media/codec2/tests/C2SampleComponent_test.cpp - third_party/android/platform/frameworks/av - Git at Google

 /*
  * Copyright 2014 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_NDEBUG 0
 #define LOG_TAG "C2SampleComponent_test"

 #include <gtest/gtest.h>

 #define __C2_GENERATE_GLOBAL_VARS__
 #include <C2Component.h>
 #include <C2Config.h>
 #include <C2Debug.h>
 #include <C2Enum.h>

 #include <unordered_map>

 class C2SampleComponentTest : public ::testing::Test {
 };

 void PrintTo(const C2FieldDescriptor &fd, ::std::ostream *os) {
     using FD=C2FieldDescriptor;
     switch (fd.type()) {
     case FD::INT32: *os << "i32"; break;
     case FD::INT64: *os << "i64"; break;
     case FD::UINT32: *os << "u32"; break;
     case FD::UINT64: *os << "u64"; break;
     case FD::FLOAT: *os << "float"; break;
     case FD::STRING: *os << "char"; break;
     case FD::BLOB: *os << "u8"; break;
     default:
         if (fd.type() & FD::STRUCT_FLAG) {
             *os << "struct-" << (fd.type() & ~FD::STRUCT_FLAG);
         } else {
             *os << "type-" << fd.type();
         }
     }
     *os << " " << fd.name();
     if (fd.extent() > 1) {
         *os << "[" << fd.extent() << "]";
     } else if (fd.extent() == 0) {
         *os << "[]";
     }
     *os << " (" << fd._mFieldId << "*" << fd.extent() << ")";
 }

 C2ENUM(
     MetadataType, int32_t,
     kInvalid = -1,
     kNone = 0,
     kGralloc,
     kNativeHandle,
     kANativeWindow,
     kCamera,
 )

 enum {
     kParamIndexVideoConfig = 0x1234,
 };

 struct C2VideoConfigStruct {
     int32_t width;
     uint32_t height;
     MetadataType metadataType;
     int32_t supportedFormats[];

     C2VideoConfigStruct() {}

     DEFINE_AND_DESCRIBE_FLEX_C2STRUCT(VideoConfig, supportedFormats)
     C2FIELD(width, "width")
     C2FIELD(height, "height")
     C2FIELD(metadataType, "metadata-type")
     C2FIELD(supportedFormats, "formats")
 };

 typedef C2PortParam<C2Tuning, C2VideoConfigStruct> C2VideoConfigPortTuning;

 class MyComponentInstance : public C2ComponentInterface {
 public:
     virtual C2String getName() const override {
         /// \todo this seems too specific
         return "sample.interface";
     };

     virtual c2_node_id_t getId() const override {
         /// \todo how are these shared?
         return 0;
     }

     virtual c2_status_t config_vb(
             const std::vector<C2Param*> &params,
             c2_blocking_t mayBlock,
             std::vector<std::unique_ptr<C2SettingResult>>* const failures) override {
         (void)params;
         (void)failures;
         (void)mayBlock;
         return C2_OMITTED;
     }

     virtual c2_status_t createTunnel_sm(c2_node_id_t targetComponent) override {
         (void)targetComponent;
         return C2_OMITTED;
     }

     virtual c2_status_t query_vb(
             const std::vector<C2Param*> &stackParams,
             const std::vector<C2Param::Index> &heapParamIndices,
             c2_blocking_t mayBlock,
             std::vector<std::unique_ptr<C2Param>>* const heapParams) const override {
         for (C2Param* const param : stackParams) {
             (void)mayBlock;
             if (!*param) { // param is already invalid - remember it
                 continue;
             }

             // note: this does not handle stream params (should use index...)
             if (!mMyParams.count(param->index())) {
                 continue; // not my param
             }

             C2Param & myParam = mMyParams.find(param->index())->second;
             if (myParam.size() != param->size()) { // incorrect size
                 param->invalidate();
                 continue;
             }

             param->updateFrom(myParam);
         }

         for (const C2Param::Index index : heapParamIndices) {
             if (mMyParams.count(index)) {
                 C2Param & myParam = mMyParams.find(index)->second;
                 std::unique_ptr<C2Param> paramCopy(C2Param::Copy(myParam));
                 heapParams->push_back(std::move(paramCopy));
             }
         }

         return C2_OK;
     }

     std::unordered_map<uint32_t, C2Param &> mMyParams;

     C2ComponentDomainSetting mDomainInfo;

     MyComponentInstance() {
         mMyParams.insert({mDomainInfo.index(), mDomainInfo});
     }

     virtual c2_status_t releaseTunnel_sm(c2_node_id_t targetComponent) override {
         (void)targetComponent;
         return C2_OMITTED;
     }

     class MyParamReflector : public C2ParamReflector {
         const MyComponentInstance *instance;

     public:
         MyParamReflector(const MyComponentInstance *i) : instance(i) { }

         virtual std::unique_ptr<C2StructDescriptor> describe(C2Param::CoreIndex paramIndex) const override {
             switch (paramIndex.typeIndex()) {
             case decltype(instance->mDomainInfo)::CORE_INDEX:
             default:
                 return std::unique_ptr<C2StructDescriptor>(new C2StructDescriptor{
                     instance->mDomainInfo.type(),
                     decltype(instance->mDomainInfo)::FieldList(),
                 });
             }
             return nullptr;
         }
     };

     virtual c2_status_t querySupportedValues_vb(
             std::vector<C2FieldSupportedValuesQuery> &fields,
             c2_blocking_t mayBlock) const override {
         (void)mayBlock;
         for (C2FieldSupportedValuesQuery &query : fields) {
             if (query.field() == C2ParamField(&mDomainInfo, &C2ComponentDomainSetting::value)) {
                 query.values = C2FieldSupportedValues(
                     false /* flag */,
                     &mDomainInfo.value
                     //,
                     //{(int32_t)C2Component::DOMAIN_VIDEO}
                 );
                 query.status = C2_OK;
             } else {
                 query.status = C2_BAD_INDEX;
             }
         }
         return C2_OK;
     }

     std::shared_ptr<C2ParamReflector> getParamReflector() const {
         return std::shared_ptr<C2ParamReflector>(new MyParamReflector(this));
     }

     virtual c2_status_t querySupportedParams_nb(
             std::vector<std::shared_ptr<C2ParamDescriptor>> * const params) const override {
         params->push_back(std::make_shared<C2ParamDescriptor>(
                 true /* required */, "_domain", &mDomainInfo));
         params->push_back(std::shared_ptr<C2ParamDescriptor>(
                 new C2ParamDescriptor(true /* required */, "_domain", &mDomainInfo)));
         return C2_OK;
     }

     virtual ~MyComponentInstance() override = default;
 };

 template<typename E, bool S=std::is_enum<E>::value>
 struct getter {
     int32_t get(const C2FieldSupportedValues::Primitive &p, int32_t*) {
         return p.i32;
     }
     int64_t get(const C2FieldSupportedValues::Primitive &p, int64_t*) {
         return p.i64;
     }
     uint32_t get(const C2FieldSupportedValues::Primitive &p, uint32_t*) {
         return p.u32;
     }
     uint64_t get(const C2FieldSupportedValues::Primitive &p, uint64_t*) {
         return p.u64;
     }
     float get(const C2FieldSupportedValues::Primitive &p, float*) {
         return p.fp;
     }
 };

 template<typename E>
 struct getter<E, true> {
      typename std::underlying_type<E>::type get(const C2FieldSupportedValues::Primitive &p, E*) {
          using u=typename std::underlying_type<E>::type;
          return getter<u>().get(p, (u*)0);
      }
 };

 template<typename T, bool E=std::is_enum<T>::value>
 struct lax_underlying_type {
     typedef typename std::underlying_type<T>::type type;
 };

 template<typename T>
 struct lax_underlying_type<T, false> {
     typedef T type;
 };

 template<typename E>
 typename lax_underlying_type<E>::type get(
         const C2FieldSupportedValues::Primitive &p, E*) {
     return getter<E>().get(p, (E*)0);
 }

 template<typename T>
 void dumpFSV(const C2FieldSupportedValues &sv, T*t) {
     using namespace std;
     cout << (std::is_enum<T>::value ? (std::is_signed<typename lax_underlying_type<T>::type>::value ? "i" : "u")
              : std::is_integral<T>::value ? std::is_signed<T>::value ? "i" : "u" : "f")
          << (8 * sizeof(T));
     if (sv.type == sv.RANGE) {
         cout << ".range(" << get(sv.range.min, t);
         if (get(sv.range.step, t) != std::is_integral<T>::value) {
             cout << ":" << get(sv.range.step, t);
         }
         if (get(sv.range.num, t) != 1 || get(sv.range.denom, t) != 1) {
             cout << ":" << get(sv.range.num, t) << "/" << get(sv.range.denom, t);
         }
         cout << get(sv.range.max, t) << ")";
     }
     if (sv.values.size()) {
         cout << (sv.type == sv.FLAGS ? ".flags(" : ".list(");
         const char *sep = "";
         for (const C2FieldSupportedValues::Primitive &p : sv.values) {
             cout << sep << get(p, t);
             sep = ",";
         }
         cout << ")";
     }
     cout << endl;
 }

 void dumpType(C2Param::Type type) {
     using namespace std;
     cout << (type.isVendor() ? "Vendor" : "C2");
     if (type.forInput()) {
         cout << "Input";
     } else if (type.forOutput()) {
         cout << "Output";
     } else if (type.forPort() && !type.forStream()) {
         cout << "Port";
     }
     if (type.forStream()) {
         cout << "Stream";
     }

     if (type.isFlexible()) {
         cout << "Flex";
     }

     cout << type.typeIndex();

     switch (type.kind()) {
     case C2Param::INFO: cout << "Info"; break;
     case C2Param::SETTING: cout << "Setting"; break;
     case C2Param::TUNING: cout << "Tuning"; break;
     case C2Param::STRUCT: cout << "Struct"; break;
     default: cout << "Kind" << (int32_t)type.kind(); break;
     }
 }

 void dumpType(C2Param::CoreIndex type) {
     using namespace std;
     cout << (type.isVendor() ? "Vendor" : "C2");
     if (type.isFlexible()) {
         cout << "Flex";
     }

     cout << type.typeIndex() << "Struct";
 }

 void dumpType(C2FieldDescriptor::type_t type) {
     using namespace std;
     switch (type) {
     case C2FieldDescriptor::BLOB: cout << "blob "; break;
     case C2FieldDescriptor::FLOAT: cout << "float "; break;
     case C2FieldDescriptor::INT32: cout << "int32_t "; break;
     case C2FieldDescriptor::INT64: cout << "int64_t "; break;
     case C2FieldDescriptor::UINT32: cout << "uint32_t "; break;
     case C2FieldDescriptor::UINT64: cout << "uint64_t "; break;
     case C2FieldDescriptor::STRING: cout << "char "; break;
     default:
         cout << "struct ";
         dumpType((C2Param::Type)type);
         break;
     }
 }

 void dumpStruct(const C2StructDescriptor &sd) {
     using namespace std;
     cout << "struct ";
     dumpType(sd.coreIndex());
     cout << " {" << endl;
     //C2FieldDescriptor &f;
     for (const C2FieldDescriptor &f : sd) {
         PrintTo(f, &cout);
         cout << endl;

         if (f.namedValues().size()) {
             cout << ".named(";
             const char *sep = "";
             for (const C2FieldDescriptor::NamedValueType &p : f.namedValues()) {
                 cout << sep << p.first << "=";
                 switch (f.type()) {
                 case C2FieldDescriptor::INT32: cout << get(p.second, (int32_t *)0); break;
                 case C2FieldDescriptor::INT64: cout << get(p.second, (int64_t *)0); break;
                 case C2FieldDescriptor::UINT32: cout << get(p.second, (uint32_t *)0); break;
                 case C2FieldDescriptor::UINT64: cout << get(p.second, (uint64_t *)0); break;
                 case C2FieldDescriptor::FLOAT: cout << get(p.second, (float *)0); break;
                 default: cout << "???"; break;
                 }
                 sep = ",";
             }
             cout << ")";
         }
     }

     cout << "};" << endl;
 }

 void dumpDesc(const C2ParamDescriptor &pd) {
     using namespace std;
     if (pd.isRequired()) {
         cout << "required ";
     }
     if (pd.isPersistent()) {
         cout << "persistent ";
     }
     cout << "struct ";
     dumpType(C2Param::Type(pd.index().type()));
     cout << " " << pd.name() << ";" << endl;
 }

 TEST_F(C2SampleComponentTest, ReflectorTest) {
     C2ComponentDomainSetting domainInfo;
     std::shared_ptr<MyComponentInstance> myComp(new MyComponentInstance);
     std::shared_ptr<C2ComponentInterface> comp = myComp;

     std::unique_ptr<C2StructDescriptor> desc{
         myComp->getParamReflector()->describe(C2ComponentDomainSetting::CORE_INDEX)};
     dumpStruct(*desc);

     std::vector<C2FieldSupportedValuesQuery> query = {
         { C2ParamField(&domainInfo, &C2ComponentDomainSetting::value),
           C2FieldSupportedValuesQuery::CURRENT },
         C2FieldSupportedValuesQuery(C2ParamField(&domainInfo, &C2ComponentDomainSetting::value),
           C2FieldSupportedValuesQuery::CURRENT),
         C2FieldSupportedValuesQuery::Current(C2ParamField(&domainInfo, &C2ComponentDomainSetting::value)),
     };

     EXPECT_EQ(C2_OK, comp->querySupportedValues_vb(query, C2_DONT_BLOCK));

     for (const C2FieldSupportedValuesQuery &q : query) {
         dumpFSV(q.values, &domainInfo.value);
     }
 }

 TEST_F(C2SampleComponentTest, FieldSupportedValuesTest) {
     typedef C2GlobalParam<C2Info, C2Uint32Value, 0> Uint32TestInfo;
     Uint32TestInfo t;
     std::vector<C2FieldSupportedValues> values;
     values.push_back(C2FieldSupportedValues(0, 10, 1));  // min, max, step
     values.push_back(C2FieldSupportedValues(1, 64, 2, 1));  // min, max, num, den
     values.push_back(C2FieldSupportedValues(false, {1, 2, 3}));  // flags, std::initializer_list
     uint32_t val[] = {1, 3, 5, 7};
     std::vector<uint32_t> v(std::begin(val), std::end(val));
     values.push_back(C2FieldSupportedValues(false, v));  // flags, std::vector

     for (const C2FieldSupportedValues &sv : values) {
         dumpFSV(sv, &t.value);
     }
 }
	/*
	* Copyright 2014 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_NDEBUG 0
	#define LOG_TAG "C2SampleComponent_test"

	#include <gtest/gtest.h>

	#define __C2_GENERATE_GLOBAL_VARS__
	#include <C2Component.h>
	#include <C2Config.h>
	#include <C2Debug.h>
	#include <C2Enum.h>

	#include <unordered_map>

	class C2SampleComponentTest : public ::testing::Test {
	};

	void PrintTo(const C2FieldDescriptor &fd, ::std::ostream *os) {
	using FD=C2FieldDescriptor;
	switch (fd.type()) {
	case FD::INT32: *os << "i32"; break;
	case FD::INT64: *os << "i64"; break;
	case FD::UINT32: *os << "u32"; break;
	case FD::UINT64: *os << "u64"; break;
	case FD::FLOAT: *os << "float"; break;
	case FD::STRING: *os << "char"; break;
	case FD::BLOB: *os << "u8"; break;
	default:
	if (fd.type() & FD::STRUCT_FLAG) {
	*os << "struct-" << (fd.type() & ~FD::STRUCT_FLAG);
	} else {
	*os << "type-" << fd.type();
	}
	}
	*os << " " << fd.name();
	if (fd.extent() > 1) {
	*os << "[" << fd.extent() << "]";
	} else if (fd.extent() == 0) {
	*os << "[]";
	}
	os << " (" << fd._mFieldId << "" << fd.extent() << ")";
	}

	C2ENUM(
	MetadataType, int32_t,
	kInvalid = -1,
	kNone = 0,
	kGralloc,
	kNativeHandle,
	kANativeWindow,
	kCamera,
	)

	enum {
	kParamIndexVideoConfig = 0x1234,
	};

	struct C2VideoConfigStruct {
	int32_t width;
	uint32_t height;
	MetadataType metadataType;
	int32_t supportedFormats[];

	C2VideoConfigStruct() {}

	DEFINE_AND_DESCRIBE_FLEX_C2STRUCT(VideoConfig, supportedFormats)
	C2FIELD(width, "width")
	C2FIELD(height, "height")
	C2FIELD(metadataType, "metadata-type")
	C2FIELD(supportedFormats, "formats")
	};

	typedef C2PortParam<C2Tuning, C2VideoConfigStruct> C2VideoConfigPortTuning;

	class MyComponentInstance : public C2ComponentInterface {
	public:
	virtual C2String getName() const override {
	/// \todo this seems too specific
	return "sample.interface";
	};

	virtual c2_node_id_t getId() const override {
	/// \todo how are these shared?
	return 0;
	}

	virtual c2_status_t config_vb(
	const std::vector<C2Param*> &params,
	c2_blocking_t mayBlock,
	std::vector<std::unique_ptr<C2SettingResult>>* const failures) override {
	(void)params;
	(void)failures;
	(void)mayBlock;
	return C2_OMITTED;
	}

	virtual c2_status_t createTunnel_sm(c2_node_id_t targetComponent) override {
	(void)targetComponent;
	return C2_OMITTED;
	}

	virtual c2_status_t query_vb(
	const std::vector<C2Param*> &stackParams,
	const std::vector<C2Param::Index> &heapParamIndices,
	c2_blocking_t mayBlock,
	std::vector<std::unique_ptr<C2Param>>* const heapParams) const override {
	for (C2Param* const param : stackParams) {
	(void)mayBlock;
	if (!*param) { // param is already invalid - remember it
	continue;
	}

	// note: this does not handle stream params (should use index...)
	if (!mMyParams.count(param->index())) {
	continue; // not my param
	}

	C2Param & myParam = mMyParams.find(param->index())->second;
	if (myParam.size() != param->size()) { // incorrect size
	param->invalidate();
	continue;
	}

	param->updateFrom(myParam);
	}

	for (const C2Param::Index index : heapParamIndices) {
	if (mMyParams.count(index)) {
	C2Param & myParam = mMyParams.find(index)->second;
	std::unique_ptr<C2Param> paramCopy(C2Param::Copy(myParam));
	heapParams->push_back(std::move(paramCopy));
	}
	}

	return C2_OK;
	}

	std::unordered_map<uint32_t, C2Param &> mMyParams;

	C2ComponentDomainSetting mDomainInfo;

	MyComponentInstance() {
	mMyParams.insert({mDomainInfo.index(), mDomainInfo});
	}

	virtual c2_status_t releaseTunnel_sm(c2_node_id_t targetComponent) override {
	(void)targetComponent;
	return C2_OMITTED;
	}

	class MyParamReflector : public C2ParamReflector {
	const MyComponentInstance *instance;

	public:
	MyParamReflector(const MyComponentInstance *i) : instance(i) { }

	virtual std::unique_ptr<C2StructDescriptor> describe(C2Param::CoreIndex paramIndex) const override {
	switch (paramIndex.typeIndex()) {
	case decltype(instance->mDomainInfo)::CORE_INDEX:
	default:
	return std::unique_ptr<C2StructDescriptor>(new C2StructDescriptor{
	instance->mDomainInfo.type(),
	decltype(instance->mDomainInfo)::FieldList(),
	});
	}
	return nullptr;
	}
	};

	virtual c2_status_t querySupportedValues_vb(
	std::vector<C2FieldSupportedValuesQuery> &fields,
	c2_blocking_t mayBlock) const override {
	(void)mayBlock;
	for (C2FieldSupportedValuesQuery &query : fields) {
	if (query.field() == C2ParamField(&mDomainInfo, &C2ComponentDomainSetting::value)) {
	query.values = C2FieldSupportedValues(
	false /* flag */,
	&mDomainInfo.value
	//,
	//{(int32_t)C2Component::DOMAIN_VIDEO}
	);
	query.status = C2_OK;
	} else {
	query.status = C2_BAD_INDEX;
	}
	}
	return C2_OK;
	}

	std::shared_ptr<C2ParamReflector> getParamReflector() const {
	return std::shared_ptr<C2ParamReflector>(new MyParamReflector(this));
	}

	virtual c2_status_t querySupportedParams_nb(
	std::vector<std::shared_ptr<C2ParamDescriptor>> * const params) const override {
	params->push_back(std::make_shared<C2ParamDescriptor>(
	true /* required */, "_domain", &mDomainInfo));
	params->push_back(std::shared_ptr<C2ParamDescriptor>(
	new C2ParamDescriptor(true /* required */, "_domain", &mDomainInfo)));
	return C2_OK;
	}

	virtual ~MyComponentInstance() override = default;
	};

	template<typename E, bool S=std::is_enum<E>::value>
	struct getter {
	int32_t get(const C2FieldSupportedValues::Primitive &p, int32_t*) {
	return p.i32;
	}
	int64_t get(const C2FieldSupportedValues::Primitive &p, int64_t*) {
	return p.i64;
	}
	uint32_t get(const C2FieldSupportedValues::Primitive &p, uint32_t*) {
	return p.u32;
	}
	uint64_t get(const C2FieldSupportedValues::Primitive &p, uint64_t*) {
	return p.u64;
	}
	float get(const C2FieldSupportedValues::Primitive &p, float*) {
	return p.fp;
	}
	};

	template<typename E>
	struct getter<E, true> {
	typename std::underlying_type<E>::type get(const C2FieldSupportedValues::Primitive &p, E*) {
	using u=typename std::underlying_type<E>::type;
	return getter<u>().get(p, (u*)0);
	}
	};

	template<typename T, bool E=std::is_enum<T>::value>
	struct lax_underlying_type {
	typedef typename std::underlying_type<T>::type type;
	};

	template<typename T>
	struct lax_underlying_type<T, false> {
	typedef T type;
	};

	template<typename E>
	typename lax_underlying_type<E>::type get(
	const C2FieldSupportedValues::Primitive &p, E*) {
	return getter<E>().get(p, (E*)0);
	}

	template<typename T>
	void dumpFSV(const C2FieldSupportedValues &sv, T*t) {
	using namespace std;
	cout << (std::is_enum<T>::value ? (std::is_signed<typename lax_underlying_type<T>::type>::value ? "i" : "u")
	: std::is_integral<T>::value ? std::is_signed<T>::value ? "i" : "u" : "f")
	<< (8 * sizeof(T));
	if (sv.type == sv.RANGE) {
	cout << ".range(" << get(sv.range.min, t);
	if (get(sv.range.step, t) != std::is_integral<T>::value) {
	cout << ":" << get(sv.range.step, t);
	}
	if (get(sv.range.num, t) != 1 \|\| get(sv.range.denom, t) != 1) {
	cout << ":" << get(sv.range.num, t) << "/" << get(sv.range.denom, t);
	}
	cout << get(sv.range.max, t) << ")";
	}
	if (sv.values.size()) {
	cout << (sv.type == sv.FLAGS ? ".flags(" : ".list(");
	const char *sep = "";
	for (const C2FieldSupportedValues::Primitive &p : sv.values) {
	cout << sep << get(p, t);
	sep = ",";
	}
	cout << ")";
	}
	cout << endl;
	}

	void dumpType(C2Param::Type type) {
	using namespace std;
	cout << (type.isVendor() ? "Vendor" : "C2");
	if (type.forInput()) {
	cout << "Input";
	} else if (type.forOutput()) {
	cout << "Output";
	} else if (type.forPort() && !type.forStream()) {
	cout << "Port";
	}
	if (type.forStream()) {
	cout << "Stream";
	}

	if (type.isFlexible()) {
	cout << "Flex";
	}

	cout << type.typeIndex();

	switch (type.kind()) {
	case C2Param::INFO: cout << "Info"; break;
	case C2Param::SETTING: cout << "Setting"; break;
	case C2Param::TUNING: cout << "Tuning"; break;
	case C2Param::STRUCT: cout << "Struct"; break;
	default: cout << "Kind" << (int32_t)type.kind(); break;
	}
	}

	void dumpType(C2Param::CoreIndex type) {
	using namespace std;
	cout << (type.isVendor() ? "Vendor" : "C2");
	if (type.isFlexible()) {
	cout << "Flex";
	}

	cout << type.typeIndex() << "Struct";
	}

	void dumpType(C2FieldDescriptor::type_t type) {
	using namespace std;
	switch (type) {
	case C2FieldDescriptor::BLOB: cout << "blob "; break;
	case C2FieldDescriptor::FLOAT: cout << "float "; break;
	case C2FieldDescriptor::INT32: cout << "int32_t "; break;
	case C2FieldDescriptor::INT64: cout << "int64_t "; break;
	case C2FieldDescriptor::UINT32: cout << "uint32_t "; break;
	case C2FieldDescriptor::UINT64: cout << "uint64_t "; break;
	case C2FieldDescriptor::STRING: cout << "char "; break;
	default:
	cout << "struct ";
	dumpType((C2Param::Type)type);
	break;
	}
	}

	void dumpStruct(const C2StructDescriptor &sd) {
	using namespace std;
	cout << "struct ";
	dumpType(sd.coreIndex());
	cout << " {" << endl;
	//C2FieldDescriptor &f;
	for (const C2FieldDescriptor &f : sd) {
	PrintTo(f, &cout);
	cout << endl;

	if (f.namedValues().size()) {
	cout << ".named(";
	const char *sep = "";
	for (const C2FieldDescriptor::NamedValueType &p : f.namedValues()) {
	cout << sep << p.first << "=";
	switch (f.type()) {
	case C2FieldDescriptor::INT32: cout << get(p.second, (int32_t *)0); break;
	case C2FieldDescriptor::INT64: cout << get(p.second, (int64_t *)0); break;
	case C2FieldDescriptor::UINT32: cout << get(p.second, (uint32_t *)0); break;
	case C2FieldDescriptor::UINT64: cout << get(p.second, (uint64_t *)0); break;
	case C2FieldDescriptor::FLOAT: cout << get(p.second, (float *)0); break;
	default: cout << "???"; break;
	}
	sep = ",";
	}
	cout << ")";
	}
	}

	cout << "};" << endl;
	}

	void dumpDesc(const C2ParamDescriptor &pd) {
	using namespace std;
	if (pd.isRequired()) {
	cout << "required ";
	}
	if (pd.isPersistent()) {
	cout << "persistent ";
	}
	cout << "struct ";
	dumpType(C2Param::Type(pd.index().type()));
	cout << " " << pd.name() << ";" << endl;
	}

	TEST_F(C2SampleComponentTest, ReflectorTest) {
	C2ComponentDomainSetting domainInfo;
	std::shared_ptr<MyComponentInstance> myComp(new MyComponentInstance);
	std::shared_ptr<C2ComponentInterface> comp = myComp;

	std::unique_ptr<C2StructDescriptor> desc{
	myComp->getParamReflector()->describe(C2ComponentDomainSetting::CORE_INDEX)};
	dumpStruct(*desc);

	std::vector<C2FieldSupportedValuesQuery> query = {
	{ C2ParamField(&domainInfo, &C2ComponentDomainSetting::value),
	C2FieldSupportedValuesQuery::CURRENT },
	C2FieldSupportedValuesQuery(C2ParamField(&domainInfo, &C2ComponentDomainSetting::value),
	C2FieldSupportedValuesQuery::CURRENT),
	C2FieldSupportedValuesQuery::Current(C2ParamField(&domainInfo, &C2ComponentDomainSetting::value)),
	};

	EXPECT_EQ(C2_OK, comp->querySupportedValues_vb(query, C2_DONT_BLOCK));

	for (const C2FieldSupportedValuesQuery &q : query) {
	dumpFSV(q.values, &domainInfo.value);
	}
	}

	TEST_F(C2SampleComponentTest, FieldSupportedValuesTest) {
	typedef C2GlobalParam<C2Info, C2Uint32Value, 0> Uint32TestInfo;
	Uint32TestInfo t;
	std::vector<C2FieldSupportedValues> values;
	values.push_back(C2FieldSupportedValues(0, 10, 1)); // min, max, step
	values.push_back(C2FieldSupportedValues(1, 64, 2, 1)); // min, max, num, den
	values.push_back(C2FieldSupportedValues(false, {1, 2, 3})); // flags, std::initializer_list
	uint32_t val[] = {1, 3, 5, 7};
	std::vector<uint32_t> v(std::begin(val), std::end(val));
	values.push_back(C2FieldSupportedValues(false, v)); // flags, std::vector

	for (const C2FieldSupportedValues &sv : values) {
	dumpFSV(sv, &t.value);
	}
	}