build_addr_from_entity(proc, proc_params->Tuple.variables[1], NULL); irValue *cond = ir_emit_comp(proc, Token_CmpEq, ir_addr_load(proc, reason_addr), v_one32); irBlock *then = ir_new_block(proc, NULL, "if.then"); irBlock *done = ir_new_block(proc, NULL, "if.done"); // NOTE(bill): Append later ir_emit_if(proc, cond, then, done); ir_start_block(proc, then); { String main_name = str_lit("main"); irValue **found = map_get(&m->members, hash_string(main_name)); if (found != NULL) { ir_emit_call(proc, *found, NULL, 0); } else { ir_emit(proc, ir_alloc_instr(proc, irInstr_StartupRuntime)); } } ir_emit_jump(proc, done); ir_start_block(proc, done); ir_emit_return(proc, v_one32); ir_end_procedure_body(proc); } #endif #if 0 && defined(GB_SYSTEM_WINDOWS) if (!m->build_context->is_dll && !has_win_main) { // proc WinMain(inst, prev: rawptr, cmd_line: ^byte, cmd_show: i32) -> i32 String name = str_lit("WinMain"); Type *proc_params = make_type_tuple(a); Type *proc_results = make_type_tuple(a); Scope *proc_scope = gb_alloc_item(a, Scope); proc_params->Tuple.variables = gb_alloc_array(a, Entity *, 4); proc_params->Tuple.variable_count = 4; proc_results->Tuple.variables = gb_alloc_array(a, Entity *, 1); proc_results->Tuple.variable_count = 1; proc_params->Tuple.variables[0] = make_entity_param(a, proc_scope, blank_token, t_rawptr, false); proc_params->Tuple.variables[1] = make_entity_param(a, proc_scope, blank_token, t_rawptr, false); proc_params->Tuple.variables[2] = make_entity_param(a, proc_scope, blank_token, t_u8_ptr, false); proc_params->Tuple.variables[3] = make_entity_param(a, proc_scope, blank_token, t_i32, false); proc_results->Tuple.variables[0] = make_entity_param(a, proc_scope, empty_token, t_i32, false); Type *proc_type = make_type_proc(a, proc_scope, proc_params, 4, proc_results, 1, false, ProcCC_Std); AstNode *body = gb_alloc_item(a, AstNode); Entity *e = make_entity_procedure(a, NULL, make_token_ident(name), proc_type, 0); irValue *p = ir_value_procedure(a, m, e, proc_type, NULL, body, name); m->entry_point_entity = e; map_set(&m->values, hash_pointer(e), p); map_set(&m->members, hash_string(name), p); irProcedure *proc = &p->Proc; proc->tags = ProcTag_no_inline; // TODO(bill): is no_inline a good idea? e->Procedure.link_name = name; ir_begin_procedure_body(proc); ir_emit_global_call(proc, "main", NULL, 0); ir_emit_return(proc, v_one32); ir_end_procedure_body(proc); } #endif { // Startup Runtime // Cleanup(bill): probably better way of doing code insertion String name = str_lit(IR_STARTUP_RUNTIME_PROC_NAME); Type *proc_type = make_type_proc(a, gb_alloc_item(a, Scope), NULL, 0, NULL, 0, false, ProcCC_Contextless); AstNode *body = gb_alloc_item(a, AstNode); Entity *e = make_entity_procedure(a, NULL, make_token_ident(name), proc_type, 0); irValue *p = ir_value_procedure(a, m, e, proc_type, NULL, body, name); map_set(&m->values, hash_pointer(e), p); map_set(&m->members, hash_string(name), p); irProcedure *proc = &p->Proc; proc->tags = ProcTag_no_inline; // TODO(bill): is no_inline a good idea? ir_begin_procedure_body(proc); { irValue **args = gb_alloc_array(a, irValue *, 1); args[0] = m->global_default_context; ir_emit_global_call(proc, "__init_context", args, 1); } // TODO(bill): Should do a dependency graph do check which order to initialize them in? for_array(i, global_variables) { irGlobalVariable *var = &global_variables[i]; if (var->decl->init_expr != NULL) { var->init = ir_build_expr(proc, var->decl->init_expr); } } // NOTE(bill): Initialize constants first for_array(i, global_variables) { irGlobalVariable *var = &global_variables[i]; if (var->init != NULL && var->init->kind == irValue_Constant) { Type *t = type_deref(ir_type(var->var)); if (is_type_any(t)) { // NOTE(bill): Edge case for `any` type Type *var_type = default_type(ir_type(var->init)); irValue *g = ir_add_global_generated(proc->module, var_type, var->init); irValue *data = ir_emit_struct_ep(proc, var->var, 0); irValue *ti = ir_emit_struct_ep(proc, var->var, 1); ir_emit_store(proc, data, ir_emit_conv(proc, g, t_rawptr)); ir_emit_store(proc, ti, ir_type_info(proc, var_type)); } else { ir_emit_store(proc, var->var, var->init); } } } for_array(i, global_variables) { irGlobalVariable *var = &global_variables[i]; if (var->init != NULL && var->init->kind != irValue_Constant) { Type *t = type_deref(ir_type(var->var)); if (is_type_any(t)) { // NOTE(bill): Edge case for `any` type Type *var_type = default_type(ir_type(var->init)); irValue *g = ir_add_global_generated(proc->module, var_type, var->init); ir_emit_store(proc, g, var->init); irValue *data = ir_emit_struct_ep(proc, var->var, 0); irValue *ti = ir_emit_struct_ep(proc, var->var, 1); ir_emit_store(proc, data, ir_emit_conv(proc, g, t_rawptr)); ir_emit_store(proc, ti, ir_type_info(proc, var_type)); } else { ir_emit_store(proc, var->var, var->init); } } } { // NOTE(bill): Setup type_info data CheckerInfo *info = proc->module->info; if (true) { irValue *global_type_table = ir_find_global_variable(proc, str_lit("__type_table")); Type *type = base_type(type_deref(ir_type(ir_global_type_info_data))); GB_ASSERT(is_type_array(type)); irValue *len = ir_const_int(proc->module->allocator, type->Array.count); ir_fill_slice(proc, global_type_table, ir_emit_array_epi(proc, ir_global_type_info_data, 0), len, len); } // Useful types Type *t_i64_slice_ptr = make_type_pointer(a, make_type_slice(a, t_i64)); Type *t_string_slice_ptr = make_type_pointer(a, make_type_slice(a, t_string)); i32 type_info_member_types_index = 0; i32 type_info_member_names_index = 0; i32 type_info_member_offsets_index = 0; for_array(type_info_map_index, info->type_info_map.entries) { auto *entry = &info->type_info_map.entries[type_info_map_index]; Type *t = cast(Type *)entry->key.ptr; t = default_type(t); if (t == t_invalid) { continue; } isize entry_index = type_info_index(info, t); irValue *tag = NULL; irValue *ti_ptr = ir_emit_array_epi(proc, ir_global_type_info_data, entry_index); ir_emit_store(proc, ir_emit_struct_ep(proc, ti_ptr, 0), ir_const_int(a, type_size_of(a, t))); ir_emit_store(proc, ir_emit_struct_ep(proc, ti_ptr, 1), ir_const_int(a, type_align_of(a, t))); switch (t->kind) { case Type_Named: { ir_emit_comment(proc, str_lit("TypeInfoNamed")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_named_ptr); // TODO(bill): Which is better? The mangled name or actual name? irValue *name = ir_const_string(a, t->Named.type_name->token.string); irValue *gtip = ir_get_type_info_ptr(proc, t->Named.base); ir_emit_store(proc, ir_emit_struct_ep(proc, tag, 2), name); ir_emit_store(proc, ir_emit_struct_ep(proc, tag, 3), gtip); } break; case Type_Basic: ir_emit_comment(proc, str_lit("TypeInfoBasic")); switch (t->Basic.kind) { case Basic_bool: tag = ir_emit_conv(proc, ti_ptr, t_type_info_boolean_ptr); break; case Basic_i8: case Basic_u8: case Basic_i16: case Basic_u16: case Basic_i32: case Basic_u32: case Basic_i64: case Basic_u64: case Basic_i128: case Basic_u128: case Basic_int: case Basic_uint: { tag = ir_emit_conv(proc, ti_ptr, t_type_info_integer_ptr); irValue *is_signed = ir_const_bool(a, (t->Basic.flags & BasicFlag_Unsigned) == 0); ir_emit_store(proc, ir_emit_struct_ep(proc, tag, 2), is_signed); } break; case Basic_rune: tag = ir_emit_conv(proc, ti_ptr, t_type_info_rune_ptr); break; // case Basic_f16: case Basic_f32: case Basic_f64: tag = ir_emit_conv(proc, ti_ptr, t_type_info_float_ptr); break; // case Basic_complex32: case Basic_complex64: case Basic_complex128: tag = ir_emit_conv(proc, ti_ptr, t_type_info_complex_ptr); break; case Basic_rawptr: tag = ir_emit_conv(proc, ti_ptr, t_type_info_pointer_ptr); break; case Basic_string: tag = ir_emit_conv(proc, ti_ptr, t_type_info_string_ptr); break; case Basic_any: tag = ir_emit_conv(proc, ti_ptr, t_type_info_any_ptr); break; } break; case Type_Pointer: { ir_emit_comment(proc, str_lit("TypeInfoPointer")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_pointer_ptr); irValue *gep = ir_get_type_info_ptr(proc, t->Pointer.elem); ir_emit_store(proc, ir_emit_struct_ep(proc, tag, 2), gep); } break; case Type_Atomic: { ir_emit_comment(proc, str_lit("TypeInfoAtomic")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_atomic_ptr); irValue *gep = ir_get_type_info_ptr(proc, t->Atomic.elem); ir_emit_store(proc, ir_emit_struct_ep(proc, tag, 2), gep); } break; case Type_Array: { ir_emit_comment(proc, str_lit("TypeInfoArray")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_array_ptr); irValue *gep = ir_get_type_info_ptr(proc, t->Array.elem); ir_emit_store(proc, ir_emit_struct_ep(proc, tag, 2), gep); isize ez = type_size_of(a, t->Array.elem); irValue *elem_size = ir_emit_struct_ep(proc, tag, 3); ir_emit_store(proc, elem_size, ir_const_int(a, ez)); irValue *count = ir_emit_struct_ep(proc, tag, 4); ir_emit_store(proc, count, ir_const_int(a, t->Array.count)); } break; case Type_DynamicArray: { ir_emit_comment(proc, str_lit("TypeInfoDynamicArray")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_dynamic_array_ptr); irValue *gep = ir_get_type_info_ptr(proc, t->DynamicArray.elem); ir_emit_store(proc, ir_emit_struct_ep(proc, tag, 2), gep); isize ez = type_size_of(a, t->DynamicArray.elem); irValue *elem_size = ir_emit_struct_ep(proc, tag, 3); ir_emit_store(proc, elem_size, ir_const_int(a, ez)); } break; case Type_Slice: { ir_emit_comment(proc, str_lit("TypeInfoSlice")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_slice_ptr); irValue *gep = ir_get_type_info_ptr(proc, t->Slice.elem); ir_emit_store(proc, ir_emit_struct_ep(proc, tag, 2), gep); isize ez = type_size_of(a, t->Slice.elem); irValue *elem_size = ir_emit_struct_ep(proc, tag, 3); ir_emit_store(proc, elem_size, ir_const_int(a, ez)); } break; case Type_Vector: { ir_emit_comment(proc, str_lit("TypeInfoVector")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_vector_ptr); irValue *gep = ir_get_type_info_ptr(proc, t->Vector.elem); ir_emit_store(proc, ir_emit_struct_ep(proc, tag, 2), gep); isize ez = type_size_of(a, t->Vector.elem); ir_emit_store(proc, ir_emit_struct_ep(proc, tag, 3), ir_const_int(a, ez)); ir_emit_store(proc, ir_emit_struct_ep(proc, tag, 4), ir_const_int(a, t->Vector.count)); } break; case Type_Proc: { ir_emit_comment(proc, str_lit("TypeInfoProc")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_procedure_ptr); irValue *params = ir_emit_struct_ep(proc, tag, 2); irValue *results = ir_emit_struct_ep(proc, tag, 3); irValue *variadic = ir_emit_struct_ep(proc, tag, 4); irValue *convention = ir_emit_struct_ep(proc, tag, 5); if (t->Proc.params != NULL) { ir_emit_store(proc, params, ir_get_type_info_ptr(proc, t->Proc.params)); } if (t->Proc.results != NULL) { ir_emit_store(proc, results, ir_get_type_info_ptr(proc, t->Proc.results)); } ir_emit_store(proc, variadic, ir_const_bool(a, t->Proc.variadic)); ir_emit_store(proc, convention, ir_const_int(a, t->Proc.calling_convention)); // TODO(bill): TypeInfo for procedures } break; case Type_Tuple: { ir_emit_comment(proc, str_lit("TypeInfoTuple")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_tuple_ptr); irValue *record = ir_emit_struct_ep(proc, tag, 2); irValue *memory_types = ir_type_info_member_types_offset(proc, t->Tuple.variable_count); irValue *memory_names = ir_type_info_member_names_offset(proc, t->Tuple.variable_count); for (isize i = 0; i < t->Tuple.variable_count; i++) { // NOTE(bill): offset is not used for tuples Entity *f = t->Tuple.variables[i]; irValue *index = ir_const_int(a, i); irValue *type_info = ir_emit_ptr_offset(proc, memory_types, index); ir_emit_store(proc, type_info, ir_type_info(proc, f->type)); if (f->token.string.len > 0) { irValue *name = ir_emit_ptr_offset(proc, memory_names, index); ir_emit_store(proc, name, ir_const_string(a, f->token.string)); } } irValue *count = ir_const_int(a, t->Tuple.variable_count); ir_fill_slice(proc, ir_emit_struct_ep(proc, record, 0), memory_types, count, count); ir_fill_slice(proc, ir_emit_struct_ep(proc, record, 1), memory_names, count, count); } break; case Type_Record: { switch (t->Record.kind) { case TypeRecord_Struct: { ir_emit_comment(proc, str_lit("TypeInfoStruct")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_struct_ptr); irValue *record = ir_emit_struct_ep(proc, tag, 2); { irValue *packed = ir_const_bool(a, t->Record.is_packed); irValue *ordered = ir_const_bool(a, t->Record.is_ordered); irValue *custom_align = ir_const_bool(a, t->Record.custom_align != 0); ir_emit_store(proc, ir_emit_struct_ep(proc, record, 4), packed); ir_emit_store(proc, ir_emit_struct_ep(proc, record, 5), ordered); ir_emit_store(proc, ir_emit_struct_ep(proc, record, 6), custom_align); } irValue *memory_types = ir_type_info_member_types_offset(proc, t->Record.field_count); irValue *memory_names = ir_type_info_member_names_offset(proc, t->Record.field_count); irValue *memory_offsets = ir_type_info_member_offsets_offset(proc, t->Record.field_count); irValue *memory_usings = ir_type_info_member_usings_offset(proc, t->Record.field_count); type_set_offsets(a, t); // NOTE(bill): Just incase the offsets have not been set yet for (isize source_index = 0; source_index < t->Record.field_count; source_index++) { // TODO(bill): Order fields in source order not layout order Entity *f = t->Record.fields_in_src_order[source_index]; irValue *tip = ir_get_type_info_ptr(proc, f->type); i64 foffset = t->Record.offsets[f->Variable.field_index]; GB_ASSERT(f->kind == Entity_Variable && f->flags & EntityFlag_Field); irValue *index = ir_const_int(a, source_index); irValue *type_info = ir_emit_ptr_offset(proc, memory_types, index); irValue *offset = ir_emit_ptr_offset(proc, memory_offsets, index); irValue *is_using = ir_emit_ptr_offset(proc, memory_usings, index); ir_emit_store(proc, type_info, ir_type_info(proc, f->type)); if (f->token.string.len > 0) { irValue *name = ir_emit_ptr_offset(proc, memory_names, index); ir_emit_store(proc, name, ir_const_string(a, f->token.string)); } ir_emit_store(proc, offset, ir_const_int(a, foffset)); ir_emit_store(proc, is_using, ir_const_bool(a, (f->flags&EntityFlag_Using) != 0)); } irValue *count = ir_const_int(a, t->Record.field_count); ir_fill_slice(proc, ir_emit_struct_ep(proc, record, 0), memory_types, count, count); ir_fill_slice(proc, ir_emit_struct_ep(proc, record, 1), memory_names, count, count); ir_fill_slice(proc, ir_emit_struct_ep(proc, record, 2), memory_offsets, count, count); ir_fill_slice(proc, ir_emit_struct_ep(proc, record, 3), memory_usings, count, count); } break; case TypeRecord_Union: { ir_emit_comment(proc, str_lit("TypeInfoUnion")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_union_ptr); { irValue *common_fields = ir_emit_struct_ep(proc, tag, 2); isize field_count = t->Record.field_count; irValue *memory_types = ir_type_info_member_types_offset(proc, field_count); irValue *memory_names = ir_type_info_member_names_offset(proc, field_count); irValue *memory_offsets = ir_type_info_member_offsets_offset(proc, field_count); type_set_offsets(a, t); // NOTE(bill): Just incase the offsets have not been set yet for (isize field_index = 0; field_index < field_count; field_index++) { // TODO(bill): Order fields in source order not layout order Entity *f = t->Record.fields[field_index]; irValue *tip = ir_get_type_info_ptr(proc, f->type); i64 foffset = t->Record.offsets[f->Variable.field_index]; GB_ASSERT(f->kind == Entity_Variable && f->flags & EntityFlag_Field); irValue *index = ir_const_int(a, field_index); irValue *type_info = ir_emit_ptr_offset(proc, memory_types, index); irValue *offset = ir_emit_ptr_offset(proc, memory_offsets, index); ir_emit_store(proc, type_info, ir_type_info(proc, f->type)); if (f->token.string.len > 0) { irValue *name = ir_emit_ptr_offset(proc, memory_names, index); ir_emit_store(proc, name, ir_const_string(a, f->token.string)); } ir_emit_store(proc, offset, ir_const_int(a, foffset)); } irValue *count = ir_const_int(a, field_count); ir_fill_slice(proc, ir_emit_struct_ep(proc, common_fields, 0), memory_types, count, count); ir_fill_slice(proc, ir_emit_struct_ep(proc, common_fields, 1), memory_names, count, count); ir_fill_slice(proc, ir_emit_struct_ep(proc, common_fields, 2), memory_offsets, count, count); } { irValue *variant_names = ir_emit_struct_ep(proc, tag, 3); irValue *variant_types = ir_emit_struct_ep(proc, tag, 4); isize variant_count = gb_max(0, t->Record.variant_count-1); irValue *memory_names = ir_type_info_member_names_offset(proc, variant_count); irValue *memory_types = ir_type_info_member_types_offset(proc, variant_count); // NOTE(bill): Zeroth is nil so ignore it for (isize variant_index = 0; variant_index < variant_count; variant_index++) { Entity *f = t->Record.variants[variant_index+1]; // Skip zeroth irValue *tip = ir_get_type_info_ptr(proc, f->type); irValue *index = ir_const_int(a, variant_index); irValue *type_info = ir_emit_ptr_offset(proc, memory_types, index); ir_emit_store(proc, type_info, ir_type_info(proc, f->type)); if (f->token.string.len > 0) { irValue *name = ir_emit_ptr_offset(proc, memory_names, index); ir_emit_store(proc, name, ir_const_string(a, f->token.string)); } } irValue *count = ir_const_int(a, variant_count); ir_fill_slice(proc, variant_names, memory_names, count, count); ir_fill_slice(proc, variant_types, memory_types, count, count); } } break; case TypeRecord_RawUnion: { ir_emit_comment(proc, str_lit("TypeInfoRawUnion")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_raw_union_ptr); irValue *record = ir_emit_struct_ep(proc, tag, 2); irValue *memory_types = ir_type_info_member_types_offset(proc, t->Record.field_count); irValue *memory_names = ir_type_info_member_names_offset(proc, t->Record.field_count); irValue *memory_offsets = ir_type_info_member_offsets_offset(proc, t->Record.field_count); for (isize i = 0; i < t->Record.field_count; i++) { Entity *f = t->Record.fields[i]; irValue *index = ir_const_int(a, i); irValue *type_info = ir_emit_ptr_offset(proc, memory_types, index); // NOTE(bill): Offsets are always 0 ir_emit_store(proc, type_info, ir_type_info(proc, f->type)); if (f->token.string.len > 0) { irValue *name = ir_emit_ptr_offset(proc, memory_names, index); ir_emit_store(proc, name, ir_const_string(a, f->token.string)); } } irValue *count = ir_const_int(a, t->Record.field_count); ir_fill_slice(proc, ir_emit_struct_ep(proc, record, 0), memory_types, count, count); ir_fill_slice(proc, ir_emit_struct_ep(proc, record, 1), memory_names, count, count); ir_fill_slice(proc, ir_emit_struct_ep(proc, record, 2), memory_offsets, count, count); } break; case TypeRecord_Enum: ir_emit_comment(proc, str_lit("TypeInfoEnum")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_enum_ptr); { GB_ASSERT(t->Record.enum_base_type != NULL); irValue *base = ir_type_info(proc, t->Record.enum_base_type); ir_emit_store(proc, ir_emit_struct_ep(proc, tag, 2), base); if (t->Record.field_count > 0) { Entity **fields = t->Record.fields; isize count = t->Record.field_count; irValue *name_array = ir_generate_array(m, t_string, count, str_lit("__$enum_names"), cast(i64)entry_index); irValue *value_array = ir_generate_array(m, t_type_info_enum_value, count, str_lit("__$enum_values"), cast(i64)entry_index); bool is_value_int = is_type_integer(t->Record.enum_base_type); for (isize i = 0; i < count; i++) { irValue *name_ep = ir_emit_array_epi(proc, name_array, i); irValue *value_ep = ir_emit_array_epi(proc, value_array, i); ExactValue value = fields[i]->Constant.value; if (is_value_int) { value_ep = ir_emit_conv(proc, value_ep, t_i128_ptr); ir_emit_store(proc, value_ep, ir_value_constant(a, t_i128, value)); } else { GB_ASSERT(is_type_float(t->Record.enum_base_type)); f64 f = value.value_float; value_ep = ir_emit_conv(proc, value_ep, t_f64_ptr); ir_emit_store(proc, value_ep, ir_const_f64(a, f)); } ir_emit_store(proc, name_ep, ir_const_string(a, fields[i]->token.string)); } irValue *v_count = ir_const_int(a, count); irValue *names = ir_emit_struct_ep(proc, tag, 3); irValue *name_array_elem = ir_array_elem(proc, name_array); ir_fill_slice(proc, names, name_array_elem, v_count, v_count); irValue *values = ir_emit_struct_ep(proc, tag, 4); irValue *value_array_elem = ir_array_elem(proc, value_array); ir_fill_slice(proc, values, value_array_elem, v_count, v_count); } } break; } } break; case Type_Map: { ir_emit_comment(proc, str_lit("TypeInfoMap")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_map_ptr); irValue *key = ir_emit_struct_ep(proc, tag, 2); irValue *value = ir_emit_struct_ep(proc, tag, 3); irValue *generated_struct = ir_emit_struct_ep(proc, tag, 4); irValue *count = ir_emit_struct_ep(proc, tag, 5); ir_emit_store(proc, key, ir_get_type_info_ptr(proc, t->Map.key)); ir_emit_store(proc, value, ir_get_type_info_ptr(proc, t->Map.value)); ir_emit_store(proc, generated_struct, ir_get_type_info_ptr(proc, t->Map.generated_struct_type)); ir_emit_store(proc, count, ir_const_int(a, t->Map.count)); } break; case Type_BitField: { ir_emit_comment(proc, str_lit("TypeInfoBitField")); tag = ir_emit_conv(proc, ti_ptr, t_type_info_map_ptr); // names: []string, // bits: []u32, // offsets: []u32, isize count = t->BitField.field_count; if (count > 0) { Entity **fields = t->BitField.fields; irValue *name_array = ir_generate_array(m, t_string, count, str_lit("__$bit_field_names"), cast(i64)entry_index); irValue *bit_array = ir_generate_array(m, t_u32, count, str_lit("__$bit_field_bits"), cast(i64)entry_index); irValue *offset_array = ir_generate_array(m, t_u32, count, str_lit("__$bit_field_offsets"), cast(i64)entry_index); for (isize i = 0; i < count; i++) { Entity *f = fields[i]; GB_ASSERT(f->type != NULL); GB_ASSERT(f->type->kind == Type_BitFieldValue); irValue *name_ep = ir_emit_array_epi(proc, name_array, i); irValue *bit_ep = ir_emit_array_epi(proc, bit_array, i); irValue *offset_ep = ir_emit_array_epi(proc, offset_array, i); ir_emit_store(proc, name_ep, ir_const_string(a, f->token.string)); ir_emit_store(proc, bit_ep, ir_const_u32(a, f->type->BitFieldValue.bits)); ir_emit_store(proc, offset_ep, ir_const_u32(a, t->BitField.offsets[i])); } irValue *v_count = ir_const_int(a, count); irValue *names = ir_emit_struct_ep(proc, tag, 3); irValue *name_array_elem = ir_array_elem(proc, name_array); ir_fill_slice(proc, names, name_array_elem, v_count, v_count); irValue *bits = ir_emit_struct_ep(proc, tag, 4); irValue *bit_array_elem = ir_array_elem(proc, bit_array); ir_fill_slice(proc, bits, bit_array_elem, v_count, v_count); irValue *offsets = ir_emit_struct_ep(proc, tag, 5); irValue *offset_array_elem = ir_array_elem(proc, offset_array); ir_fill_slice(proc, offsets, offset_array_elem, v_count, v_count); } } break; } if (tag != NULL) { Type *tag_type = type_deref(ir_type(tag)); GB_ASSERT(is_type_named(tag_type)); Type *ti = base_type(t_type_info); bool found = false; for (isize i = 1; i < ti->Record.variant_count; i++) { Entity *f = ti->Record.variants[i]; if (are_types_identical(f->type, tag_type)) { found = true; irValue *tag = ir_const_int(a, i); irValue *ptr = ir_emit_union_tag_ptr(proc, ti_ptr); ir_emit_store(proc, ptr, tag); break; } } GB_ASSERT_MSG(found, "%s", type_to_string(tag_type)); } else { GB_PANIC("Unhandled TypeInfo type: %s", type_to_string(t)); } } } ir_end_procedure_body(proc); } for_array(type_info_map_index, info->type_info_map.entries) { auto *entry = &info->type_info_map.entries[type_info_map_index]; Type *t = cast(Type *)entry->key.ptr; t = default_type(t); isize entry_index = entry->value; gbString s = type_to_string(t); GB_ASSERT(s[0] != 0); // gb_printf_err("%s\n", s); } for_array(i, m->procs_to_generate) { ir_build_proc(m->procs_to_generate[i], m->procs_to_generate[i]->Proc.parent); } // Number debug info for_array(i, m->debug_info.entries) { auto *entry = &m->debug_info.entries[i]; irDebugInfo *di = entry->value; di->id = i; } // m->layout = str_lit("e-p:64:64:64-i1:8:8-i8:8:8-i16:16:16-i32:32:32-i64:64:64-f32:32:32-f64:64:64-v64:64:64-v128:128:128-a0:0:64-s0:64:64-f80:128:128-n8:16:32:64"); }