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Odin/src/llvm_backend_proc.cpp
gingerBill 3f038428a7 Begin minimizing Ast size
2021-11-14 15:12:37 +00:00

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void lb_mem_copy_overlapping(lbProcedure *p, lbValue dst, lbValue src, lbValue len, bool is_volatile) {
dst = lb_emit_conv(p, dst, t_rawptr);
src = lb_emit_conv(p, src, t_rawptr);
len = lb_emit_conv(p, len, t_int);
char const *name = "llvm.memmove";
if (LLVMIsConstant(len.value)) {
i64 const_len = cast(i64)LLVMConstIntGetSExtValue(len.value);
if (const_len <= 4*build_context.word_size) {
name = "llvm.memmove.inline";
}
}
LLVMTypeRef types[3] = {
lb_type(p->module, t_rawptr),
lb_type(p->module, t_rawptr),
lb_type(p->module, t_int)
};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s.%s.%s", name, LLVMPrintTypeToString(types[0]), LLVMPrintTypeToString(types[1]), LLVMPrintTypeToString(types[2]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[4] = {};
args[0] = dst.value;
args[1] = src.value;
args[2] = len.value;
args[3] = LLVMConstInt(LLVMInt1TypeInContext(p->module->ctx), 0, is_volatile);
LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
}
void lb_mem_copy_non_overlapping(lbProcedure *p, lbValue dst, lbValue src, lbValue len, bool is_volatile) {
dst = lb_emit_conv(p, dst, t_rawptr);
src = lb_emit_conv(p, src, t_rawptr);
len = lb_emit_conv(p, len, t_int);
char const *name = "llvm.memcpy";
if (LLVMIsConstant(len.value)) {
i64 const_len = cast(i64)LLVMConstIntGetSExtValue(len.value);
if (const_len <= 4*build_context.word_size) {
name = "llvm.memcpy.inline";
}
}
LLVMTypeRef types[3] = {
lb_type(p->module, t_rawptr),
lb_type(p->module, t_rawptr),
lb_type(p->module, t_int)
};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s.%s.%s", name, LLVMPrintTypeToString(types[0]), LLVMPrintTypeToString(types[1]), LLVMPrintTypeToString(types[2]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[4] = {};
args[0] = dst.value;
args[1] = src.value;
args[2] = len.value;
args[3] = LLVMConstInt(LLVMInt1TypeInContext(p->module->ctx), 0, is_volatile);
LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
}
lbProcedure *lb_create_procedure(lbModule *m, Entity *entity, bool ignore_body) {
GB_ASSERT(entity != nullptr);
GB_ASSERT(entity->kind == Entity_Procedure);
if (!entity->Procedure.is_foreign) {
GB_ASSERT(entity->flags & EntityFlag_ProcBodyChecked);
}
String link_name = {};
if (ignore_body) {
lbModule *other_module = lb_pkg_module(m->gen, entity->pkg);
link_name = lb_get_entity_name(other_module, entity);
} else {
link_name = lb_get_entity_name(m, entity);
}
{
StringHashKey key = string_hash_string(link_name);
lbValue *found = string_map_get(&m->members, key);
if (found) {
lb_add_entity(m, entity, *found);
return string_map_must_get(&m->procedures, key);
}
}
lbProcedure *p = gb_alloc_item(permanent_allocator(), lbProcedure);
p->module = m;
entity->code_gen_module = m;
entity->code_gen_procedure = p;
p->entity = entity;
p->name = link_name;
DeclInfo *decl = entity->decl_info;
ast_node(pl, ProcLit, decl->proc_lit);
Type *pt = base_type(entity->type);
GB_ASSERT(pt->kind == Type_Proc);
p->type = entity->type;
p->type_expr = decl->type_expr;
p->body = pl->body;
p->inlining = pl->inlining;
p->is_foreign = entity->Procedure.is_foreign;
p->is_export = entity->Procedure.is_export;
p->is_entry_point = false;
gbAllocator a = heap_allocator();
p->children.allocator = a;
p->params.allocator = a;
p->defer_stmts.allocator = a;
p->blocks.allocator = a;
p->branch_blocks.allocator = a;
p->context_stack.allocator = a;
p->scope_stack.allocator = a;
if (p->is_foreign) {
lb_add_foreign_library_path(p->module, entity->Procedure.foreign_library);
}
char *c_link_name = alloc_cstring(permanent_allocator(), p->name);
LLVMTypeRef func_ptr_type = lb_type(m, p->type);
LLVMTypeRef func_type = LLVMGetElementType(func_ptr_type);
p->value = LLVMAddFunction(m->mod, c_link_name, func_type);
lb_ensure_abi_function_type(m, p);
lb_add_function_type_attributes(p->value, p->abi_function_type, p->abi_function_type->calling_convention);
if (pt->Proc.diverging) {
lb_add_attribute_to_proc(m, p->value, "noreturn");
}
if (pt->Proc.calling_convention == ProcCC_Naked) {
lb_add_attribute_to_proc(m, p->value, "naked");
}
switch (p->inlining) {
case ProcInlining_inline:
lb_add_attribute_to_proc(m, p->value, "alwaysinline");
break;
case ProcInlining_no_inline:
lb_add_attribute_to_proc(m, p->value, "noinline");
break;
}
if (entity->flags & EntityFlag_Cold) {
lb_add_attribute_to_proc(m, p->value, "cold");
}
switch (entity->Procedure.optimization_mode) {
case ProcedureOptimizationMode_None:
lb_add_attribute_to_proc(m, p->value, "optnone");
break;
case ProcedureOptimizationMode_Minimal:
lb_add_attribute_to_proc(m, p->value, "optnone");
break;
case ProcedureOptimizationMode_Size:
lb_add_attribute_to_proc(m, p->value, "optsize");
break;
case ProcedureOptimizationMode_Speed:
// TODO(bill): handle this correctly
lb_add_attribute_to_proc(m, p->value, "optsize");
break;
}
// lbCallingConventionKind cc_kind = lbCallingConvention_C;
// // TODO(bill): Clean up this logic
// if (build_context.metrics.os != TargetOs_js) {
// cc_kind = lb_calling_convention_map[pt->Proc.calling_convention];
// }
// LLVMSetFunctionCallConv(p->value, cc_kind);
lbValue proc_value = {p->value, p->type};
lb_add_entity(m, entity, proc_value);
lb_add_member(m, p->name, proc_value);
lb_add_procedure_value(m, p);
if (p->is_export) {
LLVMSetLinkage(p->value, LLVMDLLExportLinkage);
LLVMSetDLLStorageClass(p->value, LLVMDLLExportStorageClass);
LLVMSetVisibility(p->value, LLVMDefaultVisibility);
lb_set_wasm_export_attributes(p->value, p->name);
} else if (!p->is_foreign) {
if (!USE_SEPARATE_MODULES) {
LLVMSetLinkage(p->value, LLVMInternalLinkage);
// NOTE(bill): if a procedure is defined in package runtime and uses a custom link name,
// then it is very likely it is required by LLVM and thus cannot have internal linkage
if (entity->pkg != nullptr && entity->pkg->kind == Package_Runtime && p->body != nullptr) {
GB_ASSERT(entity->kind == Entity_Procedure);
String link_name = entity->Procedure.link_name;
if (entity->flags & EntityFlag_CustomLinkName &&
link_name != "") {
if (string_starts_with(link_name, str_lit("__"))) {
LLVMSetLinkage(p->value, LLVMExternalLinkage);
} else {
LLVMSetLinkage(p->value, LLVMInternalLinkage);
}
}
}
}
}
lb_set_linkage_from_entity_flags(p->module, p->value, entity->flags);
if (p->is_foreign) {
lb_set_wasm_import_attributes(p->value, entity, p->name);
}
// NOTE(bill): offset==0 is the return value
isize offset = 1;
if (pt->Proc.return_by_pointer) {
offset = 2;
}
isize parameter_index = 0;
if (pt->Proc.param_count) {
TypeTuple *params = &pt->Proc.params->Tuple;
for (isize i = 0; i < pt->Proc.param_count; i++) {
Entity *e = params->variables[i];
if (e->kind != Entity_Variable) {
continue;
}
if (i+1 == params->variables.count && pt->Proc.c_vararg) {
continue;
}
if (e->flags&EntityFlag_NoAlias) {
lb_add_proc_attribute_at_index(p, offset+parameter_index, "noalias");
}
parameter_index += 1;
}
}
if (ignore_body) {
p->body = nullptr;
LLVMSetLinkage(p->value, LLVMExternalLinkage);
}
if (m->debug_builder) { // Debug Information
Type *bt = base_type(p->type);
unsigned line = cast(unsigned)entity->token.pos.line;
LLVMMetadataRef scope = nullptr;
LLVMMetadataRef file = nullptr;
LLVMMetadataRef type = nullptr;
scope = p->module->debug_compile_unit;
type = lb_debug_type_internal_proc(m, bt);
Ast *ident = entity->identifier.load();
if (entity->file != nullptr) {
file = lb_get_llvm_metadata(m, entity->file);
scope = file;
} else if (ident != nullptr && ident->file_id != 0) {
file = lb_get_llvm_metadata(m, ident->file());
scope = file;
} else if (entity->scope != nullptr) {
file = lb_get_llvm_metadata(m, entity->scope->file);
scope = file;
}
GB_ASSERT_MSG(file != nullptr, "%.*s", LIT(entity->token.string));
// LLVMBool is_local_to_unit = !entity->Procedure.is_export;
LLVMBool is_local_to_unit = false;
LLVMBool is_definition = p->body != nullptr;
unsigned scope_line = line;
u32 flags = LLVMDIFlagStaticMember;
LLVMBool is_optimized = false;
if (bt->Proc.diverging) {
flags |= LLVMDIFlagNoReturn;
}
if (p->body == nullptr) {
flags |= LLVMDIFlagPrototyped;
is_optimized = false;
}
if (p->body != nullptr) {
// String debug_name = entity->token.string.text;
String debug_name = p->name;
p->debug_info = LLVMDIBuilderCreateFunction(m->debug_builder, scope,
cast(char const *)debug_name.text, debug_name.len,
cast(char const *)p->name.text, p->name.len,
file, line, type,
is_local_to_unit, is_definition,
scope_line, cast(LLVMDIFlags)flags, is_optimized
);
GB_ASSERT(p->debug_info != nullptr);
LLVMSetSubprogram(p->value, p->debug_info);
lb_set_llvm_metadata(m, p, p->debug_info);
}
}
return p;
}
lbProcedure *lb_create_dummy_procedure(lbModule *m, String link_name, Type *type) {
{
lbValue *found = string_map_get(&m->members, link_name);
GB_ASSERT(found == nullptr);
}
lbProcedure *p = gb_alloc_item(permanent_allocator(), lbProcedure);
p->module = m;
p->name = link_name;
p->type = type;
p->type_expr = nullptr;
p->body = nullptr;
p->tags = 0;
p->inlining = ProcInlining_none;
p->is_foreign = false;
p->is_export = false;
p->is_entry_point = false;
gbAllocator a = permanent_allocator();
p->children.allocator = a;
p->params.allocator = a;
p->defer_stmts.allocator = a;
p->blocks.allocator = a;
p->branch_blocks.allocator = a;
p->context_stack.allocator = a;
char *c_link_name = alloc_cstring(permanent_allocator(), p->name);
LLVMTypeRef func_ptr_type = lb_type(m, p->type);
LLVMTypeRef func_type = LLVMGetElementType(func_ptr_type);
p->value = LLVMAddFunction(m->mod, c_link_name, func_type);
Type *pt = p->type;
lbCallingConventionKind cc_kind = lbCallingConvention_C;
// TODO(bill): Clean up this logic
if (!is_arch_wasm()) {
cc_kind = lb_calling_convention_map[pt->Proc.calling_convention];
}
LLVMSetFunctionCallConv(p->value, cc_kind);
lbValue proc_value = {p->value, p->type};
lb_add_member(m, p->name, proc_value);
lb_add_procedure_value(m, p);
// NOTE(bill): offset==0 is the return value
isize offset = 1;
if (pt->Proc.return_by_pointer) {
lb_add_proc_attribute_at_index(p, 1, "sret");
lb_add_proc_attribute_at_index(p, 1, "noalias");
offset = 2;
}
isize parameter_index = 0;
if (pt->Proc.calling_convention == ProcCC_Odin) {
lb_add_proc_attribute_at_index(p, offset+parameter_index, "noalias");
lb_add_proc_attribute_at_index(p, offset+parameter_index, "nonnull");
lb_add_proc_attribute_at_index(p, offset+parameter_index, "nocapture");
}
return p;
}
lbValue lb_value_param(lbProcedure *p, Entity *e, Type *abi_type, i32 index, lbParamPasskind *kind_) {
lbParamPasskind kind = lbParamPass_Value;
if (e != nullptr && !are_types_identical(abi_type, e->type)) {
if (is_type_pointer(abi_type)) {
GB_ASSERT(e->kind == Entity_Variable);
Type *av = core_type(type_deref(abi_type));
if (are_types_identical(av, core_type(e->type))) {
kind = lbParamPass_Pointer;
if (e->flags&EntityFlag_Value) {
kind = lbParamPass_ConstRef;
}
} else {
kind = lbParamPass_BitCast;
}
} else if (is_type_integer(abi_type)) {
kind = lbParamPass_Integer;
} else if (abi_type == t_llvm_bool) {
kind = lbParamPass_Value;
} else if (is_type_boolean(abi_type)) {
kind = lbParamPass_Integer;
} else if (is_type_simd_vector(abi_type)) {
kind = lbParamPass_BitCast;
} else if (is_type_float(abi_type)) {
kind = lbParamPass_BitCast;
} else if (is_type_tuple(abi_type)) {
kind = lbParamPass_Tuple;
} else if (is_type_proc(abi_type)) {
kind = lbParamPass_Value;
} else {
GB_PANIC("Invalid abi type pass kind %s", type_to_string(abi_type));
}
}
if (kind_) *kind_ = kind;
lbValue res = {};
res.value = LLVMGetParam(p->value, cast(unsigned)index);
res.type = abi_type;
return res;
}
void lb_start_block(lbProcedure *p, lbBlock *b) {
GB_ASSERT(b != nullptr);
if (!b->appended) {
b->appended = true;
LLVMAppendExistingBasicBlock(p->value, b->block);
}
LLVMPositionBuilderAtEnd(p->builder, b->block);
p->curr_block = b;
}
void lb_begin_procedure_body(lbProcedure *p) {
DeclInfo *decl = decl_info_of_entity(p->entity);
if (decl != nullptr) {
for_array(i, decl->labels) {
BlockLabel bl = decl->labels[i];
lbBranchBlocks bb = {bl.label, nullptr, nullptr};
array_add(&p->branch_blocks, bb);
}
}
p->builder = LLVMCreateBuilderInContext(p->module->ctx);
p->decl_block = lb_create_block(p, "decls", true);
p->entry_block = lb_create_block(p, "entry", true);
lb_start_block(p, p->entry_block);
GB_ASSERT(p->type != nullptr);
lb_ensure_abi_function_type(p->module, p);
{
lbFunctionType *ft = p->abi_function_type;
unsigned param_offset = 0;
lbValue return_ptr_value = {};
if (ft->ret.kind == lbArg_Indirect) {
// NOTE(bill): this must be parameter 0
String name = str_lit("agg.result");
Type *ptr_type = alloc_type_pointer(reduce_tuple_to_single_type(p->type->Proc.results));
Entity *e = alloc_entity_param(nullptr, make_token_ident(name), ptr_type, false, false);
e->flags |= EntityFlag_Sret | EntityFlag_NoAlias;
return_ptr_value.value = LLVMGetParam(p->value, 0);
LLVMSetValueName2(return_ptr_value.value, cast(char const *)name.text, name.len);
return_ptr_value.type = ptr_type;
p->return_ptr = lb_addr(return_ptr_value);
lb_add_entity(p->module, e, return_ptr_value);
param_offset += 1;
}
if (p->type->Proc.params != nullptr) {
TypeTuple *params = &p->type->Proc.params->Tuple;
unsigned param_index = 0;
for_array(i, params->variables) {
Entity *e = params->variables[i];
if (e->kind != Entity_Variable) {
continue;
}
lbArgType *arg_type = &ft->args[param_index];
if (arg_type->kind == lbArg_Ignore) {
continue;
} else if (arg_type->kind == lbArg_Direct) {
lbParamPasskind kind = lbParamPass_Value;
LLVMTypeRef param_type = lb_type(p->module, e->type);
if (param_type != arg_type->type) {
kind = lbParamPass_BitCast;
}
LLVMValueRef value = LLVMGetParam(p->value, param_offset+param_index);
value = OdinLLVMBuildTransmute(p, value, param_type);
lbValue param = {};
param.value = value;
param.type = e->type;
array_add(&p->params, param);
if (e->token.string.len != 0) {
lbAddr l = lb_add_local(p, e->type, e, false, param_index);
lb_addr_store(p, l, param);
}
param_index += 1;
} else if (arg_type->kind == lbArg_Indirect) {
LLVMValueRef value_ptr = LLVMGetParam(p->value, param_offset+param_index);
LLVMValueRef value = LLVMBuildLoad(p->builder, value_ptr, "");
lbValue param = {};
param.value = value;
param.type = e->type;
array_add(&p->params, param);
lbValue ptr = {};
ptr.value = value_ptr;
ptr.type = alloc_type_pointer(e->type);
lb_add_entity(p->module, e, ptr);
param_index += 1;
}
}
}
if (p->type->Proc.has_named_results) {
GB_ASSERT(p->type->Proc.result_count > 0);
TypeTuple *results = &p->type->Proc.results->Tuple;
for_array(i, results->variables) {
Entity *e = results->variables[i];
GB_ASSERT(e->kind == Entity_Variable);
if (e->token.string != "") {
GB_ASSERT(!is_blank_ident(e->token));
lbAddr res = {};
if (return_ptr_value.value) {
lbValue ptr = return_ptr_value;
if (results->variables.count != 1) {
ptr = lb_emit_struct_ep(p, ptr, cast(i32)i);
}
res = lb_addr(ptr);
lb_add_entity(p->module, e, ptr);
} else {
res = lb_add_local(p, e->type, e);
}
if (e->Variable.param_value.kind != ParameterValue_Invalid) {
lbValue c = lb_handle_param_value(p, e->type, e->Variable.param_value, e->token.pos);
lb_addr_store(p, res, c);
}
}
}
}
}
if (p->type->Proc.calling_convention == ProcCC_Odin) {
lb_push_context_onto_stack_from_implicit_parameter(p);
}
lb_start_block(p, p->entry_block);
if (p->debug_info != nullptr) {
TokenPos pos = {};
if (p->body != nullptr) {
pos = ast_token(p->body).pos;
} else if (p->type_expr != nullptr) {
pos = ast_token(p->type_expr).pos;
} else if (p->entity != nullptr) {
pos = p->entity->token.pos;
}
if (pos.file_id != 0) {
LLVMSetCurrentDebugLocation2(p->builder, lb_debug_location_from_token_pos(p, pos));
}
if (p->context_stack.count != 0) {
lb_add_debug_context_variable(p, lb_find_or_generate_context_ptr(p));
}
}
}
void lb_end_procedure_body(lbProcedure *p) {
LLVMPositionBuilderAtEnd(p->builder, p->decl_block->block);
LLVMBuildBr(p->builder, p->entry_block->block);
LLVMPositionBuilderAtEnd(p->builder, p->curr_block->block);
LLVMValueRef instr = nullptr;
// Make sure there is a "ret void" at the end of a procedure with no return type
if (p->type->Proc.result_count == 0) {
instr = LLVMGetLastInstruction(p->curr_block->block);
if (!lb_is_instr_terminating(instr)) {
lb_emit_defer_stmts(p, lbDeferExit_Return, nullptr);
LLVMBuildRetVoid(p->builder);
}
}
LLVMBasicBlockRef first_block = LLVMGetFirstBasicBlock(p->value);
LLVMBasicBlockRef block = nullptr;
// Make sure every block terminates, and if not, make it unreachable
for (block = first_block; block != nullptr; block = LLVMGetNextBasicBlock(block)) {
instr = LLVMGetLastInstruction(block);
if (instr == nullptr || !lb_is_instr_terminating(instr)) {
LLVMPositionBuilderAtEnd(p->builder, block);
LLVMBuildUnreachable(p->builder);
}
}
p->curr_block = nullptr;
p->state_flags = 0;
}
void lb_end_procedure(lbProcedure *p) {
LLVMDisposeBuilder(p->builder);
}
void lb_build_nested_proc(lbProcedure *p, AstProcLit *pd, Entity *e) {
GB_ASSERT(pd->body != nullptr);
lbModule *m = p->module;
auto *min_dep_set = &m->info->minimum_dependency_set;
if (ptr_set_exists(min_dep_set, 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 (e->Procedure.link_name.len > 0) {
pd_name = e->Procedure.link_name;
}
isize name_len = p->name.len + 1 + pd_name.len + 1 + 10 + 1;
char *name_text = gb_alloc_array(permanent_allocator(), char, name_len);
i32 guid = cast(i32)p->children.count;
name_len = gb_snprintf(name_text, name_len, "%.*s.%.*s-%d", LIT(p->name), LIT(pd_name), guid);
String name = make_string(cast(u8 *)name_text, name_len-1);
e->Procedure.link_name = name;
lbProcedure *nested_proc = lb_create_procedure(p->module, e);
e->code_gen_procedure = nested_proc;
lbValue value = {};
value.value = nested_proc->value;
value.type = nested_proc->type;
lb_add_entity(m, e, value);
array_add(&p->children, nested_proc);
array_add(&m->procedures_to_generate, nested_proc);
}
Array<lbValue> lb_value_to_array(lbProcedure *p, lbValue value) {
Array<lbValue> array = {};
Type *t = base_type(value.type);
if (t == nullptr) {
// Do nothing
} else if (is_type_tuple(t)) {
GB_ASSERT(t->kind == Type_Tuple);
auto *rt = &t->Tuple;
if (rt->variables.count > 0) {
array = array_make<lbValue>(permanent_allocator(), rt->variables.count);
for_array(i, rt->variables) {
lbValue elem = lb_emit_struct_ev(p, value, cast(i32)i);
array[i] = elem;
}
}
} else {
array = array_make<lbValue>(permanent_allocator(), 1);
array[0] = value;
}
return array;
}
lbValue lb_emit_call_internal(lbProcedure *p, lbValue value, lbValue return_ptr, Array<lbValue> const &processed_args, Type *abi_rt, lbAddr context_ptr, ProcInlining inlining) {
GB_ASSERT(p->module->ctx == LLVMGetTypeContext(LLVMTypeOf(value.value)));
unsigned arg_count = cast(unsigned)processed_args.count;
if (return_ptr.value != nullptr) {
arg_count += 1;
}
if (context_ptr.addr.value != nullptr) {
arg_count += 1;
}
LLVMValueRef *args = gb_alloc_array(permanent_allocator(), LLVMValueRef, arg_count);
isize arg_index = 0;
if (return_ptr.value != nullptr) {
args[arg_index++] = return_ptr.value;
}
for_array(i, processed_args) {
lbValue arg = processed_args[i];
args[arg_index++] = arg.value;
}
if (context_ptr.addr.value != nullptr) {
LLVMValueRef cp = context_ptr.addr.value;
cp = LLVMBuildPointerCast(p->builder, cp, lb_type(p->module, t_rawptr), "");
args[arg_index++] = cp;
}
LLVMBasicBlockRef curr_block = LLVMGetInsertBlock(p->builder);
GB_ASSERT(curr_block != p->decl_block->block);
{
LLVMTypeRef ftp = lb_type(p->module, value.type);
LLVMValueRef fn = value.value;
if (!lb_is_type_kind(LLVMTypeOf(value.value), LLVMFunctionTypeKind)) {
fn = LLVMBuildPointerCast(p->builder, fn, ftp, "");
}
LLVMTypeRef fnp = LLVMGetElementType(LLVMTypeOf(fn));
GB_ASSERT_MSG(lb_is_type_kind(fnp, LLVMFunctionTypeKind), "%s", LLVMPrintTypeToString(fnp));
{
unsigned param_count = LLVMCountParamTypes(fnp);
GB_ASSERT(arg_count >= param_count);
LLVMTypeRef *param_types = gb_alloc_array(temporary_allocator(), LLVMTypeRef, param_count);
LLVMGetParamTypes(fnp, param_types);
for (unsigned i = 0; i < param_count; i++) {
LLVMTypeRef param_type = param_types[i];
LLVMTypeRef arg_type = LLVMTypeOf(args[i]);
// LLVMTypeKind param_kind = LLVMGetTypeKind(param_type);
// LLVMTypeKind arg_kind = LLVMGetTypeKind(arg_type);
GB_ASSERT_MSG(
arg_type == param_type,
"Parameter types do not match: %s != %s, argument: %s",
LLVMPrintTypeToString(arg_type),
LLVMPrintTypeToString(param_type),
LLVMPrintValueToString(args[i])
);
}
}
LLVMValueRef ret = LLVMBuildCall2(p->builder, fnp, fn, args, arg_count, "");
switch (inlining) {
case ProcInlining_none:
break;
case ProcInlining_inline:
LLVMAddCallSiteAttribute(ret, LLVMAttributeIndex_FunctionIndex, lb_create_enum_attribute(p->module->ctx, "alwaysinline"));
break;
case ProcInlining_no_inline:
LLVMAddCallSiteAttribute(ret, LLVMAttributeIndex_FunctionIndex, lb_create_enum_attribute(p->module->ctx, "noinline"));
break;
}
lbValue res = {};
res.value = ret;
res.type = abi_rt;
return res;
}
}
lbValue lb_lookup_runtime_procedure(lbModule *m, String const &name) {
AstPackage *pkg = m->info->runtime_package;
Entity *e = scope_lookup_current(pkg->scope, name);
return lb_find_procedure_value_from_entity(m, e);
}
lbValue lb_emit_runtime_call(lbProcedure *p, char const *c_name, Array<lbValue> const &args) {
String name = make_string_c(c_name);
lbValue proc = lb_lookup_runtime_procedure(p->module, name);
return lb_emit_call(p, proc, args);
}
lbValue lb_emit_conjugate(lbProcedure *p, lbValue val, Type *type) {
lbValue res = {};
Type *t = val.type;
if (is_type_complex(t)) {
res = lb_addr_get_ptr(p, lb_add_local_generated(p, type, false));
lbValue real = lb_emit_struct_ev(p, val, 0);
lbValue imag = lb_emit_struct_ev(p, val, 1);
imag = lb_emit_unary_arith(p, Token_Sub, imag, imag.type);
lb_emit_store(p, lb_emit_struct_ep(p, res, 0), real);
lb_emit_store(p, lb_emit_struct_ep(p, res, 1), imag);
} else if (is_type_quaternion(t)) {
// @QuaternionLayout
res = lb_addr_get_ptr(p, lb_add_local_generated(p, type, false));
lbValue real = lb_emit_struct_ev(p, val, 3);
lbValue imag = lb_emit_struct_ev(p, val, 0);
lbValue jmag = lb_emit_struct_ev(p, val, 1);
lbValue kmag = lb_emit_struct_ev(p, val, 2);
imag = lb_emit_unary_arith(p, Token_Sub, imag, imag.type);
jmag = lb_emit_unary_arith(p, Token_Sub, jmag, jmag.type);
kmag = lb_emit_unary_arith(p, Token_Sub, kmag, kmag.type);
lb_emit_store(p, lb_emit_struct_ep(p, res, 3), real);
lb_emit_store(p, lb_emit_struct_ep(p, res, 0), imag);
lb_emit_store(p, lb_emit_struct_ep(p, res, 1), jmag);
lb_emit_store(p, lb_emit_struct_ep(p, res, 2), kmag);
} else if (is_type_array_like(t)) {
res = lb_addr_get_ptr(p, lb_add_local_generated(p, type, true));
Type *elem_type = base_array_type(t);
i64 count = get_array_type_count(t);
for (i64 i = 0; i < count; i++) {
lbValue dst = lb_emit_array_epi(p, res, i);
lbValue elem = lb_emit_struct_ev(p, val, cast(i32)i);
elem = lb_emit_conjugate(p, elem, elem_type);
lb_emit_store(p, dst, elem);
}
} else if (is_type_matrix(t)) {
Type *mt = base_type(t);
GB_ASSERT(mt->kind == Type_Matrix);
Type *elem_type = mt->Matrix.elem;
res = lb_addr_get_ptr(p, lb_add_local_generated(p, type, true));
for (i64 j = 0; j < mt->Matrix.column_count; j++) {
for (i64 i = 0; i < mt->Matrix.row_count; i++) {
lbValue dst = lb_emit_matrix_epi(p, res, i, j);
lbValue elem = lb_emit_matrix_ev(p, val, i, j);
elem = lb_emit_conjugate(p, elem, elem_type);
lb_emit_store(p, dst, elem);
}
}
}
return lb_emit_load(p, res);
}
lbValue lb_emit_call(lbProcedure *p, lbValue value, Array<lbValue> const &args, ProcInlining inlining, bool use_copy_elision_hint) {
lbModule *m = p->module;
Type *pt = base_type(value.type);
GB_ASSERT(pt->kind == Type_Proc);
Type *results = pt->Proc.results;
if (p->entity != nullptr) {
if (p->entity->flags & EntityFlag_Disabled) {
return {};
}
}
lbAddr context_ptr = {};
if (pt->Proc.calling_convention == ProcCC_Odin) {
context_ptr = lb_find_or_generate_context_ptr(p);
}
defer (if (pt->Proc.diverging) {
LLVMBuildUnreachable(p->builder);
});
bool is_c_vararg = pt->Proc.c_vararg;
isize param_count = pt->Proc.param_count;
if (is_c_vararg) {
GB_ASSERT(param_count-1 <= args.count);
param_count -= 1;
} else {
GB_ASSERT_MSG(param_count == args.count, "%td == %td", param_count, args.count);
}
lbValue result = {};
auto processed_args = array_make<lbValue>(permanent_allocator(), 0, args.count);
{
lbFunctionType *ft = lb_get_function_type(m, p, pt);
bool return_by_pointer = ft->ret.kind == lbArg_Indirect;
unsigned param_index = 0;
for (isize i = 0; i < param_count; i++) {
Entity *e = pt->Proc.params->Tuple.variables[i];
if (e->kind != Entity_Variable) {
continue;
}
GB_ASSERT(e->flags & EntityFlag_Param);
Type *original_type = e->type;
lbArgType *arg = &ft->args[param_index];
if (arg->kind == lbArg_Ignore) {
continue;
}
lbValue x = lb_emit_conv(p, args[i], original_type);
LLVMTypeRef xt = lb_type(p->module, x.type);
if (arg->kind == lbArg_Direct) {
LLVMTypeRef abi_type = arg->cast_type;
if (!abi_type) {
abi_type = arg->type;
}
if (xt == abi_type) {
array_add(&processed_args, x);
} else {
x.value = OdinLLVMBuildTransmute(p, x.value, abi_type);
array_add(&processed_args, x);
}
} else if (arg->kind == lbArg_Indirect) {
lbValue ptr = {};
if (arg->is_byval) {
ptr = lb_copy_value_to_ptr(p, x, original_type, arg->byval_alignment);
} else if (is_calling_convention_odin(pt->Proc.calling_convention)) {
// NOTE(bill): Odin parameters are immutable so the original value can be passed if possible
// i.e. `T const &` in C++
ptr = lb_address_from_load_or_generate_local(p, x);
} else {
ptr = lb_copy_value_to_ptr(p, x, original_type, 16);
}
array_add(&processed_args, ptr);
}
param_index += 1;
}
if (is_c_vararg) {
for (isize i = processed_args.count; i < args.count; i++) {
array_add(&processed_args, args[i]);
}
}
if (inlining == ProcInlining_none) {
inlining = p->inlining;
}
Type *rt = reduce_tuple_to_single_type(results);
if (return_by_pointer) {
lbValue return_ptr = {};
if (use_copy_elision_hint && p->copy_elision_hint.ptr.value != nullptr) {
if (are_types_identical(type_deref(p->copy_elision_hint.ptr.type), rt)) {
return_ptr = lb_consume_copy_elision_hint(p);
}
}
if (return_ptr.value == nullptr) {
lbAddr r = lb_add_local_generated(p, rt, true);
return_ptr = r.addr;
}
GB_ASSERT(is_type_pointer(return_ptr.type));
lb_emit_call_internal(p, value, return_ptr, processed_args, nullptr, context_ptr, inlining);
result = lb_emit_load(p, return_ptr);
} else if (rt != nullptr) {
result = lb_emit_call_internal(p, value, {}, processed_args, rt, context_ptr, inlining);
if (ft->ret.cast_type) {
result.value = OdinLLVMBuildTransmute(p, result.value, ft->ret.cast_type);
}
result.value = OdinLLVMBuildTransmute(p, result.value, ft->ret.type);
result.type = rt;
if (LLVMTypeOf(result.value) == LLVMInt1TypeInContext(p->module->ctx)) {
result.type = t_llvm_bool;
}
if (!is_type_tuple(rt)) {
result = lb_emit_conv(p, result, rt);
}
} else {
lb_emit_call_internal(p, value, {}, processed_args, nullptr, context_ptr, inlining);
}
}
Entity **found = map_get(&p->module->procedure_values, value.value);
if (found != nullptr) {
Entity *e = *found;
if (e != nullptr && entity_has_deferred_procedure(e)) {
DeferredProcedureKind kind = e->Procedure.deferred_procedure.kind;
Entity *deferred_entity = e->Procedure.deferred_procedure.entity;
lbValue deferred = lb_find_procedure_value_from_entity(p->module, deferred_entity);
auto in_args = args;
Array<lbValue> result_as_args = {};
switch (kind) {
case DeferredProcedure_none:
break;
case DeferredProcedure_in:
result_as_args = in_args;
break;
case DeferredProcedure_out:
result_as_args = lb_value_to_array(p, result);
break;
case DeferredProcedure_in_out:
{
auto out_args = lb_value_to_array(p, result);
array_init(&result_as_args, permanent_allocator(), in_args.count + out_args.count);
array_copy(&result_as_args, in_args, 0);
array_copy(&result_as_args, out_args, in_args.count);
}
break;
}
lb_add_defer_proc(p, p->scope_index, deferred, result_as_args);
}
}
return result;
}
lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv, BuiltinProcId id) {
ast_node(ce, CallExpr, expr);
switch (id) {
case BuiltinProc_DIRECTIVE: {
ast_node(bd, BasicDirective, ce->proc);
String name = bd->name.string;
GB_ASSERT(name == "location");
String procedure = p->entity->token.string;
TokenPos pos = ast_token(ce->proc).pos;
if (ce->args.count > 0) {
Ast *ident = unselector_expr(ce->args[0]);
GB_ASSERT(ident->kind == Ast_Ident);
Entity *e = entity_of_node(ident);
GB_ASSERT(e != nullptr);
if (e->parent_proc_decl != nullptr && e->parent_proc_decl->entity != nullptr) {
procedure = e->parent_proc_decl->entity->token.string;
} else {
procedure = str_lit("");
}
pos = e->token.pos;
}
return lb_emit_source_code_location(p, procedure, pos);
}
case BuiltinProc_type_info_of: {
Ast *arg = ce->args[0];
TypeAndValue tav = type_and_value_of_expr(arg);
if (tav.mode == Addressing_Type) {
Type *t = default_type(type_of_expr(arg));
return lb_type_info(p->module, t);
}
GB_ASSERT(is_type_typeid(tav.type));
auto args = array_make<lbValue>(permanent_allocator(), 1);
args[0] = lb_build_expr(p, arg);
return lb_emit_runtime_call(p, "__type_info_of", args);
}
case BuiltinProc_typeid_of: {
Ast *arg = ce->args[0];
TypeAndValue tav = type_and_value_of_expr(arg);
GB_ASSERT(tav.mode == Addressing_Type);
Type *t = default_type(type_of_expr(arg));
return lb_typeid(p->module, t);
}
case BuiltinProc_len: {
lbValue v = lb_build_expr(p, ce->args[0]);
Type *t = base_type(v.type);
if (is_type_pointer(t)) {
// IMPORTANT TODO(bill): Should there be a nil pointer check?
v = lb_emit_load(p, v);
t = type_deref(t);
}
if (is_type_cstring(t)) {
return lb_cstring_len(p, v);
} else if (is_type_string(t)) {
return lb_string_len(p, v);
} else if (is_type_array(t)) {
GB_PANIC("Array lengths are constant");
} else if (is_type_slice(t)) {
return lb_slice_len(p, v);
} else if (is_type_dynamic_array(t)) {
return lb_dynamic_array_len(p, v);
} else if (is_type_map(t)) {
return lb_map_len(p, v);
} else if (is_type_soa_struct(t)) {
return lb_soa_struct_len(p, v);
}
GB_PANIC("Unreachable");
break;
}
case BuiltinProc_cap: {
lbValue v = lb_build_expr(p, ce->args[0]);
Type *t = base_type(v.type);
if (is_type_pointer(t)) {
// IMPORTANT TODO(bill): Should there be a nil pointer check?
v = lb_emit_load(p, 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_slice(t)) {
return lb_slice_len(p, v);
} else if (is_type_dynamic_array(t)) {
return lb_dynamic_array_cap(p, v);
} else if (is_type_map(t)) {
return lb_map_cap(p, v);
} else if (is_type_soa_struct(t)) {
return lb_soa_struct_cap(p, v);
}
GB_PANIC("Unreachable");
break;
}
case BuiltinProc_swizzle: {
isize index_count = ce->args.count-1;
if (is_type_simd_vector(tv.type)) {
lbValue vec = lb_build_expr(p, ce->args[0]);
if (index_count == 0) {
return vec;
}
unsigned mask_len = cast(unsigned)index_count;
LLVMValueRef *mask_elems = gb_alloc_array(permanent_allocator(), LLVMValueRef, index_count);
for (isize i = 1; i < ce->args.count; i++) {
TypeAndValue tv = type_and_value_of_expr(ce->args[i]);
GB_ASSERT(is_type_integer(tv.type));
GB_ASSERT(tv.value.kind == ExactValue_Integer);
u32 index = cast(u32)big_int_to_i64(&tv.value.value_integer);
mask_elems[i-1] = LLVMConstInt(lb_type(p->module, t_u32), index, false);
}
LLVMValueRef mask = LLVMConstVector(mask_elems, mask_len);
LLVMValueRef v1 = vec.value;
LLVMValueRef v2 = vec.value;
lbValue res = {};
res.type = tv.type;
res.value = LLVMBuildShuffleVector(p->builder, v1, v2, mask, "");
return res;
}
lbAddr addr = lb_build_array_swizzle_addr(p, ce, tv);
return lb_addr_load(p, addr);
}
case BuiltinProc_complex: {
lbValue real = lb_build_expr(p, ce->args[0]);
lbValue imag = lb_build_expr(p, ce->args[1]);
lbAddr dst_addr = lb_add_local_generated(p, tv.type, false);
lbValue dst = lb_addr_get_ptr(p, dst_addr);
Type *ft = base_complex_elem_type(tv.type);
real = lb_emit_conv(p, real, ft);
imag = lb_emit_conv(p, imag, ft);
lb_emit_store(p, lb_emit_struct_ep(p, dst, 0), real);
lb_emit_store(p, lb_emit_struct_ep(p, dst, 1), imag);
return lb_emit_load(p, dst);
}
case BuiltinProc_quaternion: {
lbValue real = lb_build_expr(p, ce->args[0]);
lbValue imag = lb_build_expr(p, ce->args[1]);
lbValue jmag = lb_build_expr(p, ce->args[2]);
lbValue kmag = lb_build_expr(p, ce->args[3]);
// @QuaternionLayout
lbAddr dst_addr = lb_add_local_generated(p, tv.type, false);
lbValue dst = lb_addr_get_ptr(p, dst_addr);
Type *ft = base_complex_elem_type(tv.type);
real = lb_emit_conv(p, real, ft);
imag = lb_emit_conv(p, imag, ft);
jmag = lb_emit_conv(p, jmag, ft);
kmag = lb_emit_conv(p, kmag, ft);
lb_emit_store(p, lb_emit_struct_ep(p, dst, 3), real);
lb_emit_store(p, lb_emit_struct_ep(p, dst, 0), imag);
lb_emit_store(p, lb_emit_struct_ep(p, dst, 1), jmag);
lb_emit_store(p, lb_emit_struct_ep(p, dst, 2), kmag);
return lb_emit_load(p, dst);
}
case BuiltinProc_real: {
lbValue val = lb_build_expr(p, ce->args[0]);
if (is_type_complex(val.type)) {
lbValue real = lb_emit_struct_ev(p, val, 0);
return lb_emit_conv(p, real, tv.type);
} else if (is_type_quaternion(val.type)) {
// @QuaternionLayout
lbValue real = lb_emit_struct_ev(p, val, 3);
return lb_emit_conv(p, real, tv.type);
}
GB_PANIC("invalid type for real");
return {};
}
case BuiltinProc_imag: {
lbValue val = lb_build_expr(p, ce->args[0]);
if (is_type_complex(val.type)) {
lbValue imag = lb_emit_struct_ev(p, val, 1);
return lb_emit_conv(p, imag, tv.type);
} else if (is_type_quaternion(val.type)) {
// @QuaternionLayout
lbValue imag = lb_emit_struct_ev(p, val, 0);
return lb_emit_conv(p, imag, tv.type);
}
GB_PANIC("invalid type for imag");
return {};
}
case BuiltinProc_jmag: {
lbValue val = lb_build_expr(p, ce->args[0]);
if (is_type_quaternion(val.type)) {
// @QuaternionLayout
lbValue imag = lb_emit_struct_ev(p, val, 1);
return lb_emit_conv(p, imag, tv.type);
}
GB_PANIC("invalid type for jmag");
return {};
}
case BuiltinProc_kmag: {
lbValue val = lb_build_expr(p, ce->args[0]);
if (is_type_quaternion(val.type)) {
// @QuaternionLayout
lbValue imag = lb_emit_struct_ev(p, val, 2);
return lb_emit_conv(p, imag, tv.type);
}
GB_PANIC("invalid type for kmag");
return {};
}
case BuiltinProc_conj: {
lbValue val = lb_build_expr(p, ce->args[0]);
return lb_emit_conjugate(p, val, tv.type);
}
case BuiltinProc_expand_to_tuple: {
lbValue val = lb_build_expr(p, ce->args[0]);
Type *t = base_type(val.type);
if (!is_type_tuple(tv.type)) {
if (t->kind == Type_Struct) {
GB_ASSERT(t->Struct.fields.count == 1);
return lb_emit_struct_ev(p, val, 0);
} else if (t->kind == Type_Array) {
GB_ASSERT(t->Array.count == 1);
return lb_emit_array_epi(p, val, 0);
} else {
GB_PANIC("Unknown type of expand_to_tuple");
}
}
GB_ASSERT(is_type_tuple(tv.type));
// NOTE(bill): Doesn't need to be zero because it will be initialized in the loops
lbValue tuple = lb_addr_get_ptr(p, lb_add_local_generated(p, tv.type, false));
if (t->kind == Type_Struct) {
for_array(src_index, t->Struct.fields) {
Entity *field = t->Struct.fields[src_index];
i32 field_index = field->Variable.field_index;
lbValue f = lb_emit_struct_ev(p, val, field_index);
lbValue ep = lb_emit_struct_ep(p, tuple, cast(i32)src_index);
lb_emit_store(p, ep, f);
}
} else if (is_type_array_like(t)) {
// TODO(bill): Clean-up this code
lbValue ap = lb_address_from_load_or_generate_local(p, val);
i32 n = cast(i32)get_array_type_count(t);
for (i32 i = 0; i < n; i++) {
lbValue f = lb_emit_load(p, lb_emit_array_epi(p, ap, i));
lbValue ep = lb_emit_struct_ep(p, tuple, i);
lb_emit_store(p, ep, f);
}
} else {
GB_PANIC("Unknown type of expand_to_tuple");
}
return lb_emit_load(p, tuple);
}
case BuiltinProc_min: {
Type *t = type_of_expr(expr);
if (ce->args.count == 2) {
return lb_emit_min(p, t, lb_build_expr(p, ce->args[0]), lb_build_expr(p, ce->args[1]));
} else {
lbValue x = lb_build_expr(p, ce->args[0]);
for (isize i = 1; i < ce->args.count; i++) {
x = lb_emit_min(p, t, x, lb_build_expr(p, ce->args[i]));
}
return x;
}
}
case BuiltinProc_max: {
Type *t = type_of_expr(expr);
if (ce->args.count == 2) {
return lb_emit_max(p, t, lb_build_expr(p, ce->args[0]), lb_build_expr(p, ce->args[1]));
} else {
lbValue x = lb_build_expr(p, ce->args[0]);
for (isize i = 1; i < ce->args.count; i++) {
x = lb_emit_max(p, t, x, lb_build_expr(p, ce->args[i]));
}
return x;
}
}
case BuiltinProc_abs: {
lbValue x = lb_build_expr(p, ce->args[0]);
Type *t = x.type;
if (is_type_unsigned(t)) {
return x;
}
if (is_type_quaternion(t)) {
i64 sz = 8*type_size_of(t);
auto args = array_make<lbValue>(permanent_allocator(), 1);
args[0] = x;
switch (sz) {
case 64: return lb_emit_runtime_call(p, "abs_quaternion64", args);
case 128: return lb_emit_runtime_call(p, "abs_quaternion128", args);
case 256: return lb_emit_runtime_call(p, "abs_quaternion256", args);
}
GB_PANIC("Unknown complex type");
} else if (is_type_complex(t)) {
i64 sz = 8*type_size_of(t);
auto args = array_make<lbValue>(permanent_allocator(), 1);
args[0] = x;
switch (sz) {
case 32: return lb_emit_runtime_call(p, "abs_complex32", args);
case 64: return lb_emit_runtime_call(p, "abs_complex64", args);
case 128: return lb_emit_runtime_call(p, "abs_complex128", args);
}
GB_PANIC("Unknown complex type");
}
lbValue zero = lb_const_nil(p->module, t);
lbValue cond = lb_emit_comp(p, Token_Lt, x, zero);
lbValue neg = lb_emit_unary_arith(p, Token_Sub, x, t);
return lb_emit_select(p, cond, neg, x);
}
case BuiltinProc_clamp:
return lb_emit_clamp(p, type_of_expr(expr),
lb_build_expr(p, ce->args[0]),
lb_build_expr(p, ce->args[1]),
lb_build_expr(p, ce->args[2]));
case BuiltinProc_soa_zip:
return lb_soa_zip(p, ce, tv);
case BuiltinProc_soa_unzip:
return lb_soa_unzip(p, ce, tv);
case BuiltinProc_transpose:
{
lbValue m = lb_build_expr(p, ce->args[0]);
return lb_emit_matrix_tranpose(p, m, tv.type);
}
case BuiltinProc_outer_product:
{
lbValue a = lb_build_expr(p, ce->args[0]);
lbValue b = lb_build_expr(p, ce->args[1]);
return lb_emit_outer_product(p, a, b, tv.type);
}
case BuiltinProc_hadamard_product:
{
lbValue a = lb_build_expr(p, ce->args[0]);
lbValue b = lb_build_expr(p, ce->args[1]);
if (is_type_array(tv.type)) {
return lb_emit_arith(p, Token_Mul, a, b, tv.type);
}
GB_ASSERT(is_type_matrix(tv.type));
return lb_emit_arith_matrix(p, Token_Mul, a, b, tv.type, true);
}
case BuiltinProc_matrix_flatten:
{
lbValue m = lb_build_expr(p, ce->args[0]);
return lb_emit_matrix_flatten(p, m, tv.type);
}
// "Intrinsics"
case BuiltinProc_alloca:
{
lbValue sz = lb_build_expr(p, ce->args[0]);
i64 al = exact_value_to_i64(type_and_value_of_expr(ce->args[1]).value);
lbValue res = {};
res.type = t_u8_ptr;
res.value = LLVMBuildArrayAlloca(p->builder, lb_type(p->module, t_u8), sz.value, "");
LLVMSetAlignment(res.value, cast(unsigned)al);
return res;
}
case BuiltinProc_cpu_relax:
if (build_context.metrics.arch == TargetArch_386 ||
build_context.metrics.arch == TargetArch_amd64) {
LLVMTypeRef func_type = LLVMFunctionType(LLVMVoidTypeInContext(p->module->ctx), nullptr, 0, false);
LLVMValueRef the_asm = llvm_get_inline_asm(func_type, str_lit("pause"), {});
GB_ASSERT(the_asm != nullptr);
LLVMBuildCall2(p->builder, func_type, the_asm, nullptr, 0, "");
} else if (build_context.metrics.arch == TargetArch_arm64) {
LLVMTypeRef func_type = LLVMFunctionType(LLVMVoidTypeInContext(p->module->ctx), nullptr, 0, false);
LLVMValueRef the_asm = llvm_get_inline_asm(func_type, str_lit("yield"), {});
GB_ASSERT(the_asm != nullptr);
LLVMBuildCall2(p->builder, func_type, the_asm, nullptr, 0, "");
}
return {};
case BuiltinProc_debug_trap:
case BuiltinProc_trap:
{
char const *name = nullptr;
switch (id) {
case BuiltinProc_debug_trap: name = "llvm.debugtrap"; break;
case BuiltinProc_trap: name = "llvm.trap"; break;
}
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s", name);
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, nullptr, 0);
LLVMBuildCall(p->builder, ip, nullptr, 0, "");
if (id == BuiltinProc_trap) {
LLVMBuildUnreachable(p->builder);
}
return {};
}
case BuiltinProc_read_cycle_counter:
{
char const *name = "llvm.readcyclecounter";
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s", name);
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, nullptr, 0);
lbValue res = {};
res.value = LLVMBuildCall(p->builder, ip, nullptr, 0, "");
res.type = tv.type;
return res;
}
case BuiltinProc_count_trailing_zeros:
return lb_emit_count_trailing_zeros(p, lb_build_expr(p, ce->args[0]), tv.type);
case BuiltinProc_count_leading_zeros:
return lb_emit_count_leading_zeros(p, lb_build_expr(p, ce->args[0]), tv.type);
case BuiltinProc_count_ones:
return lb_emit_count_ones(p, lb_build_expr(p, ce->args[0]), tv.type);
case BuiltinProc_count_zeros:
return lb_emit_count_zeros(p, lb_build_expr(p, ce->args[0]), tv.type);
case BuiltinProc_reverse_bits:
return lb_emit_reverse_bits(p, lb_build_expr(p, ce->args[0]), tv.type);
case BuiltinProc_byte_swap:
{
lbValue x = lb_build_expr(p, ce->args[0]);
x = lb_emit_conv(p, x, tv.type);
return lb_emit_byte_swap(p, x, tv.type);
}
case BuiltinProc_overflow_add:
case BuiltinProc_overflow_sub:
case BuiltinProc_overflow_mul:
{
Type *main_type = tv.type;
Type *type = main_type;
if (is_type_tuple(main_type)) {
type = main_type->Tuple.variables[0]->type;
}
lbValue x = lb_build_expr(p, ce->args[0]);
lbValue y = lb_build_expr(p, ce->args[1]);
x = lb_emit_conv(p, x, type);
y = lb_emit_conv(p, y, type);
char const *name = nullptr;
if (is_type_unsigned(type)) {
switch (id) {
case BuiltinProc_overflow_add: name = "llvm.uadd.with.overflow"; break;
case BuiltinProc_overflow_sub: name = "llvm.usub.with.overflow"; break;
case BuiltinProc_overflow_mul: name = "llvm.umul.with.overflow"; break;
}
} else {
switch (id) {
case BuiltinProc_overflow_add: name = "llvm.sadd.with.overflow"; break;
case BuiltinProc_overflow_sub: name = "llvm.ssub.with.overflow"; break;
case BuiltinProc_overflow_mul: name = "llvm.smul.with.overflow"; break;
}
}
LLVMTypeRef types[1] = {lb_type(p->module, type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[2] = {};
args[0] = x.value;
args[1] = y.value;
lbValue res = {};
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
if (is_type_tuple(main_type)) {
Type *res_type = nullptr;
gbAllocator a = permanent_allocator();
res_type = alloc_type_tuple();
slice_init(&res_type->Tuple.variables, a, 2);
res_type->Tuple.variables[0] = alloc_entity_field(nullptr, blank_token, type, false, 0);
res_type->Tuple.variables[1] = alloc_entity_field(nullptr, blank_token, t_llvm_bool, false, 1);
res.type = res_type;
} else {
res.value = LLVMBuildExtractValue(p->builder, res.value, 0, "");
res.type = type;
}
return res;
}
case BuiltinProc_sqrt:
{
Type *type = tv.type;
lbValue x = lb_build_expr(p, ce->args[0]);
x = lb_emit_conv(p, x, type);
char const *name = "llvm.sqrt";
LLVMTypeRef types[1] = {lb_type(p->module, type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[1] = {};
args[0] = x.value;
lbValue res = {};
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.type = type;
return res;
}
case BuiltinProc_mem_copy:
{
lbValue dst = lb_build_expr(p, ce->args[0]);
lbValue src = lb_build_expr(p, ce->args[1]);
lbValue len = lb_build_expr(p, ce->args[2]);
lb_mem_copy_overlapping(p, dst, src, len, false);
return {};
}
case BuiltinProc_mem_copy_non_overlapping:
{
lbValue dst = lb_build_expr(p, ce->args[0]);
lbValue src = lb_build_expr(p, ce->args[1]);
lbValue len = lb_build_expr(p, ce->args[2]);
lb_mem_copy_non_overlapping(p, dst, src, len, false);
return {};
}
case BuiltinProc_mem_zero:
{
lbValue ptr = lb_build_expr(p, ce->args[0]);
lbValue len = lb_build_expr(p, ce->args[1]);
ptr = lb_emit_conv(p, ptr, t_rawptr);
len = lb_emit_conv(p, len, t_int);
unsigned alignment = 1;
lb_mem_zero_ptr_internal(p, ptr.value, len.value, alignment, false);
return {};
}
case BuiltinProc_mem_zero_volatile:
{
lbValue ptr = lb_build_expr(p, ce->args[0]);
lbValue len = lb_build_expr(p, ce->args[1]);
ptr = lb_emit_conv(p, ptr, t_rawptr);
len = lb_emit_conv(p, len, t_int);
unsigned alignment = 1;
lb_mem_zero_ptr_internal(p, ptr.value, len.value, alignment, true);
return {};
}
case BuiltinProc_ptr_offset:
{
lbValue ptr = lb_build_expr(p, ce->args[0]);
lbValue len = lb_build_expr(p, ce->args[1]);
len = lb_emit_conv(p, len, t_int);
LLVMValueRef indices[1] = {
len.value,
};
lbValue res = {};
res.type = tv.type;
res.value = LLVMBuildGEP(p->builder, ptr.value, indices, gb_count_of(indices), "");
return res;
}
case BuiltinProc_ptr_sub:
{
lbValue ptr0 = lb_build_expr(p, ce->args[0]);
lbValue ptr1 = lb_build_expr(p, ce->args[1]);
LLVMTypeRef type_int = lb_type(p->module, t_int);
LLVMValueRef diff = LLVMBuildPtrDiff(p->builder, ptr0.value, ptr1.value, "");
diff = LLVMBuildIntCast2(p->builder, diff, type_int, /*signed*/true, "");
lbValue res = {};
res.type = t_int;
res.value = diff;
return res;
}
case BuiltinProc_atomic_fence:
LLVMBuildFence(p->builder, LLVMAtomicOrderingSequentiallyConsistent, false, "");
return {};
case BuiltinProc_atomic_fence_acq:
LLVMBuildFence(p->builder, LLVMAtomicOrderingAcquire, false, "");
return {};
case BuiltinProc_atomic_fence_rel:
LLVMBuildFence(p->builder, LLVMAtomicOrderingRelease, false, "");
return {};
case BuiltinProc_atomic_fence_acqrel:
LLVMBuildFence(p->builder, LLVMAtomicOrderingAcquireRelease, false, "");
return {};
case BuiltinProc_volatile_store:
case BuiltinProc_atomic_store:
case BuiltinProc_atomic_store_rel:
case BuiltinProc_atomic_store_relaxed:
case BuiltinProc_atomic_store_unordered: {
lbValue dst = lb_build_expr(p, ce->args[0]);
lbValue val = lb_build_expr(p, ce->args[1]);
val = lb_emit_conv(p, val, type_deref(dst.type));
LLVMValueRef instr = LLVMBuildStore(p->builder, val.value, dst.value);
switch (id) {
case BuiltinProc_volatile_store: LLVMSetVolatile(instr, true); break;
case BuiltinProc_atomic_store: LLVMSetOrdering(instr, LLVMAtomicOrderingSequentiallyConsistent); break;
case BuiltinProc_atomic_store_rel: LLVMSetOrdering(instr, LLVMAtomicOrderingRelease); break;
case BuiltinProc_atomic_store_relaxed: LLVMSetOrdering(instr, LLVMAtomicOrderingMonotonic); break;
case BuiltinProc_atomic_store_unordered: LLVMSetOrdering(instr, LLVMAtomicOrderingUnordered); break;
}
LLVMSetAlignment(instr, cast(unsigned)type_align_of(type_deref(dst.type)));
return {};
}
case BuiltinProc_volatile_load:
case BuiltinProc_atomic_load:
case BuiltinProc_atomic_load_acq:
case BuiltinProc_atomic_load_relaxed:
case BuiltinProc_atomic_load_unordered: {
lbValue dst = lb_build_expr(p, ce->args[0]);
LLVMValueRef instr = LLVMBuildLoad(p->builder, dst.value, "");
switch (id) {
case BuiltinProc_volatile_load: LLVMSetVolatile(instr, true); break;
case BuiltinProc_atomic_load: LLVMSetOrdering(instr, LLVMAtomicOrderingSequentiallyConsistent); break;
case BuiltinProc_atomic_load_acq: LLVMSetOrdering(instr, LLVMAtomicOrderingAcquire); break;
case BuiltinProc_atomic_load_relaxed: LLVMSetOrdering(instr, LLVMAtomicOrderingMonotonic); break;
case BuiltinProc_atomic_load_unordered: LLVMSetOrdering(instr, LLVMAtomicOrderingUnordered); break;
}
LLVMSetAlignment(instr, cast(unsigned)type_align_of(type_deref(dst.type)));
lbValue res = {};
res.value = instr;
res.type = type_deref(dst.type);
return res;
}
case BuiltinProc_unaligned_store:
{
lbValue dst = lb_build_expr(p, ce->args[0]);
lbValue src = lb_build_expr(p, ce->args[1]);
src = lb_address_from_load_or_generate_local(p, src);
Type *t = type_deref(dst.type);
lb_mem_copy_non_overlapping(p, dst, src, lb_const_int(p->module, t_int, type_size_of(t)), false);
return {};
}
case BuiltinProc_unaligned_load:
{
lbValue src = lb_build_expr(p, ce->args[0]);
Type *t = type_deref(src.type);
lbAddr dst = lb_add_local_generated(p, t, false);
lb_mem_copy_non_overlapping(p, dst.addr, src, lb_const_int(p->module, t_int, type_size_of(t)), false);
return lb_addr_load(p, dst);
}
case BuiltinProc_atomic_add:
case BuiltinProc_atomic_add_acq:
case BuiltinProc_atomic_add_rel:
case BuiltinProc_atomic_add_acqrel:
case BuiltinProc_atomic_add_relaxed:
case BuiltinProc_atomic_sub:
case BuiltinProc_atomic_sub_acq:
case BuiltinProc_atomic_sub_rel:
case BuiltinProc_atomic_sub_acqrel:
case BuiltinProc_atomic_sub_relaxed:
case BuiltinProc_atomic_and:
case BuiltinProc_atomic_and_acq:
case BuiltinProc_atomic_and_rel:
case BuiltinProc_atomic_and_acqrel:
case BuiltinProc_atomic_and_relaxed:
case BuiltinProc_atomic_nand:
case BuiltinProc_atomic_nand_acq:
case BuiltinProc_atomic_nand_rel:
case BuiltinProc_atomic_nand_acqrel:
case BuiltinProc_atomic_nand_relaxed:
case BuiltinProc_atomic_or:
case BuiltinProc_atomic_or_acq:
case BuiltinProc_atomic_or_rel:
case BuiltinProc_atomic_or_acqrel:
case BuiltinProc_atomic_or_relaxed:
case BuiltinProc_atomic_xor:
case BuiltinProc_atomic_xor_acq:
case BuiltinProc_atomic_xor_rel:
case BuiltinProc_atomic_xor_acqrel:
case BuiltinProc_atomic_xor_relaxed:
case BuiltinProc_atomic_xchg:
case BuiltinProc_atomic_xchg_acq:
case BuiltinProc_atomic_xchg_rel:
case BuiltinProc_atomic_xchg_acqrel:
case BuiltinProc_atomic_xchg_relaxed: {
lbValue dst = lb_build_expr(p, ce->args[0]);
lbValue val = lb_build_expr(p, ce->args[1]);
val = lb_emit_conv(p, val, type_deref(dst.type));
LLVMAtomicRMWBinOp op = {};
LLVMAtomicOrdering ordering = {};
switch (id) {
case BuiltinProc_atomic_add: op = LLVMAtomicRMWBinOpAdd; ordering = LLVMAtomicOrderingSequentiallyConsistent; break;
case BuiltinProc_atomic_add_acq: op = LLVMAtomicRMWBinOpAdd; ordering = LLVMAtomicOrderingAcquire; break;
case BuiltinProc_atomic_add_rel: op = LLVMAtomicRMWBinOpAdd; ordering = LLVMAtomicOrderingRelease; break;
case BuiltinProc_atomic_add_acqrel: op = LLVMAtomicRMWBinOpAdd; ordering = LLVMAtomicOrderingAcquireRelease; break;
case BuiltinProc_atomic_add_relaxed: op = LLVMAtomicRMWBinOpAdd; ordering = LLVMAtomicOrderingMonotonic; break;
case BuiltinProc_atomic_sub: op = LLVMAtomicRMWBinOpSub; ordering = LLVMAtomicOrderingSequentiallyConsistent; break;
case BuiltinProc_atomic_sub_acq: op = LLVMAtomicRMWBinOpSub; ordering = LLVMAtomicOrderingAcquire; break;
case BuiltinProc_atomic_sub_rel: op = LLVMAtomicRMWBinOpSub; ordering = LLVMAtomicOrderingRelease; break;
case BuiltinProc_atomic_sub_acqrel: op = LLVMAtomicRMWBinOpSub; ordering = LLVMAtomicOrderingAcquireRelease; break;
case BuiltinProc_atomic_sub_relaxed: op = LLVMAtomicRMWBinOpSub; ordering = LLVMAtomicOrderingMonotonic; break;
case BuiltinProc_atomic_and: op = LLVMAtomicRMWBinOpAnd; ordering = LLVMAtomicOrderingSequentiallyConsistent; break;
case BuiltinProc_atomic_and_acq: op = LLVMAtomicRMWBinOpAnd; ordering = LLVMAtomicOrderingAcquire; break;
case BuiltinProc_atomic_and_rel: op = LLVMAtomicRMWBinOpAnd; ordering = LLVMAtomicOrderingRelease; break;
case BuiltinProc_atomic_and_acqrel: op = LLVMAtomicRMWBinOpAnd; ordering = LLVMAtomicOrderingAcquireRelease; break;
case BuiltinProc_atomic_and_relaxed: op = LLVMAtomicRMWBinOpAnd; ordering = LLVMAtomicOrderingMonotonic; break;
case BuiltinProc_atomic_nand: op = LLVMAtomicRMWBinOpNand; ordering = LLVMAtomicOrderingSequentiallyConsistent; break;
case BuiltinProc_atomic_nand_acq: op = LLVMAtomicRMWBinOpNand; ordering = LLVMAtomicOrderingAcquire; break;
case BuiltinProc_atomic_nand_rel: op = LLVMAtomicRMWBinOpNand; ordering = LLVMAtomicOrderingRelease; break;
case BuiltinProc_atomic_nand_acqrel: op = LLVMAtomicRMWBinOpNand; ordering = LLVMAtomicOrderingAcquireRelease; break;
case BuiltinProc_atomic_nand_relaxed: op = LLVMAtomicRMWBinOpNand; ordering = LLVMAtomicOrderingMonotonic; break;
case BuiltinProc_atomic_or: op = LLVMAtomicRMWBinOpOr; ordering = LLVMAtomicOrderingSequentiallyConsistent; break;
case BuiltinProc_atomic_or_acq: op = LLVMAtomicRMWBinOpOr; ordering = LLVMAtomicOrderingAcquire; break;
case BuiltinProc_atomic_or_rel: op = LLVMAtomicRMWBinOpOr; ordering = LLVMAtomicOrderingRelease; break;
case BuiltinProc_atomic_or_acqrel: op = LLVMAtomicRMWBinOpOr; ordering = LLVMAtomicOrderingAcquireRelease; break;
case BuiltinProc_atomic_or_relaxed: op = LLVMAtomicRMWBinOpOr; ordering = LLVMAtomicOrderingMonotonic; break;
case BuiltinProc_atomic_xor: op = LLVMAtomicRMWBinOpXor; ordering = LLVMAtomicOrderingSequentiallyConsistent; break;
case BuiltinProc_atomic_xor_acq: op = LLVMAtomicRMWBinOpXor; ordering = LLVMAtomicOrderingAcquire; break;
case BuiltinProc_atomic_xor_rel: op = LLVMAtomicRMWBinOpXor; ordering = LLVMAtomicOrderingRelease; break;
case BuiltinProc_atomic_xor_acqrel: op = LLVMAtomicRMWBinOpXor; ordering = LLVMAtomicOrderingAcquireRelease; break;
case BuiltinProc_atomic_xor_relaxed: op = LLVMAtomicRMWBinOpXor; ordering = LLVMAtomicOrderingMonotonic; break;
case BuiltinProc_atomic_xchg: op = LLVMAtomicRMWBinOpXchg; ordering = LLVMAtomicOrderingSequentiallyConsistent; break;
case BuiltinProc_atomic_xchg_acq: op = LLVMAtomicRMWBinOpXchg; ordering = LLVMAtomicOrderingAcquire; break;
case BuiltinProc_atomic_xchg_rel: op = LLVMAtomicRMWBinOpXchg; ordering = LLVMAtomicOrderingRelease; break;
case BuiltinProc_atomic_xchg_acqrel: op = LLVMAtomicRMWBinOpXchg; ordering = LLVMAtomicOrderingAcquireRelease; break;
case BuiltinProc_atomic_xchg_relaxed: op = LLVMAtomicRMWBinOpXchg; ordering = LLVMAtomicOrderingMonotonic; break;
}
lbValue res = {};
res.value = LLVMBuildAtomicRMW(p->builder, op, dst.value, val.value, ordering, false);
res.type = tv.type;
return res;
}
case BuiltinProc_atomic_cxchg:
case BuiltinProc_atomic_cxchg_acq:
case BuiltinProc_atomic_cxchg_rel:
case BuiltinProc_atomic_cxchg_acqrel:
case BuiltinProc_atomic_cxchg_relaxed:
case BuiltinProc_atomic_cxchg_failrelaxed:
case BuiltinProc_atomic_cxchg_failacq:
case BuiltinProc_atomic_cxchg_acq_failrelaxed:
case BuiltinProc_atomic_cxchg_acqrel_failrelaxed:
case BuiltinProc_atomic_cxchgweak:
case BuiltinProc_atomic_cxchgweak_acq:
case BuiltinProc_atomic_cxchgweak_rel:
case BuiltinProc_atomic_cxchgweak_acqrel:
case BuiltinProc_atomic_cxchgweak_relaxed:
case BuiltinProc_atomic_cxchgweak_failrelaxed:
case BuiltinProc_atomic_cxchgweak_failacq:
case BuiltinProc_atomic_cxchgweak_acq_failrelaxed:
case BuiltinProc_atomic_cxchgweak_acqrel_failrelaxed: {
lbValue address = lb_build_expr(p, ce->args[0]);
Type *elem = type_deref(address.type);
lbValue old_value = lb_build_expr(p, ce->args[1]);
lbValue new_value = lb_build_expr(p, ce->args[2]);
old_value = lb_emit_conv(p, old_value, elem);
new_value = lb_emit_conv(p, new_value, elem);
LLVMAtomicOrdering success_ordering = {};
LLVMAtomicOrdering failure_ordering = {};
LLVMBool weak = false;
switch (id) {
case BuiltinProc_atomic_cxchg: success_ordering = LLVMAtomicOrderingSequentiallyConsistent; failure_ordering = LLVMAtomicOrderingSequentiallyConsistent; weak = false; break;
case BuiltinProc_atomic_cxchg_acq: success_ordering = LLVMAtomicOrderingAcquire; failure_ordering = LLVMAtomicOrderingSequentiallyConsistent; weak = false; break;
case BuiltinProc_atomic_cxchg_rel: success_ordering = LLVMAtomicOrderingRelease; failure_ordering = LLVMAtomicOrderingSequentiallyConsistent; weak = false; break;
case BuiltinProc_atomic_cxchg_acqrel: success_ordering = LLVMAtomicOrderingAcquireRelease; failure_ordering = LLVMAtomicOrderingSequentiallyConsistent; weak = false; break;
case BuiltinProc_atomic_cxchg_relaxed: success_ordering = LLVMAtomicOrderingMonotonic; failure_ordering = LLVMAtomicOrderingMonotonic; weak = false; break;
case BuiltinProc_atomic_cxchg_failrelaxed: success_ordering = LLVMAtomicOrderingSequentiallyConsistent; failure_ordering = LLVMAtomicOrderingMonotonic; weak = false; break;
case BuiltinProc_atomic_cxchg_failacq: success_ordering = LLVMAtomicOrderingSequentiallyConsistent; failure_ordering = LLVMAtomicOrderingAcquire; weak = false; break;
case BuiltinProc_atomic_cxchg_acq_failrelaxed: success_ordering = LLVMAtomicOrderingAcquire; failure_ordering = LLVMAtomicOrderingMonotonic; weak = false; break;
case BuiltinProc_atomic_cxchg_acqrel_failrelaxed: success_ordering = LLVMAtomicOrderingAcquireRelease; failure_ordering = LLVMAtomicOrderingMonotonic; weak = false; break;
case BuiltinProc_atomic_cxchgweak: success_ordering = LLVMAtomicOrderingSequentiallyConsistent; failure_ordering = LLVMAtomicOrderingSequentiallyConsistent; weak = false; break;
case BuiltinProc_atomic_cxchgweak_acq: success_ordering = LLVMAtomicOrderingAcquire; failure_ordering = LLVMAtomicOrderingSequentiallyConsistent; weak = true; break;
case BuiltinProc_atomic_cxchgweak_rel: success_ordering = LLVMAtomicOrderingRelease; failure_ordering = LLVMAtomicOrderingSequentiallyConsistent; weak = true; break;
case BuiltinProc_atomic_cxchgweak_acqrel: success_ordering = LLVMAtomicOrderingAcquireRelease; failure_ordering = LLVMAtomicOrderingSequentiallyConsistent; weak = true; break;
case BuiltinProc_atomic_cxchgweak_relaxed: success_ordering = LLVMAtomicOrderingMonotonic; failure_ordering = LLVMAtomicOrderingMonotonic; weak = true; break;
case BuiltinProc_atomic_cxchgweak_failrelaxed: success_ordering = LLVMAtomicOrderingSequentiallyConsistent; failure_ordering = LLVMAtomicOrderingMonotonic; weak = true; break;
case BuiltinProc_atomic_cxchgweak_failacq: success_ordering = LLVMAtomicOrderingSequentiallyConsistent; failure_ordering = LLVMAtomicOrderingAcquire; weak = true; break;
case BuiltinProc_atomic_cxchgweak_acq_failrelaxed: success_ordering = LLVMAtomicOrderingAcquire; failure_ordering = LLVMAtomicOrderingMonotonic; weak = true; break;
case BuiltinProc_atomic_cxchgweak_acqrel_failrelaxed: success_ordering = LLVMAtomicOrderingAcquireRelease; failure_ordering = LLVMAtomicOrderingMonotonic; weak = true; break;
}
// TODO(bill): Figure out how to make it weak
LLVMBool single_threaded = weak;
LLVMValueRef value = LLVMBuildAtomicCmpXchg(
p->builder, address.value,
old_value.value, new_value.value,
success_ordering,
failure_ordering,
single_threaded
);
if (tv.type->kind == Type_Tuple) {
Type *fix_typed = alloc_type_tuple();
slice_init(&fix_typed->Tuple.variables, permanent_allocator(), 2);
fix_typed->Tuple.variables[0] = tv.type->Tuple.variables[0];
fix_typed->Tuple.variables[1] = alloc_entity_field(nullptr, blank_token, t_llvm_bool, false, 1);
lbValue res = {};
res.value = value;
res.type = fix_typed;
return res;
} else {
lbValue res = {};
res.value = LLVMBuildExtractValue(p->builder, value, 0, "");
res.type = tv.type;
return res;
}
}
case BuiltinProc_type_equal_proc:
return lb_get_equal_proc_for_type(p->module, ce->args[0]->tav.type);
case BuiltinProc_type_hasher_proc:
return lb_get_hasher_proc_for_type(p->module, ce->args[0]->tav.type);
case BuiltinProc_fixed_point_mul:
case BuiltinProc_fixed_point_div:
case BuiltinProc_fixed_point_mul_sat:
case BuiltinProc_fixed_point_div_sat:
{
Type *platform_type = integer_endian_type_to_platform_type(tv.type);
lbValue x = lb_emit_conv(p, lb_build_expr(p, ce->args[0]), platform_type);
lbValue y = lb_emit_conv(p, lb_build_expr(p, ce->args[1]), platform_type);
lbValue scale = lb_emit_conv(p, lb_build_expr(p, ce->args[2]), t_i32);
char const *name = nullptr;
if (is_type_unsigned(tv.type)) {
switch (id) {
case BuiltinProc_fixed_point_mul: name = "llvm.umul.fix"; break;
case BuiltinProc_fixed_point_div: name = "llvm.udiv.fix"; break;
case BuiltinProc_fixed_point_mul_sat: name = "llvm.umul.fix.sat"; break;
case BuiltinProc_fixed_point_div_sat: name = "llvm.udiv.fix.sat"; break;
}
} else {
switch (id) {
case BuiltinProc_fixed_point_mul: name = "llvm.smul.fix"; break;
case BuiltinProc_fixed_point_div: name = "llvm.sdiv.fix"; break;
case BuiltinProc_fixed_point_mul_sat: name = "llvm.smul.fix.sat"; break;
case BuiltinProc_fixed_point_div_sat: name = "llvm.sdiv.fix.sat"; break;
}
}
GB_ASSERT(name != nullptr);
LLVMTypeRef types[1] = {lb_type(p->module, platform_type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
lbValue res = {};
LLVMValueRef args[3] = {};
args[0] = x.value;
args[1] = y.value;
args[2] = scale.value;
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.type = platform_type;
return lb_emit_conv(p, res, tv.type);
}
case BuiltinProc_expect:
{
Type *t = default_type(tv.type);
lbValue x = lb_emit_conv(p, lb_build_expr(p, ce->args[0]), t);
lbValue y = lb_emit_conv(p, lb_build_expr(p, ce->args[1]), t);
char const *name = "llvm.expect";
LLVMTypeRef types[1] = {lb_type(p->module, t)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
lbValue res = {};
LLVMValueRef args[2] = {};
args[0] = x.value;
args[1] = y.value;
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.type = t;
return lb_emit_conv(p, res, t);
}
case BuiltinProc_prefetch_read_instruction:
case BuiltinProc_prefetch_read_data:
case BuiltinProc_prefetch_write_instruction:
case BuiltinProc_prefetch_write_data:
{
lbValue ptr = lb_emit_conv(p, lb_build_expr(p, ce->args[0]), t_rawptr);
unsigned long long locality = cast(unsigned long long)exact_value_to_i64(ce->args[1]->tav.value);
unsigned long long rw = 0;
unsigned long long cache = 0;
switch (id) {
case BuiltinProc_prefetch_read_instruction:
rw = 0;
cache = 0;
break;
case BuiltinProc_prefetch_read_data:
rw = 0;
cache = 1;
break;
case BuiltinProc_prefetch_write_instruction:
rw = 1;
cache = 0;
break;
case BuiltinProc_prefetch_write_data:
rw = 1;
cache = 1;
break;
}
char const *name = "llvm.prefetch";
LLVMTypeRef types[1] = {lb_type(p->module, t_rawptr)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMTypeRef llvm_i32 = lb_type(p->module, t_i32);
LLVMValueRef args[4] = {};
args[0] = ptr.value;
args[1] = LLVMConstInt(llvm_i32, rw, false);
args[2] = LLVMConstInt(llvm_i32, locality, false);
args[3] = LLVMConstInt(llvm_i32, cache, false);
lbValue res = {};
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.type = nullptr;
return res;
}
case BuiltinProc_syscall:
{
unsigned arg_count = cast(unsigned)ce->args.count;
LLVMValueRef *args = gb_alloc_array(permanent_allocator(), LLVMValueRef, arg_count);
for_array(i, ce->args) {
lbValue arg = lb_build_expr(p, ce->args[i]);
arg = lb_emit_conv(p, arg, t_uintptr);
args[i] = arg.value;
}
LLVMTypeRef llvm_uintptr = lb_type(p->module, t_uintptr);
LLVMTypeRef *llvm_arg_types = gb_alloc_array(permanent_allocator(), LLVMTypeRef, arg_count);
for (unsigned i = 0; i < arg_count; i++) {
llvm_arg_types[i] = llvm_uintptr;
}
LLVMTypeRef func_type = LLVMFunctionType(llvm_uintptr, llvm_arg_types, arg_count, false);
LLVMValueRef inline_asm = nullptr;
switch (build_context.metrics.arch) {
case TargetArch_amd64:
{
GB_ASSERT(arg_count <= 7);
char asm_string[] = "syscall";
gbString constraints = gb_string_make(heap_allocator(), "={rax}");
for (unsigned i = 0; i < arg_count; i++) {
constraints = gb_string_appendc(constraints, ",{");
static char const *regs[] = {
"rax",
"rdi",
"rsi",
"rdx",
"r10",
"r8",
"r9"
};
constraints = gb_string_appendc(constraints, regs[i]);
constraints = gb_string_appendc(constraints, "}");
}
// The SYSCALL instruction stores the address of the
// following instruction into RCX, and RFLAGS in R11.
//
// RSP is not saved, but at least on Linux it appears
// that the kernel system-call handler does the right
// thing.
//
// Some but not all system calls will additionally
// clobber memory.
//
// TODO: FreeBSD is different and will also clobber
// R8, R9, and R10. Additionally CF is used to
// indicate an error instead of -errno.
constraints = gb_string_appendc(constraints, ",~{rcx},~{r11},~{memory}");
inline_asm = llvm_get_inline_asm(func_type, make_string_c(asm_string), make_string_c(constraints));
}
break;
case TargetArch_386:
{
GB_ASSERT(arg_count <= 7);
char asm_string_default[] = "int $0x80";
char *asm_string = asm_string_default;
gbString constraints = gb_string_make(heap_allocator(), "={eax}");
for (unsigned i = 0; i < gb_min(arg_count, 6); i++) {
constraints = gb_string_appendc(constraints, ",{");
static char const *regs[] = {
"eax",
"ebx",
"ecx",
"edx",
"esi",
"edi",
};
constraints = gb_string_appendc(constraints, regs[i]);
constraints = gb_string_appendc(constraints, "}");
}
if (arg_count == 7) {
char asm_string7[] = "push %[arg6]\npush %%ebp\nmov 4(%%esp), %%ebp\nint $0x80\npop %%ebp\nadd $4, %%esp";
asm_string = asm_string7;
constraints = gb_string_appendc(constraints, ",rm");
}
inline_asm = llvm_get_inline_asm(func_type, make_string_c(asm_string), make_string_c(constraints));
}
break;
case TargetArch_arm64:
{
GB_ASSERT(arg_count <= 7);
char asm_string[] = "svc #0";
gbString constraints = gb_string_make(heap_allocator(), "={x0}");
for (unsigned i = 0; i < arg_count; i++) {
constraints = gb_string_appendc(constraints, ",{");
static char const *regs[] = {
"x8",
"x0",
"x1",
"x2",
"x3",
"x4",
"x5",
};
constraints = gb_string_appendc(constraints, regs[i]);
constraints = gb_string_appendc(constraints, "}");
}
inline_asm = llvm_get_inline_asm(func_type, make_string_c(asm_string), make_string_c(constraints));
}
break;
default:
GB_PANIC("Unsupported platform");
}
lbValue res = {};
res.value = LLVMBuildCall2(p->builder, func_type, inline_asm, args, arg_count, "");
res.type = t_uintptr;
return res;
}
}
GB_PANIC("Unhandled built-in procedure %.*s", LIT(builtin_procs[id].name));
return {};
}
lbValue lb_handle_param_value(lbProcedure *p, Type *parameter_type, ParameterValue const &param_value, TokenPos const &pos) {
switch (param_value.kind) {
case ParameterValue_Constant:
if (is_type_constant_type(parameter_type)) {
auto res = lb_const_value(p->module, parameter_type, param_value.value);
return res;
} else {
ExactValue ev = param_value.value;
lbValue arg = {};
Type *type = type_of_expr(param_value.original_ast_expr);
if (type != nullptr) {
arg = lb_const_value(p->module, type, ev);
} else {
arg = lb_const_value(p->module, parameter_type, param_value.value);
}
return lb_emit_conv(p, arg, parameter_type);
}
case ParameterValue_Nil:
return lb_const_nil(p->module, parameter_type);
case ParameterValue_Location:
{
String proc_name = {};
if (p->entity != nullptr) {
proc_name = p->entity->token.string;
}
return lb_emit_source_code_location(p, proc_name, pos);
}
case ParameterValue_Value:
return lb_build_expr(p, param_value.ast_value);
}
return lb_const_nil(p->module, parameter_type);
}
lbValue lb_build_call_expr_internal(lbProcedure *p, Ast *expr);
lbValue lb_build_call_expr(lbProcedure *p, Ast *expr) {
expr = unparen_expr(expr);
ast_node(ce, CallExpr, expr);
if (ce->sce_temp_data) {
return *(lbValue *)ce->sce_temp_data;
}
lbValue res = lb_build_call_expr_internal(p, expr);
if (ce->optional_ok_one) { // TODO(bill): Minor hack for #optional_ok procedures
GB_ASSERT(is_type_tuple(res.type));
GB_ASSERT(res.type->Tuple.variables.count == 2);
return lb_emit_struct_ev(p, res, 0);
}
return res;
}
lbValue lb_build_call_expr_internal(lbProcedure *p, Ast *expr) {
lbModule *m = p->module;
TypeAndValue tv = type_and_value_of_expr(expr);
ast_node(ce, CallExpr, expr);
TypeAndValue proc_tv = type_and_value_of_expr(ce->proc);
AddressingMode proc_mode = proc_tv.mode;
if (proc_mode == Addressing_Type) {
GB_ASSERT(ce->args.count == 1);
lbValue x = lb_build_expr(p, ce->args[0]);
lbValue y = lb_emit_conv(p, x, tv.type);
return y;
}
Ast *pexpr = unparen_expr(ce->proc);
if (proc_mode == Addressing_Builtin) {
Entity *e = entity_of_node(pexpr);
BuiltinProcId id = BuiltinProc_Invalid;
if (e != nullptr) {
id = cast(BuiltinProcId)e->Builtin.id;
} else {
id = BuiltinProc_DIRECTIVE;
}
return lb_build_builtin_proc(p, expr, tv, id);
}
// NOTE(bill): Regular call
lbValue value = {};
Ast *proc_expr = unparen_expr(ce->proc);
if (proc_expr->tav.mode == Addressing_Constant) {
ExactValue v = proc_expr->tav.value;
switch (v.kind) {
case ExactValue_Integer:
{
u64 u = big_int_to_u64(&v.value_integer);
lbValue x = {};
x.value = LLVMConstInt(lb_type(m, t_uintptr), u, false);
x.type = t_uintptr;
x = lb_emit_conv(p, x, t_rawptr);
value = lb_emit_conv(p, x, proc_expr->tav.type);
break;
}
case ExactValue_Pointer:
{
u64 u = cast(u64)v.value_pointer;
lbValue x = {};
x.value = LLVMConstInt(lb_type(m, t_uintptr), u, false);
x.type = t_uintptr;
x = lb_emit_conv(p, x, t_rawptr);
value = lb_emit_conv(p, x, proc_expr->tav.type);
break;
}
}
}
Entity *proc_entity = entity_of_node(proc_expr);
if (proc_entity != nullptr) {
if (proc_entity->flags & EntityFlag_Disabled) {
return {};
}
}
if (value.value == nullptr) {
value = lb_build_expr(p, proc_expr);
}
GB_ASSERT(value.value != nullptr);
Type *proc_type_ = base_type(value.type);
GB_ASSERT(proc_type_->kind == Type_Proc);
TypeProc *pt = &proc_type_->Proc;
if (is_call_expr_field_value(ce)) {
auto args = array_make<lbValue>(permanent_allocator(), pt->param_count);
for_array(arg_index, ce->args) {
Ast *arg = ce->args[arg_index];
ast_node(fv, FieldValue, arg);
GB_ASSERT(fv->field->kind == Ast_Ident);
String name = fv->field->Ident.token.string;
isize index = lookup_procedure_parameter(pt, name);
GB_ASSERT(index >= 0);
TypeAndValue tav = type_and_value_of_expr(fv->value);
if (tav.mode == Addressing_Type) {
args[index] = lb_const_nil(m, tav.type);
} else {
args[index] = lb_build_expr(p, fv->value);
}
}
TypeTuple *params = &pt->params->Tuple;
for (isize i = 0; i < args.count; i++) {
Entity *e = params->variables[i];
if (e->kind == Entity_TypeName) {
args[i] = lb_const_nil(m, e->type);
} else if (e->kind == Entity_Constant) {
continue;
} else {
GB_ASSERT(e->kind == Entity_Variable);
if (args[i].value == nullptr) {
args[i] = lb_handle_param_value(p, e->type, e->Variable.param_value, ast_token(expr).pos);
} else {
args[i] = lb_emit_conv(p, args[i], e->type);
}
}
}
for (isize i = 0; i < args.count; i++) {
Entity *e = params->variables[i];
if (args[i].type == nullptr) {
continue;
} else if (is_type_untyped_nil(args[i].type)) {
args[i] = lb_const_nil(m, e->type);
} else if (is_type_untyped_undef(args[i].type)) {
args[i] = lb_const_undef(m, e->type);
}
}
return lb_emit_call(p, value, args, ce->inlining, p->copy_elision_hint.ast == expr);
}
isize arg_index = 0;
isize arg_count = 0;
for_array(i, ce->args) {
Ast *arg = ce->args[i];
TypeAndValue tav = type_and_value_of_expr(arg);
GB_ASSERT_MSG(tav.mode != Addressing_Invalid, "%s %s %d", expr_to_string(arg), expr_to_string(expr), tav.mode);
GB_ASSERT_MSG(tav.mode != Addressing_ProcGroup, "%s", expr_to_string(arg));
Type *at = tav.type;
if (at->kind == Type_Tuple) {
arg_count += at->Tuple.variables.count;
} else {
arg_count++;
}
}
isize param_count = 0;
if (pt->params) {
GB_ASSERT(pt->params->kind == Type_Tuple);
param_count = pt->params->Tuple.variables.count;
}
auto args = array_make<lbValue>(permanent_allocator(), cast(isize)gb_max(param_count, arg_count));
isize variadic_index = pt->variadic_index;
bool variadic = pt->variadic && variadic_index >= 0;
bool vari_expand = ce->ellipsis.pos.line != 0;
bool is_c_vararg = pt->c_vararg;
String proc_name = {};
if (p->entity != nullptr) {
proc_name = p->entity->token.string;
}
TokenPos pos = ast_token(ce->proc).pos;
TypeTuple *param_tuple = nullptr;
if (pt->params) {
GB_ASSERT(pt->params->kind == Type_Tuple);
param_tuple = &pt->params->Tuple;
}
for_array(i, ce->args) {
Ast *arg = ce->args[i];
TypeAndValue arg_tv = type_and_value_of_expr(arg);
if (arg_tv.mode == Addressing_Type) {
args[arg_index++] = lb_const_nil(m, arg_tv.type);
} else {
lbValue a = lb_build_expr(p, arg);
Type *at = a.type;
if (at->kind == Type_Tuple) {
for_array(i, at->Tuple.variables) {
lbValue v = lb_emit_struct_ev(p, a, cast(i32)i);
args[arg_index++] = v;
}
} else {
args[arg_index++] = a;
}
}
}
if (param_count > 0) {
GB_ASSERT_MSG(pt->params != nullptr, "%s %td", expr_to_string(expr), pt->param_count);
GB_ASSERT(param_count < 1000000);
if (arg_count < param_count) {
isize end = cast(isize)param_count;
if (variadic) {
end = variadic_index;
}
while (arg_index < end) {
Entity *e = param_tuple->variables[arg_index];
GB_ASSERT(e->kind == Entity_Variable);
args[arg_index++] = lb_handle_param_value(p, e->type, e->Variable.param_value, ast_token(expr).pos);
}
}
if (is_c_vararg) {
GB_ASSERT(variadic);
GB_ASSERT(!vari_expand);
isize i = 0;
for (; i < variadic_index; i++) {
Entity *e = param_tuple->variables[i];
if (e->kind == Entity_Variable) {
args[i] = lb_emit_conv(p, args[i], e->type);
}
}
Type *variadic_type = param_tuple->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] = lb_emit_conv(p, args[i], variadic_type);
}
} else {
for (; i < arg_count; i++) {
args[i] = lb_emit_conv(p, args[i], default_type(args[i].type));
}
}
} else if (variadic) {
isize i = 0;
for (; i < variadic_index; i++) {
Entity *e = param_tuple->variables[i];
if (e->kind == Entity_Variable) {
args[i] = lb_emit_conv(p, args[i], e->type);
}
}
if (!vari_expand) {
Type *variadic_type = param_tuple->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] = lb_emit_conv(p, args[i], variadic_type);
}
}
} else {
for (isize i = 0; i < param_count; i++) {
Entity *e = param_tuple->variables[i];
if (e->kind == Entity_Variable) {
if (args[i].value == nullptr) {
continue;
}
GB_ASSERT_MSG(args[i].value != nullptr, "%.*s", LIT(e->token.string));
args[i] = lb_emit_conv(p, args[i], e->type);
}
}
}
if (variadic && !vari_expand && !is_c_vararg) {
// variadic call argument generation
Type *slice_type = param_tuple->variables[variadic_index]->type;
Type *elem_type = base_type(slice_type)->Slice.elem;
lbAddr slice = lb_add_local_generated(p, slice_type, true);
isize slice_len = arg_count+1 - (variadic_index+1);
if (slice_len > 0) {
lbAddr base_array = lb_add_local_generated(p, alloc_type_array(elem_type, slice_len), true);
for (isize i = variadic_index, j = 0; i < arg_count; i++, j++) {
lbValue addr = lb_emit_array_epi(p, base_array.addr, cast(i32)j);
lb_emit_store(p, addr, args[i]);
}
lbValue base_elem = lb_emit_array_epi(p, base_array.addr, 0);
lbValue len = lb_const_int(m, t_int, slice_len);
lb_fill_slice(p, slice, base_elem, len);
}
arg_count = param_count;
args[variadic_index] = lb_addr_load(p, slice);
}
}
if (variadic && variadic_index+1 < param_count) {
for (isize i = variadic_index+1; i < param_count; i++) {
Entity *e = param_tuple->variables[i];
args[i] = lb_handle_param_value(p, e->type, e->Variable.param_value, ast_token(expr).pos);
}
}
isize final_count = param_count;
if (is_c_vararg) {
final_count = arg_count;
}
if (param_tuple != nullptr) {
for (isize i = 0; i < gb_min(args.count, param_tuple->variables.count); i++) {
Entity *e = param_tuple->variables[i];
if (args[i].type == nullptr) {
continue;
} else if (is_type_untyped_nil(args[i].type)) {
args[i] = lb_const_nil(m, e->type);
} else if (is_type_untyped_undef(args[i].type)) {
args[i] = lb_const_undef(m, e->type);
}
}
}
auto call_args = array_slice(args, 0, final_count);
return lb_emit_call(p, value, call_args, ce->inlining, p->copy_elision_hint.ast == expr);
}
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