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skia2/tests/FrontBufferedStreamTest.cpp
scroggo a1193e4b0e Make SkStream *not* ref counted. 
SkStream is a stateful object, so it does not make sense for it to have
multiple owners. Make SkStream inherit directly from SkNoncopyable.

Update methods which previously called SkStream::ref() (e.g.
SkImageDecoder::buildTileIndex() and SkFrontBufferedStream::Create(),
which required the existing owners to call SkStream::unref()) to take
ownership of their SkStream parameters and delete when done (including
on failure).

Switch all SkAutoTUnref<SkStream>s to SkAutoTDelete<SkStream>s. In some
cases this means heap allocating streams that were previously stack
allocated.

Respect ownership rules of SkTypeface::CreateFromStream() and
SkImageDecoder::buildTileIndex().

Update the comments for exceptional methods which do not affect the
ownership of their SkStream parameters (e.g.
SkPicture::CreateFromStream() and SkTypeface::Deserialize()) to be
explicit about ownership.

Remove test_stream_life, which tested that buildTileIndex() behaved
correctly when SkStream was a ref counted object. The test does not
make sense now that it is not.

In SkPDFStream, remove the SkMemoryStream member. Instead of using it,
create a new SkMemoryStream to pass to fDataStream (which is now an
SkAutoTDelete).

Make other pdf rasterizers behave like SkPDFDocumentToBitmap.

SkPDFDocumentToBitmap delete the SkStream, so do the same in the
following pdf rasterizers:

SkPopplerRasterizePDF
SkNativeRasterizePDF
SkNoRasterizePDF

Requires a change to Android, which currently treats SkStreams as ref
counted objects.

Review URL: https://codereview.chromium.org/849103004
2015-01-21 12:09:53 -08:00

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/*
* Copyright 2013 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "SkBitmap.h"
#include "SkFrontBufferedStream.h"
#include "SkImageDecoder.h"
#include "SkRefCnt.h"
#include "SkStream.h"
#include "SkTypes.h"
#include "Test.h"
static void test_read(skiatest::Reporter* reporter, SkStream* bufferedStream,
const void* expectations, size_t bytesToRead) {
// output for reading bufferedStream.
SkAutoMalloc storage(bytesToRead);
const size_t bytesRead = bufferedStream->read(storage.get(), bytesToRead);
REPORTER_ASSERT(reporter, bytesRead == bytesToRead || bufferedStream->isAtEnd());
REPORTER_ASSERT(reporter, memcmp(storage.get(), expectations, bytesRead) == 0);
}
static void test_rewind(skiatest::Reporter* reporter,
SkStream* bufferedStream, bool shouldSucceed) {
const bool success = bufferedStream->rewind();
REPORTER_ASSERT(reporter, success == shouldSucceed);
}
// Test that hasLength() returns the correct value, based on the stream
// being wrapped. A length can only be known if the wrapped stream has a
// length and it has a position (so its initial position can be taken into
// account when computing the length).
static void test_hasLength(skiatest::Reporter* reporter,
const SkStream& bufferedStream,
const SkStream& streamBeingBuffered) {
if (streamBeingBuffered.hasLength() && streamBeingBuffered.hasPosition()) {
REPORTER_ASSERT(reporter, bufferedStream.hasLength());
} else {
REPORTER_ASSERT(reporter, !bufferedStream.hasLength());
}
}
// All tests will buffer this string, and compare output to the original.
// The string is long to ensure that all of our lengths being tested are
// smaller than the string length.
const char gAbcs[] = "abcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwxyzabcdefghijklmnopqrstuvwx";
// Tests reading the stream across boundaries of what has been buffered so far and what
// the total buffer size is.
static void test_incremental_buffering(skiatest::Reporter* reporter, size_t bufferSize) {
// NOTE: For this and other tests in this file, we cheat and continue to refer to the
// wrapped stream, but that's okay because we know the wrapping stream has not been
// deleted yet (and we only call const methods in it).
SkMemoryStream* memStream = SkNEW_ARGS(SkMemoryStream, (gAbcs, strlen(gAbcs), false));
SkAutoTDelete<SkStream> bufferedStream(SkFrontBufferedStream::Create(memStream, bufferSize));
test_hasLength(reporter, *bufferedStream.get(), *memStream);
// First, test reading less than the max buffer size.
test_read(reporter, bufferedStream, gAbcs, bufferSize / 2);
// Now test rewinding back to the beginning and reading less than what was
// already buffered.
test_rewind(reporter, bufferedStream, true);
test_read(reporter, bufferedStream, gAbcs, bufferSize / 4);
// Now test reading part of what was buffered, and buffering new data.
test_read(reporter, bufferedStream, gAbcs + bufferedStream->getPosition(), bufferSize / 2);
// Now test reading what was buffered, buffering new data, and
// reading directly from the stream.
test_rewind(reporter, bufferedStream, true);
test_read(reporter, bufferedStream, gAbcs, bufferSize << 1);
// We have reached the end of the buffer, so rewinding will fail.
// This test assumes that the stream is larger than the buffer; otherwise the
// result of rewind should be true.
test_rewind(reporter, bufferedStream, false);
}
static void test_perfectly_sized_buffer(skiatest::Reporter* reporter, size_t bufferSize) {
SkMemoryStream* memStream = SkNEW_ARGS(SkMemoryStream, (gAbcs, strlen(gAbcs), false));
SkAutoTDelete<SkStream> bufferedStream(SkFrontBufferedStream::Create(memStream, bufferSize));
test_hasLength(reporter, *bufferedStream.get(), *memStream);
// Read exactly the amount that fits in the buffer.
test_read(reporter, bufferedStream, gAbcs, bufferSize);
// Rewinding should succeed.
test_rewind(reporter, bufferedStream, true);
// Once again reading buffered info should succeed
test_read(reporter, bufferedStream, gAbcs, bufferSize);
// Read past the size of the buffer. At this point, we cannot return.
test_read(reporter, bufferedStream, gAbcs + bufferedStream->getPosition(), 1);
test_rewind(reporter, bufferedStream, false);
}
static void test_skipping(skiatest::Reporter* reporter, size_t bufferSize) {
SkMemoryStream* memStream = SkNEW_ARGS(SkMemoryStream, (gAbcs, strlen(gAbcs), false));
SkAutoTDelete<SkStream> bufferedStream(SkFrontBufferedStream::Create(memStream, bufferSize));
test_hasLength(reporter, *bufferedStream.get(), *memStream);
// Skip half the buffer.
bufferedStream->skip(bufferSize / 2);
// Rewind, then read part of the buffer, which should have been read.
test_rewind(reporter, bufferedStream, true);
test_read(reporter, bufferedStream, gAbcs, bufferSize / 4);
// Now skip beyond the buffered piece, but still within the total buffer.
bufferedStream->skip(bufferSize / 2);
// Test that reading will still work.
test_read(reporter, bufferedStream, gAbcs + bufferedStream->getPosition(), bufferSize / 4);
test_rewind(reporter, bufferedStream, true);
test_read(reporter, bufferedStream, gAbcs, bufferSize);
}
// A custom class whose isAtEnd behaves the way Android's stream does - since it is an adaptor to a
// Java InputStream, it does not know that it is at the end until it has attempted to read beyond
// the end and failed. Used by test_read_beyond_buffer.
class AndroidLikeMemoryStream : public SkMemoryStream {
public:
AndroidLikeMemoryStream(void* data, size_t size, bool ownMemory)
: INHERITED(data, size, ownMemory)
, fIsAtEnd(false) {}
size_t read(void* dst, size_t requested) SK_OVERRIDE {
size_t bytesRead = this->INHERITED::read(dst, requested);
if (bytesRead < requested) {
fIsAtEnd = true;
}
return bytesRead;
}
bool isAtEnd() const SK_OVERRIDE {
return fIsAtEnd;
}
private:
bool fIsAtEnd;
typedef SkMemoryStream INHERITED;
};
// This test ensures that buffering the exact length of the stream and attempting to read beyond it
// does not invalidate the buffer.
static void test_read_beyond_buffer(skiatest::Reporter* reporter, size_t bufferSize) {
// Use a stream that behaves like Android's stream.
AndroidLikeMemoryStream* memStream = SkNEW_ARGS(AndroidLikeMemoryStream, ((void*)gAbcs, bufferSize, false));
// Create a buffer that matches the length of the stream.
SkAutoTDelete<SkStream> bufferedStream(SkFrontBufferedStream::Create(memStream, bufferSize));
test_hasLength(reporter, *bufferedStream.get(), *memStream);
// Attempt to read one more than the bufferSize
test_read(reporter, bufferedStream.get(), gAbcs, bufferSize + 1);
test_rewind(reporter, bufferedStream.get(), true);
// Ensure that the initial read did not invalidate the buffer.
test_read(reporter, bufferedStream, gAbcs, bufferSize);
}
// Dummy stream that optionally has a length and/or position. Tests that FrontBufferedStream's
// length depends on the stream it's buffering having a length and position.
class LengthOptionalStream : public SkStream {
public:
LengthOptionalStream(bool hasLength, bool hasPosition)
: fHasLength(hasLength)
, fHasPosition(hasPosition)
{}
bool hasLength() const SK_OVERRIDE {
return fHasLength;
}
bool hasPosition() const SK_OVERRIDE {
return fHasPosition;
}
size_t read(void*, size_t) SK_OVERRIDE {
return 0;
}
bool isAtEnd() const SK_OVERRIDE {
return true;
}
private:
const bool fHasLength;
const bool fHasPosition;
};
// Test all possible combinations of the wrapped stream having a length and a position.
static void test_length_combos(skiatest::Reporter* reporter, size_t bufferSize) {
for (int hasLen = 0; hasLen <= 1; hasLen++) {
for (int hasPos = 0; hasPos <= 1; hasPos++) {
LengthOptionalStream* stream = SkNEW_ARGS(LengthOptionalStream, (SkToBool(hasLen), SkToBool(hasPos)));
SkAutoTDelete<SkStream> buffered(SkFrontBufferedStream::Create(stream, bufferSize));
test_hasLength(reporter, *buffered.get(), *stream);
}
}
}
// Test using a stream with an initial offset.
static void test_initial_offset(skiatest::Reporter* reporter, size_t bufferSize) {
SkMemoryStream* memStream = SkNEW_ARGS(SkMemoryStream, (gAbcs, strlen(gAbcs), false));
// Skip a few characters into the memStream, so that bufferedStream represents an offset into
// the stream it wraps.
const size_t arbitraryOffset = 17;
memStream->skip(arbitraryOffset);
SkAutoTDelete<SkStream> bufferedStream(SkFrontBufferedStream::Create(memStream, bufferSize));
// Since SkMemoryStream has a length and a position, bufferedStream must also.
REPORTER_ASSERT(reporter, bufferedStream->hasLength());
const size_t amountToRead = 10;
const size_t bufferedLength = bufferedStream->getLength();
size_t currentPosition = bufferedStream->getPosition();
REPORTER_ASSERT(reporter, 0 == currentPosition);
// Read the stream in chunks. After each read, the position must match currentPosition,
// which sums the amount attempted to read, unless the end of the stream has been reached.
// Importantly, the end should not have been reached until currentPosition == bufferedLength.
while (currentPosition < bufferedLength) {
REPORTER_ASSERT(reporter, !bufferedStream->isAtEnd());
test_read(reporter, bufferedStream, gAbcs + arbitraryOffset + currentPosition,
amountToRead);
currentPosition = SkTMin(currentPosition + amountToRead, bufferedLength);
REPORTER_ASSERT(reporter, bufferedStream->getPosition() == currentPosition);
}
REPORTER_ASSERT(reporter, bufferedStream->isAtEnd());
REPORTER_ASSERT(reporter, bufferedLength == currentPosition);
}
static void test_buffers(skiatest::Reporter* reporter, size_t bufferSize) {
test_incremental_buffering(reporter, bufferSize);
test_perfectly_sized_buffer(reporter, bufferSize);
test_skipping(reporter, bufferSize);
test_read_beyond_buffer(reporter, bufferSize);
test_length_combos(reporter, bufferSize);
test_initial_offset(reporter, bufferSize);
}
DEF_TEST(FrontBufferedStream, reporter) {
// Test 6 and 64, which are used by Android, as well as another arbitrary length.
test_buffers(reporter, 6);
test_buffers(reporter, 15);
test_buffers(reporter, 64);
}
// Test that a FrontBufferedStream does not allow reading after the end of a stream.
// This class is a dummy SkStream which reports that it is at the end on the first
// read (simulating a failure). Then it tracks whether someone calls read() again.
class FailingStream : public SkStream {
public:
FailingStream()
: fAtEnd(false)
, fReadAfterEnd(false)
{}
size_t read(void* buffer, size_t size) SK_OVERRIDE {
if (fAtEnd) {
fReadAfterEnd = true;
} else {
fAtEnd = true;
}
return 0;
}
bool isAtEnd() const SK_OVERRIDE {
return fAtEnd;
}
bool readAfterEnd() const {
return fReadAfterEnd;
}
private:
bool fAtEnd;
bool fReadAfterEnd;
};
DEF_TEST(ShortFrontBufferedStream, reporter) {
FailingStream* failingStream = SkNEW(FailingStream);
SkAutoTDelete<SkStreamRewindable> stream(SkFrontBufferedStream::Create(failingStream, 64));
SkBitmap bm;
// The return value of DecodeStream is not important. We are just using DecodeStream because
// it simulates a bug. DecodeStream will read the stream, then rewind, then attempt to read
// again. FrontBufferedStream::read should not continue to read its underlying stream beyond
// its end.
SkImageDecoder::DecodeStream(stream, &bm);
REPORTER_ASSERT(reporter, !failingStream->readAfterEnd());
}
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