renderscript/1.0/vts/functional/VtsCopyTests.cpp - LeafOS-Project/android_hardware_interfaces - Gitiles

 /*
  * Copyright (C) 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.
 */

 #include "VtsHalRenderscriptV1_0TargetTest.h"

 /*
  * This test creates a 1D Allocation with 128 Float Elements, and two float
  * vector dataIn & dataOut. dataIn is pre-populated with data, and copied into
  * the Allocation using allocation1DWrite. Then the Allocation is copied into
  * dataOut with allocation1DRead.
  *
  * Calls: elementCreate, typeCreate, allocationCreateTyped, allocation1DWrite,
  * allocation1DRead
  *
  * Expect: dataIn & dataOut are the same.
  */
 TEST_P(RenderscriptHidlTest, Simple1DCopyTest) {
     // float1
     Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
     ASSERT_NE(Element(0), element);

     // 128 x float1
     Type type = context->typeCreate(element, 128, 0, 0, false, false, YuvFormat::YUV_NONE);
     ASSERT_NE(Type(0), type);

     // 128 x float1
     Allocation allocation = context->allocationCreateTyped(type, AllocationMipmapControl::NONE,
                                                            (int)AllocationUsageType::SCRIPT,
                                                            (Ptr)nullptr);
     ASSERT_NE(Allocation(0), allocation);

     std::vector<float> dataIn(128), dataOut(128);
     std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
     hidl_vec<uint8_t> _data;
     _data.setToExternal((uint8_t*)dataIn.data(), dataIn.size()*sizeof(float));
     context->allocation1DWrite(allocation, 0, 0, (Size)dataIn.size(), _data);
     context->allocation1DRead(allocation, 0, 0, (uint32_t)dataOut.size(), (Ptr)dataOut.data(),
                               (Size)dataOut.size()*sizeof(float));
     EXPECT_EQ(dataIn, dataOut);
 }

 /*
  * This test creates a 2D Allocation with 128 * 128 Float Elements, and two
  * float vector dataIn & dataOut. dataIn is pre-populated with data, and copied
  * into the Allocation using allocation2DWrite. Then the Allocation is copied
  * into dataOut with allocation2DRead.
  *
  * Calls: elementCreate, typeCreate, allocationCreateTyped, allocation2DWrite,
  * allocation2DRead
  *
  * Expect: dataIn & dataOut are the same.
  */
 TEST_P(RenderscriptHidlTest, Simple2DCopyTest) {
     // float1
     Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
     ASSERT_NE(Element(0), element);

     // 128 x 128 x float1
     Type type = context->typeCreate(element, 128, 128, 0, false, false, YuvFormat::YUV_NONE);
     ASSERT_NE(Type(0), type);

     // 128 x 128 x float1
     Allocation allocation = context->allocationCreateTyped(type, AllocationMipmapControl::NONE,
                                                            (int)AllocationUsageType::SCRIPT,
                                                            (Ptr)nullptr);
     ASSERT_NE(Allocation(0), allocation);

     std::vector<float> dataIn(128*128), dataOut(128*128);
     std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
     hidl_vec<uint8_t> _data;
     _data.setToExternal((uint8_t*)dataIn.data(), dataIn.size()*sizeof(float));
     context->allocation2DWrite(allocation, 0, 0, 0, AllocationCubemapFace::POSITIVE_X, 128, 128,
                                _data, 0);
     context->allocation2DRead(allocation, 0, 0, 0, AllocationCubemapFace::POSITIVE_X, 128, 128,
                               (Ptr)dataOut.data(), (Size)dataOut.size()*sizeof(float), 0);
     EXPECT_EQ(dataIn, dataOut);
 }

 /*
  * This test creates a 3D Allocation with 32 * 32 * 32 Float Elements, and two
  * float vector dataIn & dataOut. dataIn is pre-populated with data, and copied
  * into the Allocation using allocation3DWrite. Then the Allocation is copied
  * into dataOut with allocation3DRead.
  *
  * Calls: elementCreate, typeCreate, allocationCreateTyped, allocation3DWrite,
  * allocation3DRead
  *
  * Expect: dataIn & dataOut are the same.
  */
 TEST_P(RenderscriptHidlTest, Simple3DCopyTest) {
     // float1
     Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
     ASSERT_NE(Element(0), element);

     // 32 x 32 x 32 x float1
     Type type = context->typeCreate(element, 32, 32, 32, false, false, YuvFormat::YUV_NONE);
     ASSERT_NE(Type(0), type);

     // 32 x 32 x 32 x float1
     Allocation allocation = context->allocationCreateTyped(type, AllocationMipmapControl::NONE,
                                                            (int)AllocationUsageType::SCRIPT,
                                                            (Ptr)nullptr);
     ASSERT_NE(Allocation(0), allocation);

     std::vector<float> dataIn(32*32*32), dataOut(32*32*32);
     std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
     hidl_vec<uint8_t> _data;
     _data.setToExternal((uint8_t*)dataIn.data(), dataIn.size()*sizeof(float));
     context->allocation3DWrite(allocation, 0, 0, 0, 0, 32, 32, 32, _data, 0);
     context->allocation3DRead(allocation, 0, 0, 0, 0, 32, 32, 32, (Ptr)dataOut.data(),
                               (Size)dataOut.size()*sizeof(float), 0);
     EXPECT_EQ(dataIn, dataOut);
 }

 /*
  * This test creates a 2D Allocation with 512 * 512 Float Elements with
  * allocationCreateFromBitmap, and two float vector dataIn & dataOut. dataIn is
  * pre-populated with data, and copied into the Allocation using
  * allocationCopyToBitmap. Then the Allocation is copied into dataOut with
  * allocationRead.
  *
  * Calls: elementCreate, typeCreate, allocationCreateFromBitmap,
  * allocationCopyToBitmap, allocationRead
  *
  * Expect: dataIn & dataOut are the same.
  */
 TEST_P(RenderscriptHidlTest, SimpleBitmapTest) {
     // float1
     Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
     ASSERT_NE(Element(0), element);

     // 512 x 512 x float1
     Type type = context->typeCreate(element, 512, 512, 0, false, false, YuvFormat::YUV_NONE);
     ASSERT_NE(Type(0), type);

     std::vector<float> dataIn(512*512), dataOut1(512*512), dataOut2(512*512);
     std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
     hidl_vec<uint8_t> _data;
     _data.setToExternal((uint8_t*)dataIn.data(), dataIn.size()*sizeof(float));
     // 512 x 512 x float1
     Allocation allocation = context->allocationCreateFromBitmap(type,
                                                                 AllocationMipmapControl::NONE,
                                                                 _data,
                                                                 (int)AllocationUsageType::SCRIPT);
     ASSERT_NE(Allocation(0), allocation);

     context->allocationCopyToBitmap(allocation, (Ptr)dataOut1.data(),
                                     (Size)dataOut1.size()*sizeof(float));
     EXPECT_EQ(dataIn, dataOut1);

     context->allocationRead(allocation, (Ptr)dataOut2.data(), (Size)dataOut2.size()*sizeof(float));
     EXPECT_EQ(dataIn, dataOut2);
 }

 /*
  * This test creates two 2D Allocations, one with 512 * 512 Float Elements, the
  * other with 256 * 256 Float Elements. The larger Allocation is pre-populated
  * with dataIn, and copied into the smaller Allocation using
  * allocationCopy2DRange. Then the Allocation is copied into dataOut with
  * allocationRead.
  *
  * Calls: elementCreate, typeCreate, allocationCreateFromBitmap,
  * allocationCreateTyped, allocationCopy2DRange, allocationRead
  *
  * Expect: dataIn & dataOut are the same.
  */
 TEST_P(RenderscriptHidlTest, AllocationCopy2DRangeTest) {
     // float1
     Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
     ASSERT_NE(Element(0), element);

     // 512 x 512 x float1
     Type typeSrc = context->typeCreate(element, 512, 512, 0, false, false, YuvFormat::YUV_NONE);
     ASSERT_NE(Type(0), typeSrc);

     // 256 x 256 x float1
     Type typeDst = context->typeCreate(element, 256, 256, 0, false, false, YuvFormat::YUV_NONE);
     ASSERT_NE(Type(0), typeDst);

     std::vector<float> dataIn(512*512), dataOut(256*256), expected(256*256);
     std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
     hidl_vec<uint8_t> _data;
     _data.setToExternal((uint8_t*)dataIn.data(), dataIn.size()*sizeof(float));
     // 512 x 512 x float1
     Allocation allocSrc = context->allocationCreateFromBitmap(typeSrc,
                                                               AllocationMipmapControl::NONE, _data,
                                                               (int)AllocationUsageType::SCRIPT);
     ASSERT_NE(Allocation(0), allocSrc);

     // 256 x 256 x float1
     Allocation allocDst = context->allocationCreateTyped(typeDst, AllocationMipmapControl::NONE,
                                                          (int)AllocationUsageType::SCRIPT,
                                                          (Ptr)nullptr);
     ASSERT_NE(Allocation(0), allocDst);

     context->allocationCopy2DRange(allocDst, 0, 0, 0, AllocationCubemapFace::POSITIVE_X, 256, 256,
                                    allocSrc, 128, 128, 0, AllocationCubemapFace::POSITIVE_X);
     context->allocationRead(allocDst, (Ptr)dataOut.data(), (Size)dataOut.size()*sizeof(float));
     for (int i = 0; i < 256; ++i) {
         for (int j = 0; j < 256; ++j) {
             expected[i*256 + j] = dataIn[(i+128)*512 + (j+128)];
         }
     }
     EXPECT_EQ(expected, dataOut);
 }

 /*
  * This test creates two 3D Allocations, one with 128 * 128 * 128 Float
  * Elements, the other with 64 * 64 * 64 Float Elements. The larger Allocation
  * is pre-populated with dataIn, and copied into the smaller Allocation using
  * allocationCopy3DRange. Then the Allocation is copied into dataOut with
  * allocationRead.
  *
  * Calls: elementCreate, typeCreate, allocationCreateTyped, allocation3DWrite,
  * allocationCopy3DRange, allocationRead
  *
  * Expect: dataIn & dataOut are the same.
  */
 TEST_P(RenderscriptHidlTest, AllocationCopy3DRangeTest) {
     // float1
     Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
     ASSERT_NE(Element(0), element);

     // 128 x 128 x 128 x float1
     Type typeSrc = context->typeCreate(element, 128, 128, 128, false, false, YuvFormat::YUV_NONE);
     ASSERT_NE(Type(0), typeSrc);

     // 64 x 64 x 64 x float1
     Type typeDst = context->typeCreate(element, 64, 64, 64, false, false, YuvFormat::YUV_NONE);
     ASSERT_NE(Type(0), typeDst);

     std::vector<float> dataIn(128*128*128), dataOut(64*64*64), expected(64*64*64);
     std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
     hidl_vec<uint8_t> _data;
     _data.setToExternal((uint8_t*)dataIn.data(), dataIn.size()*sizeof(float));
     // 512 x 512 x float1
     Allocation allocSrc = context->allocationCreateTyped(typeSrc, AllocationMipmapControl::NONE,
                                                          (int)AllocationUsageType::SCRIPT,
                                                          (Ptr)nullptr);
     ASSERT_NE(Allocation(0), allocSrc);

     // 256 x 256 x float1
     Allocation allocDst = context->allocationCreateTyped(typeDst, AllocationMipmapControl::NONE,
                                                          (int)AllocationUsageType::SCRIPT,
                                                          (Ptr)nullptr);
     ASSERT_NE(Allocation(0), allocDst);

     context->allocation3DWrite(allocSrc, 0, 0, 0, 0, 128, 128, 128, _data, 128*sizeof(float));
     context->allocationCopy3DRange(allocDst, 0, 0, 0, 0, 64, 64, 64, allocSrc, 32, 32, 32, 0);
     context->allocationRead(allocDst, (Ptr)dataOut.data(), (Size)dataOut.size()*sizeof(float));
     for (int i = 0; i < 64; ++i) {
         for (int j = 0; j < 64; ++j) {
             for (int k = 0; k < 64; ++k) {
                 expected[i*64*64 + j*64 + k] = dataIn[(i+32)*128*128 + (j+32)*128 + (k+32)];
             }
         }
     }
     EXPECT_EQ(expected, dataOut);
 }

 /*
  * This test creates one 2D Allocations, one with 512 * 512 Float Elements, and
  * one 2D AllocationAdapter with a window of 256 * 256 based on the Allocation.
  * The Allocation is pre-populated with dataIn. Then the Allocation is copied
  * into dataOut with allocationRead on the AllocationAdapter.
  *
  * Calls: elementCreate, typeCreate, allocationCreateFromBitmap,
  * allocationAdapterCreate, allocationAdapterOffset, allocation2DRead
  *
  * Expect: dataIn & dataOut are the same.
  */
 TEST_P(RenderscriptHidlTest, SimpleAdapterTest) {
     // float1
     Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
     ASSERT_NE(Element(0), element);

     // 512 x 512 x float1
     Type type = context->typeCreate(element, 512, 512, 0, false, false, YuvFormat::YUV_NONE);
     ASSERT_NE(Type(0), type);

     std::vector<float> dataIn(512*512), dataOut(256*256), expected;
     std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
     hidl_vec<uint8_t> _data;
     _data.setToExternal((uint8_t*)dataIn.data(), dataIn.size()*sizeof(float));
     // 512 x 512 x float1
     Allocation allocation = context->allocationCreateFromBitmap(type,
                                                                 AllocationMipmapControl::NONE,
                                                                 _data,
                                                                 (int)AllocationUsageType::SCRIPT);
     ASSERT_NE(Allocation(0), allocation);

     // 256 x 256 x float1
     Type subType = context->typeCreate(element, 256, 256, 0, false, false, YuvFormat::YUV_NONE);
     ASSERT_NE(Type(0), subType);

     // 256 x 256 x float1
     AllocationAdapter allocationAdapter = context->allocationAdapterCreate(subType, allocation);
     ASSERT_NE(AllocationAdapter(0), allocationAdapter);

     std::vector<uint32_t> offsets(9, 0);
     offsets[0] = 128;
     offsets[1] = 128;
     hidl_vec<uint32_t> _offsets;
     _offsets.setToExternal(offsets.data(), offsets.size());
     // origin at (128,128)
     context->allocationAdapterOffset(allocationAdapter, _offsets);

     context->allocation2DRead(allocationAdapter, 0, 0, 0, AllocationCubemapFace::POSITIVE_X, 256,
                               256, (Ptr)dataOut.data(), (Size)dataOut.size()*sizeof(float), 0);
     for (int i = 128; i < 128 + 256; ++i) {
         for (int j = 128; j < 128 + 256; ++j) {
             expected.push_back(i * 512 + j);
         }
     }
     EXPECT_EQ(expected, dataOut);
 }

 /*
  * This test creates one 2D Allocations, one with 64 * 64 USIGNED_8 Elements,
  * and with AllocationMipmapControl::FULL. The Allocation is pre-populated with
  * dataIn and the mipmaps are filled with allocationGenerateMipmaps. Then
  * dataOut is then overridden with allocation2DRead.
  *
  * Calls: elementCreate, typeCreate, allocationCreateTyped, allocation2DWrite,
  * allocationGenerateMipmaps, allocationSyncAll, allocation2DRead
  *
  * Expect: dataIn & dataOut are the same.
  */
 TEST_P(RenderscriptHidlTest, SimpleMipmapTest) {
     // uint8_t
     Element element = context->elementCreate(DataType::UNSIGNED_8, DataKind::USER, false, 1);
     ASSERT_NE(Element(0), element);

     // 64 x 64 x uint8_t
     Type type = context->typeCreate(element, 64, 64, 0, true, false, YuvFormat::YUV_NONE);
     ASSERT_NE(Type(0), type);

     std::vector<uint8_t> dataIn(64*64), dataOut(32*32), expected(32*32);
     std::generate(dataIn.begin(), dataIn.end(),
                   [](){ static int val = 0; return (uint8_t)(0xFF & val++); });
     hidl_vec<uint8_t> _data;
     _data.setToExternal((uint8_t*)dataIn.data(), dataIn.size()*sizeof(uint8_t));
     // 64 x 64 x uint8_t
     Allocation allocation = context->allocationCreateTyped(type, AllocationMipmapControl::FULL,
                                                          (int)AllocationUsageType::SCRIPT,
                                                          (Ptr)nullptr);
     ASSERT_NE(Allocation(0), allocation);

     context->allocation2DWrite(allocation, 0, 0, 0, AllocationCubemapFace::POSITIVE_X, 64, 64,
                                _data, 64*sizeof(uint8_t));
     context->allocationGenerateMipmaps(allocation);
     context->allocationSyncAll(allocation, AllocationUsageType::SCRIPT);
     context->allocation2DRead(allocation, 0, 0, 1, AllocationCubemapFace::POSITIVE_X, 32, 32,
                               (Ptr)dataOut.data(), (Size)dataOut.size()*sizeof(uint8_t),
                               32*sizeof(uint8_t));
     for (int i = 0; i < 32; ++i) {
         for (int j = 0; j < 32; ++j) {
             expected[i*32 + j] = ((uint32_t)dataIn[i*2*64 + j*2] + dataIn[i*2*64 + j*2 + 1] +
                                   dataIn[i*2*64 + j*2 + 64] + dataIn[i*2*64 + j*2 + 64+1]) / 4;
         }
     }
     EXPECT_EQ(expected, dataOut);
 }

 /*
  * This test creates one 2D Allocations, one with 128 * 128 Float Elements with
  * allocationCubeCreateFromBitmap. The Allocation is pre-populated with dataIn
  * and the mipmaps are filled with allocationGenerateMipmaps. Then dataOut is
  * then overridden with allocation2DRead.
  *
  * Calls: elementCreate, typeCreate, allocationCubeCreateFromBitmap,
  * allocation2DRead
  *
  * Expect: dataIn & dataOut are the same.
  */
 TEST_P(RenderscriptHidlTest, SimpleCubemapTest) {
     // float1
     Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
     ASSERT_NE(Element(0), element);

     // 128 x 128 x float1
     Type type = context->typeCreate(element, 128, 128, 0, false, true, YuvFormat::YUV_NONE);
     ASSERT_NE(Type(0), type);

     std::vector<float> dataIn(128*128*6), dataOut(128*128), expected(128*128);
     std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
     hidl_vec<uint8_t> _data;
     _data.setToExternal((uint8_t*)dataIn.data(), dataIn.size()*sizeof(float));
     // 128 x 128 x float1 x 6
     Allocation allocation = context->allocationCubeCreateFromBitmap(
         type, AllocationMipmapControl::NONE, _data, (int)AllocationUsageType::SCRIPT);
     ASSERT_NE(Allocation(0), allocation);

     context->allocation2DRead(allocation, 0, 0, 0, AllocationCubemapFace::NEGATIVE_Z, 128,
                               128, (Ptr)dataOut.data(), (Size)dataOut.size()*sizeof(float),
                               128*sizeof(float));
     for (int i = 0; i < 128; ++i) {
         for (int j = 0; j < 128; ++j) {
             expected[i*128 + j] = i*128*6 + j + 128*5;
         }
     }
     EXPECT_EQ(expected, dataOut);
 }

 /*
  * This test creates a complex element type (uint8_t, uint32_t) out of known
  * elements. It then verifies the element structure was created correctly.
  * Finally, the test creates a 1-wide, 1-dimension allocation of this type
  * and transfers memory to and from a single cell of this Allocation.
  *
  * Calls: elementCreate, elementComplexCreate, elementGetSubElements,
  * typeCreate, allocationCreateTyped, allocationElementWrite,
  * allocationElementRead
  */
 TEST_P(RenderscriptHidlTest, ComplexElementTest) {
     Element element1 = context->elementCreate(DataType::UNSIGNED_8, DataKind::USER, false, 1);
     ASSERT_NE(Element(0), element1);

     Element element2 = context->elementCreate(DataType::UNSIGNED_32, DataKind::USER, false, 1);
     ASSERT_NE(Element(0), element2);

     hidl_vec<Element> eins = {element1, element2};
     hidl_vec<hidl_string> names = {hidl_string("first"), hidl_string("second")};
     hidl_vec<Size> arraySizesPtr = {1, 1};
     Element element3 = context->elementComplexCreate(eins, names, arraySizesPtr);
     ASSERT_NE(Element(0), element3);

     std::vector<Element> ids;
     std::vector<std::string> namesOut;
     std::vector<Size> arraySizesOut;
     context->elementGetSubElements(element3, 2, [&](const hidl_vec<Element>& _ids,
                                                     const hidl_vec<hidl_string>& _names,
                                                     const hidl_vec<Size>& _arraySizes){
                                                         ids = _ids;
                                                         namesOut.push_back(_names[0]);
                                                         namesOut.push_back(_names[1]);
                                                         arraySizesOut = _arraySizes;
                                                     });
     EXPECT_EQ(element1, ids[0]);
     EXPECT_EQ(element2, ids[1]);
     EXPECT_EQ("first", namesOut[0]);
     EXPECT_EQ("second", namesOut[1]);
     EXPECT_EQ(Size(1), arraySizesOut[0]);
     EXPECT_EQ(Size(1), arraySizesOut[1]);

     // 1 x (uint8_t, uint32_t)
     Type type = context->typeCreate(element3, 1, 0, 0, false, false, YuvFormat::YUV_NONE);
     ASSERT_NE(Type(0), type);

     // 1 x (uint8_t, uint32_t)
     Allocation allocation = context->allocationCreateTyped(type, AllocationMipmapControl::NONE,
                                                            (int)AllocationUsageType::SCRIPT,
                                                            (Ptr)nullptr);
     ASSERT_NE(Allocation(0), allocation);

     std::vector<uint32_t> dataIn(1), dataOut(1);
     std::generate(dataIn.begin(), dataIn.end(), [](){ static uint32_t val = 0; return val++; });
     hidl_vec<uint8_t> _data;
     _data.setToExternal((uint8_t*)dataIn.data(), dataIn.size()*sizeof(uint32_t));
     context->allocationElementWrite(allocation, 0, 0, 0, 0, _data, 1);
     context->allocationElementRead(allocation, 0, 0, 0, 0, (Ptr)dataOut.data(),
                                    (Size)dataOut.size()*sizeof(uint32_t), 1);
     EXPECT_EQ(dataIn, dataOut);
 }
	/*
	* Copyright (C) 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.
	*/

	#include "VtsHalRenderscriptV1_0TargetTest.h"

	/*
	* This test creates a 1D Allocation with 128 Float Elements, and two float
	* vector dataIn & dataOut. dataIn is pre-populated with data, and copied into
	* the Allocation using allocation1DWrite. Then the Allocation is copied into
	* dataOut with allocation1DRead.
	*
	* Calls: elementCreate, typeCreate, allocationCreateTyped, allocation1DWrite,
	* allocation1DRead
	*
	* Expect: dataIn & dataOut are the same.
	*/
	TEST_P(RenderscriptHidlTest, Simple1DCopyTest) {
	// float1
	Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
	ASSERT_NE(Element(0), element);

	// 128 x float1
	Type type = context->typeCreate(element, 128, 0, 0, false, false, YuvFormat::YUV_NONE);
	ASSERT_NE(Type(0), type);

	// 128 x float1
	Allocation allocation = context->allocationCreateTyped(type, AllocationMipmapControl::NONE,
	(int)AllocationUsageType::SCRIPT,
	(Ptr)nullptr);
	ASSERT_NE(Allocation(0), allocation);

	std::vector<float> dataIn(128), dataOut(128);
	std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
	hidl_vec<uint8_t> _data;
	_data.setToExternal((uint8_t)dataIn.data(), dataIn.size()sizeof(float));
	context->allocation1DWrite(allocation, 0, 0, (Size)dataIn.size(), _data);
	context->allocation1DRead(allocation, 0, 0, (uint32_t)dataOut.size(), (Ptr)dataOut.data(),
	(Size)dataOut.size()*sizeof(float));
	EXPECT_EQ(dataIn, dataOut);
	}

	/*
	* This test creates a 2D Allocation with 128 * 128 Float Elements, and two
	* float vector dataIn & dataOut. dataIn is pre-populated with data, and copied
	* into the Allocation using allocation2DWrite. Then the Allocation is copied
	* into dataOut with allocation2DRead.
	*
	* Calls: elementCreate, typeCreate, allocationCreateTyped, allocation2DWrite,
	* allocation2DRead
	*
	* Expect: dataIn & dataOut are the same.
	*/
	TEST_P(RenderscriptHidlTest, Simple2DCopyTest) {
	// float1
	Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
	ASSERT_NE(Element(0), element);

	// 128 x 128 x float1
	Type type = context->typeCreate(element, 128, 128, 0, false, false, YuvFormat::YUV_NONE);
	ASSERT_NE(Type(0), type);

	// 128 x 128 x float1
	Allocation allocation = context->allocationCreateTyped(type, AllocationMipmapControl::NONE,
	(int)AllocationUsageType::SCRIPT,
	(Ptr)nullptr);
	ASSERT_NE(Allocation(0), allocation);

	std::vector<float> dataIn(128128), dataOut(128128);
	std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
	hidl_vec<uint8_t> _data;
	_data.setToExternal((uint8_t)dataIn.data(), dataIn.size()sizeof(float));
	context->allocation2DWrite(allocation, 0, 0, 0, AllocationCubemapFace::POSITIVE_X, 128, 128,
	_data, 0);
	context->allocation2DRead(allocation, 0, 0, 0, AllocationCubemapFace::POSITIVE_X, 128, 128,
	(Ptr)dataOut.data(), (Size)dataOut.size()*sizeof(float), 0);
	EXPECT_EQ(dataIn, dataOut);
	}

	/*
	* This test creates a 3D Allocation with 32 * 32 * 32 Float Elements, and two
	* float vector dataIn & dataOut. dataIn is pre-populated with data, and copied
	* into the Allocation using allocation3DWrite. Then the Allocation is copied
	* into dataOut with allocation3DRead.
	*
	* Calls: elementCreate, typeCreate, allocationCreateTyped, allocation3DWrite,
	* allocation3DRead
	*
	* Expect: dataIn & dataOut are the same.
	*/
	TEST_P(RenderscriptHidlTest, Simple3DCopyTest) {
	// float1
	Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
	ASSERT_NE(Element(0), element);

	// 32 x 32 x 32 x float1
	Type type = context->typeCreate(element, 32, 32, 32, false, false, YuvFormat::YUV_NONE);
	ASSERT_NE(Type(0), type);

	// 32 x 32 x 32 x float1
	Allocation allocation = context->allocationCreateTyped(type, AllocationMipmapControl::NONE,
	(int)AllocationUsageType::SCRIPT,
	(Ptr)nullptr);
	ASSERT_NE(Allocation(0), allocation);

	std::vector<float> dataIn(323232), dataOut(323232);
	std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
	hidl_vec<uint8_t> _data;
	_data.setToExternal((uint8_t)dataIn.data(), dataIn.size()sizeof(float));
	context->allocation3DWrite(allocation, 0, 0, 0, 0, 32, 32, 32, _data, 0);
	context->allocation3DRead(allocation, 0, 0, 0, 0, 32, 32, 32, (Ptr)dataOut.data(),
	(Size)dataOut.size()*sizeof(float), 0);
	EXPECT_EQ(dataIn, dataOut);
	}

	/*
	* This test creates a 2D Allocation with 512 * 512 Float Elements with
	* allocationCreateFromBitmap, and two float vector dataIn & dataOut. dataIn is
	* pre-populated with data, and copied into the Allocation using
	* allocationCopyToBitmap. Then the Allocation is copied into dataOut with
	* allocationRead.
	*
	* Calls: elementCreate, typeCreate, allocationCreateFromBitmap,
	* allocationCopyToBitmap, allocationRead
	*
	* Expect: dataIn & dataOut are the same.
	*/
	TEST_P(RenderscriptHidlTest, SimpleBitmapTest) {
	// float1
	Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
	ASSERT_NE(Element(0), element);

	// 512 x 512 x float1
	Type type = context->typeCreate(element, 512, 512, 0, false, false, YuvFormat::YUV_NONE);
	ASSERT_NE(Type(0), type);

	std::vector<float> dataIn(512512), dataOut1(512512), dataOut2(512*512);
	std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
	hidl_vec<uint8_t> _data;
	_data.setToExternal((uint8_t)dataIn.data(), dataIn.size()sizeof(float));
	// 512 x 512 x float1
	Allocation allocation = context->allocationCreateFromBitmap(type,
	AllocationMipmapControl::NONE,
	_data,
	(int)AllocationUsageType::SCRIPT);
	ASSERT_NE(Allocation(0), allocation);

	context->allocationCopyToBitmap(allocation, (Ptr)dataOut1.data(),
	(Size)dataOut1.size()*sizeof(float));
	EXPECT_EQ(dataIn, dataOut1);

	context->allocationRead(allocation, (Ptr)dataOut2.data(), (Size)dataOut2.size()*sizeof(float));
	EXPECT_EQ(dataIn, dataOut2);
	}

	/*
	* This test creates two 2D Allocations, one with 512 * 512 Float Elements, the
	* other with 256 * 256 Float Elements. The larger Allocation is pre-populated
	* with dataIn, and copied into the smaller Allocation using
	* allocationCopy2DRange. Then the Allocation is copied into dataOut with
	* allocationRead.
	*
	* Calls: elementCreate, typeCreate, allocationCreateFromBitmap,
	* allocationCreateTyped, allocationCopy2DRange, allocationRead
	*
	* Expect: dataIn & dataOut are the same.
	*/
	TEST_P(RenderscriptHidlTest, AllocationCopy2DRangeTest) {
	// float1
	Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
	ASSERT_NE(Element(0), element);

	// 512 x 512 x float1
	Type typeSrc = context->typeCreate(element, 512, 512, 0, false, false, YuvFormat::YUV_NONE);
	ASSERT_NE(Type(0), typeSrc);

	// 256 x 256 x float1
	Type typeDst = context->typeCreate(element, 256, 256, 0, false, false, YuvFormat::YUV_NONE);
	ASSERT_NE(Type(0), typeDst);

	std::vector<float> dataIn(512512), dataOut(256256), expected(256*256);
	std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
	hidl_vec<uint8_t> _data;
	_data.setToExternal((uint8_t)dataIn.data(), dataIn.size()sizeof(float));
	// 512 x 512 x float1
	Allocation allocSrc = context->allocationCreateFromBitmap(typeSrc,
	AllocationMipmapControl::NONE, _data,
	(int)AllocationUsageType::SCRIPT);
	ASSERT_NE(Allocation(0), allocSrc);

	// 256 x 256 x float1
	Allocation allocDst = context->allocationCreateTyped(typeDst, AllocationMipmapControl::NONE,
	(int)AllocationUsageType::SCRIPT,
	(Ptr)nullptr);
	ASSERT_NE(Allocation(0), allocDst);

	context->allocationCopy2DRange(allocDst, 0, 0, 0, AllocationCubemapFace::POSITIVE_X, 256, 256,
	allocSrc, 128, 128, 0, AllocationCubemapFace::POSITIVE_X);
	context->allocationRead(allocDst, (Ptr)dataOut.data(), (Size)dataOut.size()*sizeof(float));
	for (int i = 0; i < 256; ++i) {
	for (int j = 0; j < 256; ++j) {
	expected[i256 + j] = dataIn[(i+128)512 + (j+128)];
	}
	}
	EXPECT_EQ(expected, dataOut);
	}

	/*
	* This test creates two 3D Allocations, one with 128 * 128 * 128 Float
	* Elements, the other with 64 * 64 * 64 Float Elements. The larger Allocation
	* is pre-populated with dataIn, and copied into the smaller Allocation using
	* allocationCopy3DRange. Then the Allocation is copied into dataOut with
	* allocationRead.
	*
	* Calls: elementCreate, typeCreate, allocationCreateTyped, allocation3DWrite,
	* allocationCopy3DRange, allocationRead
	*
	* Expect: dataIn & dataOut are the same.
	*/
	TEST_P(RenderscriptHidlTest, AllocationCopy3DRangeTest) {
	// float1
	Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
	ASSERT_NE(Element(0), element);

	// 128 x 128 x 128 x float1
	Type typeSrc = context->typeCreate(element, 128, 128, 128, false, false, YuvFormat::YUV_NONE);
	ASSERT_NE(Type(0), typeSrc);

	// 64 x 64 x 64 x float1
	Type typeDst = context->typeCreate(element, 64, 64, 64, false, false, YuvFormat::YUV_NONE);
	ASSERT_NE(Type(0), typeDst);

	std::vector<float> dataIn(128128128), dataOut(646464), expected(646464);
	std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
	hidl_vec<uint8_t> _data;
	_data.setToExternal((uint8_t)dataIn.data(), dataIn.size()sizeof(float));
	// 512 x 512 x float1
	Allocation allocSrc = context->allocationCreateTyped(typeSrc, AllocationMipmapControl::NONE,
	(int)AllocationUsageType::SCRIPT,
	(Ptr)nullptr);
	ASSERT_NE(Allocation(0), allocSrc);

	// 256 x 256 x float1
	Allocation allocDst = context->allocationCreateTyped(typeDst, AllocationMipmapControl::NONE,
	(int)AllocationUsageType::SCRIPT,
	(Ptr)nullptr);
	ASSERT_NE(Allocation(0), allocDst);

	context->allocation3DWrite(allocSrc, 0, 0, 0, 0, 128, 128, 128, _data, 128*sizeof(float));
	context->allocationCopy3DRange(allocDst, 0, 0, 0, 0, 64, 64, 64, allocSrc, 32, 32, 32, 0);
	context->allocationRead(allocDst, (Ptr)dataOut.data(), (Size)dataOut.size()*sizeof(float));
	for (int i = 0; i < 64; ++i) {
	for (int j = 0; j < 64; ++j) {
	for (int k = 0; k < 64; ++k) {
	expected[i6464 + j64 + k] = dataIn[(i+32)128128 + (j+32)128 + (k+32)];
	}
	}
	}
	EXPECT_EQ(expected, dataOut);
	}

	/*
	* This test creates one 2D Allocations, one with 512 * 512 Float Elements, and
	* one 2D AllocationAdapter with a window of 256 * 256 based on the Allocation.
	* The Allocation is pre-populated with dataIn. Then the Allocation is copied
	* into dataOut with allocationRead on the AllocationAdapter.
	*
	* Calls: elementCreate, typeCreate, allocationCreateFromBitmap,
	* allocationAdapterCreate, allocationAdapterOffset, allocation2DRead
	*
	* Expect: dataIn & dataOut are the same.
	*/
	TEST_P(RenderscriptHidlTest, SimpleAdapterTest) {
	// float1
	Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
	ASSERT_NE(Element(0), element);

	// 512 x 512 x float1
	Type type = context->typeCreate(element, 512, 512, 0, false, false, YuvFormat::YUV_NONE);
	ASSERT_NE(Type(0), type);

	std::vector<float> dataIn(512512), dataOut(256256), expected;
	std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
	hidl_vec<uint8_t> _data;
	_data.setToExternal((uint8_t)dataIn.data(), dataIn.size()sizeof(float));
	// 512 x 512 x float1
	Allocation allocation = context->allocationCreateFromBitmap(type,
	AllocationMipmapControl::NONE,
	_data,
	(int)AllocationUsageType::SCRIPT);
	ASSERT_NE(Allocation(0), allocation);

	// 256 x 256 x float1
	Type subType = context->typeCreate(element, 256, 256, 0, false, false, YuvFormat::YUV_NONE);
	ASSERT_NE(Type(0), subType);

	// 256 x 256 x float1
	AllocationAdapter allocationAdapter = context->allocationAdapterCreate(subType, allocation);
	ASSERT_NE(AllocationAdapter(0), allocationAdapter);

	std::vector<uint32_t> offsets(9, 0);
	offsets[0] = 128;
	offsets[1] = 128;
	hidl_vec<uint32_t> _offsets;
	_offsets.setToExternal(offsets.data(), offsets.size());
	// origin at (128,128)
	context->allocationAdapterOffset(allocationAdapter, _offsets);

	context->allocation2DRead(allocationAdapter, 0, 0, 0, AllocationCubemapFace::POSITIVE_X, 256,
	256, (Ptr)dataOut.data(), (Size)dataOut.size()*sizeof(float), 0);
	for (int i = 128; i < 128 + 256; ++i) {
	for (int j = 128; j < 128 + 256; ++j) {
	expected.push_back(i * 512 + j);
	}
	}
	EXPECT_EQ(expected, dataOut);
	}

	/*
	* This test creates one 2D Allocations, one with 64 * 64 USIGNED_8 Elements,
	* and with AllocationMipmapControl::FULL. The Allocation is pre-populated with
	* dataIn and the mipmaps are filled with allocationGenerateMipmaps. Then
	* dataOut is then overridden with allocation2DRead.
	*
	* Calls: elementCreate, typeCreate, allocationCreateTyped, allocation2DWrite,
	* allocationGenerateMipmaps, allocationSyncAll, allocation2DRead
	*
	* Expect: dataIn & dataOut are the same.
	*/
	TEST_P(RenderscriptHidlTest, SimpleMipmapTest) {
	// uint8_t
	Element element = context->elementCreate(DataType::UNSIGNED_8, DataKind::USER, false, 1);
	ASSERT_NE(Element(0), element);

	// 64 x 64 x uint8_t
	Type type = context->typeCreate(element, 64, 64, 0, true, false, YuvFormat::YUV_NONE);
	ASSERT_NE(Type(0), type);

	std::vector<uint8_t> dataIn(6464), dataOut(3232), expected(32*32);
	std::generate(dataIn.begin(), dataIn.end(),
	[](){ static int val = 0; return (uint8_t)(0xFF & val++); });
	hidl_vec<uint8_t> _data;
	_data.setToExternal((uint8_t)dataIn.data(), dataIn.size()sizeof(uint8_t));
	// 64 x 64 x uint8_t
	Allocation allocation = context->allocationCreateTyped(type, AllocationMipmapControl::FULL,
	(int)AllocationUsageType::SCRIPT,
	(Ptr)nullptr);
	ASSERT_NE(Allocation(0), allocation);

	context->allocation2DWrite(allocation, 0, 0, 0, AllocationCubemapFace::POSITIVE_X, 64, 64,
	_data, 64*sizeof(uint8_t));
	context->allocationGenerateMipmaps(allocation);
	context->allocationSyncAll(allocation, AllocationUsageType::SCRIPT);
	context->allocation2DRead(allocation, 0, 0, 1, AllocationCubemapFace::POSITIVE_X, 32, 32,
	(Ptr)dataOut.data(), (Size)dataOut.size()*sizeof(uint8_t),
	32*sizeof(uint8_t));
	for (int i = 0; i < 32; ++i) {
	for (int j = 0; j < 32; ++j) {
	expected[i32 + j] = ((uint32_t)dataIn[i264 + j2] + dataIn[i264 + j*2 + 1] +
	dataIn[i264 + j2 + 64] + dataIn[i264 + j2 + 64+1]) / 4;
	}
	}
	EXPECT_EQ(expected, dataOut);
	}

	/*
	* This test creates one 2D Allocations, one with 128 * 128 Float Elements with
	* allocationCubeCreateFromBitmap. The Allocation is pre-populated with dataIn
	* and the mipmaps are filled with allocationGenerateMipmaps. Then dataOut is
	* then overridden with allocation2DRead.
	*
	* Calls: elementCreate, typeCreate, allocationCubeCreateFromBitmap,
	* allocation2DRead
	*
	* Expect: dataIn & dataOut are the same.
	*/
	TEST_P(RenderscriptHidlTest, SimpleCubemapTest) {
	// float1
	Element element = context->elementCreate(DataType::FLOAT_32, DataKind::USER, false, 1);
	ASSERT_NE(Element(0), element);

	// 128 x 128 x float1
	Type type = context->typeCreate(element, 128, 128, 0, false, true, YuvFormat::YUV_NONE);
	ASSERT_NE(Type(0), type);

	std::vector<float> dataIn(1281286), dataOut(128128), expected(128128);
	std::generate(dataIn.begin(), dataIn.end(), [](){ static int val = 0; return (float)val++; });
	hidl_vec<uint8_t> _data;
	_data.setToExternal((uint8_t)dataIn.data(), dataIn.size()sizeof(float));
	// 128 x 128 x float1 x 6
	Allocation allocation = context->allocationCubeCreateFromBitmap(
	type, AllocationMipmapControl::NONE, _data, (int)AllocationUsageType::SCRIPT);
	ASSERT_NE(Allocation(0), allocation);

	context->allocation2DRead(allocation, 0, 0, 0, AllocationCubemapFace::NEGATIVE_Z, 128,
	128, (Ptr)dataOut.data(), (Size)dataOut.size()*sizeof(float),
	128*sizeof(float));
	for (int i = 0; i < 128; ++i) {
	for (int j = 0; j < 128; ++j) {
	expected[i128 + j] = i1286 + j + 1285;
	}
	}
	EXPECT_EQ(expected, dataOut);
	}

	/*
	* This test creates a complex element type (uint8_t, uint32_t) out of known
	* elements. It then verifies the element structure was created correctly.
	* Finally, the test creates a 1-wide, 1-dimension allocation of this type
	* and transfers memory to and from a single cell of this Allocation.
	*
	* Calls: elementCreate, elementComplexCreate, elementGetSubElements,
	* typeCreate, allocationCreateTyped, allocationElementWrite,
	* allocationElementRead
	*/
	TEST_P(RenderscriptHidlTest, ComplexElementTest) {
	Element element1 = context->elementCreate(DataType::UNSIGNED_8, DataKind::USER, false, 1);
	ASSERT_NE(Element(0), element1);

	Element element2 = context->elementCreate(DataType::UNSIGNED_32, DataKind::USER, false, 1);
	ASSERT_NE(Element(0), element2);

	hidl_vec<Element> eins = {element1, element2};
	hidl_vec<hidl_string> names = {hidl_string("first"), hidl_string("second")};
	hidl_vec<Size> arraySizesPtr = {1, 1};
	Element element3 = context->elementComplexCreate(eins, names, arraySizesPtr);
	ASSERT_NE(Element(0), element3);

	std::vector<Element> ids;
	std::vector<std::string> namesOut;
	std::vector<Size> arraySizesOut;
	context->elementGetSubElements(element3, 2, [&](const hidl_vec<Element>& _ids,
	const hidl_vec<hidl_string>& _names,
	const hidl_vec<Size>& _arraySizes){
	ids = _ids;
	namesOut.push_back(_names[0]);
	namesOut.push_back(_names[1]);
	arraySizesOut = _arraySizes;
	});
	EXPECT_EQ(element1, ids[0]);
	EXPECT_EQ(element2, ids[1]);
	EXPECT_EQ("first", namesOut[0]);
	EXPECT_EQ("second", namesOut[1]);
	EXPECT_EQ(Size(1), arraySizesOut[0]);
	EXPECT_EQ(Size(1), arraySizesOut[1]);

	// 1 x (uint8_t, uint32_t)
	Type type = context->typeCreate(element3, 1, 0, 0, false, false, YuvFormat::YUV_NONE);
	ASSERT_NE(Type(0), type);

	// 1 x (uint8_t, uint32_t)
	Allocation allocation = context->allocationCreateTyped(type, AllocationMipmapControl::NONE,
	(int)AllocationUsageType::SCRIPT,
	(Ptr)nullptr);
	ASSERT_NE(Allocation(0), allocation);

	std::vector<uint32_t> dataIn(1), dataOut(1);
	std::generate(dataIn.begin(), dataIn.end(), [](){ static uint32_t val = 0; return val++; });
	hidl_vec<uint8_t> _data;
	_data.setToExternal((uint8_t)dataIn.data(), dataIn.size()sizeof(uint32_t));
	context->allocationElementWrite(allocation, 0, 0, 0, 0, _data, 1);
	context->allocationElementRead(allocation, 0, 0, 0, 0, (Ptr)dataOut.data(),
	(Size)dataOut.size()*sizeof(uint32_t), 1);
	EXPECT_EQ(dataIn, dataOut);
	}