Move Codec2-related code from hardware/google/av
Test: None
Bug: 112362730
Change-Id: Ie2f8ff431d65c40333f267ab9877d47089adeea4
diff --git a/media/codec2/tests/C2ComponentInterface_test.cpp b/media/codec2/tests/C2ComponentInterface_test.cpp
new file mode 100644
index 0000000..e907964
--- /dev/null
+++ b/media/codec2/tests/C2ComponentInterface_test.cpp
@@ -0,0 +1,706 @@
+/*
+ * Copyright 2017 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.
+ */
+
+#define LOG_TAG "C2ComponentInterface_test"
+
+#include <dlfcn.h>
+#include <stdio.h>
+
+#include <gtest/gtest.h>
+#include <utils/Log.h>
+
+#include <C2Component.h>
+#include <C2Config.h>
+#include <util/C2InterfaceHelper.h>
+#include <C2Param.h>
+
+#if !defined(UNUSED)
+#define UNUSED(expr) \
+ do { \
+ (void)(expr); \
+ } while (0)
+
+#endif //!defined(UNUSED)
+
+namespace android {
+
+template <class T> std::unique_ptr<T> alloc_unique_cstr(const char *cstr) {
+ size_t len = strlen(cstr);
+ std::unique_ptr<T> ptr = T::AllocUnique(len);
+ memcpy(ptr->m.value, cstr, len);
+ return ptr;
+}
+
+class C2CompIntfTest : public ::testing::Test {
+protected:
+ C2CompIntfTest() {}
+ ~C2CompIntfTest() override {}
+
+ void setComponent(std::shared_ptr<C2ComponentInterface> intf) {
+ mIntf = intf;
+ }
+
+ void resetResults() {
+ mIntf = nullptr;
+ mParamResults.clear();
+ }
+
+ template <typename T> void testUnsupportedParam();
+
+ template <typename T> void testSupportedParam();
+
+ // testReadOnlyParam() and testWritableParam() are the main functions for testing a parameter.
+ // A caller should find out if a tested parameter is read-only or writable before calling them
+ // and it must call one of the corresponded them.
+
+ // If a parameter is read-only this is called.
+ // Test read-only parameter |preParam|. The test expects failure while config() with |newParam|,
+ // and make sure |preParam| stay unchanged.
+ template <typename T>
+ void testReadOnlyParam(const T &preParam, const T &newParam);
+
+ // If a parameter is writable this is called.
+ // Test one filed |writableField| for given writable parameter |param|.
+ // |validValues| contains all values obtained from querySupportedValues() for |writableField|.
+ // The test checks validity for config() with each value, and make sure values are config-ed
+ // by query() them out. |invalidValues| contains some values which are not in |validValues|.
+ // The test expects C2_BAD_VALUE while config() with these values,
+ // and |param| should stay unchanged.
+ template <typename TParam, typename TRealField, typename TField>
+ void testWritableParam(TParam *const param, TRealField *const writableField,
+ const std::vector<TField> &validValues,
+ const std::vector<TField> &invalidValues);
+
+ // Test all the defined parameters in C2Param.h.
+ void testMain(std::shared_ptr<C2ComponentInterface> intf,
+ const std::string &componentName);
+
+ // Check permission of parameter type |T| for testing interface.
+ // This should be called first of the testing per parameter type,
+ // therefore different testing process is applied according to the permission type.
+ template <typename T>
+ void checkParamPermission(
+ int *const writable,
+ const std::vector<std::shared_ptr<C2ParamDescriptor>> &supportedParams);
+
+private:
+ enum ParamPermission : int {
+ WRITABLE,
+ READONLY,
+ UNSUPPORTED,
+ };
+
+ struct paramTestInfo {
+ std::string name;
+ int result;
+ paramTestInfo(const char *name_, int result_)
+ : name(name_), result(result_) {}
+ };
+
+ // queryOnStack() and queryonHeap() both call an interface's query_vb() and
+ // check if a component has a parameter whose type is |T|.
+ // If a component has, the value should be copied into an argument, that is
+ // |p| in queryOnStack() and |heapParams| in queryOnHeap().
+ // The return value is c2_status_t (e.g. C2_OK).
+ template <typename T> c2_status_t queryOnStack(T *const p);
+
+ template <typename T>
+ c2_status_t queryOnHeap(const T &p,
+ std::vector<std::unique_ptr<C2Param>> *const heapParams);
+
+ // Get a value whose type is |T| in a component. The value is copied to |param|.
+ // This should be called only if a component has the parameter.
+ template <typename T> void getValue(T *const param);
+
+ // Check if the parameter's value in component is equal to |expected| and
+ // queryOnStack() and queryOnHeap() are succeeded. When this function called,
+ // it should be guaranteed a component has the parameter.
+ template <typename T> void queryParamAsExpected(const T &expected);
+
+ // Test if query functions works correctly for supported parameters.
+ // "Support" means here a component has the parameter.
+ template <typename T> void querySupportedParam();
+
+ // Test query functions works correctly for unsupported parameters.
+ // "Unsupport" means here a component doesn't have the parameter.
+ template <typename T> void queryUnsupportedParam();
+
+ // Execute an interface's config_vb(). |T| is a single parameter type, not std::vector.
+ // config() creates std::vector<C2Param *> {p} and passes it to config_vb().
+ template <typename T>
+ c2_status_t
+ config(T *const p,
+ std::vector<std::unique_ptr<C2SettingResult>> *const failures);
+
+ // Test if config works correctly for read-only parameters.
+ // Because the failure of config() is assumed, |newParam| doesn't matter.
+ template <typename T> void configReadOnlyParam(const T &newParam);
+
+ // Test if config works correctly for writable parameters.
+ // This changes the parameter's value to |newParam|.
+ // |stConfig| is a return value of config().
+ template <typename T> void configWritableParamValidValue(const T &newParam, c2_status_t *stConfig);
+
+ // Test if config works correctly in the case an invalid value |newParam| is tried to write
+ // to an writable parameter.
+ template <typename T> void configWritableParamInvalidValue(const T &newParam);
+
+ // Create values for testing from |validValueInfos|. The values are returned as arguments.
+ // |validValues| : valid values, which can be written for the parameter.
+ // |InvalidValues| : invalid values, which cannot be written for the parameter.
+ // config() should be failed if these values are used as new values.
+ // This function should be called only for writable and supported parameters.
+ template <typename TField>
+ void getTestValues(const C2FieldSupportedValues &validValueInfos,
+ std::vector<TField> *const validValues,
+ std::vector<TField> *const invalidValues);
+
+ // Output the summary of test results. Categorizes parameters with their configuration.
+ void outputResults(const std::string &name);
+
+ std::shared_ptr<C2ComponentInterface> mIntf;
+ std::vector<paramTestInfo> mParamResults;
+ std::string mCurrentParamName;
+};
+
+// factory function
+// TODO(hiroh): Add factory functions for other types.
+template <typename T> std::unique_ptr<T> makeParam() {
+ return std::make_unique<T>();
+}
+
+template <> std::unique_ptr<C2PortMimeConfig::input> makeParam() {
+ // TODO(hiroh): Set more precise length.
+ return C2PortMimeConfig::input::AllocUnique(100);
+}
+
+#define TRACED_FAILURE(func) \
+ do { \
+ SCOPED_TRACE(mCurrentParamName); \
+ func; \
+ if (::testing::Test::HasFatalFailure()) { \
+ return; \
+ } \
+ } while (false)
+
+template <typename T> c2_status_t C2CompIntfTest::queryOnStack(T *const p) {
+ std::vector<C2Param*> stackParams{p};
+ return mIntf->query_vb(stackParams, {}, C2_DONT_BLOCK, nullptr);
+}
+
+template <typename T>
+c2_status_t C2CompIntfTest::queryOnHeap(
+ const T &p, std::vector<std::unique_ptr<C2Param>> *const heapParams) {
+ uint32_t index = p.index() & ~0x03FE0000;
+ if (p.forStream()) {
+ index |= ((p.stream() << 17) & 0x01FE0000) | 0x02000000;
+ }
+ return mIntf->query_vb({}, {index}, C2_DONT_BLOCK, heapParams);
+}
+
+template <typename T> void C2CompIntfTest::getValue(T *const param) {
+ // When getValue() is called, a component has to have the parameter.
+ ASSERT_EQ(C2_OK, queryOnStack(param));
+}
+
+template <typename T>
+void C2CompIntfTest::queryParamAsExpected(const T &expected) {
+ // TODO(hiroh): Don't create param on stack and call queryOnStack for flex params.
+ // Note that all the current supported parameters are non-flex params.
+ T stack;
+ std::unique_ptr<T> pHeap = makeParam<T>();
+ std::vector<std::unique_ptr<C2Param>> heapParams;
+
+ ASSERT_EQ(C2_OK, queryOnStack(&stack));
+
+ // |stack| is a parameter value. The parameter size shouldn't be 0.
+ EXPECT_NE(0u, stack.size());
+ EXPECT_EQ(stack, expected);
+
+ ASSERT_EQ(C2_OK, queryOnHeap(*pHeap, &heapParams));
+
+ // |*heapParams[0]| is a parameter value. The size of |heapParams| has to be one.
+ ASSERT_EQ(1u, heapParams.size());
+ EXPECT_TRUE(heapParams[0]);
+ EXPECT_EQ(*heapParams[0], expected);
+}
+
+template <typename T> void C2CompIntfTest::querySupportedParam() {
+ std::unique_ptr<T> param = makeParam<T>();
+ // The current parameter's value is acquired by getValue(), which should be succeeded.
+ getValue(param.get());
+ queryParamAsExpected(*param);
+}
+
+template <typename T> void C2CompIntfTest::queryUnsupportedParam() {
+ // TODO(hiroh): Don't create param on stack and call queryOnStack for flex params.
+ // Note that all the current supported parameters are non-flex params.
+ T stack;
+ std::unique_ptr<T> pHeap = makeParam<T>();
+ std::vector<std::unique_ptr<C2Param>> heapParams;
+ // If a component doesn't have the parameter, queryOnStack() and queryOnHeap()
+ // should return C2_BAD_INDEX.
+ ASSERT_EQ(C2_BAD_INDEX, queryOnStack(&stack));
+ EXPECT_FALSE(stack);
+ ASSERT_EQ(C2_BAD_INDEX, queryOnHeap(*pHeap, &heapParams));
+ EXPECT_EQ(0u, heapParams.size());
+}
+
+template <typename T>
+c2_status_t C2CompIntfTest::config(
+ T *const p, std::vector<std::unique_ptr<C2SettingResult>> *const failures) {
+ std::vector<C2Param*> params{p};
+ return mIntf->config_vb(params, C2_DONT_BLOCK, failures);
+}
+
+// Create a new parameter copied from |p|.
+template <typename T> std::unique_ptr<T> makeParamFrom(const T &p) {
+ std::unique_ptr<T> retP = makeParam<T>();
+ EXPECT_TRUE(retP->updateFrom(p));
+ EXPECT_TRUE(memcmp(retP.get(), &p, sizeof(T)) == 0);
+ return retP;
+}
+
+template <typename T>
+void C2CompIntfTest::configReadOnlyParam(const T &newParam) {
+ std::unique_ptr<T> p = makeParamFrom(newParam);
+
+ std::vector<C2Param*> params{p.get()};
+ std::vector<std::unique_ptr<C2SettingResult>> failures;
+
+ // config_vb should be failed because a parameter is read-only.
+ ASSERT_EQ(C2_BAD_VALUE, mIntf->config_vb(params, C2_DONT_BLOCK, &failures));
+ ASSERT_EQ(1u, failures.size());
+ EXPECT_EQ(C2SettingResult::READ_ONLY, failures[0]->failure);
+}
+
+template <typename T>
+void C2CompIntfTest::configWritableParamValidValue(const T &newParam, c2_status_t *configResult) {
+ std::unique_ptr<T> p = makeParamFrom(newParam);
+
+ std::vector<C2Param*> params{p.get()};
+ std::vector<std::unique_ptr<C2SettingResult>> failures;
+ // In most cases, config_vb return C2_OK and the parameter's value should be changed
+ // to |newParam|, which is confirmed in a caller of configWritableParamValueValue().
+ // However, this can return ~~~~ and the parameter's values is not changed,
+ // because there may be dependent limitations between fields or between parameters.
+ // TODO(hiroh): I have to fill the return value. Comments in C2Component.h doesn't mention
+ // about the return value when conflict happens. I set C2_BAD_VALUE to it temporarily now.
+ c2_status_t stConfig = mIntf->config_vb(params, C2_DONT_BLOCK, &failures);
+ if (stConfig == C2_OK) {
+ EXPECT_EQ(0u, failures.size());
+ } else {
+ ASSERT_EQ(C2_BAD_VALUE, stConfig);
+ EXPECT_EQ(1u, failures.size());
+ EXPECT_EQ(C2SettingResult::CONFLICT, failures[0]->failure);
+ }
+ *configResult = stConfig;
+}
+
+template <typename T>
+void C2CompIntfTest::configWritableParamInvalidValue(const T &newParam) {
+ std::unique_ptr<T> p = makeParamFrom(newParam);
+
+ std::vector<C2Param*> params{p.get()};
+ std::vector<std::unique_ptr<C2SettingResult>> failures;
+ // Although a parameter is writable, config_vb should be failed,
+ // because a new value is invalid.
+ ASSERT_EQ(C2_BAD_VALUE, mIntf->config_vb(params, C2_DONT_BLOCK, &failures));
+ ASSERT_EQ(1u, failures.size());
+ EXPECT_EQ(C2SettingResult::BAD_VALUE, failures[0]->failure);
+}
+
+// There is only used enum type for the field type, that is C2DomainKind.
+// If another field type is added, it is necessary to add function for that.
+template <>
+void C2CompIntfTest::getTestValues(
+ const C2FieldSupportedValues &validValueInfos,
+ std::vector<C2DomainKind> *const validValues,
+ std::vector<C2DomainKind> *const invalidValues) {
+ UNUSED(validValueInfos);
+ validValues->emplace_back(C2DomainVideo);
+ validValues->emplace_back(C2DomainAudio);
+ validValues->emplace_back(C2DomainOther);
+
+ // There is no invalid value.
+ UNUSED(invalidValues);
+}
+
+template <typename TField>
+void C2CompIntfTest::getTestValues(
+ const C2FieldSupportedValues &validValueInfos,
+ std::vector<TField> *const validValues,
+ std::vector<TField> *const invalidValues) {
+ using TStorage = typename _c2_reduce_enum_to_underlying_type<TField>::type;
+
+ // The supported values are represented by C2Values. C2Value::Primitive needs to
+ // be transformed to a primitive value. This function is one to do that.
+ auto prim2Value = [](const C2Value::Primitive &prim) -> TField {
+ return (TField)prim.ref<TStorage>();
+ static_assert(std::is_same<TStorage, int32_t>::value ||
+ std::is_same<TStorage, uint32_t>::value ||
+ std::is_same<TStorage, int64_t>::value ||
+ std::is_same<TStorage, uint64_t>::value ||
+ std::is_same<TStorage, float>::value, "Invalid TField type.");
+ };
+
+ // The size of validValueInfos is one.
+ const auto &c2FSV = validValueInfos;
+
+ switch (c2FSV.type) {
+ case C2FieldSupportedValues::type_t::EMPTY: {
+ invalidValues->emplace_back(TField(0));
+ // TODO(hiroh) : Should other invalid values be tested?
+ break;
+ }
+ case C2FieldSupportedValues::type_t::RANGE: {
+ const auto &range = c2FSV.range;
+ auto rmin = prim2Value(range.min);
+ auto rmax = prim2Value(range.max);
+ auto rstep = prim2Value(range.step);
+
+ ASSERT_LE(rmin, rmax);
+
+ if (rstep != 0) {
+ // Increase linear
+ for (auto v = rmin; v <= rmax; v = TField(v + rstep)) {
+ validValues->emplace_back(v);
+ }
+ if (rmin > std::numeric_limits<TField>::min()) {
+ invalidValues->emplace_back(TField(rmin - 1));
+ }
+ if (rmax < std::numeric_limits<TField>::max()) {
+ invalidValues->emplace_back(TField(rmax + 1));
+ }
+ const unsigned int N = validValues->size();
+ if (N >= 2) {
+ if (std::is_same<TField, float>::value) {
+ invalidValues->emplace_back(TField((validValues->at(0) + validValues->at(1)) / 2));
+ invalidValues->emplace_back(TField((validValues->at(N - 2) + validValues->at(N - 1)) / 2));
+ } else {
+ if (rstep > 1) {
+ invalidValues->emplace_back(TField(validValues->at(0) + 1));
+ invalidValues->emplace_back(TField(validValues->at(N - 1) - 1));
+ }
+ }
+ }
+ } else {
+ // There should be two cases, except linear case.
+ // 1. integer geometric case
+ // 2. float geometric case
+
+ auto num = prim2Value(range.num);
+ auto denom = prim2Value(range.denom);
+
+ // If both range.num and range.denom are 1 and step is 0, we should use
+ // VALUES, shouldn't we?
+ ASSERT_FALSE(num == 1 && denom == 1);
+
+ // (num / denom) is not less than 1.
+ ASSERT_FALSE(denom == 0);
+ ASSERT_LE(denom, num);
+ for (auto v = rmin; v <= rmax; v = TField(v * num / denom)) {
+ validValues->emplace_back(v);
+ }
+
+ if (rmin > std::numeric_limits<TField>::min()) {
+ invalidValues->emplace_back(TField(rmin - 1));
+ }
+ if (rmax < std::numeric_limits<TField>::max()) {
+ invalidValues->emplace_back(TField(rmax + 1));
+ }
+
+ const unsigned int N = validValues->size();
+ if (N >= 2) {
+ if (std::is_same<TField, float>::value) {
+ invalidValues->emplace_back(TField((validValues->at(0) + validValues->at(1)) / 2));
+ invalidValues->emplace_back(TField((validValues->at(N - 2) + validValues->at(N - 1)) / 2));
+ } else {
+ if (validValues->at(1) - validValues->at(0) > 1) {
+ invalidValues->emplace_back(TField(validValues->at(0) + 1));
+ }
+ if (validValues->at(N - 1) - validValues->at(N - 2) > 1) {
+ invalidValues->emplace_back(TField(validValues->at(N - 1) - 1));
+ }
+ }
+ }
+ }
+ break;
+ }
+ case C2FieldSupportedValues::type_t::VALUES: {
+ for (const C2Value::Primitive &prim : c2FSV.values) {
+ validValues->emplace_back(prim2Value(prim));
+ }
+ auto minv = *std::min_element(validValues->begin(), validValues->end());
+ auto maxv = *std::max_element(validValues->begin(), validValues->end());
+ if (minv - 1 > std::numeric_limits<TField>::min()) {
+ invalidValues->emplace_back(TField(minv - 1));
+ }
+ if (maxv + 1 < std::numeric_limits<TField>::max()) {
+ invalidValues->emplace_back(TField(maxv + 1));
+ }
+ break;
+ }
+ case C2FieldSupportedValues::type_t::FLAGS: {
+ // TODO(hiroh) : Implement the case that param.type is FLAGS.
+ break;
+ }
+ }
+}
+
+template <typename T>
+void C2CompIntfTest::testReadOnlyParam(const T &preParam, const T &newParam) {
+ TRACED_FAILURE(configReadOnlyParam(newParam));
+ // Parameter value must not be changed
+ TRACED_FAILURE(queryParamAsExpected(preParam));
+}
+
+template <typename TParam, typename TRealField, typename TField>
+void C2CompIntfTest::testWritableParam(
+ TParam *const param, TRealField *const writableField,
+ const std::vector<TField> &validValues,
+ const std::vector<TField> &invalidValues) {
+ c2_status_t stConfig;
+
+ // Get the parameter's value in the beginning in order to reset the value at the end.
+ TRACED_FAILURE(getValue(param));
+ std::unique_ptr<TParam> defaultParam = makeParamFrom(*param);
+
+ // Test valid values
+ for (const auto &val : validValues) {
+ std::unique_ptr<TParam> preParam = makeParamFrom(*param);
+
+ // Param is try to be changed
+ *writableField = val;
+ TRACED_FAILURE(configWritableParamValidValue(*param, &stConfig));
+ if (stConfig == C2_OK) {
+ TRACED_FAILURE(queryParamAsExpected(*param));
+ } else {
+ // Param is unchanged because a field value conflicts with other field or parameter.
+ TRACED_FAILURE(queryParamAsExpected(*preParam));
+ }
+ }
+
+ // Store the current parameter in order to test |param| is unchanged
+ // after trying to write an invalid value.
+ std::unique_ptr<TParam> lastValidParam = makeParamFrom(*param);
+
+ // Test invalid values
+ for (const auto &val : invalidValues) {
+ // Param is changed
+ *writableField = val;
+ TRACED_FAILURE(configWritableParamInvalidValue(*param));
+ TRACED_FAILURE(queryParamAsExpected(*lastValidParam));
+ }
+ // Reset the parameter by config().
+ TRACED_FAILURE(configWritableParamValidValue(*defaultParam, &stConfig));
+}
+
+template <typename T> void C2CompIntfTest::testUnsupportedParam() {
+ TRACED_FAILURE(queryUnsupportedParam<T>());
+}
+
+template <typename T> void C2CompIntfTest::testSupportedParam() {
+ TRACED_FAILURE(querySupportedParam<T>());
+}
+
+bool isSupportedParam(
+ const C2Param ¶m,
+ const std::vector<std::shared_ptr<C2ParamDescriptor>> &sParams) {
+ for (const auto &pd : sParams) {
+ if (param.type() == pd->index().type()) {
+ return true;
+ }
+ }
+ return false;
+}
+
+template <typename T>
+void C2CompIntfTest::checkParamPermission(
+ int *const result,
+ const std::vector<std::shared_ptr<C2ParamDescriptor>> &supportedParams) {
+ std::unique_ptr<T> param = makeParam<T>();
+
+ if (!isSupportedParam(*param, supportedParams)) {
+ // If a parameter isn't supported, it just finish after calling testUnsupportedParam().
+ testUnsupportedParam<T>();
+ *result = ParamPermission::UNSUPPORTED;
+ return;
+ }
+
+ testSupportedParam<T>();
+
+ TRACED_FAILURE(getValue(param.get()));
+ std::vector<std::unique_ptr<C2SettingResult>> failures;
+ // Config does not change the parameter, because param is the present param.
+ // This config is executed to find out if a parameter is read-only or writable.
+ c2_status_t stStack = config(param.get(), &failures);
+ if (stStack == C2_BAD_VALUE) {
+ // Read-only
+ std::unique_ptr<T> newParam = makeParam<T>();
+ testReadOnlyParam(*param, *newParam);
+ *result = ParamPermission::READONLY;
+ } else {
+ // Writable
+ EXPECT_EQ(stStack, C2_OK);
+ *result = ParamPermission::WRITABLE;
+ }
+}
+
+void C2CompIntfTest::outputResults(const std::string &name) {
+ std::vector<std::string> params[3];
+ for (const auto &testInfo : mParamResults) {
+ int result = testInfo.result;
+ ASSERT_TRUE(0 <= result && result <= 2);
+ params[result].emplace_back(testInfo.name);
+ }
+ const char *resultString[] = {"Writable", "Read-Only", "Unsupported"};
+ printf("\n----TEST RESULTS (%s)----\n\n", name.c_str());
+ for (int i = 0; i < 3; i++) {
+ printf("[ %s ]\n", resultString[i]);
+ for (const auto &t : params[i]) {
+ printf("%s\n", t.c_str());
+ }
+ printf("\n");
+ }
+}
+
+#define TEST_GENERAL_WRITABLE_FIELD(TParam_, field_type_name_, field_name_) \
+ do { \
+ std::unique_ptr<TParam_> param = makeParam<TParam_>(); \
+ std::vector<C2FieldSupportedValuesQuery> validValueInfos = { \
+ C2FieldSupportedValuesQuery::Current( \
+ C2ParamField(param.get(), &field_type_name_::field_name_)) \
+ }; \
+ ASSERT_EQ(C2_OK, \
+ mIntf->querySupportedValues_vb(validValueInfos, C2_DONT_BLOCK)); \
+ ASSERT_EQ(1u, validValueInfos.size()); \
+ std::vector<decltype(param->field_name_)> validValues; \
+ std::vector<decltype(param->field_name_)> invalidValues; \
+ getTestValues(validValueInfos[0].values, &validValues, &invalidValues); \
+ testWritableParam(param.get(), ¶m->field_name_, validValues,\
+ invalidValues); \
+ } while (0)
+
+#define TEST_VSSTRUCT_WRITABLE_FIELD(TParam_, field_type_name_) \
+ do { \
+ TEST_GENERAL_WRITABLE_FIELD(TParam_, field_type_name_, width); \
+ TEST_GENERAL_WRITABLE_FIELD(TParam_, field_type_name_, height); \
+ } while (0)
+
+#define TEST_U32_WRITABLE_FIELD(TParam_, field_type_name_) \
+ TEST_GENERAL_WRITABLE_FIELD(TParam_, field_type_name_, value)
+
+#define TEST_ENUM_WRITABLE_FIELD(TParam_, field_type_name_) \
+ TEST_GENERAL_WRITABLE_FIELD(TParam_, field_type_name_, value)
+
+// TODO(hiroh): Support parameters based on char[] and uint32_t[].
+//#define TEST_STRING_WRITABLE_FIELD(TParam_, field_type_name_)
+// TEST_GENERAL_WRITABLE_FIELD(TParam_, field_type_name_, m.value)
+//#define TEST_U32ARRAY_WRITABLE_FIELD(Tparam_, field_type_name_)
+// TEST_GENERAL_WRITABLE_FIELD(Tparam_, uint32_t[], field_type_name_, values)
+
+#define EACH_TEST(TParam_, field_type_name_, test_name) \
+ do { \
+ int result = 0; \
+ this->mCurrentParamName = #TParam_; \
+ checkParamPermission<TParam_>(&result, supportedParams); \
+ if (result == ParamPermission::WRITABLE) { \
+ test_name(TParam_, field_type_name_); \
+ } \
+ mParamResults.emplace_back(#TParam_, result); \
+ } while (0)
+
+#define EACH_TEST_SELF(type_, test_name) EACH_TEST(type_, type_, test_name)
+#define EACH_TEST_INPUT(type_, test_name) EACH_TEST(type_::input, type_, test_name)
+#define EACH_TEST_OUTPUT(type_, test_name) EACH_TEST(type_::output, type_, test_name)
+void C2CompIntfTest::testMain(std::shared_ptr<C2ComponentInterface> intf,
+ const std::string &componentName) {
+ setComponent(intf);
+
+ std::vector<std::shared_ptr<C2ParamDescriptor>> supportedParams;
+ ASSERT_EQ(C2_OK, mIntf->querySupportedParams_nb(&supportedParams));
+
+ EACH_TEST_SELF(C2ComponentLatencyInfo, TEST_U32_WRITABLE_FIELD);
+ EACH_TEST_SELF(C2ComponentTemporalInfo, TEST_U32_WRITABLE_FIELD);
+ EACH_TEST_INPUT(C2PortLatencyInfo, TEST_U32_WRITABLE_FIELD);
+ EACH_TEST_OUTPUT(C2PortLatencyInfo, TEST_U32_WRITABLE_FIELD);
+ EACH_TEST_INPUT(C2StreamFormatConfig, TEST_U32_WRITABLE_FIELD);
+ EACH_TEST_OUTPUT(C2StreamFormatConfig, TEST_U32_WRITABLE_FIELD);
+ EACH_TEST_INPUT(C2PortStreamCountConfig, TEST_U32_WRITABLE_FIELD);
+ EACH_TEST_OUTPUT(C2PortStreamCountConfig, TEST_U32_WRITABLE_FIELD);
+
+ EACH_TEST_SELF(C2ComponentDomainInfo, TEST_ENUM_WRITABLE_FIELD);
+
+ // TODO(hiroh): Support parameters based on uint32_t[] and char[].
+ // EACH_TEST_INPUT(C2PortMimeConfig, TEST_STRING_WRITABLE_FIELD);
+ // EACH_TEST_OUTPUT(C2PortMimeConfig, TEST_STRING_WRITABLE_FIELD);
+ // EACH_TEST_INPUT(C2StreamMimeConfig, TEST_STRING_WRITABLE_FIELD);
+ // EACH_TEST_OUTPUT(C2StreamMimeConfig, TEST_STRING_WRITABLE_FIELD);
+
+ // EACH_TEST_SELF(C2SupportedParamsInfo, TEST_U32ARRAY_WRITABLE_FIELD);
+ // EACH_TEST_SELF(C2RequiredParamsInfo, TEST_U32ARRAY_WRITABLE_FIELD);
+ // EACH_TEST_SELF(C2ReadOnlyParamsInfo, TEST_U32ARRAY_WRITABLE_FIELD);
+ // EACH_TEST_SELF(C2RequestedInfosInfo, TEST_U32ARRAY_WRITABLE_FIELD);
+
+ EACH_TEST_INPUT(C2VideoSizeStreamInfo, TEST_VSSTRUCT_WRITABLE_FIELD);
+ EACH_TEST_OUTPUT(C2VideoSizeStreamInfo, TEST_VSSTRUCT_WRITABLE_FIELD);
+ EACH_TEST_INPUT(C2VideoSizeStreamTuning, TEST_VSSTRUCT_WRITABLE_FIELD);
+ EACH_TEST_OUTPUT(C2VideoSizeStreamTuning, TEST_VSSTRUCT_WRITABLE_FIELD);
+ EACH_TEST_INPUT(C2MaxVideoSizeHintPortSetting, TEST_VSSTRUCT_WRITABLE_FIELD);
+ EACH_TEST_OUTPUT(C2MaxVideoSizeHintPortSetting, TEST_VSSTRUCT_WRITABLE_FIELD);
+
+ outputResults(componentName);
+ resetResults();
+}
+
+TEST_F(C2CompIntfTest, C2V4L2CodecIntf) {
+
+ // Read a shared object library.
+ void* compLib = dlopen("system/lib/libv4l2_codec2.so", RTLD_NOW);
+
+ if (!compLib) {
+ printf("Cannot open library: %s.\n", dlerror());
+ FAIL();
+ return;
+ }
+
+ typedef C2ComponentStore* create_t();
+ create_t* create_store= (create_t*) dlsym(compLib, "create_store");
+ const char* dlsym_error = dlerror();
+ if (dlsym_error) {
+ printf("Cannot load symbol create: %s.\n", dlsym_error);
+ FAIL();
+ return;
+ }
+
+ typedef void destroy_t(C2ComponentStore*);
+ destroy_t* destroy_store = (destroy_t*) dlsym(compLib, "destroy_store");
+ dlsym_error = dlerror();
+ if (dlsym_error) {
+ printf("Cannot load symbol destroy: %s.\n", dlsym_error);
+ FAIL();
+ return;
+ }
+
+ std::shared_ptr<C2ComponentStore> componentStore(create_store(), destroy_store);
+ std::shared_ptr<C2ComponentInterface> componentIntf;
+ componentStore->createInterface("v4l2.decoder", &componentIntf);
+ auto componentName = "C2V4L2Codec";
+ testMain(componentIntf, componentName);
+}
+
+} // namespace android