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// Copyright 2020 The Pigweed Authors
//
// Licensed under the Apache License, Version 2.0 (the "License"); you may not
// use this file except in compliance with the License. You may obtain a copy of
// the License at
//
// https://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
// WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
// License for the specific language governing permissions and limitations under
// the License.
// This test directly verifies the facade logic, by leveraging a fake backend
// that captures arguments and returns rather than aborting execution.
#include "pw_assert_test/fake_backend.h"
// This directly includes the assert facade implementation header rather than
// going through the backend header indirection mechanism, to prevent the real
// assert backend from triggering.
//
// clang-format off
#include "pw_assert/internal/check_impl.h"
// clang-format on
#include "gtest/gtest.h"
#include "pw_status/status.h"
namespace {
#define EXPECT_MESSAGE(expected_assert_message) \
do { \
EXPECT_STREQ(pw_captured_assert.message, expected_assert_message); \
} while (0)
class AssertFail : public ::testing::Test {
protected:
void SetUp() override { pw_captured_assert.triggered = 0; }
void TearDown() override { EXPECT_EQ(pw_captured_assert.triggered, 1); }
};
class AssertPass : public ::testing::Test {
protected:
void SetUp() override { pw_captured_assert.triggered = 0; }
void TearDown() override { EXPECT_EQ(pw_captured_assert.triggered, 0); }
};
// PW_CRASH(...)
TEST_F(AssertFail, CrashMessageNoArguments) {
PW_CRASH("Goodbye");
EXPECT_MESSAGE("Goodbye");
}
TEST_F(AssertFail, CrashMessageWithArguments) {
PW_CRASH("Goodbye cruel %s", "world");
EXPECT_MESSAGE("Goodbye cruel world");
}
// PW_CHECK(...) - No message
TEST_F(AssertPass, CheckNoMessage) { PW_CHECK(true); }
TEST_F(AssertFail, CheckNoMessage) {
PW_CHECK(false);
EXPECT_MESSAGE("Check failed: false. ");
}
TEST_F(AssertPass, CheckNoMessageComplexExpression) { PW_CHECK(2 == 2); }
TEST_F(AssertFail, CheckNoMessageComplexExpression) {
PW_CHECK(1 == 2);
EXPECT_MESSAGE("Check failed: 1 == 2. ");
}
// PW_CHECK(..., msg) - With message; with and without arguments.
TEST_F(AssertPass, CheckMessageNoArguments) { PW_CHECK(true, "Hello"); }
TEST_F(AssertFail, CheckMessageNoArguments) {
PW_CHECK(false, "Hello");
EXPECT_MESSAGE("Check failed: false. Hello");
}
TEST_F(AssertPass, CheckMessageWithArguments) { PW_CHECK(true, "Hello %d", 5); }
TEST_F(AssertFail, CheckMessageWithArguments) {
PW_CHECK(false, "Hello %d", 5);
EXPECT_MESSAGE("Check failed: false. Hello 5");
}
// PW_CHECK_INT_*(...)
// Binary checks with ints, comparisons: <, <=, =, !=, >, >=.
// Test message formatting separate from the triggering.
// Only test formatting for the type once.
TEST_F(AssertFail, IntLessThanNoMessageNoArguments) {
PW_CHECK_INT_LT(5, -2);
EXPECT_MESSAGE("Check failed: 5 (=5) < -2 (=-2). ");
}
TEST_F(AssertFail, IntLessThanMessageNoArguments) {
PW_CHECK_INT_LT(5, -2, "msg");
EXPECT_MESSAGE("Check failed: 5 (=5) < -2 (=-2). msg");
}
TEST_F(AssertFail, IntLessThanMessageArguments) {
PW_CHECK_INT_LT(5, -2, "msg: %d", 6);
EXPECT_MESSAGE("Check failed: 5 (=5) < -2 (=-2). msg: 6");
}
// Test comparison boundaries.
// INT <
TEST_F(AssertPass, IntLt1) { PW_CHECK_INT_LT(-1, 2); }
TEST_F(AssertPass, IntLt2) { PW_CHECK_INT_LT(1, 2); }
TEST_F(AssertFail, IntLt3) { PW_CHECK_INT_LT(-1, -2); }
TEST_F(AssertFail, IntLt4) { PW_CHECK_INT_LT(1, 1); }
// INT <=
TEST_F(AssertPass, IntLe1) { PW_CHECK_INT_LE(-1, 2); }
TEST_F(AssertPass, IntLe2) { PW_CHECK_INT_LE(1, 2); }
TEST_F(AssertFail, IntLe3) { PW_CHECK_INT_LE(-1, -2); }
TEST_F(AssertPass, IntLe4) { PW_CHECK_INT_LE(1, 1); }
// INT ==
TEST_F(AssertFail, IntEq1) { PW_CHECK_INT_EQ(-1, 2); }
TEST_F(AssertFail, IntEq2) { PW_CHECK_INT_EQ(1, 2); }
TEST_F(AssertFail, IntEq3) { PW_CHECK_INT_EQ(-1, -2); }
TEST_F(AssertPass, IntEq4) { PW_CHECK_INT_EQ(1, 1); }
// INT !=
TEST_F(AssertPass, IntNe1) { PW_CHECK_INT_NE(-1, 2); }
TEST_F(AssertPass, IntNe2) { PW_CHECK_INT_NE(1, 2); }
TEST_F(AssertPass, IntNe3) { PW_CHECK_INT_NE(-1, -2); }
TEST_F(AssertFail, IntNe4) { PW_CHECK_INT_NE(1, 1); }
// INT >
TEST_F(AssertFail, IntGt1) { PW_CHECK_INT_GT(-1, 2); }
TEST_F(AssertFail, IntGt2) { PW_CHECK_INT_GT(1, 2); }
TEST_F(AssertPass, IntGt3) { PW_CHECK_INT_GT(-1, -2); }
TEST_F(AssertFail, IntGt4) { PW_CHECK_INT_GT(1, 1); }
// INT >=
TEST_F(AssertFail, IntGe1) { PW_CHECK_INT_GE(-1, 2); }
TEST_F(AssertFail, IntGe2) { PW_CHECK_INT_GE(1, 2); }
TEST_F(AssertPass, IntGe3) { PW_CHECK_INT_GE(-1, -2); }
TEST_F(AssertPass, IntGe4) { PW_CHECK_INT_GE(1, 1); }
// PW_CHECK_UINT_*(...)
// Binary checks with uints, comparisons: <, <=, =, !=, >, >=.
// Test message formatting separate from the triggering.
// Only test formatting for the type once.
TEST_F(AssertFail, UintLessThanNoMessageNoArguments) {
PW_CHECK_UINT_LT(5, 2);
EXPECT_MESSAGE("Check failed: 5 (=5) < 2 (=2). ");
}
TEST_F(AssertFail, UintLessThanMessageNoArguments) {
PW_CHECK_UINT_LT(5, 2, "msg");
EXPECT_MESSAGE("Check failed: 5 (=5) < 2 (=2). msg");
}
TEST_F(AssertFail, UintLessThanMessageArguments) {
PW_CHECK_UINT_LT(5, 2, "msg: %d", 6);
EXPECT_MESSAGE("Check failed: 5 (=5) < 2 (=2). msg: 6");
}
// Test comparison boundaries.
// UINT <
TEST_F(AssertPass, UintLt1) { PW_CHECK_UINT_LT(1, 2); }
TEST_F(AssertFail, UintLt2) { PW_CHECK_UINT_LT(2, 2); }
TEST_F(AssertFail, UintLt3) { PW_CHECK_UINT_LT(2, 1); }
// UINT <=
TEST_F(AssertPass, UintLe1) { PW_CHECK_UINT_LE(1, 2); }
TEST_F(AssertPass, UintLe2) { PW_CHECK_UINT_LE(2, 2); }
TEST_F(AssertFail, UintLe3) { PW_CHECK_UINT_LE(2, 1); }
// UINT ==
TEST_F(AssertFail, UintEq1) { PW_CHECK_UINT_EQ(1, 2); }
TEST_F(AssertPass, UintEq2) { PW_CHECK_UINT_EQ(2, 2); }
TEST_F(AssertFail, UintEq3) { PW_CHECK_UINT_EQ(2, 1); }
// UINT !=
TEST_F(AssertPass, UintNe1) { PW_CHECK_UINT_NE(1, 2); }
TEST_F(AssertFail, UintNe2) { PW_CHECK_UINT_NE(2, 2); }
TEST_F(AssertPass, UintNe3) { PW_CHECK_UINT_NE(2, 1); }
// UINT >
TEST_F(AssertFail, UintGt1) { PW_CHECK_UINT_GT(1, 2); }
TEST_F(AssertFail, UintGt2) { PW_CHECK_UINT_GT(2, 2); }
TEST_F(AssertPass, UintGt3) { PW_CHECK_UINT_GT(2, 1); }
// UINT >=
TEST_F(AssertFail, UintGe1) { PW_CHECK_UINT_GE(1, 2); }
TEST_F(AssertPass, UintGe2) { PW_CHECK_UINT_GE(2, 2); }
TEST_F(AssertPass, UintGe3) { PW_CHECK_UINT_GE(2, 1); }
// PW_CHECK_PTR_*(...)
// Binary checks with uints, comparisons: <, <=, =, !=, >, >=.
// Note: The format checks are skipped since they're not portable.
// Test comparison boundaries.
// PTR <
TEST_F(AssertPass, PtrLt1) {
PW_CHECK_PTR_LT(reinterpret_cast<void*>(0xa), reinterpret_cast<void*>(0xb));
}
TEST_F(AssertFail, PtrLt2) {
PW_CHECK_PTR_LT(reinterpret_cast<void*>(0xb), reinterpret_cast<void*>(0xb));
}
TEST_F(AssertFail, PtrLt3) {
PW_CHECK_PTR_LT(reinterpret_cast<void*>(0xb), reinterpret_cast<void*>(0xa));
}
// PTR <=
TEST_F(AssertPass, PtrLe1) {
PW_CHECK_PTR_LE(reinterpret_cast<void*>(0xa), reinterpret_cast<void*>(0xb));
}
TEST_F(AssertPass, PtrLe2) {
PW_CHECK_PTR_LE(reinterpret_cast<void*>(0xb), reinterpret_cast<void*>(0xb));
}
TEST_F(AssertFail, PtrLe3) {
PW_CHECK_PTR_LE(reinterpret_cast<void*>(0xb), reinterpret_cast<void*>(0xa));
}
// PTR ==
TEST_F(AssertFail, PtrEq1) {
PW_CHECK_PTR_EQ(reinterpret_cast<void*>(0xa), reinterpret_cast<void*>(0xb));
}
TEST_F(AssertPass, PtrEq2) {
PW_CHECK_PTR_EQ(reinterpret_cast<void*>(0xb), reinterpret_cast<void*>(0xb));
}
TEST_F(AssertFail, PtrEq3) {
PW_CHECK_PTR_EQ(reinterpret_cast<void*>(0xb), reinterpret_cast<void*>(0xa));
}
// PTR !=
TEST_F(AssertPass, PtrNe1) {
PW_CHECK_PTR_NE(reinterpret_cast<void*>(0xa), reinterpret_cast<void*>(0xb));
}
TEST_F(AssertFail, PtrNe2) {
PW_CHECK_PTR_NE(reinterpret_cast<void*>(0xb), reinterpret_cast<void*>(0xb));
}
TEST_F(AssertPass, PtrNe3) {
PW_CHECK_PTR_NE(reinterpret_cast<void*>(0xb), reinterpret_cast<void*>(0xa));
}
// PTR >
TEST_F(AssertFail, PtrGt1) {
PW_CHECK_PTR_GT(reinterpret_cast<void*>(0xa), reinterpret_cast<void*>(0xb));
}
TEST_F(AssertFail, PtrGt2) {
PW_CHECK_PTR_GT(reinterpret_cast<void*>(0xb), reinterpret_cast<void*>(0xb));
}
TEST_F(AssertPass, PtrGt3) {
PW_CHECK_PTR_GT(reinterpret_cast<void*>(0xb), reinterpret_cast<void*>(0xa));
}
// PTR >=
TEST_F(AssertFail, PtrGe1) {
PW_CHECK_PTR_GE(reinterpret_cast<void*>(0xa), reinterpret_cast<void*>(0xb));
}
TEST_F(AssertPass, PtrGe2) {
PW_CHECK_PTR_GE(reinterpret_cast<void*>(0xb), reinterpret_cast<void*>(0xb));
}
TEST_F(AssertPass, PtrGe3) {
PW_CHECK_PTR_GE(reinterpret_cast<void*>(0xb), reinterpret_cast<void*>(0xa));
}
// NOTNULL
TEST_F(AssertPass, PtrNotNull) {
PW_CHECK_NOTNULL(reinterpret_cast<void*>(0xa));
}
TEST_F(AssertFail, PtrNotNull) {
PW_CHECK_NOTNULL(reinterpret_cast<void*>(0x0));
}
[[maybe_unused]] void Function1() {}
[[maybe_unused]] bool Function2(int) { return false; }
// NOTNULL for function poionters
TEST_F(AssertPass, FunctionPtrNotNull) {
PW_CHECK_NOTNULL(&Function1);
PW_CHECK_NOTNULL(&Function2);
}
TEST_F(AssertFail, FunctionPtrNotNull) {
void (*const function)() = nullptr;
PW_CHECK_NOTNULL(function);
}
// Note: Due to platform inconsistencies, the below test for the NOTNULL
// message doesn't work. Some platforms print NULL formatted as %p as "(nil)",
// others "0x0". Leaving this here for reference.
//
// TEST_F(AssertFail, PtrNotNullDescription) {
// intptr_t intptr = 0;
// PW_CHECK_NOTNULL(intptr);
// EXPECT_MESSAGE("Check failed: intptr (=0x0) != nullptr (=0x0). ");
// }
// PW_CHECK_FLOAT_*(...)
// Binary checks with floats, comparisons: EXACT_LT, EXACT_LE, NEAR, EXACT_EQ,
// EXACT_NE, EXACT_GE, EXACT_GT.
// Test message formatting separate from the triggering.
// Only test formatting for the type once.
TEST_F(AssertFail, FloatLessThanNoMessageNoArguments) {
PW_CHECK_FLOAT_EXACT_LT(5.2, 2.3);
EXPECT_MESSAGE("Check failed: 5.2 (=5.200000) < 2.3 (=2.300000). ");
}
TEST_F(AssertFail, FloatLessThanMessageNoArguments) {
PW_CHECK_FLOAT_EXACT_LT(5.2, 2.3, "msg");
EXPECT_MESSAGE("Check failed: 5.2 (=5.200000) < 2.3 (=2.300000). msg");
}
TEST_F(AssertFail, FloatLessThanMessageArguments) {
PW_CHECK_FLOAT_EXACT_LT(5.2, 2.3, "msg: %d", 6);
EXPECT_MESSAGE("Check failed: 5.2 (=5.200000) < 2.3 (=2.300000). msg: 6");
}
// Check float NEAR both above and below the permitted range.
TEST_F(AssertFail, FloatNearAboveNoMessageNoArguments) {
PW_CHECK_FLOAT_NEAR(5.2, 2.3, 0.1);
EXPECT_MESSAGE(
"Check failed: 5.2 (=5.200000) <= 2.3 + abs_tolerance (=2.400000). ");
}
TEST_F(AssertFail, FloatNearAboveMessageNoArguments) {
PW_CHECK_FLOAT_NEAR(5.2, 2.3, 0.1, "msg");
EXPECT_MESSAGE(
"Check failed: 5.2 (=5.200000) <= 2.3 + abs_tolerance (=2.400000). msg");
}
TEST_F(AssertFail, FloatNearAboveMessageArguments) {
PW_CHECK_FLOAT_NEAR(5.2, 2.3, 0.1, "msg: %d", 6);
EXPECT_MESSAGE(
"Check failed: 5.2 (=5.200000) <= 2.3 + abs_tolerance (=2.400000). msg: "
"6");
}
TEST_F(AssertFail, FloatNearBelowNoMessageNoArguments) {
PW_CHECK_FLOAT_NEAR(1.2, 2.3, 0.1);
EXPECT_MESSAGE(
"Check failed: 1.2 (=1.200000) >= 2.3 - abs_tolerance (=2.200000). ");
}
TEST_F(AssertFail, FloatNearBelowMessageNoArguments) {
PW_CHECK_FLOAT_NEAR(1.2, 2.3, 0.1, "msg");
EXPECT_MESSAGE(
"Check failed: 1.2 (=1.200000) >= 2.3 - abs_tolerance (=2.200000). msg");
}
TEST_F(AssertFail, FloatNearBelowMessageArguments) {
PW_CHECK_FLOAT_NEAR(1.2, 2.3, 0.1, "msg: %d", 6);
EXPECT_MESSAGE(
"Check failed: 1.2 (=1.200000) >= 2.3 - abs_tolerance (=2.200000). msg: "
"6");
}
// Test comparison boundaries.
// Note: The below example numbers all round to integer 1, to detect accidental
// integer conversions in the asserts.
// FLOAT <
TEST_F(AssertPass, FloatLt1) { PW_CHECK_FLOAT_EXACT_LT(1.1, 1.2); }
TEST_F(AssertFail, FloatLt2) { PW_CHECK_FLOAT_EXACT_LT(1.2, 1.2); }
TEST_F(AssertFail, FloatLt3) { PW_CHECK_FLOAT_EXACT_LT(1.2, 1.1); }
// FLOAT <=
TEST_F(AssertPass, FloatLe1) { PW_CHECK_FLOAT_EXACT_LE(1.1, 1.2); }
TEST_F(AssertPass, FloatLe2) { PW_CHECK_FLOAT_EXACT_LE(1.2, 1.2); }
TEST_F(AssertFail, FloatLe3) { PW_CHECK_FLOAT_EXACT_LE(1.2, 1.1); }
// FLOAT ~= based on absolute error.
TEST_F(AssertFail, FloatNearAbs1) { PW_CHECK_FLOAT_NEAR(1.09, 1.2, 0.1); }
TEST_F(AssertPass, FloatNearAbs2) { PW_CHECK_FLOAT_NEAR(1.1, 1.2, 0.1); }
TEST_F(AssertPass, FloatNearAbs3) { PW_CHECK_FLOAT_NEAR(1.2, 1.2, 0.1); }
TEST_F(AssertPass, FloatNearAbs4) { PW_CHECK_FLOAT_NEAR(1.2, 1.1, 0.1); }
TEST_F(AssertFail, FloatNearAbs5) { PW_CHECK_FLOAT_NEAR(1.21, 1.1, 0.1); }
// Make sure the abs_tolerance is asserted to be >= 0.
TEST_F(AssertFail, FloatNearAbs6) { PW_CHECK_FLOAT_NEAR(1.2, 1.2, -0.1); }
TEST_F(AssertPass, FloatNearAbs7) { PW_CHECK_FLOAT_NEAR(1.2, 1.2, 0.0); }
// FLOAT ==
TEST_F(AssertFail, FloatEq1) { PW_CHECK_FLOAT_EXACT_EQ(1.1, 1.2); }
TEST_F(AssertPass, FloatEq2) { PW_CHECK_FLOAT_EXACT_EQ(1.2, 1.2); }
TEST_F(AssertFail, FloatEq3) { PW_CHECK_FLOAT_EXACT_EQ(1.2, 1.1); }
// FLOAT !=
TEST_F(AssertPass, FloatNe1) { PW_CHECK_FLOAT_EXACT_NE(1.1, 1.2); }
TEST_F(AssertFail, FloatNe2) { PW_CHECK_FLOAT_EXACT_NE(1.2, 1.2); }
TEST_F(AssertPass, FloatNe3) { PW_CHECK_FLOAT_EXACT_NE(1.2, 1.1); }
// FLOAT >
TEST_F(AssertFail, FloatGt1) { PW_CHECK_FLOAT_EXACT_GT(1.1, 1.2); }
TEST_F(AssertFail, FloatGt2) { PW_CHECK_FLOAT_EXACT_GT(1.2, 1.2); }
TEST_F(AssertPass, FloatGt3) { PW_CHECK_FLOAT_EXACT_GT(1.2, 1.1); }
// FLOAT >=
TEST_F(AssertFail, FloatGe1) { PW_CHECK_FLOAT_EXACT_GE(1.1, 1.2); }
TEST_F(AssertPass, FloatGe2) { PW_CHECK_FLOAT_EXACT_GE(1.2, 1.2); }
TEST_F(AssertPass, FloatGe3) { PW_CHECK_FLOAT_EXACT_GE(1.2, 1.1); }
// Nested comma handling.
static int Add3(int a, int b, int c) { return a + b + c; }
TEST_F(AssertFail, CommaHandlingLeftSide) {
PW_CHECK_INT_EQ(Add3(1, 2, 3), 4);
EXPECT_MESSAGE("Check failed: Add3(1, 2, 3) (=6) == 4 (=4). ");
}
TEST_F(AssertFail, CommaHandlingRightSide) {
PW_CHECK_INT_EQ(4, Add3(1, 2, 3));
EXPECT_MESSAGE("Check failed: 4 (=4) == Add3(1, 2, 3) (=6). ");
}
// Verify that the CHECK_*(x,y) macros only evaluate their arguments once.
struct MultiEvaluateTestContext {
int IncrementAndReturnZero() {
counter += 1;
return 0;
}
int counter = 0;
};
TEST(AssertPass, CheckSingleSideEffectingCall) {
MultiEvaluateTestContext ctx;
PW_CHECK(ctx.IncrementAndReturnZero() == 0);
EXPECT_EQ(ctx.counter, 1);
}
TEST(AssertFail, CheckSingleSideEffectingCall) {
MultiEvaluateTestContext ctx;
PW_CHECK(ctx.IncrementAndReturnZero() == 1);
EXPECT_EQ(ctx.counter, 1);
}
TEST(AssertPass, BinaryOpSingleSideEffectingCall) {
MultiEvaluateTestContext ctx;
PW_CHECK_INT_EQ(0, ctx.IncrementAndReturnZero());
EXPECT_EQ(ctx.counter, 1);
}
TEST(AssertPass, BinaryOpTwoSideEffectingCalls) {
MultiEvaluateTestContext ctx;
PW_CHECK_INT_EQ(ctx.IncrementAndReturnZero(), ctx.IncrementAndReturnZero());
EXPECT_EQ(ctx.counter, 2);
}
TEST(AssertFail, BinaryOpSingleSideEffectingCall) {
MultiEvaluateTestContext ctx;
PW_CHECK_INT_EQ(12314, ctx.IncrementAndReturnZero());
EXPECT_EQ(ctx.counter, 1);
}
TEST(AssertFail, BinaryOpTwoSideEffectingCalls) {
MultiEvaluateTestContext ctx;
PW_CHECK_INT_EQ(ctx.IncrementAndReturnZero() + 10,
ctx.IncrementAndReturnZero());
EXPECT_EQ(ctx.counter, 2);
}
TEST(AssertPass, CheckOkSingleSideEffectingCall) {
MultiEvaluateTestContext ctx;
PW_CHECK_OK(ctx.IncrementAndReturnZero() ? pw::OkStatus() : pw::OkStatus());
EXPECT_EQ(ctx.counter, 1);
}
TEST(AssertFail, CheckOkSingleSideEffectingCall) {
MultiEvaluateTestContext ctx;
PW_CHECK_OK(ctx.IncrementAndReturnZero() ? pw::Status::NotFound()
: pw::Status::NotFound());
EXPECT_EQ(ctx.counter, 1);
}
// Verify side effects of debug checks work as expected.
// Only check a couple of cases, since the logic is all the same.
// When DCHECKs are enabled, they behave the same as normal checks.
// When DCHECKs are disabled, they should not trip, and their arguments
// shouldn't be evaluated.
constexpr int kExpectedSideEffects = PW_ASSERT_ENABLE_DEBUG;
TEST(AssertPass, DCheckEnabledSingleSideEffectingCall) {
MultiEvaluateTestContext ctx;
PW_DCHECK(ctx.IncrementAndReturnZero() == 0);
EXPECT_EQ(ctx.counter, kExpectedSideEffects);
}
TEST(AssertFail, DCheckEnabledSingleSideEffectingCall) {
MultiEvaluateTestContext ctx;
PW_DCHECK(ctx.IncrementAndReturnZero() == 1);
EXPECT_EQ(ctx.counter, kExpectedSideEffects);
}
TEST(AssertPass, DCheckEnabledBinaryOpSingleSideEffectingCall) {
MultiEvaluateTestContext ctx;
PW_DCHECK_INT_EQ(0, ctx.IncrementAndReturnZero());
EXPECT_EQ(ctx.counter, kExpectedSideEffects);
}
TEST(AssertPass, DCheckEnabledBinaryOpTwoSideEffectingCalls) {
MultiEvaluateTestContext ctx;
PW_DCHECK_INT_EQ(ctx.IncrementAndReturnZero(), ctx.IncrementAndReturnZero());
EXPECT_EQ(ctx.counter, 2 * kExpectedSideEffects);
}
TEST(AssertFail, DCheckEnabledBinaryOpSingleSideEffectingCall) {
MultiEvaluateTestContext ctx;
PW_DCHECK_INT_EQ(12314, ctx.IncrementAndReturnZero());
EXPECT_EQ(ctx.counter, kExpectedSideEffects);
}
TEST(AssertFail, DCheckEnabledBinaryOpTwoSideEffectingCalls) {
MultiEvaluateTestContext ctx;
PW_DCHECK_INT_EQ(ctx.IncrementAndReturnZero() + 10,
ctx.IncrementAndReturnZero());
EXPECT_EQ(ctx.counter, 2 * kExpectedSideEffects);
}
TEST(AssertPass, DCheckOkSingleSideEffectingCall) {
MultiEvaluateTestContext ctx;
PW_DCHECK_OK(ctx.IncrementAndReturnZero() ? pw::OkStatus() : pw::OkStatus());
EXPECT_EQ(ctx.counter, kExpectedSideEffects);
}
TEST(AssertFail, DCheckOkSingleSideEffectingCall) {
MultiEvaluateTestContext ctx;
PW_DCHECK_OK(ctx.IncrementAndReturnZero() ? pw::Status::NotFound()
: pw::Status::NotFound());
EXPECT_EQ(ctx.counter, kExpectedSideEffects);
}
// Verify PW_CHECK_OK, including message handling.
TEST_F(AssertFail, StatusNotOK) {
pw::Status status = pw::Status::Unknown();
PW_CHECK_OK(status);
EXPECT_MESSAGE("Check failed: status (=UNKNOWN) == OkStatus() (=OK). ");
}
TEST_F(AssertFail, StatusNotOKMessageNoArguments) {
pw::Status status = pw::Status::Unknown();
PW_CHECK_OK(status, "msg");
EXPECT_MESSAGE("Check failed: status (=UNKNOWN) == OkStatus() (=OK). msg");
}
TEST_F(AssertFail, StatusNotOKMessageArguments) {
pw::Status status = pw::Status::Unknown();
PW_CHECK_OK(status, "msg: %d", 5);
EXPECT_MESSAGE("Check failed: status (=UNKNOWN) == OkStatus() (=OK). msg: 5");
}
// Example expression for the test below.
pw::Status DoTheThing() { return pw::Status::ResourceExhausted(); }
TEST_F(AssertFail, NonTrivialExpression) {
PW_CHECK_OK(DoTheThing());
EXPECT_MESSAGE(
"Check failed: DoTheThing() (=RESOURCE_EXHAUSTED) == OkStatus() (=OK). ");
}
// Note: This function seems pointless but it is not, since pw::Status::FOO
// constants are not actually status objects, but code objects. This way we can
// ensure the macros work with both real status objects and literals.
TEST_F(AssertPass, Function) { PW_CHECK_OK(pw::OkStatus()); }
TEST_F(AssertPass, Enum) { PW_CHECK_OK(PW_STATUS_OK); }
TEST_F(AssertFail, Function) { PW_CHECK_OK(pw::Status::Unknown()); }
TEST_F(AssertFail, Enum) { PW_CHECK_OK(PW_STATUS_UNKNOWN); }
#if PW_ASSERT_ENABLE_DEBUG
// In debug mode, the asserts should check their arguments.
TEST_F(AssertPass, DCheckFunction) { PW_DCHECK_OK(pw::OkStatus()); }
TEST_F(AssertPass, DCheckEnum) { PW_DCHECK_OK(PW_STATUS_OK); }
TEST_F(AssertFail, DCheckFunction) { PW_DCHECK_OK(pw::Status::Unknown()); }
TEST_F(AssertFail, DCheckEnum) { PW_DCHECK_OK(PW_STATUS_UNKNOWN); }
#else // PW_ASSERT_ENABLE_DEBUG
// In release mode, all the asserts should pass.
TEST_F(AssertPass, DCheckFunction_Ok) { PW_DCHECK_OK(pw::OkStatus()); }
TEST_F(AssertPass, DCheckEnum_Ok) { PW_DCHECK_OK(PW_STATUS_OK); }
TEST_F(AssertPass, DCheckFunction_Err) { PW_DCHECK_OK(pw::Status::Unknown()); }
TEST_F(AssertPass, DCheckEnum_Err) { PW_DCHECK_OK(PW_STATUS_UNKNOWN); }
#endif // PW_ASSERT_ENABLE_DEBUG
// TODO: Figure out how to run some of these tests is C.
} // namespace