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llvm-mirror/unittests/FileCheck/FileCheckTest.cpp
2021-05-14 19:16:31 +02:00

1781 lines
74 KiB
C++

//===- llvm/unittest/FileCheck/FileCheckTest.cpp - FileCheck tests --------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#include "llvm/FileCheck/FileCheck.h"
#include "../lib/FileCheck/FileCheckImpl.h"
#include "llvm/Support/Regex.h"
#include "llvm/Testing/Support/Error.h"
#include "gtest/gtest.h"
#include <tuple>
#include <unordered_set>
using namespace llvm;
namespace {
class FileCheckTest : public ::testing::Test {};
static StringRef bufferize(SourceMgr &SM, StringRef Str) {
std::unique_ptr<MemoryBuffer> Buffer =
MemoryBuffer::getMemBufferCopy(Str, "TestBuffer");
StringRef StrBufferRef = Buffer->getBuffer();
SM.AddNewSourceBuffer(std::move(Buffer), SMLoc());
return StrBufferRef;
}
static std::string toString(const std::unordered_set<std::string> &Set) {
bool First = true;
std::string Str;
for (StringRef S : Set) {
Str += Twine(First ? "{" + S : ", " + S).str();
First = false;
}
Str += '}';
return Str;
}
template <typename ErrorT>
static void expectSameErrors(std::unordered_set<std::string> ExpectedMsgs,
Error Err) {
auto AnyErrorMsgMatch = [&ExpectedMsgs](std::string &&ErrorMsg) -> bool {
for (auto ExpectedMsgItr = ExpectedMsgs.begin(),
ExpectedMsgEnd = ExpectedMsgs.end();
ExpectedMsgItr != ExpectedMsgEnd; ++ExpectedMsgItr) {
if (ErrorMsg.find(*ExpectedMsgItr) != std::string::npos) {
ExpectedMsgs.erase(ExpectedMsgItr);
return true;
}
}
return false;
};
Error RemainingErrors = std::move(Err);
do {
RemainingErrors =
handleErrors(std::move(RemainingErrors), [&](const ErrorT &E) {
EXPECT_TRUE(AnyErrorMsgMatch(E.message()))
<< "Unexpected error message:" << std::endl
<< E.message();
});
} while (RemainingErrors && !ExpectedMsgs.empty());
EXPECT_THAT_ERROR(std::move(RemainingErrors), Succeeded());
EXPECT_TRUE(ExpectedMsgs.empty())
<< "Error message(s) not found:" << std::endl
<< toString(ExpectedMsgs);
}
template <typename ErrorT>
static void expectError(StringRef ExpectedMsg, Error Err) {
expectSameErrors<ErrorT>({ExpectedMsg.str()}, std::move(Err));
}
static void expectDiagnosticError(StringRef ExpectedMsg, Error Err) {
expectError<ErrorDiagnostic>(ExpectedMsg, std::move(Err));
}
constexpr uint64_t MaxUint64 = std::numeric_limits<uint64_t>::max();
constexpr int64_t MaxInt64 = std::numeric_limits<int64_t>::max();
constexpr int64_t MinInt64 = std::numeric_limits<int64_t>::min();
constexpr uint64_t AbsoluteMinInt64 =
static_cast<uint64_t>(-(MinInt64 + 1)) + 1;
constexpr uint64_t AbsoluteMaxInt64 = static_cast<uint64_t>(MaxInt64);
struct ExpressionFormatParameterisedFixture
: public ::testing::TestWithParam<
std::tuple<ExpressionFormat::Kind, unsigned, bool>> {
bool AlternateForm;
unsigned Precision;
bool Signed;
bool AllowHex;
bool AllowUpperHex;
ExpressionFormat Format;
Regex WildcardRegex;
StringRef TenStr;
StringRef FifteenStr;
std::string MaxUint64Str;
std::string MaxInt64Str;
std::string MinInt64Str;
StringRef FirstInvalidCharDigits;
StringRef AcceptedHexOnlyDigits;
StringRef RefusedHexOnlyDigits;
SourceMgr SM;
void SetUp() override {
ExpressionFormat::Kind Kind;
std::tie(Kind, Precision, AlternateForm) = GetParam();
AllowHex = Kind == ExpressionFormat::Kind::HexLower ||
Kind == ExpressionFormat::Kind::HexUpper;
AllowUpperHex = Kind == ExpressionFormat::Kind::HexUpper;
Signed = Kind == ExpressionFormat::Kind::Signed;
Format = ExpressionFormat(Kind, Precision, AlternateForm);
if (!AllowHex) {
MaxUint64Str = std::to_string(MaxUint64);
MaxInt64Str = std::to_string(MaxInt64);
MinInt64Str = std::to_string(MinInt64);
TenStr = "10";
FifteenStr = "15";
FirstInvalidCharDigits = "aA";
AcceptedHexOnlyDigits = RefusedHexOnlyDigits = "N/A";
return;
}
MaxUint64Str = AllowUpperHex ? "FFFFFFFFFFFFFFFF" : "ffffffffffffffff";
MaxInt64Str = AllowUpperHex ? "7FFFFFFFFFFFFFFF" : "7fffffffffffffff";
TenStr = AllowUpperHex ? "A" : "a";
FifteenStr = AllowUpperHex ? "F" : "f";
AcceptedHexOnlyDigits = AllowUpperHex ? "ABCDEF" : "abcdef";
RefusedHexOnlyDigits = AllowUpperHex ? "abcdef" : "ABCDEF";
MinInt64Str = "N/A";
FirstInvalidCharDigits = "gG";
}
void checkWildcardRegexMatch(StringRef Input,
unsigned TrailExtendTo = 0) const {
ASSERT_TRUE(TrailExtendTo == 0 || AllowHex);
SmallVector<StringRef, 4> Matches;
std::string ExtendedInput = Input.str();
size_t PrefixSize = AlternateForm ? 2 : 0;
if (TrailExtendTo > Input.size() - PrefixSize) {
size_t ExtensionSize = PrefixSize + TrailExtendTo - Input.size();
ExtendedInput.append(ExtensionSize, Input[PrefixSize]);
}
ASSERT_TRUE(WildcardRegex.match(ExtendedInput, &Matches))
<< "Wildcard regex does not match " << ExtendedInput;
EXPECT_EQ(Matches[0], ExtendedInput);
}
void checkWildcardRegexMatchFailure(StringRef Input) const {
EXPECT_FALSE(WildcardRegex.match(Input));
}
std::string addBasePrefix(StringRef Num) const {
StringRef Prefix = AlternateForm ? "0x" : "";
return (Twine(Prefix) + Twine(Num)).str();
}
void checkPerCharWildcardRegexMatchFailure(StringRef Chars) const {
for (auto C : Chars) {
std::string Str = addBasePrefix(StringRef(&C, 1));
EXPECT_FALSE(WildcardRegex.match(Str));
}
}
std::string padWithLeadingZeros(StringRef NumStr) const {
bool Negative = NumStr.startswith("-");
if (NumStr.size() - unsigned(Negative) >= Precision)
return NumStr.str();
std::string PaddedStr;
if (Negative) {
PaddedStr = "-";
NumStr = NumStr.drop_front();
}
PaddedStr.append(Precision - NumStr.size(), '0');
PaddedStr.append(NumStr.str());
return PaddedStr;
}
template <class T> void checkMatchingString(T Val, StringRef ExpectedStr) {
Expected<std::string> MatchingString =
Format.getMatchingString(ExpressionValue(Val));
ASSERT_THAT_EXPECTED(MatchingString, Succeeded())
<< "No matching string for " << Val;
EXPECT_EQ(*MatchingString, ExpectedStr);
}
template <class T> void checkMatchingStringFailure(T Val) {
Expected<std::string> MatchingString =
Format.getMatchingString(ExpressionValue(Val));
// Error message tested in ExpressionValue unit tests.
EXPECT_THAT_EXPECTED(MatchingString, Failed());
}
Expected<ExpressionValue> getValueFromStringReprFailure(StringRef Str) {
StringRef BufferizedStr = bufferize(SM, Str);
return Format.valueFromStringRepr(BufferizedStr, SM);
}
template <class T>
void checkValueFromStringRepr(StringRef Str, T ExpectedVal) {
Expected<ExpressionValue> ResultValue = getValueFromStringReprFailure(Str);
ASSERT_THAT_EXPECTED(ResultValue, Succeeded())
<< "Failed to get value from " << Str;
ASSERT_EQ(ResultValue->isNegative(), ExpectedVal < 0)
<< "Value for " << Str << " is not " << ExpectedVal;
if (ResultValue->isNegative())
EXPECT_EQ(cantFail(ResultValue->getSignedValue()),
static_cast<int64_t>(ExpectedVal));
else
EXPECT_EQ(cantFail(ResultValue->getUnsignedValue()),
static_cast<uint64_t>(ExpectedVal));
}
void checkValueFromStringReprFailure(
StringRef Str, StringRef ErrorStr = "unable to represent numeric value") {
Expected<ExpressionValue> ResultValue = getValueFromStringReprFailure(Str);
expectDiagnosticError(ErrorStr, ResultValue.takeError());
}
};
TEST_P(ExpressionFormatParameterisedFixture, FormatGetWildcardRegex) {
// Wildcard regex is valid.
Expected<std::string> WildcardPattern = Format.getWildcardRegex();
ASSERT_THAT_EXPECTED(WildcardPattern, Succeeded());
WildcardRegex = Regex((Twine("^") + *WildcardPattern + "$").str());
ASSERT_TRUE(WildcardRegex.isValid());
// Does not match empty string.
checkWildcardRegexMatchFailure("");
// Matches all decimal digits, matches several of them and match 0x prefix
// if and only if AlternateForm is true.
StringRef LongNumber = "12345678901234567890";
StringRef PrefixedLongNumber = "0x12345678901234567890";
if (AlternateForm) {
checkWildcardRegexMatch(PrefixedLongNumber);
checkWildcardRegexMatchFailure(LongNumber);
} else {
checkWildcardRegexMatch(LongNumber);
checkWildcardRegexMatchFailure(PrefixedLongNumber);
}
// Matches negative digits.
LongNumber = "-12345678901234567890";
if (Signed)
checkWildcardRegexMatch(LongNumber);
else
checkWildcardRegexMatchFailure(LongNumber);
// Check non digits or digits with wrong casing are not matched.
std::string LongNumberStr;
if (AllowHex) {
LongNumberStr = addBasePrefix(AcceptedHexOnlyDigits);
checkWildcardRegexMatch(LongNumberStr, 16);
checkPerCharWildcardRegexMatchFailure(RefusedHexOnlyDigits);
}
checkPerCharWildcardRegexMatchFailure(FirstInvalidCharDigits);
// Check leading zeros are only accepted if number of digits is less than the
// precision.
LongNumber = "01234567890123456789";
if (Precision) {
LongNumberStr = addBasePrefix(LongNumber.take_front(Precision));
checkWildcardRegexMatch(LongNumberStr);
LongNumberStr = addBasePrefix(LongNumber.take_front(Precision - 1));
checkWildcardRegexMatchFailure(LongNumberStr);
if (Precision < LongNumber.size()) {
LongNumberStr = addBasePrefix(LongNumber.take_front(Precision + 1));
checkWildcardRegexMatchFailure(LongNumberStr);
}
} else {
LongNumberStr = addBasePrefix(LongNumber);
checkWildcardRegexMatch(LongNumberStr);
}
}
TEST_P(ExpressionFormatParameterisedFixture, FormatGetMatchingString) {
checkMatchingString(0, addBasePrefix(padWithLeadingZeros("0")));
checkMatchingString(9, addBasePrefix(padWithLeadingZeros("9")));
if (Signed) {
checkMatchingString(-5, padWithLeadingZeros("-5"));
checkMatchingStringFailure(MaxUint64);
checkMatchingString(MaxInt64, padWithLeadingZeros(MaxInt64Str));
checkMatchingString(MinInt64, padWithLeadingZeros(MinInt64Str));
} else {
checkMatchingStringFailure(-5);
checkMatchingString(MaxUint64,
addBasePrefix(padWithLeadingZeros(MaxUint64Str)));
checkMatchingString(MaxInt64,
addBasePrefix(padWithLeadingZeros(MaxInt64Str)));
checkMatchingStringFailure(MinInt64);
}
checkMatchingString(10, addBasePrefix(padWithLeadingZeros(TenStr)));
checkMatchingString(15, addBasePrefix(padWithLeadingZeros(FifteenStr)));
}
TEST_P(ExpressionFormatParameterisedFixture, FormatValueFromStringRepr) {
checkValueFromStringRepr(addBasePrefix("0"), 0);
checkValueFromStringRepr(addBasePrefix("9"), 9);
if (Signed) {
checkValueFromStringRepr("-5", -5);
checkValueFromStringReprFailure(MaxUint64Str);
} else {
checkValueFromStringReprFailure("-" + addBasePrefix("5"));
checkValueFromStringRepr(addBasePrefix(MaxUint64Str), MaxUint64);
}
checkValueFromStringRepr(addBasePrefix(TenStr), 10);
checkValueFromStringRepr(addBasePrefix(FifteenStr), 15);
// Wrong casing is not tested because valueFromStringRepr() relies on
// StringRef's getAsInteger() which does not allow to restrict casing.
checkValueFromStringReprFailure(addBasePrefix("G"));
if (AlternateForm)
checkValueFromStringReprFailure("9", "missing alternate form prefix");
}
TEST_P(ExpressionFormatParameterisedFixture, FormatBoolOperator) {
EXPECT_TRUE(bool(Format));
}
INSTANTIATE_TEST_SUITE_P(
AllowedExplicitExpressionFormat, ExpressionFormatParameterisedFixture,
::testing::Values(
std::make_tuple(ExpressionFormat::Kind::Unsigned, 0, false),
std::make_tuple(ExpressionFormat::Kind::Signed, 0, false),
std::make_tuple(ExpressionFormat::Kind::HexLower, 0, false),
std::make_tuple(ExpressionFormat::Kind::HexLower, 0, true),
std::make_tuple(ExpressionFormat::Kind::HexUpper, 0, false),
std::make_tuple(ExpressionFormat::Kind::HexUpper, 0, true),
std::make_tuple(ExpressionFormat::Kind::Unsigned, 1, false),
std::make_tuple(ExpressionFormat::Kind::Signed, 1, false),
std::make_tuple(ExpressionFormat::Kind::HexLower, 1, false),
std::make_tuple(ExpressionFormat::Kind::HexLower, 1, true),
std::make_tuple(ExpressionFormat::Kind::HexUpper, 1, false),
std::make_tuple(ExpressionFormat::Kind::HexUpper, 1, true),
std::make_tuple(ExpressionFormat::Kind::Unsigned, 16, false),
std::make_tuple(ExpressionFormat::Kind::Signed, 16, false),
std::make_tuple(ExpressionFormat::Kind::HexLower, 16, false),
std::make_tuple(ExpressionFormat::Kind::HexLower, 16, true),
std::make_tuple(ExpressionFormat::Kind::HexUpper, 16, false),
std::make_tuple(ExpressionFormat::Kind::HexUpper, 16, true),
std::make_tuple(ExpressionFormat::Kind::Unsigned, 20, false),
std::make_tuple(ExpressionFormat::Kind::Signed, 20, false)));
TEST_F(FileCheckTest, NoFormatProperties) {
ExpressionFormat NoFormat(ExpressionFormat::Kind::NoFormat);
expectError<StringError>("trying to match value with invalid format",
NoFormat.getWildcardRegex().takeError());
expectError<StringError>(
"trying to match value with invalid format",
NoFormat.getMatchingString(ExpressionValue(18u)).takeError());
EXPECT_FALSE(bool(NoFormat));
}
TEST_F(FileCheckTest, FormatEqualityOperators) {
ExpressionFormat UnsignedFormat(ExpressionFormat::Kind::Unsigned);
ExpressionFormat UnsignedFormat2(ExpressionFormat::Kind::Unsigned);
EXPECT_TRUE(UnsignedFormat == UnsignedFormat2);
EXPECT_FALSE(UnsignedFormat != UnsignedFormat2);
ExpressionFormat HexLowerFormat(ExpressionFormat::Kind::HexLower);
EXPECT_FALSE(UnsignedFormat == HexLowerFormat);
EXPECT_TRUE(UnsignedFormat != HexLowerFormat);
ExpressionFormat NoFormat(ExpressionFormat::Kind::NoFormat);
ExpressionFormat NoFormat2(ExpressionFormat::Kind::NoFormat);
EXPECT_FALSE(NoFormat == NoFormat2);
EXPECT_TRUE(NoFormat != NoFormat2);
}
TEST_F(FileCheckTest, FormatKindEqualityOperators) {
ExpressionFormat UnsignedFormat(ExpressionFormat::Kind::Unsigned);
EXPECT_TRUE(UnsignedFormat == ExpressionFormat::Kind::Unsigned);
EXPECT_FALSE(UnsignedFormat != ExpressionFormat::Kind::Unsigned);
EXPECT_FALSE(UnsignedFormat == ExpressionFormat::Kind::HexLower);
EXPECT_TRUE(UnsignedFormat != ExpressionFormat::Kind::HexLower);
ExpressionFormat NoFormat(ExpressionFormat::Kind::NoFormat);
EXPECT_TRUE(NoFormat == ExpressionFormat::Kind::NoFormat);
EXPECT_FALSE(NoFormat != ExpressionFormat::Kind::NoFormat);
}
template <class T1, class T2>
static Expected<ExpressionValue> doValueOperation(binop_eval_t Operation,
T1 LeftValue, T2 RightValue) {
ExpressionValue LeftOperand(LeftValue);
ExpressionValue RightOperand(RightValue);
return Operation(LeftOperand, RightOperand);
}
template <class T>
static void expectValueEqual(ExpressionValue ActualValue, T ExpectedValue) {
EXPECT_EQ(ExpectedValue < 0, ActualValue.isNegative());
if (ExpectedValue < 0) {
Expected<int64_t> SignedActualValue = ActualValue.getSignedValue();
ASSERT_THAT_EXPECTED(SignedActualValue, Succeeded());
EXPECT_EQ(*SignedActualValue, static_cast<int64_t>(ExpectedValue));
} else {
Expected<uint64_t> UnsignedActualValue = ActualValue.getUnsignedValue();
ASSERT_THAT_EXPECTED(UnsignedActualValue, Succeeded());
EXPECT_EQ(*UnsignedActualValue, static_cast<uint64_t>(ExpectedValue));
}
}
template <class T1, class T2, class TR>
static void expectOperationValueResult(binop_eval_t Operation, T1 LeftValue,
T2 RightValue, TR ResultValue) {
Expected<ExpressionValue> OperationResult =
doValueOperation(Operation, LeftValue, RightValue);
ASSERT_THAT_EXPECTED(OperationResult, Succeeded());
expectValueEqual(*OperationResult, ResultValue);
}
template <class T1, class T2>
static void expectOperationValueResult(binop_eval_t Operation, T1 LeftValue,
T2 RightValue) {
expectError<OverflowError>(
"overflow error",
doValueOperation(Operation, LeftValue, RightValue).takeError());
}
TEST_F(FileCheckTest, ExpressionValueGetUnsigned) {
// Test positive value.
Expected<uint64_t> UnsignedValue = ExpressionValue(10).getUnsignedValue();
ASSERT_THAT_EXPECTED(UnsignedValue, Succeeded());
EXPECT_EQ(*UnsignedValue, 10U);
// Test 0.
UnsignedValue = ExpressionValue(0).getUnsignedValue();
ASSERT_THAT_EXPECTED(UnsignedValue, Succeeded());
EXPECT_EQ(*UnsignedValue, 0U);
// Test max positive value.
UnsignedValue = ExpressionValue(MaxUint64).getUnsignedValue();
ASSERT_THAT_EXPECTED(UnsignedValue, Succeeded());
EXPECT_EQ(*UnsignedValue, MaxUint64);
// Test failure with negative value.
expectError<OverflowError>(
"overflow error", ExpressionValue(-1).getUnsignedValue().takeError());
// Test failure with min negative value.
expectError<OverflowError>(
"overflow error",
ExpressionValue(MinInt64).getUnsignedValue().takeError());
}
TEST_F(FileCheckTest, ExpressionValueGetSigned) {
// Test positive value.
Expected<int64_t> SignedValue = ExpressionValue(10).getSignedValue();
ASSERT_THAT_EXPECTED(SignedValue, Succeeded());
EXPECT_EQ(*SignedValue, 10);
// Test 0.
SignedValue = ExpressionValue(0).getSignedValue();
ASSERT_THAT_EXPECTED(SignedValue, Succeeded());
EXPECT_EQ(*SignedValue, 0);
// Test max int64_t.
SignedValue = ExpressionValue(MaxInt64).getSignedValue();
ASSERT_THAT_EXPECTED(SignedValue, Succeeded());
EXPECT_EQ(*SignedValue, MaxInt64);
// Test failure with too big positive value.
expectError<OverflowError>(
"overflow error", ExpressionValue(static_cast<uint64_t>(MaxInt64) + 1)
.getSignedValue()
.takeError());
// Test failure with max uint64_t.
expectError<OverflowError>(
"overflow error",
ExpressionValue(MaxUint64).getSignedValue().takeError());
// Test negative value.
SignedValue = ExpressionValue(-10).getSignedValue();
ASSERT_THAT_EXPECTED(SignedValue, Succeeded());
EXPECT_EQ(*SignedValue, -10);
// Test min int64_t.
SignedValue = ExpressionValue(MinInt64).getSignedValue();
ASSERT_THAT_EXPECTED(SignedValue, Succeeded());
EXPECT_EQ(*SignedValue, MinInt64);
}
TEST_F(FileCheckTest, ExpressionValueAbsolute) {
// Test positive value.
expectValueEqual(ExpressionValue(10).getAbsolute(), 10);
// Test 0.
expectValueEqual(ExpressionValue(0).getAbsolute(), 0);
// Test max uint64_t.
expectValueEqual(ExpressionValue(MaxUint64).getAbsolute(), MaxUint64);
// Test negative value.
expectValueEqual(ExpressionValue(-10).getAbsolute(), 10);
// Test absence of overflow on min int64_t.
expectValueEqual(ExpressionValue(MinInt64).getAbsolute(),
static_cast<uint64_t>(-(MinInt64 + 10)) + 10);
}
TEST_F(FileCheckTest, ExpressionValueAddition) {
// Test both negative values.
expectOperationValueResult(operator+, -10, -10, -20);
// Test both negative values with underflow.
expectOperationValueResult(operator+, MinInt64, -1);
expectOperationValueResult(operator+, MinInt64, MinInt64);
// Test negative and positive value.
expectOperationValueResult(operator+, -10, 10, 0);
expectOperationValueResult(operator+, -10, 11, 1);
expectOperationValueResult(operator+, -11, 10, -1);
// Test positive and negative value.
expectOperationValueResult(operator+, 10, -10, 0);
expectOperationValueResult(operator+, 10, -11, -1);
expectOperationValueResult(operator+, 11, -10, 1);
// Test both positive values.
expectOperationValueResult(operator+, 10, 10, 20);
// Test both positive values with overflow.
expectOperationValueResult(operator+, MaxUint64, 1);
expectOperationValueResult(operator+, MaxUint64, MaxUint64);
}
TEST_F(FileCheckTest, ExpressionValueSubtraction) {
// Test negative value and value bigger than int64_t max.
expectOperationValueResult(operator-, -10, MaxUint64);
// Test negative and positive value with underflow.
expectOperationValueResult(operator-, MinInt64, 1);
// Test negative and positive value.
expectOperationValueResult(operator-, -10, 10, -20);
// Test both negative values.
expectOperationValueResult(operator-, -10, -10, 0);
expectOperationValueResult(operator-, -11, -10, -1);
expectOperationValueResult(operator-, -10, -11, 1);
// Test positive and negative values.
expectOperationValueResult(operator-, 10, -10, 20);
// Test both positive values with result positive.
expectOperationValueResult(operator-, 10, 5, 5);
// Test both positive values with underflow.
expectOperationValueResult(operator-, 0, MaxUint64);
expectOperationValueResult(operator-, 0,
static_cast<uint64_t>(-(MinInt64 + 10)) + 11);
// Test both positive values with result < -(max int64_t)
expectOperationValueResult(operator-, 10,
static_cast<uint64_t>(MaxInt64) + 11,
-MaxInt64 - 1);
// Test both positive values with 0 > result > -(max int64_t)
expectOperationValueResult(operator-, 10, 11, -1);
}
TEST_F(FileCheckTest, ExpressionValueMultiplication) {
// Test mixed signed values.
expectOperationValueResult(operator*, -3, 10, -30);
expectOperationValueResult(operator*, 2, -17, -34);
expectOperationValueResult(operator*, 0, MinInt64, 0);
expectOperationValueResult(operator*, MinInt64, 1, MinInt64);
expectOperationValueResult(operator*, 1, MinInt64, MinInt64);
expectOperationValueResult(operator*, MaxInt64, -1, -MaxInt64);
expectOperationValueResult(operator*, -1, MaxInt64, -MaxInt64);
// Test both negative values.
expectOperationValueResult(operator*, -3, -10, 30);
expectOperationValueResult(operator*, -2, -17, 34);
expectOperationValueResult(operator*, MinInt64, -1, AbsoluteMinInt64);
// Test both positive values.
expectOperationValueResult(operator*, 3, 10, 30);
expectOperationValueResult(operator*, 2, 17, 34);
expectOperationValueResult(operator*, 0, MaxUint64, 0);
// Test negative results that underflow.
expectOperationValueResult(operator*, -10, MaxInt64);
expectOperationValueResult(operator*, MaxInt64, -10);
expectOperationValueResult(operator*, 10, MinInt64);
expectOperationValueResult(operator*, MinInt64, 10);
expectOperationValueResult(operator*, -1, MaxUint64);
expectOperationValueResult(operator*, MaxUint64, -1);
expectOperationValueResult(operator*, -1, AbsoluteMaxInt64 + 2);
expectOperationValueResult(operator*, AbsoluteMaxInt64 + 2, -1);
// Test positive results that overflow.
expectOperationValueResult(operator*, 10, MaxUint64);
expectOperationValueResult(operator*, MaxUint64, 10);
expectOperationValueResult(operator*, MinInt64, -10);
expectOperationValueResult(operator*, -10, MinInt64);
}
TEST_F(FileCheckTest, ExpressionValueDivision) {
// Test mixed signed values.
expectOperationValueResult(operator/, -30, 10, -3);
expectOperationValueResult(operator/, 34, -17, -2);
expectOperationValueResult(operator/, 0, -10, 0);
expectOperationValueResult(operator/, MinInt64, 1, MinInt64);
expectOperationValueResult(operator/, MaxInt64, -1, -MaxInt64);
expectOperationValueResult(operator/, -MaxInt64, 1, -MaxInt64);
// Test both negative values.
expectOperationValueResult(operator/, -30, -10, 3);
expectOperationValueResult(operator/, -34, -17, 2);
// Test both positive values.
expectOperationValueResult(operator/, 30, 10, 3);
expectOperationValueResult(operator/, 34, 17, 2);
expectOperationValueResult(operator/, 0, 10, 0);
// Test divide by zero.
expectOperationValueResult(operator/, -10, 0);
expectOperationValueResult(operator/, 10, 0);
expectOperationValueResult(operator/, 0, 0);
// Test negative result that underflows.
expectOperationValueResult(operator/, MaxUint64, -1);
expectOperationValueResult(operator/, AbsoluteMaxInt64 + 2, -1);
}
TEST_F(FileCheckTest, ExpressionValueEquality) {
// Test negative and positive value.
EXPECT_FALSE(ExpressionValue(5) == ExpressionValue(-3));
EXPECT_TRUE(ExpressionValue(5) != ExpressionValue(-3));
EXPECT_FALSE(ExpressionValue(-2) == ExpressionValue(6));
EXPECT_TRUE(ExpressionValue(-2) != ExpressionValue(6));
EXPECT_FALSE(ExpressionValue(-7) == ExpressionValue(7));
EXPECT_TRUE(ExpressionValue(-7) != ExpressionValue(7));
EXPECT_FALSE(ExpressionValue(4) == ExpressionValue(-4));
EXPECT_TRUE(ExpressionValue(4) != ExpressionValue(-4));
EXPECT_FALSE(ExpressionValue(MaxUint64) == ExpressionValue(-1));
EXPECT_TRUE(ExpressionValue(MaxUint64) != ExpressionValue(-1));
// Test both negative values.
EXPECT_FALSE(ExpressionValue(-2) == ExpressionValue(-7));
EXPECT_TRUE(ExpressionValue(-2) != ExpressionValue(-7));
EXPECT_TRUE(ExpressionValue(-3) == ExpressionValue(-3));
EXPECT_FALSE(ExpressionValue(-3) != ExpressionValue(-3));
EXPECT_FALSE(ExpressionValue(MinInt64) == ExpressionValue(-1));
EXPECT_TRUE(ExpressionValue(MinInt64) != ExpressionValue(-1));
EXPECT_FALSE(ExpressionValue(MinInt64) == ExpressionValue(-0));
EXPECT_TRUE(ExpressionValue(MinInt64) != ExpressionValue(-0));
// Test both positive values.
EXPECT_FALSE(ExpressionValue(8) == ExpressionValue(9));
EXPECT_TRUE(ExpressionValue(8) != ExpressionValue(9));
EXPECT_TRUE(ExpressionValue(1) == ExpressionValue(1));
EXPECT_FALSE(ExpressionValue(1) != ExpressionValue(1));
// Check the signedness of zero doesn't affect equality.
EXPECT_TRUE(ExpressionValue(0) == ExpressionValue(0));
EXPECT_FALSE(ExpressionValue(0) != ExpressionValue(0));
EXPECT_TRUE(ExpressionValue(0) == ExpressionValue(-0));
EXPECT_FALSE(ExpressionValue(0) != ExpressionValue(-0));
EXPECT_TRUE(ExpressionValue(-0) == ExpressionValue(0));
EXPECT_FALSE(ExpressionValue(-0) != ExpressionValue(0));
EXPECT_TRUE(ExpressionValue(-0) == ExpressionValue(-0));
EXPECT_FALSE(ExpressionValue(-0) != ExpressionValue(-0));
}
TEST_F(FileCheckTest, Literal) {
SourceMgr SM;
// Eval returns the literal's value.
ExpressionLiteral Ten(bufferize(SM, "10"), 10u);
Expected<ExpressionValue> Value = Ten.eval();
ASSERT_THAT_EXPECTED(Value, Succeeded());
EXPECT_EQ(10, cantFail(Value->getSignedValue()));
Expected<ExpressionFormat> ImplicitFormat = Ten.getImplicitFormat(SM);
ASSERT_THAT_EXPECTED(ImplicitFormat, Succeeded());
EXPECT_EQ(*ImplicitFormat, ExpressionFormat::Kind::NoFormat);
// Min value can be correctly represented.
ExpressionLiteral Min(bufferize(SM, std::to_string(MinInt64)), MinInt64);
Value = Min.eval();
ASSERT_TRUE(bool(Value));
EXPECT_EQ(MinInt64, cantFail(Value->getSignedValue()));
// Max value can be correctly represented.
ExpressionLiteral Max(bufferize(SM, std::to_string(MaxUint64)), MaxUint64);
Value = Max.eval();
ASSERT_THAT_EXPECTED(Value, Succeeded());
EXPECT_EQ(MaxUint64, cantFail(Value->getUnsignedValue()));
}
TEST_F(FileCheckTest, Expression) {
SourceMgr SM;
std::unique_ptr<ExpressionLiteral> Ten =
std::make_unique<ExpressionLiteral>(bufferize(SM, "10"), 10u);
ExpressionLiteral *TenPtr = Ten.get();
Expression Expr(std::move(Ten),
ExpressionFormat(ExpressionFormat::Kind::HexLower));
EXPECT_EQ(Expr.getAST(), TenPtr);
EXPECT_EQ(Expr.getFormat(), ExpressionFormat::Kind::HexLower);
}
static void
expectUndefErrors(std::unordered_set<std::string> ExpectedUndefVarNames,
Error Err) {
EXPECT_THAT_ERROR(handleErrors(std::move(Err),
[&](const UndefVarError &E) {
EXPECT_EQ(ExpectedUndefVarNames.erase(
std::string(E.getVarName())),
1U);
}),
Succeeded());
EXPECT_TRUE(ExpectedUndefVarNames.empty()) << toString(ExpectedUndefVarNames);
}
TEST_F(FileCheckTest, NumericVariable) {
SourceMgr SM;
// Undefined variable: getValue and eval fail, error returned by eval holds
// the name of the undefined variable.
NumericVariable FooVar("FOO",
ExpressionFormat(ExpressionFormat::Kind::Unsigned), 1);
EXPECT_EQ("FOO", FooVar.getName());
EXPECT_EQ(FooVar.getImplicitFormat(), ExpressionFormat::Kind::Unsigned);
NumericVariableUse FooVarUse("FOO", &FooVar);
Expected<ExpressionFormat> ImplicitFormat = FooVarUse.getImplicitFormat(SM);
ASSERT_THAT_EXPECTED(ImplicitFormat, Succeeded());
EXPECT_EQ(*ImplicitFormat, ExpressionFormat::Kind::Unsigned);
EXPECT_FALSE(FooVar.getValue());
Expected<ExpressionValue> EvalResult = FooVarUse.eval();
expectUndefErrors({"FOO"}, EvalResult.takeError());
// Defined variable without string: only getValue and eval return value set.
FooVar.setValue(ExpressionValue(42u));
Optional<ExpressionValue> Value = FooVar.getValue();
ASSERT_TRUE(Value);
EXPECT_EQ(42, cantFail(Value->getSignedValue()));
EXPECT_FALSE(FooVar.getStringValue());
EvalResult = FooVarUse.eval();
ASSERT_THAT_EXPECTED(EvalResult, Succeeded());
EXPECT_EQ(42, cantFail(EvalResult->getSignedValue()));
// Defined variable with string: getValue, eval, and getStringValue return
// value set.
StringRef StringValue = "925";
FooVar.setValue(ExpressionValue(925u), StringValue);
Value = FooVar.getValue();
ASSERT_TRUE(Value);
EXPECT_EQ(925, cantFail(Value->getSignedValue()));
// getStringValue should return the same memory not just the same characters.
EXPECT_EQ(StringValue.begin(), FooVar.getStringValue().getValue().begin());
EXPECT_EQ(StringValue.end(), FooVar.getStringValue().getValue().end());
EvalResult = FooVarUse.eval();
ASSERT_THAT_EXPECTED(EvalResult, Succeeded());
EXPECT_EQ(925, cantFail(EvalResult->getSignedValue()));
EXPECT_EQ(925, cantFail(EvalResult->getSignedValue()));
// Clearing variable: getValue and eval fail. Error returned by eval holds
// the name of the cleared variable.
FooVar.clearValue();
EXPECT_FALSE(FooVar.getValue());
EXPECT_FALSE(FooVar.getStringValue());
EvalResult = FooVarUse.eval();
expectUndefErrors({"FOO"}, EvalResult.takeError());
}
TEST_F(FileCheckTest, Binop) {
SourceMgr SM;
StringRef ExprStr = bufferize(SM, "FOO+BAR");
StringRef FooStr = ExprStr.take_front(3);
NumericVariable FooVar(FooStr,
ExpressionFormat(ExpressionFormat::Kind::Unsigned), 1);
FooVar.setValue(ExpressionValue(42u));
std::unique_ptr<NumericVariableUse> FooVarUse =
std::make_unique<NumericVariableUse>(FooStr, &FooVar);
StringRef BarStr = ExprStr.take_back(3);
NumericVariable BarVar(BarStr,
ExpressionFormat(ExpressionFormat::Kind::Unsigned), 2);
BarVar.setValue(ExpressionValue(18u));
std::unique_ptr<NumericVariableUse> BarVarUse =
std::make_unique<NumericVariableUse>(BarStr, &BarVar);
binop_eval_t doAdd = operator+;
BinaryOperation Binop(ExprStr, doAdd, std::move(FooVarUse),
std::move(BarVarUse));
// Defined variables: eval returns right value; implicit format is as
// expected.
Expected<ExpressionValue> Value = Binop.eval();
ASSERT_THAT_EXPECTED(Value, Succeeded());
EXPECT_EQ(60, cantFail(Value->getSignedValue()));
Expected<ExpressionFormat> ImplicitFormat = Binop.getImplicitFormat(SM);
ASSERT_THAT_EXPECTED(ImplicitFormat, Succeeded());
EXPECT_EQ(*ImplicitFormat, ExpressionFormat::Kind::Unsigned);
// 1 undefined variable: eval fails, error contains name of undefined
// variable.
FooVar.clearValue();
Value = Binop.eval();
expectUndefErrors({"FOO"}, Value.takeError());
// 2 undefined variables: eval fails, error contains names of all undefined
// variables.
BarVar.clearValue();
Value = Binop.eval();
expectUndefErrors({"FOO", "BAR"}, Value.takeError());
// Literal + Variable has format of variable.
ExprStr = bufferize(SM, "FOO+18");
FooStr = ExprStr.take_front(3);
StringRef EighteenStr = ExprStr.take_back(2);
FooVarUse = std::make_unique<NumericVariableUse>(FooStr, &FooVar);
std::unique_ptr<ExpressionLiteral> Eighteen =
std::make_unique<ExpressionLiteral>(EighteenStr, 18u);
Binop = BinaryOperation(ExprStr, doAdd, std::move(FooVarUse),
std::move(Eighteen));
ImplicitFormat = Binop.getImplicitFormat(SM);
ASSERT_THAT_EXPECTED(ImplicitFormat, Succeeded());
EXPECT_EQ(*ImplicitFormat, ExpressionFormat::Kind::Unsigned);
ExprStr = bufferize(SM, "18+FOO");
FooStr = ExprStr.take_back(3);
EighteenStr = ExprStr.take_front(2);
FooVarUse = std::make_unique<NumericVariableUse>(FooStr, &FooVar);
Eighteen = std::make_unique<ExpressionLiteral>(EighteenStr, 18u);
Binop = BinaryOperation(ExprStr, doAdd, std::move(Eighteen),
std::move(FooVarUse));
ImplicitFormat = Binop.getImplicitFormat(SM);
ASSERT_THAT_EXPECTED(ImplicitFormat, Succeeded());
EXPECT_EQ(*ImplicitFormat, ExpressionFormat::Kind::Unsigned);
// Variables with different implicit format conflict.
ExprStr = bufferize(SM, "FOO+BAZ");
FooStr = ExprStr.take_front(3);
StringRef BazStr = ExprStr.take_back(3);
NumericVariable BazVar(BazStr,
ExpressionFormat(ExpressionFormat::Kind::HexLower), 3);
FooVarUse = std::make_unique<NumericVariableUse>(FooStr, &FooVar);
std::unique_ptr<NumericVariableUse> BazVarUse =
std::make_unique<NumericVariableUse>(BazStr, &BazVar);
Binop = BinaryOperation(ExprStr, doAdd, std::move(FooVarUse),
std::move(BazVarUse));
ImplicitFormat = Binop.getImplicitFormat(SM);
expectDiagnosticError(
"implicit format conflict between 'FOO' (%u) and 'BAZ' (%x), "
"need an explicit format specifier",
ImplicitFormat.takeError());
// All variable conflicts are reported.
ExprStr = bufferize(SM, "(FOO+BAZ)+(FOO+QUUX)");
StringRef Paren1ExprStr = ExprStr.substr(1, 7);
FooStr = Paren1ExprStr.take_front(3);
BazStr = Paren1ExprStr.take_back(3);
StringRef Paren2ExprStr = ExprStr.substr(ExprStr.rfind('(') + 1, 8);
StringRef FooStr2 = Paren2ExprStr.take_front(3);
StringRef QuuxStr = Paren2ExprStr.take_back(4);
FooVarUse = std::make_unique<NumericVariableUse>(FooStr, &FooVar);
BazVarUse = std::make_unique<NumericVariableUse>(BazStr, &BazVar);
std::unique_ptr<NumericVariableUse> FooVarUse2 =
std::make_unique<NumericVariableUse>(FooStr2, &FooVar);
NumericVariable QuuxVar(
QuuxStr, ExpressionFormat(ExpressionFormat::Kind::HexLower), 4);
std::unique_ptr<NumericVariableUse> QuuxVarUse =
std::make_unique<NumericVariableUse>(QuuxStr, &QuuxVar);
std::unique_ptr<BinaryOperation> Binop1 = std::make_unique<BinaryOperation>(
ExprStr.take_front(9), doAdd, std::move(FooVarUse), std::move(BazVarUse));
std::unique_ptr<BinaryOperation> Binop2 = std::make_unique<BinaryOperation>(
ExprStr.take_back(10), doAdd, std::move(FooVarUse2),
std::move(QuuxVarUse));
std::unique_ptr<BinaryOperation> OuterBinop =
std::make_unique<BinaryOperation>(ExprStr, doAdd, std::move(Binop1),
std::move(Binop2));
ImplicitFormat = OuterBinop->getImplicitFormat(SM);
expectSameErrors<ErrorDiagnostic>(
{("implicit format conflict between 'FOO' (%u) and 'BAZ' (%x), need an "
"explicit format specifier"),
("implicit format conflict between 'FOO' (%u) and 'QUUX' (%x), need an "
"explicit format specifier")},
ImplicitFormat.takeError());
}
TEST_F(FileCheckTest, ValidVarNameStart) {
EXPECT_TRUE(Pattern::isValidVarNameStart('a'));
EXPECT_TRUE(Pattern::isValidVarNameStart('G'));
EXPECT_TRUE(Pattern::isValidVarNameStart('_'));
EXPECT_FALSE(Pattern::isValidVarNameStart('2'));
EXPECT_FALSE(Pattern::isValidVarNameStart('$'));
EXPECT_FALSE(Pattern::isValidVarNameStart('@'));
EXPECT_FALSE(Pattern::isValidVarNameStart('+'));
EXPECT_FALSE(Pattern::isValidVarNameStart('-'));
EXPECT_FALSE(Pattern::isValidVarNameStart(':'));
}
TEST_F(FileCheckTest, ParseVar) {
SourceMgr SM;
StringRef OrigVarName = bufferize(SM, "GoodVar42");
StringRef VarName = OrigVarName;
Expected<Pattern::VariableProperties> ParsedVarResult =
Pattern::parseVariable(VarName, SM);
ASSERT_THAT_EXPECTED(ParsedVarResult, Succeeded());
EXPECT_EQ(ParsedVarResult->Name, OrigVarName);
EXPECT_TRUE(VarName.empty());
EXPECT_FALSE(ParsedVarResult->IsPseudo);
VarName = OrigVarName = bufferize(SM, "$GoodGlobalVar");
ParsedVarResult = Pattern::parseVariable(VarName, SM);
ASSERT_THAT_EXPECTED(ParsedVarResult, Succeeded());
EXPECT_EQ(ParsedVarResult->Name, OrigVarName);
EXPECT_TRUE(VarName.empty());
EXPECT_FALSE(ParsedVarResult->IsPseudo);
VarName = OrigVarName = bufferize(SM, "@GoodPseudoVar");
ParsedVarResult = Pattern::parseVariable(VarName, SM);
ASSERT_THAT_EXPECTED(ParsedVarResult, Succeeded());
EXPECT_EQ(ParsedVarResult->Name, OrigVarName);
EXPECT_TRUE(VarName.empty());
EXPECT_TRUE(ParsedVarResult->IsPseudo);
VarName = bufferize(SM, "42BadVar");
ParsedVarResult = Pattern::parseVariable(VarName, SM);
expectDiagnosticError("invalid variable name", ParsedVarResult.takeError());
VarName = bufferize(SM, "$@");
ParsedVarResult = Pattern::parseVariable(VarName, SM);
expectDiagnosticError("invalid variable name", ParsedVarResult.takeError());
VarName = OrigVarName = bufferize(SM, "B@dVar");
ParsedVarResult = Pattern::parseVariable(VarName, SM);
ASSERT_THAT_EXPECTED(ParsedVarResult, Succeeded());
EXPECT_EQ(VarName, OrigVarName.substr(1));
EXPECT_EQ(ParsedVarResult->Name, "B");
EXPECT_FALSE(ParsedVarResult->IsPseudo);
VarName = OrigVarName = bufferize(SM, "B$dVar");
ParsedVarResult = Pattern::parseVariable(VarName, SM);
ASSERT_THAT_EXPECTED(ParsedVarResult, Succeeded());
EXPECT_EQ(VarName, OrigVarName.substr(1));
EXPECT_EQ(ParsedVarResult->Name, "B");
EXPECT_FALSE(ParsedVarResult->IsPseudo);
VarName = bufferize(SM, "BadVar+");
ParsedVarResult = Pattern::parseVariable(VarName, SM);
ASSERT_THAT_EXPECTED(ParsedVarResult, Succeeded());
EXPECT_EQ(VarName, "+");
EXPECT_EQ(ParsedVarResult->Name, "BadVar");
EXPECT_FALSE(ParsedVarResult->IsPseudo);
VarName = bufferize(SM, "BadVar-");
ParsedVarResult = Pattern::parseVariable(VarName, SM);
ASSERT_THAT_EXPECTED(ParsedVarResult, Succeeded());
EXPECT_EQ(VarName, "-");
EXPECT_EQ(ParsedVarResult->Name, "BadVar");
EXPECT_FALSE(ParsedVarResult->IsPseudo);
VarName = bufferize(SM, "BadVar:");
ParsedVarResult = Pattern::parseVariable(VarName, SM);
ASSERT_THAT_EXPECTED(ParsedVarResult, Succeeded());
EXPECT_EQ(VarName, ":");
EXPECT_EQ(ParsedVarResult->Name, "BadVar");
EXPECT_FALSE(ParsedVarResult->IsPseudo);
}
static void expectNotFoundError(Error Err) {
expectError<NotFoundError>("String not found in input", std::move(Err));
}
class PatternTester {
private:
size_t LineNumber = 1;
SourceMgr SM;
FileCheckRequest Req;
FileCheckPatternContext Context;
Pattern P{Check::CheckPlain, &Context, LineNumber};
public:
PatternTester() {
std::vector<StringRef> GlobalDefines = {"#FOO=42", "BAR=BAZ", "#add=7"};
// An ASSERT_FALSE would make more sense but cannot be used in a
// constructor.
EXPECT_THAT_ERROR(Context.defineCmdlineVariables(GlobalDefines, SM),
Succeeded());
Context.createLineVariable();
// Call parsePattern to have @LINE defined.
P.parsePattern("N/A", "CHECK", SM, Req);
// parsePattern does not expect to be called twice for the same line and
// will set FixedStr and RegExStr incorrectly if it is. Therefore prepare
// a pattern for a different line.
initNextPattern();
}
void initNextPattern() {
P = Pattern(Check::CheckPlain, &Context, ++LineNumber);
}
size_t getLineNumber() const { return LineNumber; }
Expected<std::unique_ptr<Expression>>
parseSubst(StringRef Expr, bool IsLegacyLineExpr = false) {
StringRef ExprBufferRef = bufferize(SM, Expr);
Optional<NumericVariable *> DefinedNumericVariable;
return P.parseNumericSubstitutionBlock(
ExprBufferRef, DefinedNumericVariable, IsLegacyLineExpr, LineNumber,
&Context, SM);
}
bool parsePattern(StringRef Pattern) {
StringRef PatBufferRef = bufferize(SM, Pattern);
return P.parsePattern(PatBufferRef, "CHECK", SM, Req);
}
Expected<size_t> match(StringRef Buffer) {
StringRef BufferRef = bufferize(SM, Buffer);
Pattern::MatchResult Res = P.match(BufferRef, SM);
if (Res.TheError)
return std::move(Res.TheError);
return Res.TheMatch->Pos;
}
void printVariableDefs(FileCheckDiag::MatchType MatchTy,
std::vector<FileCheckDiag> &Diags) {
P.printVariableDefs(SM, MatchTy, &Diags);
}
};
TEST_F(FileCheckTest, ParseNumericSubstitutionBlock) {
PatternTester Tester;
// Variable definition.
expectDiagnosticError("invalid variable name",
Tester.parseSubst("%VAR:").takeError());
expectDiagnosticError("definition of pseudo numeric variable unsupported",
Tester.parseSubst("@LINE:").takeError());
expectDiagnosticError("string variable with name 'BAR' already exists",
Tester.parseSubst("BAR:").takeError());
expectDiagnosticError("unexpected characters after numeric variable name",
Tester.parseSubst("VAR GARBAGE:").takeError());
// Change of format.
expectDiagnosticError("format different from previous variable definition",
Tester.parseSubst("%X,FOO:").takeError());
// Invalid format.
expectDiagnosticError("invalid matching format specification in expression",
Tester.parseSubst("X,VAR1:").takeError());
expectDiagnosticError("invalid format specifier in expression",
Tester.parseSubst("%F,VAR1:").takeError());
expectDiagnosticError("invalid matching format specification in expression",
Tester.parseSubst("%X a,VAR1:").takeError());
// Acceptable variable definition.
EXPECT_THAT_EXPECTED(Tester.parseSubst("VAR1:"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst(" VAR2:"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("VAR3 :"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("VAR3: "), Succeeded());
// Acceptable variable definition with format specifier. Use parsePattern for
// variables whose definition needs to be visible for later checks.
EXPECT_FALSE(Tester.parsePattern("[[#%u, VAR_UNSIGNED:]]"));
EXPECT_FALSE(Tester.parsePattern("[[#%x, VAR_LOWER_HEX:]]"));
EXPECT_THAT_EXPECTED(Tester.parseSubst("%X, VAR_UPPER_HEX:"), Succeeded());
// Acceptable variable definition with precision specifier.
EXPECT_FALSE(Tester.parsePattern("[[#%.8X, PADDED_ADDR:]]"));
EXPECT_FALSE(Tester.parsePattern("[[#%.8, PADDED_NUM:]]"));
// Acceptable variable definition in alternate form.
EXPECT_THAT_EXPECTED(Tester.parseSubst("%#x, PREFIXED_ADDR:"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("%#X, PREFIXED_ADDR:"), Succeeded());
// Acceptable variable definition in alternate form.
expectDiagnosticError("alternate form only supported for hex values",
Tester.parseSubst("%#u, PREFIXED_UNSI:").takeError());
expectDiagnosticError("alternate form only supported for hex values",
Tester.parseSubst("%#d, PREFIXED_UNSI:").takeError());
// Acceptable variable definition from a numeric expression.
EXPECT_THAT_EXPECTED(Tester.parseSubst("FOOBAR: FOO+1"), Succeeded());
// Numeric expression. Switch to next line to make above valid definition
// available in expressions.
Tester.initNextPattern();
// Invalid variable name.
expectDiagnosticError("invalid matching constraint or operand format",
Tester.parseSubst("%VAR").takeError());
expectDiagnosticError("invalid pseudo numeric variable '@FOO'",
Tester.parseSubst("@FOO").takeError());
// parsePattern() is used here instead of parseSubst() for the variable to be
// recorded in GlobalNumericVariableTable and thus appear defined to
// parseNumericVariableUse(). Note that the same pattern object is used for
// the parsePattern() and parseSubst() since no initNextPattern() is called,
// thus appearing as being on the same line from the pattern's point of view.
ASSERT_FALSE(Tester.parsePattern("[[#SAME_LINE_VAR:]]"));
expectDiagnosticError("numeric variable 'SAME_LINE_VAR' defined earlier in "
"the same CHECK directive",
Tester.parseSubst("SAME_LINE_VAR").takeError());
// Invalid use of variable defined on the same line from an expression not
// using any variable defined on the same line.
ASSERT_FALSE(Tester.parsePattern("[[#SAME_LINE_EXPR_VAR:@LINE+1]]"));
expectDiagnosticError("numeric variable 'SAME_LINE_EXPR_VAR' defined earlier "
"in the same CHECK directive",
Tester.parseSubst("SAME_LINE_EXPR_VAR").takeError());
// Valid use of undefined variable which creates the variable and record it
// in GlobalNumericVariableTable.
ASSERT_THAT_EXPECTED(Tester.parseSubst("UNDEF"), Succeeded());
EXPECT_TRUE(Tester.parsePattern("[[UNDEF:.*]]"));
// Invalid literal.
expectDiagnosticError("unsupported operation 'U'",
Tester.parseSubst("42U").takeError());
// Valid empty expression.
EXPECT_THAT_EXPECTED(Tester.parseSubst(""), Succeeded());
// Invalid equality matching constraint with empty expression.
expectDiagnosticError("empty numeric expression should not have a constraint",
Tester.parseSubst("==").takeError());
// Valid single operand expression.
EXPECT_THAT_EXPECTED(Tester.parseSubst("FOO"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("18"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst(std::to_string(MaxUint64)),
Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("0x12"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("-30"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst(std::to_string(MinInt64)),
Succeeded());
// Valid optional matching constraint.
EXPECT_THAT_EXPECTED(Tester.parseSubst("==FOO"), Succeeded());
// Invalid matching constraint.
expectDiagnosticError("invalid matching constraint or operand format",
Tester.parseSubst("+=FOO").takeError());
// Invalid format.
expectDiagnosticError("invalid matching format specification in expression",
Tester.parseSubst("X,FOO:").takeError());
expectDiagnosticError("invalid format specifier in expression",
Tester.parseSubst("%F,FOO").takeError());
expectDiagnosticError("invalid matching format specification in expression",
Tester.parseSubst("%X a,FOO").takeError());
// Valid expression with 2 or more operands.
EXPECT_THAT_EXPECTED(Tester.parseSubst("FOO+3"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("FOO+0xC"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("FOO-3+FOO"), Succeeded());
expectDiagnosticError("unsupported operation '/'",
Tester.parseSubst("@LINE/2").takeError());
expectDiagnosticError("missing operand in expression",
Tester.parseSubst("@LINE+").takeError());
// Errors in RHS operand are bubbled up by parseBinop() to
// parseNumericSubstitutionBlock().
expectDiagnosticError("invalid operand format",
Tester.parseSubst("@LINE+%VAR").takeError());
// Invalid legacy @LINE expression with non literal rhs.
expectDiagnosticError(
"invalid operand format",
Tester.parseSubst("@LINE+@LINE", /*IsLegacyNumExpr=*/true).takeError());
// Invalid legacy @LINE expression made of a single literal.
expectDiagnosticError(
"invalid variable name",
Tester.parseSubst("2", /*IsLegacyNumExpr=*/true).takeError());
// Invalid hex literal in legacy @LINE expression.
expectDiagnosticError(
"unexpected characters at end of expression 'xC'",
Tester.parseSubst("@LINE+0xC", /*LegacyLineExpr=*/true).takeError());
// Valid expression with format specifier.
EXPECT_THAT_EXPECTED(Tester.parseSubst("%u, FOO"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("%d, FOO"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("%x, FOO"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("%X, FOO"), Succeeded());
// Valid expression with precision specifier.
EXPECT_THAT_EXPECTED(Tester.parseSubst("%.8u, FOO"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("%.8, FOO"), Succeeded());
// Valid legacy @LINE expression.
EXPECT_THAT_EXPECTED(Tester.parseSubst("@LINE+2", /*IsLegacyNumExpr=*/true),
Succeeded());
// Invalid legacy @LINE expression with more than 2 operands.
expectDiagnosticError(
"unexpected characters at end of expression '+@LINE'",
Tester.parseSubst("@LINE+2+@LINE", /*IsLegacyNumExpr=*/true).takeError());
expectDiagnosticError(
"unexpected characters at end of expression '+2'",
Tester.parseSubst("@LINE+2+2", /*IsLegacyNumExpr=*/true).takeError());
// Valid expression with several variables when their implicit formats do not
// conflict.
EXPECT_THAT_EXPECTED(Tester.parseSubst("FOO+VAR_UNSIGNED"), Succeeded());
// Valid implicit format conflict in presence of explicit formats.
EXPECT_THAT_EXPECTED(Tester.parseSubst("%X,FOO+VAR_LOWER_HEX"), Succeeded());
// Implicit format conflict.
expectDiagnosticError(
"implicit format conflict between 'FOO' (%u) and "
"'VAR_LOWER_HEX' (%x), need an explicit format specifier",
Tester.parseSubst("FOO+VAR_LOWER_HEX").takeError());
// Simple parenthesized expressions:
EXPECT_THAT_EXPECTED(Tester.parseSubst("(1)"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("(1+1)"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("(1)+1"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("((1)+1)"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("((1)+X)"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("((X)+Y)"), Succeeded());
expectDiagnosticError("missing operand in expression",
Tester.parseSubst("(").takeError());
expectDiagnosticError("missing ')' at end of nested expression",
Tester.parseSubst("(1").takeError());
expectDiagnosticError("missing operand in expression",
Tester.parseSubst("(1+").takeError());
expectDiagnosticError("missing ')' at end of nested expression",
Tester.parseSubst("(1+1").takeError());
expectDiagnosticError("missing ')' at end of nested expression",
Tester.parseSubst("((1+2+3").takeError());
expectDiagnosticError("missing ')' at end of nested expression",
Tester.parseSubst("((1+2)+3").takeError());
// Test missing operation between operands:
expectDiagnosticError("unsupported operation '('",
Tester.parseSubst("(1)(2)").takeError());
expectDiagnosticError("unsupported operation '('",
Tester.parseSubst("2(X)").takeError());
// Test more closing than opening parentheses. The diagnostic messages are
// not ideal, but for now simply check that we reject invalid input.
expectDiagnosticError("invalid matching constraint or operand format",
Tester.parseSubst(")").takeError());
expectDiagnosticError("unsupported operation ')'",
Tester.parseSubst("1)").takeError());
expectDiagnosticError("unsupported operation ')'",
Tester.parseSubst("(1+2))").takeError());
expectDiagnosticError("unsupported operation ')'",
Tester.parseSubst("(2))").takeError());
expectDiagnosticError("unsupported operation ')'",
Tester.parseSubst("(1))(").takeError());
// Valid expression with function call.
EXPECT_THAT_EXPECTED(Tester.parseSubst("add(FOO,3)"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("add (FOO,3)"), Succeeded());
// Valid expression with nested function call.
EXPECT_THAT_EXPECTED(Tester.parseSubst("add(FOO, min(BAR,10))"), Succeeded());
// Valid expression with function call taking expression as argument.
EXPECT_THAT_EXPECTED(Tester.parseSubst("add(FOO, (BAR+10) + 3)"),
Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("add(FOO, min (BAR,10) + 3)"),
Succeeded());
// Valid expression with variable named the same as a function.
EXPECT_THAT_EXPECTED(Tester.parseSubst("add"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("add+FOO"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("FOO+add"), Succeeded());
EXPECT_THAT_EXPECTED(Tester.parseSubst("add(add,add)+add"), Succeeded());
// Malformed call syntax.
expectDiagnosticError("missing ')' at end of call expression",
Tester.parseSubst("add(FOO,(BAR+7)").takeError());
expectDiagnosticError("missing ')' at end of call expression",
Tester.parseSubst("add(FOO,min(BAR,7)").takeError());
expectDiagnosticError("missing argument",
Tester.parseSubst("add(FOO,)").takeError());
expectDiagnosticError("missing argument",
Tester.parseSubst("add(,FOO)").takeError());
expectDiagnosticError("missing argument",
Tester.parseSubst("add(FOO,,3)").takeError());
// Valid call, but to an unknown function.
expectDiagnosticError("call to undefined function 'bogus_function'",
Tester.parseSubst("bogus_function(FOO,3)").takeError());
expectDiagnosticError("call to undefined function '@add'",
Tester.parseSubst("@add(2,3)").takeError());
expectDiagnosticError("call to undefined function '$add'",
Tester.parseSubst("$add(2,3)").takeError());
expectDiagnosticError("call to undefined function 'FOO'",
Tester.parseSubst("FOO(2,3)").takeError());
expectDiagnosticError("call to undefined function 'FOO'",
Tester.parseSubst("FOO (2,3)").takeError());
// Valid call, but with incorrect argument count.
expectDiagnosticError("function 'add' takes 2 arguments but 1 given",
Tester.parseSubst("add(FOO)").takeError());
expectDiagnosticError("function 'add' takes 2 arguments but 3 given",
Tester.parseSubst("add(FOO,3,4)").takeError());
// Valid call, but not part of a valid expression.
expectDiagnosticError("unsupported operation 'a'",
Tester.parseSubst("2add(FOO,2)").takeError());
expectDiagnosticError("unsupported operation 'a'",
Tester.parseSubst("FOO add(FOO,2)").takeError());
expectDiagnosticError("unsupported operation 'a'",
Tester.parseSubst("add(FOO,2)add(FOO,2)").takeError());
}
TEST_F(FileCheckTest, ParsePattern) {
PatternTester Tester;
// Invalid space in string substitution.
EXPECT_TRUE(Tester.parsePattern("[[ BAR]]"));
// Invalid variable name in string substitution.
EXPECT_TRUE(Tester.parsePattern("[[42INVALID]]"));
// Invalid string variable definition.
EXPECT_TRUE(Tester.parsePattern("[[@PAT:]]"));
EXPECT_TRUE(Tester.parsePattern("[[PAT+2:]]"));
// Collision with numeric variable.
EXPECT_TRUE(Tester.parsePattern("[[FOO:]]"));
// Invalid use of string variable.
EXPECT_TRUE(Tester.parsePattern("[[FOO-BAR]]"));
// Valid use of string variable.
EXPECT_FALSE(Tester.parsePattern("[[BAR]]"));
// Valid string variable definition.
EXPECT_FALSE(Tester.parsePattern("[[PAT:[0-9]+]]"));
// Invalid numeric substitution.
EXPECT_TRUE(Tester.parsePattern("[[#42INVALID]]"));
// Valid numeric substitution.
EXPECT_FALSE(Tester.parsePattern("[[#FOO]]"));
// Valid legacy @LINE expression.
EXPECT_FALSE(Tester.parsePattern("[[@LINE+2]]"));
// Invalid legacy @LINE expression with non decimal literal.
EXPECT_TRUE(Tester.parsePattern("[[@LINE+0x3]]"));
}
TEST_F(FileCheckTest, Match) {
PatternTester Tester;
// Check a substitution error is diagnosed.
ASSERT_FALSE(Tester.parsePattern("[[#%u, -1]]"));
expectDiagnosticError(
"unable to substitute variable or numeric expression: overflow error",
Tester.match("").takeError());
// Check matching an empty expression only matches a number.
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#]]"));
expectNotFoundError(Tester.match("FAIL").takeError());
EXPECT_THAT_EXPECTED(Tester.match("18"), Succeeded());
// Check matching a definition only matches a number with the right format.
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#NUMVAR:]]"));
expectNotFoundError(Tester.match("FAIL").takeError());
expectNotFoundError(Tester.match("").takeError());
EXPECT_THAT_EXPECTED(Tester.match("18"), Succeeded());
Tester.initNextPattern();
Tester.parsePattern("[[#%u,NUMVAR_UNSIGNED:]]");
expectNotFoundError(Tester.match("C").takeError());
EXPECT_THAT_EXPECTED(Tester.match("20"), Succeeded());
Tester.initNextPattern();
Tester.parsePattern("[[#%x,NUMVAR_LOWER_HEX:]]");
expectNotFoundError(Tester.match("g").takeError());
expectNotFoundError(Tester.match("C").takeError());
EXPECT_THAT_EXPECTED(Tester.match("c"), Succeeded());
Tester.initNextPattern();
Tester.parsePattern("[[#%X,NUMVAR_UPPER_HEX:]]");
expectNotFoundError(Tester.match("H").takeError());
expectNotFoundError(Tester.match("b").takeError());
EXPECT_THAT_EXPECTED(Tester.match("B"), Succeeded());
// Check matching expressions with no explicit format matches the values in
// the right format.
Tester.initNextPattern();
Tester.parsePattern("[[#NUMVAR_UNSIGNED-5]]");
expectNotFoundError(Tester.match("f").takeError());
expectNotFoundError(Tester.match("F").takeError());
EXPECT_THAT_EXPECTED(Tester.match("15"), Succeeded());
Tester.initNextPattern();
Tester.parsePattern("[[#NUMVAR_LOWER_HEX+1]]");
expectNotFoundError(Tester.match("13").takeError());
expectNotFoundError(Tester.match("D").takeError());
EXPECT_THAT_EXPECTED(Tester.match("d"), Succeeded());
Tester.initNextPattern();
Tester.parsePattern("[[#NUMVAR_UPPER_HEX+1]]");
expectNotFoundError(Tester.match("12").takeError());
expectNotFoundError(Tester.match("c").takeError());
EXPECT_THAT_EXPECTED(Tester.match("C"), Succeeded());
// Check matching an undefined variable returns a NotFound error.
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("100"));
expectNotFoundError(Tester.match("101").takeError());
// Check matching the defined variable matches the correct number only.
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#NUMVAR]]"));
EXPECT_THAT_EXPECTED(Tester.match("18"), Succeeded());
// Check matching several substitutions does not match them independently.
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#NUMVAR]] [[#NUMVAR+2]]"));
expectNotFoundError(Tester.match("19 21").takeError());
expectNotFoundError(Tester.match("18 21").takeError());
EXPECT_THAT_EXPECTED(Tester.match("18 20"), Succeeded());
// Check matching a numeric expression using @LINE after a match failure uses
// the correct value for @LINE.
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#@LINE]]"));
// Ok, @LINE matches the current line number.
EXPECT_THAT_EXPECTED(Tester.match(std::to_string(Tester.getLineNumber())),
Succeeded());
Tester.initNextPattern();
// Match with substitution failure.
ASSERT_FALSE(Tester.parsePattern("[[#UNKNOWN1+UNKNOWN2]]"));
expectSameErrors<ErrorDiagnostic>(
{"undefined variable: UNKNOWN1", "undefined variable: UNKNOWN2"},
Tester.match("FOO").takeError());
Tester.initNextPattern();
// Check that @LINE matches the later (given the calls to initNextPattern())
// line number.
EXPECT_FALSE(Tester.parsePattern("[[#@LINE]]"));
EXPECT_THAT_EXPECTED(Tester.match(std::to_string(Tester.getLineNumber())),
Succeeded());
}
TEST_F(FileCheckTest, MatchParen) {
PatternTester Tester;
// Check simple parenthesized expressions
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#NUMVAR:]]"));
expectNotFoundError(Tester.match("FAIL").takeError());
expectNotFoundError(Tester.match("").takeError());
EXPECT_THAT_EXPECTED(Tester.match("18"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#NUMVAR + (2 + 2)]]"));
expectNotFoundError(Tester.match("21").takeError());
EXPECT_THAT_EXPECTED(Tester.match("22"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#NUMVAR + (2)]]"));
EXPECT_THAT_EXPECTED(Tester.match("20"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#NUMVAR+(2)]]"));
EXPECT_THAT_EXPECTED(Tester.match("20"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#NUMVAR+(NUMVAR)]]"));
EXPECT_THAT_EXPECTED(Tester.match("36"), Succeeded());
// Check nested parenthesized expressions:
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#NUMVAR+(2+(2))]]"));
EXPECT_THAT_EXPECTED(Tester.match("22"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#NUMVAR+(2+(NUMVAR))]]"));
EXPECT_THAT_EXPECTED(Tester.match("38"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#NUMVAR+((((NUMVAR))))]]"));
EXPECT_THAT_EXPECTED(Tester.match("36"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#NUMVAR+((((NUMVAR)))-1)-1]]"));
EXPECT_THAT_EXPECTED(Tester.match("34"), Succeeded());
// Parentheses can also be the first character after the '#':
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#(NUMVAR)]]"));
EXPECT_THAT_EXPECTED(Tester.match("18"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#(NUMVAR+2)]]"));
EXPECT_THAT_EXPECTED(Tester.match("20"), Succeeded());
}
TEST_F(FileCheckTest, MatchBuiltinFunctions) {
PatternTester Tester;
// Esnure #NUMVAR has the expected value.
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#NUMVAR:]]"));
expectNotFoundError(Tester.match("FAIL").takeError());
expectNotFoundError(Tester.match("").takeError());
EXPECT_THAT_EXPECTED(Tester.match("18"), Succeeded());
// Check each builtin function generates the expected result.
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#add(NUMVAR,13)]]"));
EXPECT_THAT_EXPECTED(Tester.match("31"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#div(NUMVAR,3)]]"));
EXPECT_THAT_EXPECTED(Tester.match("6"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#max(NUMVAR,5)]]"));
EXPECT_THAT_EXPECTED(Tester.match("18"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#max(NUMVAR,99)]]"));
EXPECT_THAT_EXPECTED(Tester.match("99"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#min(NUMVAR,5)]]"));
EXPECT_THAT_EXPECTED(Tester.match("5"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#min(NUMVAR,99)]]"));
EXPECT_THAT_EXPECTED(Tester.match("18"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#mul(NUMVAR,3)]]"));
EXPECT_THAT_EXPECTED(Tester.match("54"), Succeeded());
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#sub(NUMVAR,7)]]"));
EXPECT_THAT_EXPECTED(Tester.match("11"), Succeeded());
// Check nested function calls.
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#add(min(7,2),max(4,10))]]"));
EXPECT_THAT_EXPECTED(Tester.match("12"), Succeeded());
// Check function call that uses a variable of the same name.
Tester.initNextPattern();
ASSERT_FALSE(Tester.parsePattern("[[#add(add,add)+min (add,3)+add]]"));
EXPECT_THAT_EXPECTED(Tester.match("24"), Succeeded());
}
TEST_F(FileCheckTest, Substitution) {
SourceMgr SM;
FileCheckPatternContext Context;
EXPECT_THAT_ERROR(Context.defineCmdlineVariables({"FOO=BAR"}, SM),
Succeeded());
// Substitution of an undefined string variable fails and error holds that
// variable's name.
StringSubstitution StringSubstitution(&Context, "VAR404", 42);
Expected<std::string> SubstValue = StringSubstitution.getResult();
expectUndefErrors({"VAR404"}, SubstValue.takeError());
// Numeric substitution blocks constituted of defined numeric variables are
// substituted for the variable's value.
NumericVariable NVar("N", ExpressionFormat(ExpressionFormat::Kind::Unsigned),
1);
NVar.setValue(ExpressionValue(10u));
auto NVarUse = std::make_unique<NumericVariableUse>("N", &NVar);
auto ExpressionN = std::make_unique<Expression>(
std::move(NVarUse), ExpressionFormat(ExpressionFormat::Kind::HexUpper));
NumericSubstitution SubstitutionN(&Context, "N", std::move(ExpressionN),
/*InsertIdx=*/30);
SubstValue = SubstitutionN.getResult();
ASSERT_THAT_EXPECTED(SubstValue, Succeeded());
EXPECT_EQ("A", *SubstValue);
// Substitution of an undefined numeric variable fails, error holds name of
// undefined variable.
NVar.clearValue();
SubstValue = SubstitutionN.getResult();
expectUndefErrors({"N"}, SubstValue.takeError());
// Substitution of a defined string variable returns the right value.
Pattern P(Check::CheckPlain, &Context, 1);
StringSubstitution = llvm::StringSubstitution(&Context, "FOO", 42);
SubstValue = StringSubstitution.getResult();
ASSERT_THAT_EXPECTED(SubstValue, Succeeded());
EXPECT_EQ("BAR", *SubstValue);
}
TEST_F(FileCheckTest, FileCheckContext) {
FileCheckPatternContext Cxt;
SourceMgr SM;
// No definition.
EXPECT_THAT_ERROR(Cxt.defineCmdlineVariables({}, SM), Succeeded());
// Missing equal sign.
expectDiagnosticError("missing equal sign in global definition",
Cxt.defineCmdlineVariables({"LocalVar"}, SM));
expectDiagnosticError("missing equal sign in global definition",
Cxt.defineCmdlineVariables({"#LocalNumVar"}, SM));
// Empty variable name.
expectDiagnosticError("empty variable name",
Cxt.defineCmdlineVariables({"=18"}, SM));
expectDiagnosticError("empty variable name",
Cxt.defineCmdlineVariables({"#=18"}, SM));
// Invalid variable name.
expectDiagnosticError("invalid variable name",
Cxt.defineCmdlineVariables({"18LocalVar=18"}, SM));
expectDiagnosticError("invalid variable name",
Cxt.defineCmdlineVariables({"#18LocalNumVar=18"}, SM));
// Name conflict between pattern and numeric variable.
expectDiagnosticError(
"string variable with name 'LocalVar' already exists",
Cxt.defineCmdlineVariables({"LocalVar=18", "#LocalVar=36"}, SM));
Cxt = FileCheckPatternContext();
expectDiagnosticError(
"numeric variable with name 'LocalNumVar' already exists",
Cxt.defineCmdlineVariables({"#LocalNumVar=18", "LocalNumVar=36"}, SM));
Cxt = FileCheckPatternContext();
// Invalid numeric value for numeric variable.
expectUndefErrors({"x"}, Cxt.defineCmdlineVariables({"#LocalNumVar=x"}, SM));
// Define local variables from command-line.
std::vector<StringRef> GlobalDefines;
// Clear local variables to remove dummy numeric variable x that
// parseNumericSubstitutionBlock would have created and stored in
// GlobalNumericVariableTable.
Cxt.clearLocalVars();
GlobalDefines.emplace_back("LocalVar=FOO");
GlobalDefines.emplace_back("EmptyVar=");
GlobalDefines.emplace_back("#LocalNumVar1=18");
GlobalDefines.emplace_back("#%x,LocalNumVar2=LocalNumVar1+2");
GlobalDefines.emplace_back("#LocalNumVar3=0xc");
ASSERT_THAT_ERROR(Cxt.defineCmdlineVariables(GlobalDefines, SM), Succeeded());
// Create @LINE pseudo numeric variable and check it is present by matching
// it.
size_t LineNumber = 1;
Pattern P(Check::CheckPlain, &Cxt, LineNumber);
FileCheckRequest Req;
Cxt.createLineVariable();
ASSERT_FALSE(P.parsePattern("[[@LINE]]", "CHECK", SM, Req));
Pattern::MatchResult Res = P.match("1", SM);
ASSERT_THAT_ERROR(std::move(Res.TheError), Succeeded());
#ifndef NDEBUG
// Recreating @LINE pseudo numeric variable fails.
EXPECT_DEATH(Cxt.createLineVariable(),
"@LINE pseudo numeric variable already created");
#endif
// Check defined variables are present and undefined ones are absent.
StringRef LocalVarStr = "LocalVar";
StringRef LocalNumVar1Ref = bufferize(SM, "LocalNumVar1");
StringRef LocalNumVar2Ref = bufferize(SM, "LocalNumVar2");
StringRef LocalNumVar3Ref = bufferize(SM, "LocalNumVar3");
StringRef EmptyVarStr = "EmptyVar";
StringRef UnknownVarStr = "UnknownVar";
Expected<StringRef> LocalVar = Cxt.getPatternVarValue(LocalVarStr);
P = Pattern(Check::CheckPlain, &Cxt, ++LineNumber);
Optional<NumericVariable *> DefinedNumericVariable;
Expected<std::unique_ptr<Expression>> ExpressionPointer =
P.parseNumericSubstitutionBlock(LocalNumVar1Ref, DefinedNumericVariable,
/*IsLegacyLineExpr=*/false, LineNumber,
&Cxt, SM);
ASSERT_THAT_EXPECTED(LocalVar, Succeeded());
EXPECT_EQ(*LocalVar, "FOO");
Expected<StringRef> EmptyVar = Cxt.getPatternVarValue(EmptyVarStr);
Expected<StringRef> UnknownVar = Cxt.getPatternVarValue(UnknownVarStr);
ASSERT_THAT_EXPECTED(ExpressionPointer, Succeeded());
Expected<ExpressionValue> ExpressionVal =
(*ExpressionPointer)->getAST()->eval();
ASSERT_THAT_EXPECTED(ExpressionVal, Succeeded());
EXPECT_EQ(cantFail(ExpressionVal->getSignedValue()), 18);
ExpressionPointer = P.parseNumericSubstitutionBlock(
LocalNumVar2Ref, DefinedNumericVariable,
/*IsLegacyLineExpr=*/false, LineNumber, &Cxt, SM);
ASSERT_THAT_EXPECTED(ExpressionPointer, Succeeded());
ExpressionVal = (*ExpressionPointer)->getAST()->eval();
ASSERT_THAT_EXPECTED(ExpressionVal, Succeeded());
EXPECT_EQ(cantFail(ExpressionVal->getSignedValue()), 20);
ExpressionPointer = P.parseNumericSubstitutionBlock(
LocalNumVar3Ref, DefinedNumericVariable,
/*IsLegacyLineExpr=*/false, LineNumber, &Cxt, SM);
ASSERT_THAT_EXPECTED(ExpressionPointer, Succeeded());
ExpressionVal = (*ExpressionPointer)->getAST()->eval();
ASSERT_THAT_EXPECTED(ExpressionVal, Succeeded());
EXPECT_EQ(cantFail(ExpressionVal->getSignedValue()), 12);
ASSERT_THAT_EXPECTED(EmptyVar, Succeeded());
EXPECT_EQ(*EmptyVar, "");
expectUndefErrors({std::string(UnknownVarStr)}, UnknownVar.takeError());
// Clear local variables and check they become absent.
Cxt.clearLocalVars();
LocalVar = Cxt.getPatternVarValue(LocalVarStr);
expectUndefErrors({std::string(LocalVarStr)}, LocalVar.takeError());
// Check a numeric expression's evaluation fails if called after clearing of
// local variables, if it was created before. This is important because local
// variable clearing due to --enable-var-scope happens after numeric
// expressions are linked to the numeric variables they use.
expectUndefErrors({"LocalNumVar3"},
(*ExpressionPointer)->getAST()->eval().takeError());
P = Pattern(Check::CheckPlain, &Cxt, ++LineNumber);
ExpressionPointer = P.parseNumericSubstitutionBlock(
LocalNumVar1Ref, DefinedNumericVariable, /*IsLegacyLineExpr=*/false,
LineNumber, &Cxt, SM);
ASSERT_THAT_EXPECTED(ExpressionPointer, Succeeded());
ExpressionVal = (*ExpressionPointer)->getAST()->eval();
expectUndefErrors({"LocalNumVar1"}, ExpressionVal.takeError());
ExpressionPointer = P.parseNumericSubstitutionBlock(
LocalNumVar2Ref, DefinedNumericVariable, /*IsLegacyLineExpr=*/false,
LineNumber, &Cxt, SM);
ASSERT_THAT_EXPECTED(ExpressionPointer, Succeeded());
ExpressionVal = (*ExpressionPointer)->getAST()->eval();
expectUndefErrors({"LocalNumVar2"}, ExpressionVal.takeError());
EmptyVar = Cxt.getPatternVarValue(EmptyVarStr);
expectUndefErrors({"EmptyVar"}, EmptyVar.takeError());
// Clear again because parseNumericSubstitutionBlock would have created a
// dummy variable and stored it in GlobalNumericVariableTable.
Cxt.clearLocalVars();
// Redefine global variables and check variables are defined again.
GlobalDefines.emplace_back("$GlobalVar=BAR");
GlobalDefines.emplace_back("#$GlobalNumVar=36");
ASSERT_THAT_ERROR(Cxt.defineCmdlineVariables(GlobalDefines, SM), Succeeded());
StringRef GlobalVarStr = "$GlobalVar";
StringRef GlobalNumVarRef = bufferize(SM, "$GlobalNumVar");
Expected<StringRef> GlobalVar = Cxt.getPatternVarValue(GlobalVarStr);
ASSERT_THAT_EXPECTED(GlobalVar, Succeeded());
EXPECT_EQ(*GlobalVar, "BAR");
P = Pattern(Check::CheckPlain, &Cxt, ++LineNumber);
ExpressionPointer = P.parseNumericSubstitutionBlock(
GlobalNumVarRef, DefinedNumericVariable, /*IsLegacyLineExpr=*/false,
LineNumber, &Cxt, SM);
ASSERT_THAT_EXPECTED(ExpressionPointer, Succeeded());
ExpressionVal = (*ExpressionPointer)->getAST()->eval();
ASSERT_THAT_EXPECTED(ExpressionVal, Succeeded());
EXPECT_EQ(cantFail(ExpressionVal->getSignedValue()), 36);
// Clear local variables and check global variables remain defined.
Cxt.clearLocalVars();
EXPECT_THAT_EXPECTED(Cxt.getPatternVarValue(GlobalVarStr), Succeeded());
P = Pattern(Check::CheckPlain, &Cxt, ++LineNumber);
ExpressionPointer = P.parseNumericSubstitutionBlock(
GlobalNumVarRef, DefinedNumericVariable, /*IsLegacyLineExpr=*/false,
LineNumber, &Cxt, SM);
ASSERT_THAT_EXPECTED(ExpressionPointer, Succeeded());
ExpressionVal = (*ExpressionPointer)->getAST()->eval();
ASSERT_THAT_EXPECTED(ExpressionVal, Succeeded());
EXPECT_EQ(cantFail(ExpressionVal->getSignedValue()), 36);
}
TEST_F(FileCheckTest, CapturedVarDiags) {
PatternTester Tester;
ASSERT_FALSE(Tester.parsePattern("[[STRVAR:[a-z]+]] [[#NUMVAR:@LINE]]"));
EXPECT_THAT_EXPECTED(Tester.match("foobar 2"), Succeeded());
std::vector<FileCheckDiag> Diags;
Tester.printVariableDefs(FileCheckDiag::MatchFoundAndExpected, Diags);
EXPECT_EQ(Diags.size(), 2ul);
for (FileCheckDiag Diag : Diags) {
EXPECT_EQ(Diag.CheckTy, Check::CheckPlain);
EXPECT_EQ(Diag.MatchTy, FileCheckDiag::MatchFoundAndExpected);
EXPECT_EQ(Diag.InputStartLine, 1u);
EXPECT_EQ(Diag.InputEndLine, 1u);
}
EXPECT_EQ(Diags[0].InputStartCol, 1u);
EXPECT_EQ(Diags[0].InputEndCol, 7u);
EXPECT_EQ(Diags[1].InputStartCol, 8u);
EXPECT_EQ(Diags[1].InputEndCol, 9u);
EXPECT_EQ(Diags[0].Note, "captured var \"STRVAR\"");
EXPECT_EQ(Diags[1].Note, "captured var \"NUMVAR\"");
}
} // namespace