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Odin/src/llvm_backend_const.cpp

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gb_internal bool lb_is_const(lbValue value) {
LLVMValueRef v = value.value;
if (is_type_untyped_nil(value.type)) {
// TODO(bill): Is this correct behaviour?
return true;
}
if (LLVMIsConstant(v)) {
return true;
}
return false;
}
gb_internal bool lb_is_const_or_global(lbValue value) {
if (lb_is_const(value)) {
return true;
}
return false;
}
gb_internal bool lb_is_elem_const(Ast *elem, Type *elem_type) {
if (!elem_type_can_be_constant(elem_type)) {
return false;
}
if (elem->kind == Ast_FieldValue) {
elem = elem->FieldValue.value;
}
TypeAndValue tav = type_and_value_of_expr(elem);
GB_ASSERT_MSG(tav.mode != Addressing_Invalid, "%s %s", expr_to_string(elem), type_to_string(tav.type));
return tav.value.kind != ExactValue_Invalid;
}
gb_internal bool lb_is_const_nil(lbValue value) {
LLVMValueRef v = value.value;
if (v != nullptr && LLVMIsConstant(v)) {
if (LLVMIsAConstantAggregateZero(v)) {
return true;
} else if (LLVMIsAConstantPointerNull(v)) {
return true;
}
}
return false;
}
gb_internal bool lb_is_expr_constant_zero(Ast *expr) {
GB_ASSERT(expr != nullptr);
auto v = exact_value_to_integer(expr->tav.value);
if (v.kind == ExactValue_Integer) {
return big_int_cmp_zero(&v.value_integer) == 0;
}
return false;
}
gb_internal String lb_get_const_string(lbModule *m, lbValue value) {
GB_ASSERT(lb_is_const(value));
GB_ASSERT(LLVMIsConstant(value.value));
Type *t = base_type(value.type);
GB_ASSERT(are_types_identical(t, t_string));
unsigned ptr_indices[1] = {0};
unsigned len_indices[1] = {1};
LLVMValueRef underlying_ptr = llvm_const_extract_value(m, value.value, ptr_indices, gb_count_of(ptr_indices));
LLVMValueRef underlying_len = llvm_const_extract_value(m, value.value, len_indices, gb_count_of(len_indices));
GB_ASSERT(LLVMGetConstOpcode(underlying_ptr) == LLVMGetElementPtr);
underlying_ptr = LLVMGetOperand(underlying_ptr, 0);
GB_ASSERT(LLVMIsAGlobalVariable(underlying_ptr));
underlying_ptr = LLVMGetInitializer(underlying_ptr);
size_t length = 0;
char const *text = LLVMGetAsString(underlying_ptr, &length);
isize real_length = cast(isize)LLVMConstIntGetSExtValue(underlying_len);
return make_string(cast(u8 const *)text, real_length);
}
gb_internal LLVMValueRef llvm_const_cast(lbModule *m, LLVMValueRef val, LLVMTypeRef dst, bool *failure_) {
LLVMTypeRef src = LLVMTypeOf(val);
if (src == dst) {
return val;
}
if (LLVMIsNull(val)) {
return LLVMConstNull(dst);
}
GB_ASSERT_MSG(lb_sizeof(dst) == lb_sizeof(src), "%s vs %s", LLVMPrintTypeToString(dst), LLVMPrintTypeToString(src));
LLVMTypeKind kind = LLVMGetTypeKind(dst);
switch (kind) {
case LLVMPointerTypeKind: {
return LLVMConstPointerCast(val, dst);
}
case LLVMStructTypeKind: {
unsigned src_n = LLVMCountStructElementTypes(src);
unsigned dst_n = LLVMCountStructElementTypes(dst);
if (src_n != dst_n) goto failure;
LLVMValueRef *field_vals = temporary_alloc_array<LLVMValueRef>(dst_n);
for (unsigned i = 0; i < dst_n; i++) {
LLVMValueRef field_val = llvm_const_extract_value(m, val, i);
if (field_val == nullptr) goto failure;
LLVMTypeRef dst_elem_ty = LLVMStructGetTypeAtIndex(dst, i);
field_vals[i] = llvm_const_cast(m, field_val, dst_elem_ty, failure_);
if (failure_ && *failure_) goto failure;
}
if (!LLVMIsLiteralStruct(dst)) {
return LLVMConstNamedStruct(dst, field_vals, dst_n);
} else {
return LLVMConstStructInContext(m->ctx, field_vals, dst_n, LLVMIsPackedStruct(dst));
}
}
}
failure:
if (failure_) *failure_ = true;
return val;
}
gb_internal lbValue lb_const_ptr_cast(lbModule *m, lbValue value, Type *t) {
GB_ASSERT(is_type_internally_pointer_like(value.type));
GB_ASSERT(is_type_internally_pointer_like(t));
GB_ASSERT(lb_is_const(value));
lbValue res = {};
res.value = LLVMConstPointerCast(value.value, lb_type(m, t));
res.type = t;
return res;
}
gb_internal LLVMValueRef llvm_const_string_internal(lbModule *m, Type *t, LLVMValueRef data, LLVMValueRef len) {
GB_ASSERT(!is_type_string16(t));
if (build_context.metrics.ptr_size < build_context.metrics.int_size) {
LLVMValueRef values[3] = {
data,
LLVMConstNull(lb_type(m, t_i32)),
len,
};
return llvm_const_named_struct_internal(m, lb_type(m, t), values, 3);
} else {
LLVMValueRef values[2] = {
data,
len,
};
return llvm_const_named_struct_internal(m, lb_type(m, t), values, 2);
}
}
gb_internal LLVMValueRef llvm_const_string16_internal(lbModule *m, Type *t, LLVMValueRef data, LLVMValueRef len) {
GB_ASSERT(is_type_string16(t));
if (build_context.metrics.ptr_size < build_context.metrics.int_size) {
LLVMValueRef values[3] = {
data,
LLVMConstNull(lb_type(m, t_i32)),
len,
};
return llvm_const_named_struct_internal(m, lb_type(m, t), values, 3);
} else {
LLVMValueRef values[2] = {
data,
len,
};
return llvm_const_named_struct_internal(m, lb_type(m, t), values, 2);
}
}
gb_internal LLVMValueRef llvm_const_named_struct(lbModule *m, Type *t, LLVMValueRef *values, isize value_count_) {
LLVMTypeRef struct_type = lb_type(m, t);
GB_ASSERT(LLVMGetTypeKind(struct_type) == LLVMStructTypeKind);
unsigned value_count = cast(unsigned)value_count_;
unsigned elem_count = LLVMCountStructElementTypes(struct_type);
if (elem_count == value_count) {
return llvm_const_named_struct_internal(m, struct_type, values, value_count_);
}
Type *bt = base_type(t);
GB_ASSERT(bt->kind == Type_Struct || bt->kind == Type_Union);
GB_ASSERT(value_count_ == bt->Struct.fields.count);
auto field_remapping = lb_get_struct_remapping(m, t);
unsigned values_with_padding_count = elem_count;
LLVMValueRef *values_with_padding = gb_alloc_array(permanent_allocator(), LLVMValueRef, values_with_padding_count);
for (unsigned i = 0; i < value_count; i++) {
values_with_padding[field_remapping[i]] = values[i];
}
for (unsigned i = 0; i < values_with_padding_count; i++) {
if (values_with_padding[i] == nullptr) {
values_with_padding[i] = LLVMConstNull(LLVMStructGetTypeAtIndex(struct_type, i));
}
}
return llvm_const_named_struct_internal(m, struct_type, values_with_padding, values_with_padding_count);
}
gb_internal LLVMValueRef llvm_const_named_struct_internal(lbModule *m, LLVMTypeRef t, LLVMValueRef *values, isize value_count_) {
unsigned value_count = cast(unsigned)value_count_;
unsigned elem_count = LLVMCountStructElementTypes(t);
GB_ASSERT_MSG(value_count == elem_count, "%s %u %u", LLVMPrintTypeToString(t), value_count, elem_count);
bool failure = false;
for (unsigned i = 0; i < elem_count; i++) {
LLVMTypeRef elem_type = LLVMStructGetTypeAtIndex(t, i);
values[i] = llvm_const_cast(m, values[i], elem_type, &failure);
}
if (failure) {
return LLVMConstStructInContext(m->ctx, values, value_count, true);
}
return LLVMConstNamedStruct(t, values, value_count);
}
gb_internal LLVMValueRef llvm_const_array(lbModule *m, LLVMTypeRef elem_type, LLVMValueRef *values, isize value_count_) {
unsigned value_count = cast(unsigned)value_count_;
bool failure = false;
for (unsigned i = 0; i < value_count; i++) {
values[i] = llvm_const_cast(m, values[i], elem_type, &failure);
}
if (failure) {
return LLVMConstStructInContext(m->ctx, values, value_count, false);
}
for (unsigned i = 0; i < value_count; i++) {
if (elem_type != LLVMTypeOf(values[i])) {
return LLVMConstStructInContext(m->ctx, values, value_count, false);
}
}
return LLVMConstArray(elem_type, values, value_count);
}
gb_internal LLVMValueRef llvm_const_slice_internal(lbModule *m, LLVMValueRef data, LLVMValueRef len) {
if (build_context.metrics.ptr_size < build_context.metrics.int_size) {
GB_ASSERT(build_context.metrics.ptr_size == 4);
GB_ASSERT(build_context.metrics.int_size == 8);
LLVMValueRef vals[3] = {
data,
LLVMConstNull(lb_type(m, t_u32)),
len,
};
return LLVMConstStructInContext(m->ctx, vals, gb_count_of(vals), false);
} else {
LLVMValueRef vals[2] = {
data,
len,
};
return LLVMConstStructInContext(m->ctx, vals, gb_count_of(vals), false);
}
}
gb_internal LLVMValueRef llvm_const_slice(lbModule *m, lbValue data, lbValue len) {
GB_ASSERT(is_type_pointer(data.type) || is_type_multi_pointer(data.type));
GB_ASSERT(are_types_identical(len.type, t_int));
return llvm_const_slice_internal(m, data.value, len.value);
}
gb_internal lbValue lb_const_nil(lbModule *m, Type *type) {
LLVMValueRef v = LLVMConstNull(lb_type(m, type));
return lbValue{v, type};
}
gb_internal lbValue lb_const_undef(lbModule *m, Type *type) {
LLVMValueRef v = LLVMGetUndef(lb_type(m, type));
return lbValue{v, type};
}
gb_internal lbValue lb_const_int(lbModule *m, Type *type, u64 value) {
lbValue res = {};
res.value = LLVMConstInt(lb_type(m, type), cast(unsigned long long)value, !is_type_unsigned(type));
res.type = type;
return res;
}
gb_internal lbValue lb_const_string(lbModule *m, String const &value) {
return lb_const_value(m, t_string, exact_value_string(value));
}
gb_internal lbValue lb_const_string(lbModule *m, String16 const &value) {
return lb_const_value(m, t_string16, exact_value_string16(value));
}
gb_internal lbValue lb_const_bool(lbModule *m, Type *type, bool value) {
lbValue res = {};
res.value = LLVMConstInt(lb_type(m, type), value, false);
res.type = type;
return res;
}
gb_internal LLVMValueRef lb_const_f16(lbModule *m, f32 f, Type *type=t_f16) {
GB_ASSERT(type_size_of(type) == 2);
u16 u = f32_to_f16(f);
if (is_type_different_to_arch_endianness(type)) {
u = gb_endian_swap16(u);
}
LLVMValueRef i = LLVMConstInt(LLVMInt16TypeInContext(m->ctx), u, false);
return LLVMConstBitCast(i, lb_type(m, type));
}
gb_internal LLVMValueRef lb_const_f32(lbModule *m, f32 f, Type *type=t_f32) {
GB_ASSERT(type_size_of(type) == 4);
u32 u = bit_cast<u32>(f);
if (is_type_different_to_arch_endianness(type)) {
u = gb_endian_swap32(u);
}
LLVMValueRef i = LLVMConstInt(LLVMInt32TypeInContext(m->ctx), u, false);
return LLVMConstBitCast(i, lb_type(m, type));
}
gb_internal bool lb_is_expr_untyped_const(Ast *expr) {
auto const &tv = type_and_value_of_expr(expr);
if (is_type_untyped(tv.type)) {
return tv.value.kind != ExactValue_Invalid;
}
return false;
}
gb_internal lbValue lb_expr_untyped_const_to_typed(lbModule *m, Ast *expr, Type *t) {
GB_ASSERT(is_type_typed(t));
auto const &tv = type_and_value_of_expr(expr);
return lb_const_value(m, t, tv.value);
}
gb_internal lbValue lb_const_source_code_location_const(lbModule *m, String const &procedure_, TokenPos const &pos) {
String file = get_file_path_string(pos.file_id);
String procedure = procedure_;
i32 line = pos.line;
i32 column = pos.column;
switch (build_context.source_code_location_info) {
case SourceCodeLocationInfo_Normal:
break;
case SourceCodeLocationInfo_Obfuscated:
file = obfuscate_string(file, "F");
procedure = obfuscate_string(procedure, "P");
line = obfuscate_i32(line);
column = obfuscate_i32(column);
break;
case SourceCodeLocationInfo_Filename:
file = last_path_element(file);
break;
case SourceCodeLocationInfo_None:
file = str_lit("");
procedure = str_lit("");
line = 0;
column = 0;
break;
}
LLVMValueRef fields[4] = {};
fields[0]/*file*/ = lb_find_or_add_entity_string(m, file, false).value;
fields[1]/*line*/ = lb_const_int(m, t_i32, line).value;
fields[2]/*column*/ = lb_const_int(m, t_i32, column).value;
fields[3]/*procedure*/ = lb_find_or_add_entity_string(m, procedure, false).value;
lbValue res = {};
res.value = llvm_const_named_struct(m, t_source_code_location, fields, gb_count_of(fields));
res.type = t_source_code_location;
return res;
}
gb_internal lbValue lb_emit_source_code_location_const(lbProcedure *p, String const &procedure, TokenPos const &pos) {
lbModule *m = p->module;
return lb_const_source_code_location_const(m, procedure, pos);
}
gb_internal lbValue lb_emit_source_code_location_const(lbProcedure *p, Ast *node) {
String proc_name = {};
if (p->entity) {
proc_name = p->entity->token.string;
}
TokenPos pos = {};
if (node) {
pos = ast_token(node).pos;
}
return lb_emit_source_code_location_const(p, proc_name, pos);
}
gb_internal String lb_source_code_location_gen_name(String const &procedure, TokenPos const &pos) {
gbString s = gb_string_make(permanent_allocator(), "scl$[");
s = gb_string_append_length(s, procedure.text, procedure.len);
if (pos.offset != 0) {
s = gb_string_append_fmt(s, "%d", pos.offset);
} else {
s = gb_string_append_fmt(s, "%d_%d", pos.line, pos.column);
}
s = gb_string_appendc(s, "]");
return make_string(cast(u8 const *)s, gb_string_length(s));
}
gb_internal String lb_source_code_location_gen_name(lbProcedure *p, Ast *node) {
String proc_name = {};
if (p->entity) {
proc_name = p->entity->token.string;
}
TokenPos pos = {};
if (node) {
pos = ast_token(node).pos;
}
return lb_source_code_location_gen_name(proc_name, pos);
}
gb_internal lbValue lb_emit_source_code_location_as_global_ptr(lbProcedure *p, String const &procedure, TokenPos const &pos) {
lbValue loc = lb_emit_source_code_location_const(p, procedure, pos);
lbAddr addr = lb_add_global_generated_with_name(p->module, loc.type, loc, lb_source_code_location_gen_name(procedure, pos));
lb_make_global_private_const(addr);
return addr.addr;
}
gb_internal lbValue lb_const_source_code_location_as_global_ptr(lbModule *m, String const &procedure, TokenPos const &pos) {
lbValue loc = lb_const_source_code_location_const(m, procedure, pos);
lbAddr addr = lb_add_global_generated_with_name(m, loc.type, loc, lb_source_code_location_gen_name(procedure, pos));
lb_make_global_private_const(addr);
return addr.addr;
}
gb_internal lbValue lb_emit_source_code_location_as_global_ptr(lbProcedure *p, Ast *node) {
lbValue loc = lb_emit_source_code_location_const(p, node);
lbAddr addr = lb_add_global_generated_with_name(p->module, loc.type, loc, lb_source_code_location_gen_name(p, node));
lb_make_global_private_const(addr);
return addr.addr;
}
gb_internal lbValue lb_emit_source_code_location_as_global(lbProcedure *p, String const &procedure, TokenPos const &pos) {
return lb_emit_load(p, lb_emit_source_code_location_as_global_ptr(p, procedure, pos));
}
gb_internal lbValue lb_emit_source_code_location_as_global(lbProcedure *p, Ast *node) {
return lb_emit_load(p, lb_emit_source_code_location_as_global_ptr(p, node));
}
gb_internal LLVMValueRef lb_build_constant_array_values(lbModule *m, Type *type, Type *elem_type, isize count, LLVMValueRef *values, lbConstContext cc) {
if (cc.allow_local) {
cc.is_rodata = false;
}
bool is_local = cc.allow_local && m->curr_procedure != nullptr;
bool is_const = true;
if (is_local) {
for (isize i = 0; i < count; i++) {
GB_ASSERT(values[i] != nullptr);
if (!LLVMIsConstant(values[i])) {
is_const = false;
break;
}
}
}
if (!is_const) {
LLVMTypeRef llvm_elem_type = lb_type(m, elem_type);
lbProcedure *p = m->curr_procedure;
GB_ASSERT(p != nullptr);
lbAddr v = lb_add_local_generated(p, type, false);
lbValue ptr = lb_addr_get_ptr(p, v);
for (isize i = 0; i < count; i++) {
lbValue elem = lb_emit_array_epi(p, ptr, i);
if (is_type_proc(elem_type)) {
values[i] = LLVMConstPointerCast(values[i], llvm_elem_type);
}
LLVMBuildStore(p->builder, values[i], elem.value);
}
return lb_addr_load(p, v).value;
}
return llvm_const_array(m, lb_type(m, elem_type), values, cast(unsigned int)count);
}
gb_internal LLVMValueRef lb_big_int_to_llvm(lbModule *m, Type *original_type, BigInt const *a) {
if (big_int_is_zero(a)) {
return LLVMConstNull(lb_type(m, original_type));
}
size_t sz = cast(size_t)type_size_of(original_type);
u64 rop64[4] = {}; // 2 u64 is the maximum we will ever need, so doubling it will be fine :P
u8 *rop = cast(u8 *)rop64;
size_t max_count = 0;
size_t written = 0;
size_t size = 1;
size_t nails = 0;
mp_endian endian = MP_LITTLE_ENDIAN;
max_count = mp_pack_count(a, nails, size);
if (sz < max_count) {
debug_print_big_int(a);
gb_printf_err("%s -> %tu\n", type_to_string(original_type), sz);;
}
GB_ASSERT_MSG(sz >= max_count, "max_count: %tu, sz: %tu, written: %tu, type %s", max_count, sz, written, type_to_string(original_type));
GB_ASSERT(gb_size_of(rop64) >= sz);
mp_err err = mp_pack(rop, sz, &written,
MP_LSB_FIRST,
size, endian, nails,
a);
GB_ASSERT(err == MP_OKAY);
if (!is_type_endian_little(original_type)) {
for (size_t i = 0; i < sz/2; i++) {
u8 tmp = rop[i];
rop[i] = rop[sz-1-i];
rop[sz-1-i] = tmp;
}
}
GB_ASSERT(!is_type_array(original_type));
LLVMValueRef value = LLVMConstIntOfArbitraryPrecision(lb_type(m, original_type), cast(unsigned)((sz+7)/8), cast(u64 *)rop);
if (big_int_is_neg(a)) {
value = LLVMConstNeg(value);
}
return value;
}
gb_internal bool lb_is_nested_possibly_constant(Type *ft, Selection const &sel, Ast *elem) {
GB_ASSERT(!sel.indirect);
for (i32 index : sel.index) {
Type *bt = base_type(ft);
switch (bt->kind) {
case Type_Struct:
if (bt->Struct.is_raw_union) {
return false;
}
ft = bt->Struct.fields[index]->type;
break;
case Type_Array:
ft = bt->Array.elem;
break;
default:
return false;
}
}
if (is_type_raw_union(ft)) {
return false;
}
return lb_is_elem_const(elem, ft);
}
#if LLVM_VERSION_MAJOR == 14
LLVMValueRef llvm_const_pad_to_size(lbModule *m, LLVMValueRef val, LLVMTypeRef dst_ty) {
LLVMContextRef ctx = m->ctx;
LLVMTargetDataRef td = LLVMGetModuleDataLayout(m->mod);
LLVMTypeRef src_ty = LLVMTypeOf(val);
unsigned src_bits = (unsigned)LLVMSizeOfTypeInBits(td, src_ty);
unsigned dst_bits = (unsigned)LLVMSizeOfTypeInBits(td, dst_ty);
LLVMValueRef as_int = nullptr;
LLVMTypeKind src_kind = LLVMGetTypeKind(src_ty);
if (src_kind == LLVMIntegerTypeKind ||
src_kind == LLVMFloatTypeKind ||
src_kind == LLVMDoubleTypeKind ||
src_kind == LLVMPointerTypeKind ||
src_kind == LLVMVectorTypeKind) {
LLVMTypeRef src_int_ty = LLVMIntTypeInContext(ctx, src_bits);
as_int = LLVMConstBitCast(val, src_int_ty);
} else if (src_kind == LLVMArrayTypeKind) {
unsigned elem_count = LLVMGetArrayLength(src_ty);
LLVMTypeRef elem_ty = LLVMGetElementType(src_ty);
unsigned elem_bits = (unsigned)LLVMSizeOfTypeInBits(td, elem_ty);
LLVMTypeRef src_int_ty = LLVMIntTypeInContext(ctx, src_bits);
as_int = LLVMConstInt(src_int_ty, 0, false);
for (unsigned i = 0; i < elem_count; i++) {
LLVMValueRef elem = llvm_const_extract_value(m, val, i);
LLVMTypeRef elem_int_ty = LLVMIntTypeInContext(ctx, elem_bits);
LLVMValueRef elem_int = llvm_const_pad_to_size(m, elem, elem_int_ty);
LLVMValueRef shifted = LLVMConstShl(LLVMConstZExt(elem_int, src_int_ty), LLVMConstInt(src_int_ty, i * elem_bits, false));
as_int = LLVMConstOr(as_int, shifted);
}
} else if (src_kind == LLVMStructTypeKind) {
unsigned field_count = LLVMCountStructElementTypes(src_ty);
LLVMTypeRef src_int_ty = LLVMIntTypeInContext(ctx, src_bits);
as_int = LLVMConstInt(src_int_ty, 0, false);
for (unsigned i = 0; i < field_count; i++) {
LLVMTypeRef field_ty = LLVMStructGetTypeAtIndex(src_ty, i);
unsigned field_bits = (unsigned)LLVMSizeOfTypeInBits(td, field_ty);
LLVMValueRef field = llvm_const_extract_value(m, val, i);
LLVMTypeRef field_int_ty = LLVMIntTypeInContext(ctx, field_bits);
LLVMValueRef field_int = llvm_const_pad_to_size(m, field, field_int_ty);
uint64_t field_offset_bytes = LLVMOffsetOfElement(td, src_ty, i);
uint64_t field_offset_bits = field_offset_bytes * 8;
LLVMValueRef shifted = LLVMConstShl(LLVMConstZExt(field_int, src_int_ty), LLVMConstInt(src_int_ty, field_offset_bits, false));
as_int = LLVMConstOr(as_int, shifted);
}
} else {
gb_printf_err("unsupported const_pad source type: %s\n", LLVMPrintTypeToString(src_ty));
return nullptr;
}
if (src_bits != dst_bits) {
LLVMTypeRef dst_int_ty = LLVMIntTypeInContext(ctx, dst_bits);
if (src_bits < dst_bits) {
as_int = LLVMConstZExt(as_int, dst_int_ty);
} else {
as_int = LLVMConstTrunc(as_int, dst_int_ty);
}
}
LLVMTypeKind dst_kind = LLVMGetTypeKind(dst_ty);
if (dst_kind == LLVMIntegerTypeKind ||
dst_kind == LLVMFloatTypeKind ||
dst_kind == LLVMDoubleTypeKind ||
dst_kind == LLVMPointerTypeKind ||
dst_kind == LLVMVectorTypeKind) {
return LLVMConstBitCast(as_int, dst_ty);
} else if (dst_kind == LLVMArrayTypeKind) {
unsigned elem_count = LLVMGetArrayLength(dst_ty);
LLVMTypeRef elem_ty = LLVMGetElementType(dst_ty);
unsigned elem_bits = (unsigned)LLVMSizeOfTypeInBits(td, elem_ty);
LLVMValueRef *elems = temporary_alloc_array<LLVMValueRef>(elem_count);
LLVMTypeRef as_int_ty = LLVMTypeOf(as_int);
for (unsigned i = 0; i < elem_count; i++) {
LLVMValueRef shifted = LLVMConstLShr(as_int, LLVMConstInt(as_int_ty, i * elem_bits, false));
LLVMTypeRef elem_int_ty = LLVMIntTypeInContext(ctx, elem_bits);
LLVMValueRef trunc = LLVMConstTrunc(shifted, elem_int_ty);
elems[i] = llvm_const_pad_to_size(m, trunc, elem_ty);
}
return LLVMConstArray(elem_ty, elems, elem_count);
}
gb_printf_err("unsupported const_pad destination type: %s\n", LLVMPrintTypeToString(dst_ty));
return nullptr;
}
#endif
gb_internal lbValue lb_const_value(lbModule *m, Type *type, ExactValue value, lbConstContext cc, Type *value_type) {
if (cc.allow_local) {
cc.is_rodata = false;
}
LLVMContextRef ctx = m->ctx;
type = default_type(type);
Type *original_type = type;
lbValue res = {};
res.type = original_type;
type = core_type(type);
value = convert_exact_value_for_type(value, type);
bool is_local = cc.allow_local && m->curr_procedure != nullptr;
if (is_type_union(type) && is_type_union_constantable(type)) {
Type *bt = base_type(type);
GB_ASSERT(bt->kind == Type_Union);
if (bt->Union.variants.count == 0) {
return lb_const_nil(m, original_type);
} else if (bt->Union.variants.count == 1) {
Type *t = bt->Union.variants[0];
lbValue cv = lb_const_value(m, t, value, cc);
GB_ASSERT(LLVMIsConstant(cv.value));
LLVMTypeRef llvm_type = lb_type(m, original_type);
if (is_type_union_maybe_pointer(type)) {
LLVMValueRef values[1] = {cv.value};
res.value = llvm_const_named_struct_internal(m, llvm_type, values, 1);
res.type = original_type;
return res;
} else {
unsigned tag_value = 1;
if (bt->Union.kind == UnionType_no_nil) {
tag_value = 0;
}
LLVMValueRef tag = LLVMConstInt(LLVMStructGetTypeAtIndex(llvm_type, 1), tag_value, false);
LLVMValueRef padding = nullptr;
LLVMValueRef values[3] = {cv.value, tag, padding};
isize value_count = 2;
if (LLVMCountStructElementTypes(llvm_type) > 2) {
value_count = 3;
padding = LLVMConstNull(LLVMStructGetTypeAtIndex(llvm_type, 2));
}
res.value = llvm_const_named_struct_internal(m, llvm_type, values, value_count);
res.type = original_type;
return res;
}
} else {
if (value_type == nullptr) {
if (value.kind == ExactValue_Compound) {
ast_node(cl, CompoundLit, value.value_compound);
if (cl->elems.count == 0) {
return lb_const_nil(m, original_type);
}
} else if (value.kind == ExactValue_Invalid) {
return lb_const_nil(m, original_type);
}
}
GB_ASSERT_MSG(value_type != nullptr, "%s :: %s", type_to_string(original_type), exact_value_to_string(value));
i64 block_size = bt->Union.variant_block_size;
if (are_types_identical(value_type, original_type)) {
if (value.kind == ExactValue_Compound) {
ast_node(cl, CompoundLit, value.value_compound);
if (cl->elems.count == 0) {
return lb_const_nil(m, original_type);
}
} else if (value.kind == ExactValue_Invalid) {
return lb_const_nil(m, original_type);
}
GB_PANIC("%s vs %s", type_to_string(value_type), type_to_string(original_type));
}
lbValue cv = lb_const_value(m, value_type, value, cc, value_type);
Type *variant_type = cv.type;
LLVMValueRef values[4] = {};
unsigned value_count = 0;
#if LLVM_VERSION_MAJOR == 14
LLVMTypeRef block_type = lb_type_internal_union_block_type(m, bt);
values[value_count++] = llvm_const_pad_to_size(m, cv.value, block_type);
#else
values[value_count++] = cv.value;
if (type_size_of(variant_type) != block_size) {
LLVMTypeRef padding_type = lb_type_padding_filler(m, block_size - type_size_of(variant_type), 1);
values[value_count++] = LLVMConstNull(padding_type);
}
#endif
Type *tag_type = union_tag_type(bt);
LLVMTypeRef llvm_tag_type = lb_type(m, tag_type);
i64 tag_index = union_variant_index(bt, variant_type);
GB_ASSERT(tag_index >= 0);
values[value_count++] = LLVMConstInt(llvm_tag_type, tag_index, false);
i64 used_size = block_size + type_size_of(tag_type);
i64 union_size = type_size_of(bt);
i64 padding = union_size - used_size;
if (padding > 0) {
LLVMTypeRef padding_type = lb_type_padding_filler(m, padding, 1);
values[value_count++] = LLVMConstNull(padding_type);
}
res.value = LLVMConstStructInContext(m->ctx, values, value_count, true);
return res;
}
}
if (value.kind == ExactValue_Procedure) {
lbValue res = {};
Ast *expr = unparen_expr(value.value_procedure);
GB_ASSERT(expr != nullptr);
if (expr->kind == Ast_ProcLit) {
res = lb_generate_anonymous_proc_lit(m, str_lit("_proclit"), expr);
} else {
Entity *e = entity_from_expr(expr);
res = lb_find_procedure_value_from_entity(m, e);
}
if (res.value == nullptr) {
// This is an unspecialized polymorphic procedure, return nil or dummy value
return lb_const_nil(m, original_type);
}
GB_ASSERT(LLVMGetValueKind(res.value) == LLVMFunctionValueKind);
if (LLVMGetIntrinsicID(res.value) == 0) {
// NOTE(bill): do not cast intrinsics as they are not really procedures that can be casted
res.value = LLVMConstPointerCast(res.value, lb_type(m, res.type));
}
return res;
}
// NOTE(bill): This has to be done AFTER the union stuff
if (value.kind == ExactValue_Invalid) {
return lb_const_nil(m, original_type);
}
if (value.kind == ExactValue_Typeid) {
return lb_typeid(m, value.value_typeid);
}
if (value.kind == ExactValue_Compound) {
ast_node(cl, CompoundLit, value.value_compound);
if (cl->elems.count == 0) {
return lb_const_nil(m, original_type);
}
}
// GB_ASSERT_MSG(is_type_typed(type), "%s", type_to_string(type));
if (is_type_slice(type)) {
if (value.kind == ExactValue_String) {
GB_ASSERT(is_type_slice(type));
res.value = lb_find_or_add_entity_string_byte_slice_with_type(m, value.value_string, original_type).value;
return res;
} else if (value.kind == ExactValue_String16) {
GB_ASSERT(is_type_slice(type));
res.value = lb_find_or_add_entity_string16_slice_with_type(m, value.value_string16, original_type).value;
return res;
} else {
ast_node(cl, CompoundLit, value.value_compound);
isize count = cl->elems.count;
if (count == 0) {
return lb_const_nil(m, type);
}
count = gb_max(cast(isize)cl->max_count, count);
Type *elem = base_type(type)->Slice.elem;
Type *t = alloc_type_array(elem, count);
lbValue backing_array = lb_const_value(m, t, value, cc, nullptr);
LLVMValueRef array_data = nullptr;
if (is_local) {
// NOTE(bill, 2020-06-08): This is a bit of a hack but a "constant" slice needs
// its backing data on the stack
lbProcedure *p = m->curr_procedure;
LLVMTypeRef llvm_type = lb_type(m, t);
unsigned alignment = cast(unsigned)gb_max(type_align_of(t), 16);
bool do_local_copy = false;
if (do_local_copy) {
array_data = llvm_alloca(p, llvm_type, alignment);
LLVMValueRef local_copy = llvm_alloca(p, LLVMTypeOf(backing_array.value), alignment);
LLVMBuildStore(p->builder, backing_array.value, local_copy);
LLVMBuildMemCpy(p->builder,
array_data, alignment,
local_copy, alignment,
LLVMConstInt(lb_type(m, t_int), type_size_of(t), false)
);
} else {
array_data = llvm_alloca(p, LLVMTypeOf(backing_array.value), alignment);
LLVMBuildStore(p->builder, backing_array.value, array_data);
array_data = LLVMBuildPointerCast(p->builder, array_data, LLVMPointerType(llvm_type, 0), "");
}
{
LLVMValueRef indices[2] = {llvm_zero(m), llvm_zero(m)};
LLVMValueRef ptr = LLVMBuildInBoundsGEP2(p->builder, llvm_type, array_data, indices, 2, "");
LLVMValueRef len = LLVMConstInt(lb_type(m, t_int), count, true);
lbAddr slice = lb_add_local_generated(p, original_type, false);
map_set(&m->exact_value_compound_literal_addr_map, value.value_compound, slice);
lb_fill_slice(p, slice, {ptr, alloc_type_pointer(elem)}, {len, t_int});
return lb_addr_load(p, slice);
}
} else {
u32 id = m->global_array_index.fetch_add(1);
gbString str = gb_string_make(temporary_allocator(), "csba$");
str = gb_string_appendc(str, m->module_name);
str = gb_string_append_fmt(str, "$%x", id);
String name = make_string(cast(u8 const *)str, gb_string_length(str));
Entity *e = alloc_entity_constant(nullptr, make_token_ident(name), t, value);
array_data = LLVMAddGlobal(m->mod, LLVMTypeOf(backing_array.value), str);
LLVMSetInitializer(array_data, backing_array.value);
if (cc.link_section.len > 0) {
LLVMSetSection(array_data, alloc_cstring(permanent_allocator(), cc.link_section));
}
if (cc.is_rodata) {
LLVMSetGlobalConstant(array_data, true);
}
lbValue g = {};
g.value = LLVMConstPointerCast(array_data, LLVMPointerType(lb_type(m, t), 0));
g.type = t;
lb_add_entity(m, e, g);
lb_add_member(m, name, g);
{
LLVMValueRef ptr = g.value;
LLVMValueRef len = LLVMConstInt(lb_type(m, t_int), count, true);
LLVMValueRef values[2] = {ptr, len};
res.value = llvm_const_named_struct(m, original_type, values, 2);
return res;
}
}
}
} else if (is_type_array(type) && value.kind == ExactValue_String && !is_type_u8(core_array_type(type))) {
if (is_type_rune_array(type)) {
i64 count = type->Array.count;
Type *elem = type->Array.elem;
LLVMTypeRef et = lb_type(m, elem);
Rune rune;
isize offset = 0;
isize width = 1;
String s = value.value_string;
LLVMValueRef *elems = gb_alloc_array(permanent_allocator(), LLVMValueRef, cast(isize)count);
for (i64 i = 0; i < count && offset < s.len; i++) {
width = utf8_decode(s.text+offset, s.len-offset, &rune);
offset += width;
elems[i] = LLVMConstInt(et, rune, true);
}
GB_ASSERT(offset == s.len);
res.value = llvm_const_array(m, et, elems, cast(unsigned)count);
return res;
}
// NOTE(bill, 2021-10-07): Allow for array programming value constants
Type *core_elem = core_array_type(type);
return lb_const_value(m, core_elem, value, cc);
} else if (is_type_u8_array(type) && value.kind == ExactValue_String) {
GB_ASSERT(type->Array.count == value.value_string.len);
LLVMValueRef data = LLVMConstStringInContext(ctx,
cast(char const *)value.value_string.text,
cast(unsigned)value.value_string.len,
true /*DontNullTerminate*/);
res.value = data;
return res;
} else if (is_type_array(type) &&
value.kind != ExactValue_Invalid &&
value.kind != ExactValue_String &&
value.kind != ExactValue_Compound) {
i64 count = type->Array.count;
Type *elem = type->Array.elem;
lbValue single_elem = lb_const_value(m, elem, value, cc);
LLVMValueRef *elems = gb_alloc_array(permanent_allocator(), LLVMValueRef, cast(isize)count);
for (i64 i = 0; i < count; i++) {
elems[i] = single_elem.value;
}
res.value = llvm_const_array(m, lb_type(m, elem), elems, cast(unsigned)count);
return res;
} else if (is_type_matrix(type) &&
value.kind != ExactValue_Invalid &&
value.kind != ExactValue_Compound) {
i64 row = type->Matrix.row_count;
i64 column = type->Matrix.column_count;
GB_ASSERT(row == column);
Type *elem = type->Matrix.elem;
lbValue single_elem = lb_const_value(m, elem, value, cc);
single_elem.value = llvm_const_cast(m, single_elem.value, lb_type(m, elem), /*failure_*/nullptr);
i64 total_elem_count = matrix_type_total_internal_elems(type);
LLVMValueRef *elems = gb_alloc_array(permanent_allocator(), LLVMValueRef, cast(isize)total_elem_count);
for (i64 i = 0; i < row; i++) {
elems[matrix_indices_to_offset(type, i, i)] = single_elem.value;
}
for (i64 i = 0; i < total_elem_count; i++) {
if (elems[i] == nullptr) {
elems[i] = LLVMConstNull(lb_type(m, elem));
}
}
res.value = LLVMConstArray(lb_type(m, elem), elems, cast(unsigned)total_elem_count);
return res;
} else if (is_type_simd_vector(type) &&
value.kind != ExactValue_Invalid &&
value.kind != ExactValue_Compound) {
i64 count = type->SimdVector.count;
Type *elem = type->SimdVector.elem;
lbValue single_elem = lb_const_value(m, elem, value, cc);
single_elem.value = llvm_const_cast(m, single_elem.value, lb_type(m, elem), /*failure_*/nullptr);
LLVMValueRef *elems = gb_alloc_array(permanent_allocator(), LLVMValueRef, count);
for (i64 i = 0; i < count; i++) {
elems[i] = single_elem.value;
}
res.value = LLVMConstVector(elems, cast(unsigned)count);
return res;
}
switch (value.kind) {
case ExactValue_Invalid:
res.value = LLVMConstNull(lb_type(m, original_type));
return res;
case ExactValue_Bool:
res.value = LLVMConstInt(lb_type(m, original_type), value.value_bool, false);
return res;
case ExactValue_String:
{
bool custom_link_section = cc.link_section.len > 0;
LLVMValueRef ptr = nullptr;
lbValue res = {};
res.type = default_type(original_type);
isize len = value.value_string.len;
if (is_type_string16(res.type) || is_type_cstring16(res.type)) {
TEMPORARY_ALLOCATOR_GUARD();
String16 s16 = string_to_string16(temporary_allocator(), value.value_string);
len = s16.len;
ptr = lb_find_or_add_entity_string16_ptr(m, s16, custom_link_section);
} else {
ptr = lb_find_or_add_entity_string_ptr(m, value.value_string, custom_link_section);
}
if (custom_link_section) {
LLVMSetSection(ptr, alloc_cstring(permanent_allocator(), cc.link_section));
}
if (is_type_cstring(res.type) || is_type_cstring16(res.type)) {
res.value = ptr;
} else {
if (len == 0) {
if (is_type_string16(res.type)) {
ptr = LLVMConstNull(lb_type(m, t_u16_ptr));
} else {
ptr = LLVMConstNull(lb_type(m, t_u8_ptr));
}
}
LLVMValueRef str_len = LLVMConstInt(lb_type(m, t_int), len, true);
GB_ASSERT(is_type_string(original_type));
if (is_type_string16(res.type)) {
res.value = llvm_const_string16_internal(m, original_type, ptr, str_len);
} else {
res.value = llvm_const_string_internal(m, original_type, ptr, str_len);
}
}
return res;
}
case ExactValue_String16:
{
GB_ASSERT(is_type_string16(res.type) || is_type_cstring16(res.type));
bool custom_link_section = cc.link_section.len > 0;
LLVMValueRef ptr = lb_find_or_add_entity_string16_ptr(m, value.value_string16, custom_link_section);
lbValue res = {};
res.type = default_type(original_type);
if (custom_link_section) {
LLVMSetSection(ptr, alloc_cstring(permanent_allocator(), cc.link_section));
}
if (is_type_cstring16(res.type)) {
res.value = ptr;
} else {
if (value.value_string16.len == 0) {
ptr = LLVMConstNull(lb_type(m, t_u8_ptr));
}
LLVMValueRef str_len = LLVMConstInt(lb_type(m, t_int), value.value_string16.len, true);
GB_ASSERT(is_type_string(original_type));
res.value = llvm_const_string16_internal(m, original_type, ptr, str_len);
}
return res;
}
case ExactValue_Integer:
if (is_type_pointer(type) || is_type_multi_pointer(type) || is_type_proc(type)) {
LLVMTypeRef t = lb_type(m, original_type);
LLVMValueRef i = lb_big_int_to_llvm(m, t_uintptr, &value.value_integer);
res.value = LLVMConstIntToPtr(i, t);
} else {
res.value = lb_big_int_to_llvm(m, original_type, &value.value_integer);
}
return res;
case ExactValue_Float:
if (is_type_different_to_arch_endianness(type)) {
if (type->Basic.kind == Basic_f32le || type->Basic.kind == Basic_f32be) {
f32 f = static_cast<float>(value.value_float);
u32 u = bit_cast<u32>(f);
u = gb_endian_swap32(u);
res.value = LLVMConstReal(lb_type(m, original_type), bit_cast<f32>(u));
} else if (type->Basic.kind == Basic_f16le || type->Basic.kind == Basic_f16be) {
f32 f = static_cast<float>(value.value_float);
u16 u = f32_to_f16(f);
u = gb_endian_swap16(u);
res.value = LLVMConstReal(lb_type(m, original_type), f16_to_f32(u));
} else {
u64 u = bit_cast<u64>(value.value_float);
u = gb_endian_swap64(u);
res.value = LLVMConstReal(lb_type(m, original_type), bit_cast<f64>(u));
}
} else {
res.value = LLVMConstReal(lb_type(m, original_type), value.value_float);
}
return res;
case ExactValue_Complex:
{
LLVMValueRef values[2] = {};
switch (8*type_size_of(type)) {
case 32:
values[0] = lb_const_f16(m, cast(f32)value.value_complex->real);
values[1] = lb_const_f16(m, cast(f32)value.value_complex->imag);
break;
case 64:
values[0] = lb_const_f32(m, cast(f32)value.value_complex->real);
values[1] = lb_const_f32(m, cast(f32)value.value_complex->imag);
break;
case 128:
values[0] = LLVMConstReal(lb_type(m, t_f64), value.value_complex->real);
values[1] = LLVMConstReal(lb_type(m, t_f64), value.value_complex->imag);
break;
}
res.value = llvm_const_named_struct(m, original_type, values, 2);
return res;
}
break;
case ExactValue_Quaternion:
{
LLVMValueRef values[4] = {};
switch (8*type_size_of(type)) {
case 64:
// @QuaternionLayout
values[3] = lb_const_f16(m, cast(f32)value.value_quaternion->real);
values[0] = lb_const_f16(m, cast(f32)value.value_quaternion->imag);
values[1] = lb_const_f16(m, cast(f32)value.value_quaternion->jmag);
values[2] = lb_const_f16(m, cast(f32)value.value_quaternion->kmag);
break;
case 128:
// @QuaternionLayout
values[3] = lb_const_f32(m, cast(f32)value.value_quaternion->real);
values[0] = lb_const_f32(m, cast(f32)value.value_quaternion->imag);
values[1] = lb_const_f32(m, cast(f32)value.value_quaternion->jmag);
values[2] = lb_const_f32(m, cast(f32)value.value_quaternion->kmag);
break;
case 256:
// @QuaternionLayout
values[3] = LLVMConstReal(lb_type(m, t_f64), value.value_quaternion->real);
values[0] = LLVMConstReal(lb_type(m, t_f64), value.value_quaternion->imag);
values[1] = LLVMConstReal(lb_type(m, t_f64), value.value_quaternion->jmag);
values[2] = LLVMConstReal(lb_type(m, t_f64), value.value_quaternion->kmag);
break;
}
res.value = llvm_const_named_struct(m, original_type, values, 4);
return res;
}
break;
case ExactValue_Pointer:
res.value = LLVMConstIntToPtr(LLVMConstInt(lb_type(m, t_uintptr), value.value_pointer, false), lb_type(m, original_type));
return res;
case ExactValue_Compound:
if (is_type_slice(type)) {
return lb_const_value(m, type, value, cc);
} else if (is_type_soa_struct(type)) {
GB_ASSERT(type->kind == Type_Struct);
GB_ASSERT(type->Struct.soa_kind == StructSoa_Fixed);
ast_node(cl, CompoundLit, value.value_compound);
Type *elem_type = type->Struct.soa_elem;
isize elem_count = cl->elems.count;
if (elem_count == 0 || !elem_type_can_be_constant(elem_type)) {
return lb_const_nil(m, original_type);
}
if (cl->elems[0]->kind == Ast_FieldValue) {
TEMPORARY_ALLOCATOR_GUARD();
// TODO(bill): This is O(N*M) and will be quite slow; it should probably be sorted before hand
isize elem_count = cast(isize)type->Struct.soa_count;
LLVMValueRef *aos_values = gb_alloc_array(temporary_allocator(), LLVMValueRef, elem_count);
isize value_index = 0;
for (i64 i = 0; i < elem_count; i++) {
bool found = false;
for (isize j = 0; j < elem_count; j++) {
Ast *elem = cl->elems[j];
ast_node(fv, FieldValue, elem);
if (is_ast_range(fv->field)) {
ast_node(ie, BinaryExpr, fv->field);
TypeAndValue lo_tav = ie->left->tav;
TypeAndValue hi_tav = ie->right->tav;
GB_ASSERT(lo_tav.mode == Addressing_Constant);
GB_ASSERT(hi_tav.mode == Addressing_Constant);
TokenKind op = ie->op.kind;
i64 lo = exact_value_to_i64(lo_tav.value);
i64 hi = exact_value_to_i64(hi_tav.value);
if (op != Token_RangeHalf) {
hi += 1;
}
if (lo == i) {
TypeAndValue tav = fv->value->tav;
LLVMValueRef val = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
for (i64 k = lo; k < hi; k++) {
aos_values[value_index++] = val;
}
found = true;
i += (hi-lo-1);
break;
}
} else {
TypeAndValue index_tav = fv->field->tav;
GB_ASSERT(index_tav.mode == Addressing_Constant);
i64 index = exact_value_to_i64(index_tav.value);
if (index == i) {
TypeAndValue tav = fv->value->tav;
LLVMValueRef val = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
aos_values[value_index++] = val;
found = true;
break;
}
}
}
if (!found) {
aos_values[value_index++] = nullptr;
}
}
isize field_count = type->Struct.fields.count;
LLVMValueRef *soa_values = gb_alloc_array(temporary_allocator(), LLVMValueRef, field_count);
for (isize i = 0; i < field_count; i++) {
TEMPORARY_ALLOCATOR_GUARD();
LLVMValueRef *values = gb_alloc_array(temporary_allocator(), LLVMValueRef, elem_count);
Entity *f = type->Struct.fields[i];
Type *array_type = f->type;
GB_ASSERT(array_type->kind == Type_Array);
Type *field_type = array_type->Array.elem;
for (isize j = 0; j < elem_count; j++) {
LLVMValueRef v = aos_values[j];
if (v != nullptr) {
values[j] = llvm_const_extract_value(m, v, cast(unsigned)i);
} else {
values[j] = LLVMConstNull(lb_type(m, field_type));
}
}
soa_values[i] = lb_build_constant_array_values(m, array_type, field_type, elem_count, values, cc);
}
res.value = llvm_const_named_struct(m, type, soa_values, field_count);
return res;
} else {
GB_ASSERT_MSG(elem_count == type->Struct.soa_count, "%td != %td", elem_count, type->Struct.soa_count);
TEMPORARY_ALLOCATOR_GUARD();
isize elem_count = cast(isize)type->Struct.soa_count;
LLVMValueRef *aos_values = gb_alloc_array(temporary_allocator(), LLVMValueRef, elem_count);
for (isize i = 0; i < elem_count; i++) {
TypeAndValue tav = cl->elems[i]->tav;
GB_ASSERT(tav.mode != Addressing_Invalid);
aos_values[i] = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
}
for (isize i = elem_count; i < type->Struct.soa_count; i++) {
aos_values[i] = nullptr;
}
isize field_count = type->Struct.fields.count;
LLVMValueRef *soa_values = gb_alloc_array(temporary_allocator(), LLVMValueRef, field_count);
for (isize i = 0; i < field_count; i++) {
TEMPORARY_ALLOCATOR_GUARD();
LLVMValueRef *values = gb_alloc_array(temporary_allocator(), LLVMValueRef, elem_count);
Entity *f = type->Struct.fields[i];
Type *array_type = f->type;
GB_ASSERT(array_type->kind == Type_Array);
Type *field_type = array_type->Array.elem;
for (isize j = 0; j < elem_count; j++) {
LLVMValueRef v = aos_values[j];
if (v != nullptr) {
values[j] = llvm_const_extract_value(m, v, cast(unsigned)i);
} else {
values[j] = LLVMConstNull(lb_type(m, field_type));
}
}
soa_values[i] = lb_build_constant_array_values(m, array_type, field_type, elem_count, values, cc);
}
res.value = llvm_const_named_struct(m, type, soa_values, field_count);
return res;
}
} else if (is_type_array(type)) {
ast_node(cl, CompoundLit, value.value_compound);
Type *elem_type = type->Array.elem;
isize elem_count = cl->elems.count;
if (elem_count == 0 || !elem_type_can_be_constant(elem_type)) {
return lb_const_nil(m, original_type);
}
if (cl->elems[0]->kind == Ast_FieldValue) {
// TODO(bill): This is O(N*M) and will be quite slow; it should probably be sorted before hand
LLVMValueRef *values = gb_alloc_array(temporary_allocator(), LLVMValueRef, cast(isize)type->Array.count);
isize value_index = 0;
for (i64 i = 0; i < type->Array.count; i++) {
bool found = false;
for (isize j = 0; j < elem_count; j++) {
Ast *elem = cl->elems[j];
ast_node(fv, FieldValue, elem);
if (is_ast_range(fv->field)) {
ast_node(ie, BinaryExpr, fv->field);
TypeAndValue lo_tav = ie->left->tav;
TypeAndValue hi_tav = ie->right->tav;
GB_ASSERT(lo_tav.mode == Addressing_Constant);
GB_ASSERT(hi_tav.mode == Addressing_Constant);
TokenKind op = ie->op.kind;
i64 lo = exact_value_to_i64(lo_tav.value);
i64 hi = exact_value_to_i64(hi_tav.value);
if (op != Token_RangeHalf) {
hi += 1;
}
if (lo == i) {
TypeAndValue tav = fv->value->tav;
LLVMValueRef val = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
for (i64 k = lo; k < hi; k++) {
values[value_index++] = val;
}
found = true;
i += (hi-lo-1);
break;
}
} else {
TypeAndValue index_tav = fv->field->tav;
GB_ASSERT(index_tav.mode == Addressing_Constant);
i64 index = exact_value_to_i64(index_tav.value);
if (index == i) {
TypeAndValue tav = fv->value->tav;
LLVMValueRef val = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
values[value_index++] = val;
found = true;
break;
}
}
}
if (!found) {
values[value_index++] = LLVMConstNull(lb_type(m, elem_type));
}
}
res.value = lb_build_constant_array_values(m, type, elem_type, cast(isize)type->Array.count, values, cc);
return res;
} else if (are_types_identical(value.value_compound->tav.type, elem_type)) {
// Compound is of array item type; expand its value to all items in array.
LLVMValueRef* values = gb_alloc_array(temporary_allocator(), LLVMValueRef, cast(isize)type->Array.count);
for (isize i = 0; i < type->Array.count; i++) {
values[i] = lb_const_value(m, elem_type, value, cc, elem_type).value;
}
res.value = lb_build_constant_array_values(m, type, elem_type, cast(isize)type->Array.count, values, cc);
return res;
} else {
// Assume that compound value is an array literal
GB_ASSERT_MSG(elem_count == type->Array.count, "%td != %td", elem_count, type->Array.count);
LLVMValueRef *values = gb_alloc_array(temporary_allocator(), LLVMValueRef, cast(isize)type->Array.count);
for (isize i = 0; i < elem_count; i++) {
TypeAndValue tav = cl->elems[i]->tav;
GB_ASSERT(tav.mode != Addressing_Invalid);
values[i] = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
}
for (isize i = elem_count; i < type->Array.count; i++) {
values[i] = LLVMConstNull(lb_type(m, elem_type));
}
res.value = lb_build_constant_array_values(m, type, elem_type, cast(isize)type->Array.count, values, cc);
return res;
}
} else if (is_type_enumerated_array(type)) {
ast_node(cl, CompoundLit, value.value_compound);
Type *elem_type = type->EnumeratedArray.elem;
isize elem_count = cl->elems.count;
if (elem_count == 0 || !elem_type_can_be_constant(elem_type)) {
return lb_const_nil(m, original_type);
}
if (cl->elems[0]->kind == Ast_FieldValue) {
// TODO(bill): This is O(N*M) and will be quite slow; it should probably be sorted before hand
LLVMValueRef *values = gb_alloc_array(temporary_allocator(), LLVMValueRef, cast(isize)type->EnumeratedArray.count);
isize value_index = 0;
i64 total_lo = exact_value_to_i64(*type->EnumeratedArray.min_value);
i64 total_hi = exact_value_to_i64(*type->EnumeratedArray.max_value);
for (i64 i = total_lo; i <= total_hi; i++) {
bool found = false;
for (isize j = 0; j < elem_count; j++) {
Ast *elem = cl->elems[j];
ast_node(fv, FieldValue, elem);
if (is_ast_range(fv->field)) {
ast_node(ie, BinaryExpr, fv->field);
TypeAndValue lo_tav = ie->left->tav;
TypeAndValue hi_tav = ie->right->tav;
GB_ASSERT(lo_tav.mode == Addressing_Constant);
GB_ASSERT(hi_tav.mode == Addressing_Constant);
TokenKind op = ie->op.kind;
i64 lo = exact_value_to_i64(lo_tav.value);
i64 hi = exact_value_to_i64(hi_tav.value);
if (op != Token_RangeHalf) {
hi += 1;
}
if (lo == i) {
TypeAndValue tav = fv->value->tav;
LLVMValueRef val = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
for (i64 k = lo; k < hi; k++) {
values[value_index++] = val;
}
found = true;
i += (hi-lo-1);
break;
}
} else {
TypeAndValue index_tav = fv->field->tav;
GB_ASSERT(index_tav.mode == Addressing_Constant);
i64 index = exact_value_to_i64(index_tav.value);
if (index == i) {
TypeAndValue tav = fv->value->tav;
LLVMValueRef val = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
values[value_index++] = val;
found = true;
break;
}
}
}
if (!found) {
values[value_index++] = LLVMConstNull(lb_type(m, elem_type));
}
}
res.value = lb_build_constant_array_values(m, type, elem_type, cast(isize)type->EnumeratedArray.count, values, cc);
return res;
} else {
GB_ASSERT_MSG(elem_count == type->EnumeratedArray.count, "%td != %td", elem_count, type->EnumeratedArray.count);
LLVMValueRef *values = gb_alloc_array(temporary_allocator(), LLVMValueRef, cast(isize)type->EnumeratedArray.count);
for (isize i = 0; i < elem_count; i++) {
TypeAndValue tav = cl->elems[i]->tav;
GB_ASSERT(tav.mode != Addressing_Invalid);
values[i] = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
}
for (isize i = elem_count; i < type->EnumeratedArray.count; i++) {
values[i] = LLVMConstNull(lb_type(m, elem_type));
}
res.value = lb_build_constant_array_values(m, type, elem_type, cast(isize)type->EnumeratedArray.count, values, cc);
return res;
}
} else if (is_type_simd_vector(type)) {
ast_node(cl, CompoundLit, value.value_compound);
Type *elem_type = type->SimdVector.elem;
isize elem_count = cl->elems.count;
if (elem_count == 0) {
return lb_const_nil(m, original_type);
}
GB_ASSERT(elem_type_can_be_constant(elem_type));
isize total_elem_count = cast(isize)type->SimdVector.count;
LLVMValueRef *values = gb_alloc_array(temporary_allocator(), LLVMValueRef, total_elem_count);
if (cl->elems[0]->kind == Ast_FieldValue) {
// TODO(bill): This is O(N*M) and will be quite slow; it should probably be sorted before hand
isize value_index = 0;
for (i64 i = 0; i < total_elem_count; i++) {
bool found = false;
for (isize j = 0; j < elem_count; j++) {
Ast *elem = cl->elems[j];
ast_node(fv, FieldValue, elem);
if (is_ast_range(fv->field)) {
ast_node(ie, BinaryExpr, fv->field);
TypeAndValue lo_tav = ie->left->tav;
TypeAndValue hi_tav = ie->right->tav;
GB_ASSERT(lo_tav.mode == Addressing_Constant);
GB_ASSERT(hi_tav.mode == Addressing_Constant);
TokenKind op = ie->op.kind;
i64 lo = exact_value_to_i64(lo_tav.value);
i64 hi = exact_value_to_i64(hi_tav.value);
if (op != Token_RangeHalf) {
hi += 1;
}
if (lo == i) {
TypeAndValue tav = fv->value->tav;
LLVMValueRef val = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
for (i64 k = lo; k < hi; k++) {
values[value_index++] = val;
}
found = true;
i += (hi-lo-1);
break;
}
} else {
TypeAndValue index_tav = fv->field->tav;
GB_ASSERT(index_tav.mode == Addressing_Constant);
i64 index = exact_value_to_i64(index_tav.value);
if (index == i) {
TypeAndValue tav = fv->value->tav;
LLVMValueRef val = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
values[value_index++] = val;
found = true;
break;
}
}
}
if (!found) {
values[value_index++] = LLVMConstNull(lb_type(m, elem_type));
}
}
res.value = LLVMConstVector(values, cast(unsigned)total_elem_count);
return res;
} else {
for (isize i = 0; i < elem_count; i++) {
TypeAndValue tav = cl->elems[i]->tav;
GB_ASSERT(tav.mode != Addressing_Invalid);
values[i] = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
}
LLVMTypeRef et = lb_type(m, elem_type);
for (isize i = elem_count; i < total_elem_count; i++) {
values[i] = LLVMConstNull(et);
}
for (isize i = 0; i < total_elem_count; i++) {
values[i] = llvm_const_cast(m, values[i], et, /*failure_*/nullptr);
}
res.value = LLVMConstVector(values, cast(unsigned)total_elem_count);
return res;
}
} else if (is_type_struct(type)) {
ast_node(cl, CompoundLit, value.value_compound);
if (cl->elems.count == 0) {
return lb_const_nil(m, original_type);
}
if (is_type_raw_union(type)) {
if (is_type_raw_union_constantable(type)) {
GB_ASSERT(cl->elems.count == 1);
GB_ASSERT(cl->elems[0]->kind == Ast_FieldValue);
ast_node(fv, FieldValue, cl->elems[0]);
Entity *f = entity_of_node(fv->field);
TypeAndValue tav = fv->value->tav;
if (tav.value.kind != ExactValue_Invalid) {
lbValue value = lb_const_value(m, f->type, tav.value, cc, f->type);
LLVMValueRef values[2];
unsigned value_count = 0;
values[value_count++] = value.value;
i64 union_alignment = type_align_of(type);
i64 value_alignment = type_align_of(f->type);
i64 alignment = gb_max(gb_min(value_alignment, union_alignment), 1);
i64 union_size = type_size_of(type);
i64 value_size = lb_sizeof(LLVMTypeOf(value.value));
i64 padding = union_size-value_size;
if (padding > 0) {
LLVMTypeRef padding_type = lb_type_padding_filler(m, padding, alignment);
values[value_count++] = LLVMConstNull(padding_type);
}
LLVMValueRef res = LLVMConstStructInContext(m->ctx, values, value_count, /*packed*/padding > 0);
return {res, original_type};
}
}
return lb_const_nil(m, original_type);
}
LLVMTypeRef struct_type = lb_type(m, original_type);
auto field_remapping = lb_get_struct_remapping(m, type);
unsigned value_count = LLVMCountStructElementTypes(struct_type);
LLVMValueRef *values = gb_alloc_array(temporary_allocator(), LLVMValueRef, value_count);
bool *visited = gb_alloc_array(temporary_allocator(), bool, value_count);
if (cl->elems[0]->kind == Ast_FieldValue) {
isize elem_count = cl->elems.count;
for (isize i = 0; i < elem_count; i++) {
ast_node(fv, FieldValue, cl->elems[i]);
String name = fv->field->Ident.token.string;
TypeAndValue tav = fv->value->tav;
GB_ASSERT(tav.mode != Addressing_Invalid);
Selection sel = lookup_field(type, name, false);
GB_ASSERT(!sel.indirect);
Entity *f = type->Struct.fields[sel.index[0]];
i32 index = field_remapping[f->Variable.field_index];
if (elem_type_can_be_constant(f->type)) {
if (sel.index.count == 1) {
lbValue value = lb_const_value(m, f->type, tav.value, cc, tav.type);
LLVMTypeRef value_type = LLVMTypeOf(value.value);
GB_ASSERT_MSG(lb_sizeof(value_type) == type_size_of(f->type), "%s vs %s", LLVMPrintTypeToString(value_type), type_to_string(f->type));
values[index] = value.value;
visited[index] = true;
} else {
if (!visited[index]) {
auto new_cc = cc;
new_cc.allow_local = false;
values[index] = lb_const_value(m, f->type, {}, new_cc).value;
visited[index] = true;
}
unsigned idx_list_len = cast(unsigned)sel.index.count-1;
unsigned *idx_list = gb_alloc_array(temporary_allocator(), unsigned, idx_list_len);
if (lb_is_nested_possibly_constant(type, sel, fv->value)) {
bool is_constant = true;
Type *cv_type = f->type;
for (isize j = 1; j < sel.index.count; j++) {
i32 index = sel.index[j];
Type *cvt = base_type(cv_type);
if (cvt->kind == Type_Struct) {
if (cvt->Struct.is_raw_union) {
// sanity check which should have been caught by `lb_is_nested_possibly_constant`
is_constant = false;
break;
}
cv_type = cvt->Struct.fields[index]->type;
if (is_type_struct(cvt)) {
auto cv_field_remapping = lb_get_struct_remapping(m, cvt);
unsigned remapped_index = cast(unsigned)cv_field_remapping[index];
idx_list[j-1] = remapped_index;
} else {
idx_list[j-1] = cast(unsigned)index;
}
} else if (cvt->kind == Type_Array) {
cv_type = cvt->Array.elem;
idx_list[j-1] = cast(unsigned)index;
} else {
GB_PANIC("UNKNOWN TYPE: %s", type_to_string(cv_type));
}
}
if (is_constant) {
LLVMValueRef elem_value = lb_const_value(m, tav.type, tav.value, cc, tav.type).value;
if (LLVMIsConstant(elem_value) && LLVMIsConstant(values[index])) {
values[index] = llvm_const_insert_value(m, values[index], elem_value, idx_list, idx_list_len);
} else if (is_local) {
#if 1
lbProcedure *p = m->curr_procedure;
GB_ASSERT(p != nullptr);
if (LLVMIsConstant(values[index])) {
lbAddr addr = lb_add_local_generated(p, f->type, false);
lb_addr_store(p, addr, lbValue{values[index], f->type});
values[index] = lb_addr_load(p, addr).value;
}
GB_ASSERT(LLVMIsALoadInst(values[index]));
LLVMValueRef ptr = LLVMGetOperand(values[index], 0);
LLVMValueRef *indices = gb_alloc_array(temporary_allocator(), LLVMValueRef, idx_list_len);
LLVMTypeRef lt_u32 = lb_type(m, t_u32);
for (unsigned i = 0; i < idx_list_len; i++) {
indices[i] = LLVMConstInt(lt_u32, idx_list[i], false);
}
ptr = LLVMBuildGEP2(p->builder, lb_type(m, f->type), ptr, indices, idx_list_len, "");
ptr = LLVMBuildPointerCast(p->builder, ptr, lb_type(m, alloc_type_pointer(tav.type)), "");
if (LLVMIsALoadInst(elem_value)) {
i64 sz = type_size_of(tav.type);
LLVMValueRef src = LLVMGetOperand(elem_value, 0);
lb_mem_copy_non_overlapping(p, {ptr, t_rawptr}, {src, t_rawptr}, lb_const_int(m, t_int, sz), false);
} else {
LLVMBuildStore(p->builder, elem_value, ptr);
}
#endif
is_constant = false;
} else {
is_constant = false;
}
}
}
}
}
}
} else {
for_array(i, cl->elems) {
Entity *f = type->Struct.fields[i];
TypeAndValue tav = cl->elems[i]->tav;
ExactValue val = {};
if (tav.mode != Addressing_Invalid) {
val = tav.value;
}
i32 index = field_remapping[f->Variable.field_index];
if (elem_type_can_be_constant(f->type)) {
lbValue value = lb_const_value(m, f->type, tav.value, cc, tav.type);
LLVMTypeRef value_type = LLVMTypeOf(value.value);
GB_ASSERT_MSG(lb_sizeof(value_type) == type_size_of(f->type), "%s vs %s", LLVMPrintTypeToString(value_type), type_to_string(f->type));
values[index] = value.value;
visited[index] = true;
}
}
}
for (isize i = 0; i < value_count; i++) {
if (!visited[i]) {
GB_ASSERT(values[i] == nullptr);
LLVMTypeRef type = LLVMStructGetTypeAtIndex(struct_type, cast(unsigned)i);
values[i] = LLVMConstNull(type);
}
}
bool is_constant = true;
for (isize i = 0; i < value_count; i++) {
LLVMValueRef val = values[i];
if (!LLVMIsConstant(val)) {
GB_ASSERT(is_local);
GB_ASSERT(LLVMIsALoadInst(val));
is_constant = false;
}
}
if (is_constant) {
res.value = llvm_const_named_struct_internal(m, struct_type, values, cast(unsigned)value_count);
LLVMTypeRef res_type = LLVMTypeOf(res.value);
GB_ASSERT(lb_sizeof(res_type) == lb_sizeof(struct_type));
return res;
} else {
// TODO(bill): THIS IS HACK BUT IT WORKS FOR WHAT I NEED
LLVMValueRef *old_values = values;
LLVMValueRef *new_values = gb_alloc_array(temporary_allocator(), LLVMValueRef, value_count);
for (isize i = 0; i < value_count; i++) {
LLVMValueRef old_value = old_values[i];
if (LLVMIsConstant(old_value)) {
new_values[i] = old_value;
} else {
new_values[i] = LLVMConstNull(LLVMTypeOf(old_value));
}
}
LLVMValueRef constant_value = llvm_const_named_struct_internal(m, struct_type, new_values, cast(unsigned)value_count);
GB_ASSERT(is_local);
lbProcedure *p = m->curr_procedure;
lbAddr v = lb_add_local_generated(p, res.type, true);
map_set(&m->exact_value_compound_literal_addr_map, value.value_compound, v);
LLVMBuildStore(p->builder, constant_value, v.addr.value);
for (isize i = 0; i < value_count; i++) {
LLVMValueRef val = old_values[i];
if (!LLVMIsConstant(val)) {
LLVMValueRef dst = LLVMBuildStructGEP2(p->builder, llvm_addr_type(p->module, v.addr), v.addr.value, cast(unsigned)i, "");
// if (LLVMIsALoadInst(val)) {
// Type *ptr_type = v.addr.type;
// i64 sz = type_size_of(type_deref(ptr_type));
// LLVMValueRef src = LLVMGetOperand(val, 0);
// lb_mem_copy_non_overlapping(p, {dst, ptr_type}, {src, ptr_type}, lb_const_int(m, t_int, sz), false);
// } else {
LLVMBuildStore(p->builder, val, dst);
// }
}
}
return lb_addr_load(p, v);
}
} else if (is_type_bit_set(type)) {
ast_node(cl, CompoundLit, value.value_compound);
if (cl->elems.count == 0) {
return lb_const_nil(m, original_type);
}
i64 sz = type_size_of(type);
if (sz == 0) {
return lb_const_nil(m, original_type);
}
BigInt bits = {};
BigInt one = {};
big_int_from_u64(&one, 1);
for_array(i, cl->elems) {
Ast *e = cl->elems[i];
GB_ASSERT(e->kind != Ast_FieldValue);
TypeAndValue tav = e->tav;
if (tav.mode != Addressing_Constant) {
continue;
}
GB_ASSERT(tav.value.kind == ExactValue_Integer);
i64 v = big_int_to_i64(&tav.value.value_integer);
i64 lower = type->BitSet.lower;
u64 index = cast(u64)(v-lower);
BigInt bit = {};
big_int_from_u64(&bit, index);
big_int_shl(&bit, &one, &bit);
big_int_or(&bits, &bits, &bit);
}
res.value = lb_big_int_to_llvm(m, original_type, &bits);
return res;
} else if (is_type_matrix(type)) {
ast_node(cl, CompoundLit, value.value_compound);
Type *elem_type = type->Matrix.elem;
isize elem_count = cl->elems.count;
if (elem_count == 0 || !elem_type_can_be_constant(elem_type)) {
return lb_const_nil(m, original_type);
}
i64 max_count = type->Matrix.row_count*type->Matrix.column_count;
i64 total_count = matrix_type_total_internal_elems(type);
LLVMValueRef *values = gb_alloc_array(temporary_allocator(), LLVMValueRef, cast(isize)total_count);
if (cl->elems[0]->kind == Ast_FieldValue) {
for_array(j, cl->elems) {
Ast *elem = cl->elems[j];
ast_node(fv, FieldValue, elem);
if (is_ast_range(fv->field)) {
ast_node(ie, BinaryExpr, fv->field);
TypeAndValue lo_tav = ie->left->tav;
TypeAndValue hi_tav = ie->right->tav;
GB_ASSERT(lo_tav.mode == Addressing_Constant);
GB_ASSERT(hi_tav.mode == Addressing_Constant);
TokenKind op = ie->op.kind;
i64 lo = exact_value_to_i64(lo_tav.value);
i64 hi = exact_value_to_i64(hi_tav.value);
if (op != Token_RangeHalf) {
hi += 1;
}
GB_ASSERT(0 <= lo && lo <= max_count);
GB_ASSERT(0 <= hi && hi <= max_count);
GB_ASSERT(lo <= hi);
TypeAndValue tav = fv->value->tav;
LLVMValueRef val = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
for (i64 k = lo; k < hi; k++) {
i64 offset = matrix_row_major_index_to_offset(type, k);
GB_ASSERT(values[offset] == nullptr);
values[offset] = val;
}
} else {
TypeAndValue index_tav = fv->field->tav;
GB_ASSERT(index_tav.mode == Addressing_Constant);
i64 index = exact_value_to_i64(index_tav.value);
GB_ASSERT(index < max_count);
TypeAndValue tav = fv->value->tav;
LLVMValueRef val = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
i64 offset = matrix_row_major_index_to_offset(type, index);
GB_ASSERT(values[offset] == nullptr);
values[offset] = val;
}
}
for (i64 i = 0; i < total_count; i++) {
if (values[i] == nullptr) {
values[i] = LLVMConstNull(lb_type(m, elem_type));
}
}
res.value = lb_build_constant_array_values(m, type, elem_type, cast(isize)total_count, values, cc);
return res;
} else {
GB_ASSERT_MSG(elem_count == max_count, "%td != %td", elem_count, max_count);
LLVMValueRef *values = gb_alloc_array(temporary_allocator(), LLVMValueRef, cast(isize)total_count);
for_array(i, cl->elems) {
TypeAndValue tav = cl->elems[i]->tav;
GB_ASSERT(tav.mode != Addressing_Invalid);
i64 offset = 0;
offset = matrix_row_major_index_to_offset(type, i);
values[offset] = lb_const_value(m, elem_type, tav.value, cc, tav.type).value;
}
for (isize i = 0; i < total_count; i++) {
if (values[i] == nullptr) {
values[i] = LLVMConstNull(lb_type(m, elem_type));
}
}
res.value = lb_build_constant_array_values(m, type, elem_type, cast(isize)total_count, values, cc);
return res;
}
} else {
return lb_const_nil(m, original_type);
}
break;
case ExactValue_Procedure:
GB_PANIC("handled earlier");
break;
case ExactValue_Typeid:
return lb_typeid(m, value.value_typeid);
}
return lb_const_nil(m, original_type);
}
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