SPIRV-Tools/test/TextToBinary.cpp
David Neto 42bfd4bfab Assembly test for OpSwitch
Removes old weak and fragile tests for OpSwitch.

Adds spvtest::TextToBinaryTest::CompileWithFormatFailure
2015-10-26 12:55:33 -04:00

454 lines
18 KiB
C++

// Copyright (c) 2015 The Khronos Group Inc.
//
// Permission is hereby granted, free of charge, to any person obtaining a
// copy of this software and/or associated documentation files (the
// "Materials"), to deal in the Materials without restriction, including
// without limitation the rights to use, copy, modify, merge, publish,
// distribute, sublicense, and/or sell copies of the Materials, and to
// permit persons to whom the Materials are furnished to do so, subject to
// the following conditions:
//
// The above copyright notice and this permission notice shall be included
// in all copies or substantial portions of the Materials.
//
// MODIFICATIONS TO THIS FILE MAY MEAN IT NO LONGER ACCURATELY REFLECTS
// KHRONOS STANDARDS. THE UNMODIFIED, NORMATIVE VERSIONS OF KHRONOS
// SPECIFICATIONS AND HEADER INFORMATION ARE LOCATED AT
// https://www.khronos.org/registry/
//
// THE MATERIALS ARE PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
// EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
// MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
// IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
// CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
// TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
// MATERIALS OR THE USE OR OTHER DEALINGS IN THE MATERIALS.
#include "TestFixture.h"
#include "UnitSPIRV.h"
#include <algorithm>
#include <iomanip>
#include <utility>
#include <vector>
namespace {
using spvtest::TextToBinaryTest;
using libspirv::AssemblyContext;
using libspirv::AssemblyGrammar;
TEST(GetWord, Simple) {
EXPECT_EQ("", AssemblyContext(AutoText(""), nullptr).getWord());
EXPECT_EQ("", AssemblyContext(AutoText("\0a"), nullptr).getWord());
EXPECT_EQ("", AssemblyContext(AutoText(" a"), nullptr).getWord());
EXPECT_EQ("", AssemblyContext(AutoText("\ta"), nullptr).getWord());
EXPECT_EQ("", AssemblyContext(AutoText("\va"), nullptr).getWord());
EXPECT_EQ("", AssemblyContext(AutoText("\ra"), nullptr).getWord());
EXPECT_EQ("", AssemblyContext(AutoText("\na"), nullptr).getWord());
EXPECT_EQ("abc", AssemblyContext(AutoText("abc"), nullptr).getWord());
EXPECT_EQ("abc", AssemblyContext(AutoText("abc "), nullptr).getWord());
EXPECT_EQ("abc",
AssemblyContext(AutoText("abc\t"), nullptr).getWord());
EXPECT_EQ("abc",
AssemblyContext(AutoText("abc\r"), nullptr).getWord());
EXPECT_EQ("abc",
AssemblyContext(AutoText("abc\v"), nullptr).getWord());
EXPECT_EQ("abc",
AssemblyContext(AutoText("abc\n"), nullptr).getWord());
}
// An mask parsing test case.
struct MaskCase {
spv_operand_type_t which_enum;
uint32_t expected_value;
const char* expression;
};
using GoodMaskParseTest = ::testing::TestWithParam<MaskCase>;
TEST_P(GoodMaskParseTest, GoodMaskExpressions) {
spv_operand_table operandTable;
ASSERT_EQ(SPV_SUCCESS, spvOperandTableGet(&operandTable));
uint32_t value;
EXPECT_EQ(SPV_SUCCESS, AssemblyGrammar(operandTable, nullptr, nullptr)
.parseMaskOperand(GetParam().which_enum,
GetParam().expression, &value));
EXPECT_EQ(GetParam().expected_value, value);
}
INSTANTIATE_TEST_CASE_P(
ParseMask, GoodMaskParseTest,
::testing::ValuesIn(std::vector<MaskCase>{
{SPV_OPERAND_TYPE_FP_FAST_MATH_MODE, 0, "None"},
{SPV_OPERAND_TYPE_FP_FAST_MATH_MODE, 1, "NotNaN"},
{SPV_OPERAND_TYPE_FP_FAST_MATH_MODE, 2, "NotInf"},
{SPV_OPERAND_TYPE_FP_FAST_MATH_MODE, 3, "NotNaN|NotInf"},
// Mask experssions are symmetric.
{SPV_OPERAND_TYPE_FP_FAST_MATH_MODE, 3, "NotInf|NotNaN"},
// Repeating a value has no effect.
{SPV_OPERAND_TYPE_FP_FAST_MATH_MODE, 3, "NotInf|NotNaN|NotInf"},
// Using 3 operands still works.
{SPV_OPERAND_TYPE_FP_FAST_MATH_MODE, 0x13, "NotInf|NotNaN|Fast"},
{SPV_OPERAND_TYPE_SELECTION_CONTROL, 0, "None"},
{SPV_OPERAND_TYPE_SELECTION_CONTROL, 1, "Flatten"},
{SPV_OPERAND_TYPE_SELECTION_CONTROL, 2, "DontFlatten"},
// Weirdly, you can specify to flatten and don't flatten a selection.
{SPV_OPERAND_TYPE_SELECTION_CONTROL, 3, "Flatten|DontFlatten"},
{SPV_OPERAND_TYPE_LOOP_CONTROL, 0, "None"},
{SPV_OPERAND_TYPE_LOOP_CONTROL, 1, "Unroll"},
{SPV_OPERAND_TYPE_LOOP_CONTROL, 2, "DontUnroll"},
// Weirdly, you can specify to unroll and don't unroll a loop.
{SPV_OPERAND_TYPE_LOOP_CONTROL, 3, "Unroll|DontUnroll"},
{SPV_OPERAND_TYPE_FUNCTION_CONTROL, 0, "None"},
{SPV_OPERAND_TYPE_FUNCTION_CONTROL, 1, "Inline"},
{SPV_OPERAND_TYPE_FUNCTION_CONTROL, 2, "DontInline"},
{SPV_OPERAND_TYPE_FUNCTION_CONTROL, 4, "Pure"},
{SPV_OPERAND_TYPE_FUNCTION_CONTROL, 8, "Const"},
{SPV_OPERAND_TYPE_FUNCTION_CONTROL, 0xd, "Inline|Const|Pure"},
}));
using BadFPFastMathMaskParseTest = ::testing::TestWithParam<const char*>;
TEST_P(BadFPFastMathMaskParseTest, BadMaskExpressions) {
spv_operand_table operandTable;
ASSERT_EQ(SPV_SUCCESS, spvOperandTableGet(&operandTable));
uint32_t value;
EXPECT_NE(SPV_SUCCESS,
AssemblyGrammar(operandTable, nullptr, nullptr)
.parseMaskOperand(SPV_OPERAND_TYPE_FP_FAST_MATH_MODE,
GetParam(), &value));
}
INSTANTIATE_TEST_CASE_P(ParseMask, BadFPFastMathMaskParseTest,
::testing::ValuesIn(std::vector<const char*>{
nullptr, "", "NotValidEnum", "|", "NotInf|",
"|NotInf", "NotInf||NotNaN",
"Unroll" // A good word, but for the wrong enum
}));
// TODO(dneto): Aliasing like this relies on undefined behaviour. Fix this.
union char_word_t {
char cs[4];
uint32_t u;
};
TEST(TextToBinary, Default) {
// TODO: Ensure that on big endian systems that this converts the word to
// little endian for encoding comparison!
spv_endianness_t endian = SPV_ENDIANNESS_LITTLE;
const char* textStr = R"(
OpSource OpenCL 12
OpMemoryModel Physical64 OpenCL
OpSourceExtension "PlaceholderExtensionName"
OpEntryPoint Kernel %1 "foo"
OpExecutionMode %1 LocalSizeHint 1 1 1
%2 = OpTypeVoid
%3 = OpTypeBool
; commment
%4 = OpTypeInt 8 0 ; comment
%5 = OpTypeInt 8 1
%6 = OpTypeInt 16 0
%7 = OpTypeInt 16 1
%8 = OpTypeInt 32 0
%9 = OpTypeInt 32 1
%10 = OpTypeInt 64 0
%11 = OpTypeInt 64 1
%12 = OpTypeFloat 16
%13 = OpTypeFloat 32
%14 = OpTypeFloat 64
%15 = OpTypeVector %4 2
)";
spv_opcode_table opcodeTable;
ASSERT_EQ(SPV_SUCCESS, spvOpcodeTableGet(&opcodeTable));
spv_operand_table operandTable;
ASSERT_EQ(SPV_SUCCESS, spvOperandTableGet(&operandTable));
spv_ext_inst_table extInstTable;
ASSERT_EQ(SPV_SUCCESS, spvExtInstTableGet(&extInstTable));
spv_binary binary;
spv_diagnostic diagnostic = nullptr;
spv_result_t error =
spvTextToBinary(textStr, strlen(textStr), opcodeTable, operandTable,
extInstTable, &binary, &diagnostic);
if (error) {
spvDiagnosticPrint(diagnostic);
spvDiagnosticDestroy(diagnostic);
ASSERT_EQ(SPV_SUCCESS, error);
}
EXPECT_NE(nullptr, binary->code);
EXPECT_NE(0, binary->wordCount);
// TODO: Verify binary
ASSERT_EQ(SPV_MAGIC_NUMBER, binary->code[SPV_INDEX_MAGIC_NUMBER]);
ASSERT_EQ(SPV_VERSION_NUMBER, binary->code[SPV_INDEX_VERSION_NUMBER]);
ASSERT_EQ(SPV_GENERATOR_KHRONOS, binary->code[SPV_INDEX_GENERATOR_NUMBER]);
ASSERT_EQ(16, binary->code[SPV_INDEX_BOUND]); // TODO: Bound?
ASSERT_EQ(0, binary->code[SPV_INDEX_SCHEMA]); // Reserved: schema
uint64_t instIndex = SPV_INDEX_INSTRUCTION;
ASSERT_EQ(spvOpcodeMake(3, OpSource), binary->code[instIndex++]);
ASSERT_EQ(SourceLanguageOpenCL, binary->code[instIndex++]);
ASSERT_EQ(12, binary->code[instIndex++]);
ASSERT_EQ(spvOpcodeMake(3, OpMemoryModel), binary->code[instIndex++]);
ASSERT_EQ(AddressingModelPhysical64, binary->code[instIndex++]);
ASSERT_EQ(MemoryModelOpenCL, binary->code[instIndex++]);
uint16_t sourceExtensionWordCount =
(uint16_t)((strlen("PlaceholderExtensionName") / sizeof(uint32_t)) + 2);
ASSERT_EQ(spvOpcodeMake(sourceExtensionWordCount, OpSourceExtension),
binary->code[instIndex++]);
// TODO: This only works on little endian systems!
char_word_t cw = {{'P', 'l', 'a', 'c'}};
ASSERT_EQ(spvFixWord(cw.u, endian), binary->code[instIndex++]);
cw = {{'e', 'h', 'o', 'l'}};
ASSERT_EQ(spvFixWord(cw.u, endian), binary->code[instIndex++]);
cw = {{'d', 'e', 'r', 'E'}};
ASSERT_EQ(spvFixWord(cw.u, endian), binary->code[instIndex++]);
cw = {{'x', 't', 'e', 'n'}};
ASSERT_EQ(spvFixWord(cw.u, endian), binary->code[instIndex++]);
cw = {{'s', 'i', 'o', 'n'}};
ASSERT_EQ(spvFixWord(cw.u, endian), binary->code[instIndex++]);
cw = {{'N', 'a', 'm', 'e'}};
ASSERT_EQ(spvFixWord(cw.u, endian), binary->code[instIndex++]);
ASSERT_EQ(0, binary->code[instIndex++]);
ASSERT_EQ(spvOpcodeMake(4, OpEntryPoint), binary->code[instIndex++]);
ASSERT_EQ(ExecutionModelKernel, binary->code[instIndex++]);
ASSERT_EQ(1, binary->code[instIndex++]);
cw = {{'f', 'o', 'o', 0}};
ASSERT_EQ(spvFixWord(cw.u, endian), binary->code[instIndex++]);
ASSERT_EQ(spvOpcodeMake(6, OpExecutionMode), binary->code[instIndex++]);
ASSERT_EQ(1, binary->code[instIndex++]);
ASSERT_EQ(ExecutionModeLocalSizeHint, binary->code[instIndex++]);
ASSERT_EQ(1, binary->code[instIndex++]);
ASSERT_EQ(1, binary->code[instIndex++]);
ASSERT_EQ(1, binary->code[instIndex++]);
ASSERT_EQ(spvOpcodeMake(2, OpTypeVoid), binary->code[instIndex++]);
ASSERT_EQ(2, binary->code[instIndex++]);
ASSERT_EQ(spvOpcodeMake(2, OpTypeBool), binary->code[instIndex++]);
ASSERT_EQ(3, binary->code[instIndex++]);
ASSERT_EQ(spvOpcodeMake(4, OpTypeInt), binary->code[instIndex++]);
ASSERT_EQ(4, binary->code[instIndex++]);
ASSERT_EQ(8, binary->code[instIndex++]); // NOTE: 8 bits wide
ASSERT_EQ(0, binary->code[instIndex++]); // NOTE: Unsigned
ASSERT_EQ(spvOpcodeMake(4, OpTypeInt), binary->code[instIndex++]);
ASSERT_EQ(5, binary->code[instIndex++]);
ASSERT_EQ(8, binary->code[instIndex++]); // NOTE: 8 bits wide
ASSERT_EQ(1, binary->code[instIndex++]); // NOTE: Signed
ASSERT_EQ(spvOpcodeMake(4, OpTypeInt), binary->code[instIndex++]);
ASSERT_EQ(6, binary->code[instIndex++]);
ASSERT_EQ(16, binary->code[instIndex++]); // NOTE: 16 bits wide
ASSERT_EQ(0, binary->code[instIndex++]); // NOTE: Unsigned
ASSERT_EQ(spvOpcodeMake(4, OpTypeInt), binary->code[instIndex++]);
ASSERT_EQ(7, binary->code[instIndex++]);
ASSERT_EQ(16, binary->code[instIndex++]); // NOTE: 16 bits wide
ASSERT_EQ(1, binary->code[instIndex++]); // NOTE: Signed
ASSERT_EQ(spvOpcodeMake(4, OpTypeInt), binary->code[instIndex++]);
ASSERT_EQ(8, binary->code[instIndex++]);
ASSERT_EQ(32, binary->code[instIndex++]); // NOTE: 32 bits wide
ASSERT_EQ(0, binary->code[instIndex++]); // NOTE: Unsigned
ASSERT_EQ(spvOpcodeMake(4, OpTypeInt), binary->code[instIndex++]);
ASSERT_EQ(9, binary->code[instIndex++]);
ASSERT_EQ(32, binary->code[instIndex++]); // NOTE: 32 bits wide
ASSERT_EQ(1, binary->code[instIndex++]); // NOTE: Signed
ASSERT_EQ(spvOpcodeMake(4, OpTypeInt), binary->code[instIndex++]);
ASSERT_EQ(10, binary->code[instIndex++]);
ASSERT_EQ(64, binary->code[instIndex++]); // NOTE: 64 bits wide
ASSERT_EQ(0, binary->code[instIndex++]); // NOTE: Unsigned
ASSERT_EQ(spvOpcodeMake(4, OpTypeInt), binary->code[instIndex++]);
ASSERT_EQ(11, binary->code[instIndex++]);
ASSERT_EQ(64, binary->code[instIndex++]); // NOTE: 64 bits wide
ASSERT_EQ(1, binary->code[instIndex++]); // NOTE: Signed
ASSERT_EQ(spvOpcodeMake(3, OpTypeFloat), binary->code[instIndex++]);
ASSERT_EQ(12, binary->code[instIndex++]);
ASSERT_EQ(16, binary->code[instIndex++]); // NOTE: 16 bits wide
ASSERT_EQ(spvOpcodeMake(3, OpTypeFloat), binary->code[instIndex++]);
ASSERT_EQ(13, binary->code[instIndex++]);
ASSERT_EQ(32, binary->code[instIndex++]); // NOTE: 32 bits wide
ASSERT_EQ(spvOpcodeMake(3, OpTypeFloat), binary->code[instIndex++]);
ASSERT_EQ(14, binary->code[instIndex++]);
ASSERT_EQ(64, binary->code[instIndex++]); // NOTE: 64 bits wide
ASSERT_EQ(spvOpcodeMake(4, OpTypeVector), binary->code[instIndex++]);
ASSERT_EQ(15, binary->code[instIndex++]);
ASSERT_EQ(4, binary->code[instIndex++]);
ASSERT_EQ(2, binary->code[instIndex++]);
}
TEST_F(TextToBinaryTest, InvalidText) {
spv_binary binary;
ASSERT_EQ(SPV_ERROR_INVALID_TEXT,
spvTextToBinary(nullptr, 0, opcodeTable, operandTable, extInstTable,
&binary, &diagnostic));
}
TEST_F(TextToBinaryTest, InvalidTable) {
SetText(
"OpEntryPoint Kernel 0 \"\"\nOpExecutionMode 0 LocalSizeHint 1 1 1\n");
ASSERT_EQ(SPV_ERROR_INVALID_TABLE,
spvTextToBinary(text.str, text.length, nullptr, operandTable,
extInstTable, &binary, &diagnostic));
ASSERT_EQ(SPV_ERROR_INVALID_TABLE,
spvTextToBinary(text.str, text.length, opcodeTable, nullptr,
extInstTable, &binary, &diagnostic));
ASSERT_EQ(SPV_ERROR_INVALID_TABLE,
spvTextToBinary(text.str, text.length, opcodeTable, operandTable,
nullptr, &binary, &diagnostic));
}
TEST_F(TextToBinaryTest, InvalidPointer) {
SetText(
"OpEntryPoint Kernel 0 \"\"\nOpExecutionMode 0 LocalSizeHint 1 1 1\n");
ASSERT_EQ(SPV_ERROR_INVALID_POINTER,
spvTextToBinary(text.str, text.length, opcodeTable, operandTable,
extInstTable, nullptr, &diagnostic));
}
TEST_F(TextToBinaryTest, InvalidDiagnostic) {
SetText(
"OpEntryPoint Kernel 0 \"\"\nOpExecutionMode 0 LocalSizeHint 1 1 1\n");
spv_binary binary;
ASSERT_EQ(SPV_ERROR_INVALID_DIAGNOSTIC,
spvTextToBinary(text.str, text.length, opcodeTable, operandTable,
extInstTable, &binary, nullptr));
}
TEST_F(TextToBinaryTest, InvalidPrefix) {
SetText("Invalid");
ASSERT_EQ(SPV_ERROR_INVALID_TEXT,
spvTextToBinary(text.str, text.length, opcodeTable, operandTable,
extInstTable, &binary, &diagnostic));
if (diagnostic) {
spvDiagnosticPrint(diagnostic);
}
}
TEST_F(TextToBinaryTest, StringSpace) {
SetText("OpSourceExtension \"string with spaces\"");
EXPECT_EQ(SPV_SUCCESS,
spvTextToBinary(text.str, text.length, opcodeTable, operandTable,
extInstTable, &binary, &diagnostic));
if (diagnostic) {
spvDiagnosticPrint(diagnostic);
}
}
TEST_F(TextToBinaryTest, UnknownBeginningOfInstruction) {
SetText(R"(
OpSource OpenCL 12
OpMemoryModel Physical64 OpenCL
Google
)");
EXPECT_EQ(SPV_ERROR_INVALID_TEXT,
spvTextToBinary(text.str, text.length, opcodeTable, operandTable,
extInstTable, &binary, &diagnostic));
EXPECT_EQ(4, diagnostic->position.line + 1);
EXPECT_EQ(1, diagnostic->position.column + 1);
EXPECT_STREQ(
"Expected <opcode> or <result-id> at the beginning of an instruction, "
"found 'Google'.",
diagnostic->error);
}
TEST_F(TextToBinaryTest, NoEqualSign) {
SetText(R"(
OpSource OpenCL 12
OpMemoryModel Physical64 OpenCL
%2
)");
EXPECT_EQ(SPV_ERROR_INVALID_TEXT,
spvTextToBinary(text.str, text.length, opcodeTable, operandTable,
extInstTable, &binary, &diagnostic));
EXPECT_EQ(5, diagnostic->position.line + 1);
EXPECT_EQ(1, diagnostic->position.column + 1);
EXPECT_STREQ("Expected '=', found end of stream.", diagnostic->error);
}
TEST_F(TextToBinaryTest, NoOpCode) {
SetText(R"(
OpSource OpenCL 12
OpMemoryModel Physical64 OpenCL
%2 =
)");
EXPECT_EQ(SPV_ERROR_INVALID_TEXT,
spvTextToBinary(text.str, text.length, opcodeTable, operandTable,
extInstTable, &binary, &diagnostic));
EXPECT_EQ(5, diagnostic->position.line + 1);
EXPECT_EQ(1, diagnostic->position.column + 1);
EXPECT_STREQ("Expected opcode, found end of stream.", diagnostic->error);
}
TEST_F(TextToBinaryTest, WrongOpCode) {
SetText(R"(
OpSource OpenCL 12
OpMemoryModel Physical64 OpenCL
%2 = Wahahaha
)");
EXPECT_EQ(SPV_ERROR_INVALID_TEXT,
spvTextToBinary(text.str, text.length, opcodeTable, operandTable,
extInstTable, &binary, &diagnostic));
EXPECT_EQ(4, diagnostic->position.line + 1);
EXPECT_EQ(6, diagnostic->position.column + 1);
EXPECT_STREQ("Invalid Opcode prefix 'Wahahaha'.", diagnostic->error);
}
using TextToBinaryFloatValueTest = spvtest::TextToBinaryTestBase<
::testing::TestWithParam<std::pair<std::string, uint32_t>>>;
TEST_P(TextToBinaryFloatValueTest, NormalValues) {
const std::string assembly = "%1 = OpTypeFloat 32\n%2 = OpConstant %1 ";
const std::string input_string = assembly + GetParam().first;
const std::string expected_string =
assembly + std::to_string(GetParam().second) + "\n";
const std::string decoded_string = EncodeAndDecodeSuccessfully(input_string);
EXPECT_EQ(expected_string, decoded_string);
}
INSTANTIATE_TEST_CASE_P(
FloatValues, TextToBinaryFloatValueTest,
::testing::ValuesIn(std::vector<std::pair<std::string, uint32_t>>{
{"0.0", 0x00000000}, // +0
{"!0x00000001", 0x00000001}, // +denorm
{"!0x00800000", 0x00800000}, // +norm
{"1.5", 0x3fc00000},
{"!0x7f800000", 0x7f800000}, // +inf
{"!0x7f800001", 0x7f800001}, // NaN
{"-0.0", 0x80000000}, // -0
{"!0x80000001", 0x80000001}, // -denorm
{"!0x80800000", 0x80800000}, // -norm
{"-2.5", 0xc0200000},
{"!0xff800000", 0xff800000}, // -inf
{"!0xff800001", 0xff800001}, // NaN
}));
} // anonymous namespace