tests/ChecksumTest.cpp - platform/external/skia - Gitiles


 /*
  * Copyright 2012 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */
 #include "Test.h"

 #include "SkChecksum.h"

 // Word size that is large enough to hold results of any checksum type.
 typedef uint64_t checksum_result;

 namespace skiatest {
     class ChecksumTestClass : public Test {
     public:
         static Test* Factory(void*) {return SkNEW(ChecksumTestClass); }
     protected:
         virtual void onGetName(SkString* name) { name->set("Checksum"); }
         virtual void onRun(Reporter* reporter) {
             this->fReporter = reporter;
             RunTest();
         }
     private:
         enum Algorithm {
             kSkChecksum
         };

         // Call Compute(data, size) on the appropriate checksum algorithm,
         // depending on this->fWhichAlgorithm.
         checksum_result ComputeChecksum(const char *data, size_t size) {
             switch(fWhichAlgorithm) {
             case kSkChecksum:
                 REPORTER_ASSERT_MESSAGE(fReporter,
                                         reinterpret_cast<uintptr_t>(data) % 4 == 0,
                                         "test data pointer is not 32-bit aligned");
                 REPORTER_ASSERT_MESSAGE(fReporter, SkIsAlign4(size),
                                         "test data size is not 32-bit aligned");
                 return SkChecksum::Compute(reinterpret_cast<const uint32_t *>(data), size);
             default:
                 SkString message("fWhichAlgorithm has unknown value ");
                 message.appendf("%d", fWhichAlgorithm);
                 fReporter->reportFailed(message);
             }
             // we never get here
             return 0;
         }

         // Confirm that the checksum algorithm (specified by fWhichAlgorithm)
         // generates the same results if called twice over the same data.
         void TestChecksumSelfConsistency(size_t buf_size) {
             SkAutoMalloc storage(buf_size);
             char* ptr = reinterpret_cast<char *>(storage.get());

             REPORTER_ASSERT(fReporter,
                             GetTestDataChecksum(8, 0) ==
                             GetTestDataChecksum(8, 0));
             REPORTER_ASSERT(fReporter,
                             GetTestDataChecksum(8, 0) !=
                             GetTestDataChecksum(8, 1));

             sk_bzero(ptr, buf_size);
             checksum_result prev = 0;

             // assert that as we change values (from 0 to non-zero) in
             // our buffer, we get a different value
             for (size_t i = 0; i < buf_size; ++i) {
                 ptr[i] = (i & 0x7f) + 1; // need some non-zero value here

                 // Try checksums of different-sized chunks, but always
                 // 32-bit aligned and big enough to contain all the
                 // nonzero bytes.  (Remaining bytes will still be zero
                 // from the initial sk_bzero() call.)
                 size_t checksum_size = (((i/4)+1)*4);
                 REPORTER_ASSERT(fReporter, checksum_size <= buf_size);

                 checksum_result curr = ComputeChecksum(ptr, checksum_size);
                 REPORTER_ASSERT(fReporter, prev != curr);
                 checksum_result again = ComputeChecksum(ptr, checksum_size);
                 REPORTER_ASSERT(fReporter, again == curr);
                 prev = curr;
             }
         }

         // Return the checksum of a buffer of bytes 'len' long.
         // The pattern of values within the buffer will be consistent
         // for every call, based on 'seed'.
         checksum_result GetTestDataChecksum(size_t len, char seed=0) {
             SkAutoMalloc storage(len);
             char* start = reinterpret_cast<char *>(storage.get());
             char* ptr = start;
             for (size_t i = 0; i < len; ++i) {
                 *ptr++ = ((seed+i) & 0x7f);
             }
             checksum_result result = ComputeChecksum(start, len);
             return result;
         }

         void RunTest() {
             // Test self-consistency of checksum algorithms.
             fWhichAlgorithm = kSkChecksum;
             TestChecksumSelfConsistency(128);

             // Test checksum results that should be consistent across
             // versions and platforms.
             fWhichAlgorithm = kSkChecksum;
             REPORTER_ASSERT(fReporter, ComputeChecksum(NULL, 0) == 0);

             // TODO: note the weakness exposed by these collisions...
             // We need to improve the SkChecksum algorithm.
             // We would prefer that these asserts FAIL!
             // Filed as https://code.google.com/p/skia/issues/detail?id=981
             // ('SkChecksum algorithm allows for way too many collisions')
             fWhichAlgorithm = kSkChecksum;
             REPORTER_ASSERT(fReporter,
                 GetTestDataChecksum(128) == GetTestDataChecksum(256));
             REPORTER_ASSERT(fReporter,
                 GetTestDataChecksum(132) == GetTestDataChecksum(260));
         }

         Reporter* fReporter;
         Algorithm fWhichAlgorithm;
     };

     static TestRegistry gReg(ChecksumTestClass::Factory);
 }

	/*
	* Copyright 2012 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/
	#include "Test.h"

	#include "SkChecksum.h"

	// Word size that is large enough to hold results of any checksum type.
	typedef uint64_t checksum_result;

	namespace skiatest {
	class ChecksumTestClass : public Test {
	public:
	static Test* Factory(void*) {return SkNEW(ChecksumTestClass); }
	protected:
	virtual void onGetName(SkString* name) { name->set("Checksum"); }
	virtual void onRun(Reporter* reporter) {
	this->fReporter = reporter;
	RunTest();
	}
	private:
	enum Algorithm {
	kSkChecksum
	};

	// Call Compute(data, size) on the appropriate checksum algorithm,
	// depending on this->fWhichAlgorithm.
	checksum_result ComputeChecksum(const char *data, size_t size) {
	switch(fWhichAlgorithm) {
	case kSkChecksum:
	REPORTER_ASSERT_MESSAGE(fReporter,
	reinterpret_cast<uintptr_t>(data) % 4 == 0,
	"test data pointer is not 32-bit aligned");
	REPORTER_ASSERT_MESSAGE(fReporter, SkIsAlign4(size),
	"test data size is not 32-bit aligned");
	return SkChecksum::Compute(reinterpret_cast<const uint32_t *>(data), size);
	default:
	SkString message("fWhichAlgorithm has unknown value ");
	message.appendf("%d", fWhichAlgorithm);
	fReporter->reportFailed(message);
	}
	// we never get here
	return 0;
	}

	// Confirm that the checksum algorithm (specified by fWhichAlgorithm)
	// generates the same results if called twice over the same data.
	void TestChecksumSelfConsistency(size_t buf_size) {
	SkAutoMalloc storage(buf_size);
	char* ptr = reinterpret_cast<char *>(storage.get());

	REPORTER_ASSERT(fReporter,
	GetTestDataChecksum(8, 0) ==
	GetTestDataChecksum(8, 0));
	REPORTER_ASSERT(fReporter,
	GetTestDataChecksum(8, 0) !=
	GetTestDataChecksum(8, 1));

	sk_bzero(ptr, buf_size);
	checksum_result prev = 0;

	// assert that as we change values (from 0 to non-zero) in
	// our buffer, we get a different value
	for (size_t i = 0; i < buf_size; ++i) {
	ptr[i] = (i & 0x7f) + 1; // need some non-zero value here

	// Try checksums of different-sized chunks, but always
	// 32-bit aligned and big enough to contain all the
	// nonzero bytes. (Remaining bytes will still be zero
	// from the initial sk_bzero() call.)
	size_t checksum_size = (((i/4)+1)*4);
	REPORTER_ASSERT(fReporter, checksum_size <= buf_size);

	checksum_result curr = ComputeChecksum(ptr, checksum_size);
	REPORTER_ASSERT(fReporter, prev != curr);
	checksum_result again = ComputeChecksum(ptr, checksum_size);
	REPORTER_ASSERT(fReporter, again == curr);
	prev = curr;
	}
	}

	// Return the checksum of a buffer of bytes 'len' long.
	// The pattern of values within the buffer will be consistent
	// for every call, based on 'seed'.
	checksum_result GetTestDataChecksum(size_t len, char seed=0) {
	SkAutoMalloc storage(len);
	char* start = reinterpret_cast<char *>(storage.get());
	char* ptr = start;
	for (size_t i = 0; i < len; ++i) {
	*ptr++ = ((seed+i) & 0x7f);
	}
	checksum_result result = ComputeChecksum(start, len);
	return result;
	}

	void RunTest() {
	// Test self-consistency of checksum algorithms.
	fWhichAlgorithm = kSkChecksum;
	TestChecksumSelfConsistency(128);

	// Test checksum results that should be consistent across
	// versions and platforms.
	fWhichAlgorithm = kSkChecksum;
	REPORTER_ASSERT(fReporter, ComputeChecksum(NULL, 0) == 0);

	// TODO: note the weakness exposed by these collisions...
	// We need to improve the SkChecksum algorithm.
	// We would prefer that these asserts FAIL!
	// Filed as https://code.google.com/p/skia/issues/detail?id=981
	// ('SkChecksum algorithm allows for way too many collisions')
	fWhichAlgorithm = kSkChecksum;
	REPORTER_ASSERT(fReporter,
	GetTestDataChecksum(128) == GetTestDataChecksum(256));
	REPORTER_ASSERT(fReporter,
	GetTestDataChecksum(132) == GetTestDataChecksum(260));
	}

	Reporter* fReporter;
	Algorithm fWhichAlgorithm;
	};

	static TestRegistry gReg(ChecksumTestClass::Factory);
	}