Create VTS tests for QoS in NNAPI

Bug: 136739795 Bug: 142902514 Bug: 145300530 Test: mma Test: VtsHalNeuralnetworksV1_3TargetTest Change-Id: If3ab91cfb3158e4c33e809ff3b149dff47cda76f
2026-02-01 11:36:00 +00:00 · 2020-01-07 14:52:44 -08:00
parent 9449a28b2f
commit 616701d3cd
7 changed files with 375 additions and 21 deletions
--- a/neuralnetworks/1.3/vts/functional/Android.bp
+++ b/neuralnetworks/1.3/vts/functional/Android.bp
@@ -40,6 +40,7 @@ cc_test {
        "BasicTests.cpp",
        "CompilationCachingTests.cpp",
        "GeneratedTestHarness.cpp",
        "QualityOfServiceTests.cpp",
        "TestAssertions.cpp",
        "ValidateBurst.cpp",
        "ValidateModel.cpp",
--- a/neuralnetworks/1.3/vts/functional/GeneratedTestHarness.cpp
+++ b/neuralnetworks/1.3/vts/functional/GeneratedTestHarness.cpp
@@ -45,6 +45,7 @@
 #include "1.0/Utils.h"
 #include "1.3/Callbacks.h"
 #include "1.3/Utils.h"
 #include "ExecutionBurstController.h"
 #include "MemoryUtils.h"
 #include "TestHarness.h"
@@ -714,7 +715,8 @@ void Execute(const sp<IDevice>& device, const TestModel& testModel, TestKind tes
        } break;
        case TestKind::QUANTIZATION_COUPLING: {
            ASSERT_TRUE(testModel.hasQuant8CoupledOperands());
-            createPreparedModel(device, model, &preparedModel, /*reportSkipping*/ false);
+            createPreparedModel(device, model, &preparedModel,
                                /*reportSkipping*/ false);
            TestModel signedQuantizedModel = convertQuant8AsymmOperandsToSigned(testModel);
            sp<IPreparedModel> preparedCoupledModel;
            createPreparedModel(device, createModel(signedQuantizedModel), &preparedCoupledModel,
@@ -743,6 +745,12 @@ void Execute(const sp<IDevice>& device, const TestModel& testModel, TestKind tes
 void GeneratedTestBase::SetUp() {
    testing::TestWithParam<GeneratedTestParam>::SetUp();
    ASSERT_NE(kDevice, nullptr);
    const Return<void> ret =
            kDevice->supportsDeadlines([this](bool prepareModelDeadline, bool executionDeadline) {
                mSupportsDeadlines = {prepareModelDeadline, executionDeadline};
            });
    ASSERT_TRUE(ret.isOk());
 }
 std::vector<NamedModel> getNamedModels(const FilterFn& filter) {
--- a/neuralnetworks/1.3/vts/functional/GeneratedTestHarness.h
+++ b/neuralnetworks/1.3/vts/functional/GeneratedTestHarness.h
@@ -36,6 +36,7 @@ class GeneratedTestBase : public testing::TestWithParam<GeneratedTestParam> {
    void SetUp() override;
    const sp<IDevice> kDevice = getData(std::get<NamedDevice>(GetParam()));
    const test_helper::TestModel& kTestModel = *getData(std::get<NamedModel>(GetParam()));
    std::pair<bool, bool> mSupportsDeadlines;
 };
 using FilterFn = std::function<bool(const test_helper::TestModel&)>;
--- a/neuralnetworks/1.3/vts/functional/QualityOfServiceTests.cpp
+++ b/neuralnetworks/1.3/vts/functional/QualityOfServiceTests.cpp
@@ -0,0 +1,299 @@
 /*
 * Copyright (C) 2019 The Android Open Source Project
 *
 * 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
 *
 *      http://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.
 */
 #include "1.0/Utils.h"
 #include "1.3/Callbacks.h"
 #include "1.3/Utils.h"
 #include "GeneratedTestHarness.h"
 #include "Utils.h"
 namespace android::hardware::neuralnetworks::V1_3::vts::functional {
 using implementation::ExecutionCallback;
 using implementation::PreparedModelCallback;
 using test_helper::TestBuffer;
 using test_helper::TestModel;
 using V1_1::ExecutionPreference;
 using V1_2::MeasureTiming;
 using V1_2::OutputShape;
 using V1_2::Timing;
 using HidlToken =
        hidl_array<uint8_t, static_cast<uint32_t>(V1_2::Constant::BYTE_SIZE_OF_CACHE_TOKEN)>;
 enum class DeadlineBoundType { NOW, UNLIMITED };
 constexpr std::array<DeadlineBoundType, 2> deadlineBounds = {DeadlineBoundType::NOW,
                                                             DeadlineBoundType::UNLIMITED};
 std::string toString(DeadlineBoundType type) {
    switch (type) {
        case DeadlineBoundType::NOW:
            return "NOW";
        case DeadlineBoundType::UNLIMITED:
            return "UNLIMITED";
    }
    LOG(FATAL) << "Unrecognized DeadlineBoundType: " << static_cast<int>(type);
    return {};
 }
 using Results = std::tuple<ErrorStatus, hidl_vec<OutputShape>, Timing>;
 using MaybeResults = std::optional<Results>;
 using ExecutionFunction =
        std::function<MaybeResults(const sp<IPreparedModel>& preparedModel, const Request& request,
                                   DeadlineBoundType deadlineBound)>;
 static OptionalTimePoint makeOptionalTimePoint(DeadlineBoundType deadlineBoundType) {
    OptionalTimePoint deadline;
    switch (deadlineBoundType) {
        case DeadlineBoundType::NOW: {
            const auto currentTime = std::chrono::steady_clock::now();
            const auto currentTimeInNanoseconds =
                    std::chrono::time_point_cast<std::chrono::nanoseconds>(currentTime);
            const uint64_t nanosecondsSinceEpoch =
                    currentTimeInNanoseconds.time_since_epoch().count();
            deadline.nanoseconds(nanosecondsSinceEpoch);
        } break;
        case DeadlineBoundType::UNLIMITED: {
            uint64_t unlimited = std::numeric_limits<uint64_t>::max();
            deadline.nanoseconds(unlimited);
        } break;
    }
    return deadline;
 }
 void runPrepareModelTest(const sp<IDevice>& device, const Model& model, Priority priority,
                         std::optional<DeadlineBoundType> deadlineBound) {
    OptionalTimePoint deadline;
    if (deadlineBound.has_value()) {
        deadline = makeOptionalTimePoint(deadlineBound.value());
    }
    // see if service can handle model
    bool fullySupportsModel = false;
    const Return<void> supportedCall = device->getSupportedOperations_1_3(
            model, [&fullySupportsModel](ErrorStatus status, const hidl_vec<bool>& supported) {
                ASSERT_EQ(ErrorStatus::NONE, status);
                ASSERT_NE(0ul, supported.size());
                fullySupportsModel = std::all_of(supported.begin(), supported.end(),
                                                 [](bool valid) { return valid; });
            });
    ASSERT_TRUE(supportedCall.isOk());
    // launch prepare model
    const sp<PreparedModelCallback> preparedModelCallback = new PreparedModelCallback();
    const Return<ErrorStatus> prepareLaunchStatus = device->prepareModel_1_3(
            model, ExecutionPreference::FAST_SINGLE_ANSWER, priority, deadline,
            hidl_vec<hidl_handle>(), hidl_vec<hidl_handle>(), HidlToken(), preparedModelCallback);
    ASSERT_TRUE(prepareLaunchStatus.isOk());
    ASSERT_EQ(ErrorStatus::NONE, static_cast<ErrorStatus>(prepareLaunchStatus));
    // retrieve prepared model
    preparedModelCallback->wait();
    const ErrorStatus prepareReturnStatus = preparedModelCallback->getStatus();
    const sp<V1_0::IPreparedModel> preparedModelV1_0 = preparedModelCallback->getPreparedModel();
    const sp<IPreparedModel> preparedModel =
            IPreparedModel::castFrom(preparedModelV1_0).withDefault(nullptr);
    // The getSupportedOperations_1_3 call returns a list of operations that are
    // guaranteed not to fail if prepareModel_1_3 is called, and
    // 'fullySupportsModel' is true i.f.f. the entire model is guaranteed.
    // If a driver has any doubt that it can prepare an operation, it must
    // return false. So here, if a driver isn't sure if it can support an
    // operation, but reports that it successfully prepared the model, the test
    // can continue.
    if (!fullySupportsModel && prepareReturnStatus != ErrorStatus::NONE) {
        ASSERT_EQ(nullptr, preparedModel.get());
        return;
    }
    // verify return status
    if (!deadlineBound.has_value()) {
        EXPECT_EQ(ErrorStatus::NONE, prepareReturnStatus);
    } else {
        switch (deadlineBound.value()) {
            case DeadlineBoundType::NOW:
                // If the execution was launched with a deadline of NOW, the
                // deadline has already passed when the driver would launch the
                // execution. In this case, the driver must return
                // MISSED_DEADLINE_*.
                EXPECT_TRUE(prepareReturnStatus == ErrorStatus::MISSED_DEADLINE_TRANSIENT ||
                            prepareReturnStatus == ErrorStatus::MISSED_DEADLINE_PERSISTENT);
                break;
            case DeadlineBoundType::UNLIMITED:
                // If an unlimited deadline is supplied, we expect the execution to
                // proceed normally. In this case, check it normally by breaking out
                // of the switch statement.
                EXPECT_EQ(ErrorStatus::NONE, prepareReturnStatus);
                break;
        }
    }
    ASSERT_EQ(prepareReturnStatus == ErrorStatus::NONE, preparedModel.get() != nullptr);
 }
 void runPrepareModelTests(const sp<IDevice>& device, const Model& model,
                          bool supportsPrepareModelDeadline) {
    // test priority
    for (auto priority : hidl_enum_range<Priority>{}) {
        SCOPED_TRACE("priority: " + toString(priority));
        if (priority == kDefaultPriority) continue;
        runPrepareModelTest(device, model, priority, {});
    }
    // test deadline
    if (supportsPrepareModelDeadline) {
        for (auto deadlineBound : deadlineBounds) {
            SCOPED_TRACE("deadlineBound: " + toString(deadlineBound));
            runPrepareModelTest(device, model, kDefaultPriority, deadlineBound);
        }
    }
 }
 static MaybeResults executeAsynchronously(const sp<IPreparedModel>& preparedModel,
                                          const Request& request, DeadlineBoundType deadlineBound) {
    SCOPED_TRACE("asynchronous");
    const MeasureTiming measure = MeasureTiming::NO;
    const OptionalTimePoint deadline = makeOptionalTimePoint(deadlineBound);
    // launch execution
    const sp<ExecutionCallback> callback = new ExecutionCallback();
    Return<ErrorStatus> ret = preparedModel->execute_1_3(request, measure, deadline, callback);
    EXPECT_TRUE(ret.isOk());
    EXPECT_EQ(ErrorStatus::NONE, ret.withDefault(ErrorStatus::GENERAL_FAILURE));
    if (!ret.isOk() || ret != ErrorStatus::NONE) return std::nullopt;
    // retrieve execution results
    callback->wait();
    const ErrorStatus status = callback->getStatus();
    hidl_vec<OutputShape> outputShapes = callback->getOutputShapes();
    const Timing timing = callback->getTiming();
    // return results
    return Results{status, std::move(outputShapes), timing};
 }
 static MaybeResults executeSynchronously(const sp<IPreparedModel>& preparedModel,
                                         const Request& request, DeadlineBoundType deadlineBound) {
    SCOPED_TRACE("synchronous");
    const MeasureTiming measure = MeasureTiming::NO;
    const OptionalTimePoint deadline = makeOptionalTimePoint(deadlineBound);
    // configure results callback
    MaybeResults results;
    const auto cb = [&results](const auto&... args) { *results = {args...}; };
    // run execution
    const Return<void> ret =
            preparedModel->executeSynchronously_1_3(request, measure, deadline, cb);
    EXPECT_TRUE(ret.isOk());
    if (!ret.isOk()) return std::nullopt;
    // return results
    return results;
 }
 void runExecutionTest(const sp<IPreparedModel>& preparedModel, const TestModel& testModel,
                      const Request& request, bool synchronous, DeadlineBoundType deadlineBound) {
    const ExecutionFunction execute = synchronous ? executeSynchronously : executeAsynchronously;
    // Perform execution and unpack results.
    const auto results = execute(preparedModel, request, deadlineBound);
    if (!results.has_value()) return;
    const auto& [status, outputShapes, timing] = results.value();
    // Verify no timing information was returned
    EXPECT_EQ(UINT64_MAX, timing.timeOnDevice);
    EXPECT_EQ(UINT64_MAX, timing.timeInDriver);
    // Validate deadline information if applicable.
    switch (deadlineBound) {
        case DeadlineBoundType::NOW:
            // If the execution was launched with a deadline of NOW, the
            // deadline has already passed when the driver would launch the
            // execution. In this case, the driver must return
            // MISSED_DEADLINE_*.
            ASSERT_TRUE(status == ErrorStatus::MISSED_DEADLINE_TRANSIENT ||
                        status == ErrorStatus::MISSED_DEADLINE_PERSISTENT);
            return;
        case DeadlineBoundType::UNLIMITED:
            // If an unlimited deadline is supplied, we expect the execution to
            // proceed normally. In this case, check it normally by breaking out
            // of the switch statement.
            ASSERT_EQ(ErrorStatus::NONE, status);
            break;
    }
    // If the model output operands are fully specified, outputShapes must be either
    // either empty, or have the same number of elements as the number of outputs.
    ASSERT_TRUE(outputShapes.size() == 0 || outputShapes.size() == testModel.outputIndexes.size());
    // Go through all outputs, check returned output shapes.
    for (uint32_t i = 0; i < outputShapes.size(); i++) {
        EXPECT_TRUE(outputShapes[i].isSufficient);
        const auto& expect = testModel.operands[testModel.outputIndexes[i]].dimensions;
        const std::vector<uint32_t> actual = outputShapes[i].dimensions;
        EXPECT_EQ(expect, actual);
    }
    // Retrieve execution results.
    ASSERT_TRUE(nn::compliantWithV1_0(request));
    const V1_0::Request request10 = nn::convertToV1_0(request);
    const std::vector<TestBuffer> outputs = getOutputBuffers(request10);
    // We want "close-enough" results.
    checkResults(testModel, outputs);
 }
 void runExecutionTests(const sp<IPreparedModel>& preparedModel, const TestModel& testModel,
                       const Request& request) {
    for (bool synchronous : {false, true}) {
        for (auto deadlineBound : deadlineBounds) {
            runExecutionTest(preparedModel, testModel, request, synchronous, deadlineBound);
        }
    }
 }
 void runTests(const sp<IDevice>& device, const TestModel& testModel,
              std::pair<bool, bool> supportsDeadlines) {
    // setup
    const auto [supportsPrepareModelDeadline, supportsExecutionDeadline] = supportsDeadlines;
    if (!supportsPrepareModelDeadline && !supportsExecutionDeadline) return;
    const Model model = createModel(testModel);
    // run prepare model tests
    runPrepareModelTests(device, model, supportsPrepareModelDeadline);
    if (supportsExecutionDeadline) {
        // prepare model
        sp<IPreparedModel> preparedModel;
        createPreparedModel(device, model, &preparedModel);
        if (preparedModel == nullptr) return;
        // run execution tests
        const Request request = nn::convertToV1_3(createRequest(testModel));
        runExecutionTests(preparedModel, testModel, request);
    }
 }
 class DeadlineTest : public GeneratedTestBase {};
 TEST_P(DeadlineTest, Test) {
    runTests(kDevice, kTestModel, mSupportsDeadlines);
 }
 INSTANTIATE_GENERATED_TEST(DeadlineTest,
                           [](const TestModel& testModel) { return !testModel.expectFailure; });
 }  // namespace android::hardware::neuralnetworks::V1_3::vts::functional
--- a/neuralnetworks/1.3/vts/functional/ValidateModel.cpp
+++ b/neuralnetworks/1.3/vts/functional/ValidateModel.cpp
@@ -44,12 +44,18 @@ static void validateGetSupportedOperations(const sp<IDevice>& device, const std:
 }
 static void validatePrepareModel(const sp<IDevice>& device, const std::string& message,
-                                 const Model& model, ExecutionPreference preference) {
+                                 const Model& model, ExecutionPreference preference,
                                 bool testDeadline) {
    SCOPED_TRACE(message + " [prepareModel_1_3]");
    OptionalTimePoint deadline;
    if (testDeadline) {
        deadline.nanoseconds(std::numeric_limits<uint64_t>::max());
    }
    sp<PreparedModelCallback> preparedModelCallback = new PreparedModelCallback();
    Return<ErrorStatus> prepareLaunchStatus = device->prepareModel_1_3(
-            model, preference, kDefaultPriority, {}, hidl_vec<hidl_handle>(),
+            model, preference, kDefaultPriority, deadline, hidl_vec<hidl_handle>(),
            hidl_vec<hidl_handle>(), HidlToken(), preparedModelCallback);
    ASSERT_TRUE(prepareLaunchStatus.isOk());
    ASSERT_EQ(ErrorStatus::INVALID_ARGUMENT, static_cast<ErrorStatus>(prepareLaunchStatus));
@@ -73,12 +79,13 @@ static bool validExecutionPreference(ExecutionPreference preference) {
 // to the model does not leave this function.
 static void validate(const sp<IDevice>& device, const std::string& message, Model model,
                     const std::function<void(Model*)>& mutation,
-                     ExecutionPreference preference = ExecutionPreference::FAST_SINGLE_ANSWER) {
+                     ExecutionPreference preference = ExecutionPreference::FAST_SINGLE_ANSWER,
                     bool testDeadline = false) {
    mutation(&model);
-    if (validExecutionPreference(preference)) {
+    if (validExecutionPreference(preference) && !testDeadline) {
        validateGetSupportedOperations(device, message, model);
    }
-    validatePrepareModel(device, message, model, preference);
+    validatePrepareModel(device, message, model, preference, testDeadline);
 }
 static uint32_t addOperand(Model* model) {
@@ -714,9 +721,19 @@ static void mutateExecutionPreferenceTest(const sp<IDevice>& device, const Model
    }
 }
 ///////////////////////// DEADLINE /////////////////////////
 static void deadlineTest(const sp<IDevice>& device, const Model& model) {
    const std::string message = "deadlineTest: deadline not supported";
    const auto noop = [](Model*) {};
    validate(device, message, model, noop, ExecutionPreference::FAST_SINGLE_ANSWER,
             /*testDeadline=*/true);
 }
 ////////////////////////// ENTRY POINT //////////////////////////////
-void validateModel(const sp<IDevice>& device, const Model& model) {
+void validateModel(const sp<IDevice>& device, const Model& model,
                   bool prepareModelDeadlineSupported) {
    mutateOperandTypeTest(device, model);
    mutateOperandRankTest(device, model);
    mutateOperandScaleTest(device, model);
@@ -732,6 +749,9 @@ void validateModel(const sp<IDevice>& device, const Model& model) {
    addOperationInputTest(device, model);
    addOperationOutputTest(device, model);
    mutateExecutionPreferenceTest(device, model);
    if (!prepareModelDeadlineSupported) {
        deadlineTest(device, model);
    }
 }
 }  // namespace android::hardware::neuralnetworks::V1_3::vts::functional
--- a/neuralnetworks/1.3/vts/functional/ValidateRequest.cpp
+++ b/neuralnetworks/1.3/vts/functional/ValidateRequest.cpp
@@ -43,7 +43,8 @@ static bool badTiming(Timing timing) {
 // that use the request. Note that the request here is passed by value, and any
 // mutation to the request does not leave this function.
 static void validate(const sp<IPreparedModel>& preparedModel, const std::string& message,
-                     Request request, const std::function<void(Request*)>& mutation) {
+                     Request request, const std::function<void(Request*)>& mutation,
                     bool testDeadline = false) {
    mutation(&request);
    // We'd like to test both with timing requested and without timing
@@ -56,13 +57,18 @@ static void validate(const sp<IPreparedModel>& preparedModel, const std::string&
    };
    MeasureTiming measure = (hash & 1) ? MeasureTiming::YES : MeasureTiming::NO;
    OptionalTimePoint deadline;
    if (testDeadline) {
        deadline.nanoseconds(std::numeric_limits<uint64_t>::max());
    }
    // asynchronous
    {
        SCOPED_TRACE(message + " [execute_1_3]");
        sp<ExecutionCallback> executionCallback = new ExecutionCallback();
        Return<ErrorStatus> executeLaunchStatus =
-                preparedModel->execute_1_3(request, measure, {}, executionCallback);
+                preparedModel->execute_1_3(request, measure, deadline, executionCallback);
        ASSERT_TRUE(executeLaunchStatus.isOk());
        ASSERT_EQ(ErrorStatus::INVALID_ARGUMENT, static_cast<ErrorStatus>(executeLaunchStatus));
@@ -80,7 +86,7 @@ static void validate(const sp<IPreparedModel>& preparedModel, const std::string&
        SCOPED_TRACE(message + " [executeSynchronously_1_3]");
        Return<void> executeStatus = preparedModel->executeSynchronously_1_3(
-                request, measure, {},
+                request, measure, deadline,
                [](ErrorStatus error, const hidl_vec<OutputShape>& outputShapes,
                   const Timing& timing) {
                    ASSERT_EQ(ErrorStatus::INVALID_ARGUMENT, error);
@@ -92,7 +98,7 @@ static void validate(const sp<IPreparedModel>& preparedModel, const std::string&
    // burst
    // TODO(butlermichael): Check if we need to test burst in V1_3 if the interface remains V1_2.
-    {
+    if (!testDeadline) {
        SCOPED_TRACE(message + " [burst]");
        ASSERT_TRUE(nn::compliantWithV1_0(request));
@@ -152,11 +158,23 @@ static void removeOutputTest(const sp<IPreparedModel>& preparedModel, const Requ
    }
 }
 ///////////////////////// DEADLINE ////////////////////////////////////
 static void deadlineTest(const sp<IPreparedModel>& preparedModel, const Request& request) {
    const std::string message = "deadlineTest: deadline not supported";
    const auto noop = [](Request*) {};
    validate(preparedModel, message, request, noop, /*testDeadline=*/true);
 }
 ///////////////////////////// ENTRY POINT //////////////////////////////////
-void validateRequest(const sp<IPreparedModel>& preparedModel, const Request& request) {
+void validateRequest(const sp<IPreparedModel>& preparedModel, const Request& request,
                     bool executionDeadlineSupported) {
    removeInputTest(preparedModel, request);
    removeOutputTest(preparedModel, request);
    if (!executionDeadlineSupported) {
        deadlineTest(preparedModel, request);
    }
 }
 void validateRequestFailure(const sp<IPreparedModel>& preparedModel, const Request& request) {
--- a/neuralnetworks/1.3/vts/functional/VtsHalNeuralnetworks.cpp
+++ b/neuralnetworks/1.3/vts/functional/VtsHalNeuralnetworks.cpp
@@ -84,6 +84,7 @@ void createPreparedModel(const sp<IDevice>& device, const Model& model,
                  << std::endl;
        GTEST_SKIP();
    }
    ASSERT_EQ(ErrorStatus::NONE, prepareReturnStatus);
    ASSERT_NE(nullptr, preparedModel->get());
 }
@@ -122,23 +123,27 @@ std::string printNeuralnetworksHidlTest(
 INSTANTIATE_DEVICE_TEST(NeuralnetworksHidlTest);
 // Forward declaration from ValidateModel.cpp
-void validateModel(const sp<IDevice>& device, const Model& model);
+void validateModel(const sp<IDevice>& device, const Model& model,
                   bool prepareModelDeadlineSupported);
 // Forward declaration from ValidateRequest.cpp
-void validateRequest(const sp<IPreparedModel>& preparedModel, const Request& request);
+void validateRequest(const sp<IPreparedModel>& preparedModel, const Request& request,
                     bool executionDeadlineSupported);
 // Forward declaration from ValidateRequest.cpp
 void validateRequestFailure(const sp<IPreparedModel>& preparedModel, const Request& request);
 // Forward declaration from ValidateBurst.cpp
 void validateBurst(const sp<IPreparedModel>& preparedModel, const V1_0::Request& request);
-void validateEverything(const sp<IDevice>& device, const Model& model, const Request& request) {
+void validateEverything(const sp<IDevice>& device, const Model& model, const Request& request,
-    validateModel(device, model);
+                        std::pair<bool, bool> supportsDeadlines) {
    const auto [prepareModelDeadlineSupported, executionDeadlineSupported] = supportsDeadlines;
    validateModel(device, model, prepareModelDeadlineSupported);
    // Create IPreparedModel.
    sp<IPreparedModel> preparedModel;
    createPreparedModel(device, model, &preparedModel);
    if (preparedModel == nullptr) return;
-    validateRequest(preparedModel, request);
+    validateRequest(preparedModel, request, executionDeadlineSupported);
    // TODO(butlermichael): Check if we need to test burst in V1_3 if the interface remains V1_2.
    ASSERT_TRUE(nn::compliantWithV1_0(request));
@@ -146,10 +151,12 @@ void validateEverything(const sp<IDevice>& device, const Model& model, const Req
    validateBurst(preparedModel, request10);
 }
-void validateFailure(const sp<IDevice>& device, const Model& model, const Request& request) {
+void validateFailure(const sp<IDevice>& device, const Model& model, const Request& request,
                     std::pair<bool, bool> supportsDeadlines) {
    const bool prepareModelDeadlineSupported = supportsDeadlines.first;
    // TODO: Should this always succeed?
    //       What if the invalid input is part of the model (i.e., a parameter).
-    validateModel(device, model);
+    validateModel(device, model, prepareModelDeadlineSupported);
    // Create IPreparedModel.
    sp<IPreparedModel> preparedModel;
@@ -163,9 +170,9 @@ TEST_P(ValidationTest, Test) {
    const Model model = createModel(kTestModel);
    const Request request = nn::convertToV1_3(createRequest(kTestModel));
    if (kTestModel.expectFailure) {
-        validateFailure(kDevice, model, request);
+        validateFailure(kDevice, model, request, mSupportsDeadlines);
    } else {
-        validateEverything(kDevice, model, request);
+        validateEverything(kDevice, model, request, mSupportsDeadlines);
    }
 }