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fuchsia / third_party / android / platform / frameworks / av / refs/tags/android-mainline-10.0.0_r6 / . / media / libaaudio / tests / test_marshalling.cpp
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/*
* Copyright (C) 2016 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.
*/
// Unit tests for AAudio Marshalling of RingBuffer information.
#include <stdlib.h>
#include <math.h>
#include <android-base/unique_fd.h>
#include <binder/Parcel.h>
#include <binder/Parcelable.h>
#include <cutils/ashmem.h>
#include <gtest/gtest.h>
#include <sys/mman.h>
#include <aaudio/AAudio.h>
#include <binding/AudioEndpointParcelable.h>
using android::base::unique_fd;
using namespace android;
using namespace aaudio;
// Test adding one value.
TEST(test_marshalling, aaudio_one_read_write) {
Parcel parcel;
size_t pos = parcel.dataPosition();
const int arbitraryValue = 235;
parcel.writeInt32(arbitraryValue);
parcel.setDataPosition(pos);
int32_t y;
parcel.readInt32(&y);
EXPECT_EQ(arbitraryValue, y);
}
// Test SharedMemoryParcel.
TEST(test_marshalling, aaudio_shared_memory) {
SharedMemoryParcelable sharedMemoryA;
SharedMemoryParcelable sharedMemoryB;
const size_t memSizeBytes = 840;
unique_fd fd(ashmem_create_region("TestMarshalling", memSizeBytes));
ASSERT_LE(0, fd);
sharedMemoryA.setup(fd, memSizeBytes);
void *region1;
EXPECT_EQ(AAUDIO_OK, sharedMemoryA.resolve(0, 16, &region1)); // fits in region
EXPECT_NE(AAUDIO_OK, sharedMemoryA.resolve(-2, 16, &region1)); // offset is negative
EXPECT_NE(AAUDIO_OK, sharedMemoryA.resolve(0, memSizeBytes + 8, &region1)); // size too big
EXPECT_NE(AAUDIO_OK, sharedMemoryA.resolve(memSizeBytes - 8, 16, &region1)); // goes past the end
int32_t *buffer1 = (int32_t *)region1;
buffer1[0] = 98735; // arbitrary value
Parcel parcel;
size_t pos = parcel.dataPosition();
sharedMemoryA.writeToParcel(&parcel);
parcel.setDataPosition(pos);
sharedMemoryB.readFromParcel(&parcel);
EXPECT_EQ(sharedMemoryA.getSizeInBytes(), sharedMemoryB.getSizeInBytes());
// should see same value at two different addresses
void *region2;
EXPECT_EQ(AAUDIO_OK, sharedMemoryB.resolve(0, 16, &region2));
int32_t *buffer2 = (int32_t *)region2;
EXPECT_NE(buffer1, buffer2);
EXPECT_EQ(buffer1[0], buffer2[0]);
}
// Test SharedRegionParcel.
TEST(test_marshalling, aaudio_shared_region) {
SharedMemoryParcelable sharedMemories[2];
SharedRegionParcelable sharedRegionA;
SharedRegionParcelable sharedRegionB;
const size_t memSizeBytes = 840;
unique_fd fd(ashmem_create_region("TestMarshalling", memSizeBytes));
ASSERT_LE(0, fd);
sharedMemories[0].setup(fd, memSizeBytes);
int32_t regionOffset1 = 32;
int32_t regionSize1 = 16;
sharedRegionA.setup(0, regionOffset1, regionSize1);
void *region1;
EXPECT_EQ(AAUDIO_OK, sharedRegionA.resolve(sharedMemories, &region1));
int32_t *buffer1 = (int32_t *)region1;
buffer1[0] = 336677; // arbitrary value
Parcel parcel;
size_t pos = parcel.dataPosition();
sharedRegionA.writeToParcel(&parcel);
parcel.setDataPosition(pos);
sharedRegionB.readFromParcel(&parcel);
// should see same value
void *region2;
EXPECT_EQ(AAUDIO_OK, sharedRegionB.resolve(sharedMemories, &region2));
int32_t *buffer2 = (int32_t *)region2;
EXPECT_EQ(buffer1[0], buffer2[0]);
}
// Test RingBufferParcelable.
TEST(test_marshalling, aaudio_ring_buffer_parcelable) {
SharedMemoryParcelable sharedMemories[2];
RingBufferParcelable ringBufferA;
RingBufferParcelable ringBufferB;
const size_t bytesPerFrame = 8;
const size_t framesPerBurst = 32;
const size_t dataSizeBytes = 2048;
const int32_t counterSizeBytes = sizeof(int64_t);
const size_t memSizeBytes = dataSizeBytes + (2 * counterSizeBytes);
unique_fd fd(ashmem_create_region("TestMarshalling Z", memSizeBytes));
ASSERT_LE(0, fd);
sharedMemories[0].setup(fd, memSizeBytes);
int32_t sharedMemoryIndex = 0;
// arrange indices and data in the shared memory
int32_t readOffset = 0;
int32_t writeOffset = readOffset + counterSizeBytes;
int32_t dataOffset = writeOffset + counterSizeBytes;
ringBufferA.setupMemory(sharedMemoryIndex, dataOffset, dataSizeBytes,
readOffset, writeOffset, counterSizeBytes);
ringBufferA.setFramesPerBurst(framesPerBurst);
ringBufferA.setBytesPerFrame(bytesPerFrame);
ringBufferA.setCapacityInFrames(dataSizeBytes / bytesPerFrame);
// setup A
RingBufferDescriptor descriptorA;
EXPECT_EQ(AAUDIO_OK, ringBufferA.resolve(sharedMemories, &descriptorA));
descriptorA.dataAddress[0] = 95;
descriptorA.dataAddress[1] = 57;
descriptorA.readCounterAddress[0] = 17;
descriptorA.writeCounterAddress[0] = 39;
// write A to parcel
Parcel parcel;
size_t pos = parcel.dataPosition();
ringBufferA.writeToParcel(&parcel);
// read B from parcel
parcel.setDataPosition(pos);
ringBufferB.readFromParcel(&parcel);
RingBufferDescriptor descriptorB;
EXPECT_EQ(AAUDIO_OK, ringBufferB.resolve(sharedMemories, &descriptorB));
// A and B should match
EXPECT_EQ(descriptorA.dataAddress[0], descriptorB.dataAddress[0]);
EXPECT_EQ(descriptorA.dataAddress[1], descriptorB.dataAddress[1]);
EXPECT_EQ(descriptorA.readCounterAddress[0], descriptorB.readCounterAddress[0]);
EXPECT_EQ(descriptorA.writeCounterAddress[0], descriptorB.writeCounterAddress[0]);
EXPECT_EQ(ringBufferA.getFramesPerBurst(), ringBufferB.getFramesPerBurst());
EXPECT_EQ(ringBufferA.getBytesPerFrame(), ringBufferB.getBytesPerFrame());
EXPECT_EQ(ringBufferA.getCapacityInFrames(), ringBufferB.getCapacityInFrames());
}