base/base64_unittest.cc - cobalt - Git at Google

 // Copyright 2012 The Chromium Authors
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "base/base64.h"

 #include "base/numerics/checked_math.h"
 #include "base/strings/escape.h"
 #include "base/test/gtest_util.h"
 #include "testing/gmock/include/gmock/gmock.h"
 #include "testing/gtest/include/gtest/gtest.h"
 #include "third_party/modp_b64/modp_b64.h"

 namespace base {

 TEST(Base64Test, Basic) {
   const std::string kText = "hello world";
   const std::string kBase64Text = "aGVsbG8gd29ybGQ=";

   std::string encoded;
   std::string decoded;
   bool ok;

   Base64Encode(kText, &encoded);
   EXPECT_EQ(kBase64Text, encoded);

   ok = Base64Decode(encoded, &decoded);
   EXPECT_TRUE(ok);
   EXPECT_EQ(kText, decoded);
 }

 TEST(Base64Test, Forgiving) {
   struct {
     const char* in;

     // nullptr indicates a decode failure.
     const char* expected_out;
   } kTestCases[] = {
       // Failures that should apply in all decoding modes:
       //
       // - Characters not in the base64 alphabet
       {"abc&", nullptr},
       {"ab-d", nullptr},
       // - input len % 4 == 1
       {"abcde", nullptr},
       {"a", nullptr},

       // Invalid padding causes failure if kForgiving is set.
       {"abcd=", nullptr},
       {"abcd==", nullptr},
       {"abcd===", nullptr},
       {"abcd====", nullptr},
       {"abcd==============", nullptr},
       {"=", nullptr},
       {"====", nullptr},

       // Otherwise, inputs that are multiples of 4 always succeed, this matches
       // kStrict mode.
       {"abcd", "i\xB7\x1D"},
       {"abc=", "i\xB7"},
       {"abcdefgh", "i\xB7\x1Dy\xF8!"},

       // kForgiving mode allows for omitting padding (to a multiple of 4) if
       // len % 4 != 1.
       {"abcdef", "i\xB7\x1Dy"},
       {"abc", "i\xB7"},
       {"ab", "i"},

       // Whitespace should be allowed if kForgiving is set, matching
       // https://infra.spec.whatwg.org/#ascii-whitespace:
       // ASCII whitespace is U+0009 TAB '\t', U+000A LF '\n', U+000C FF '\f',
       // U+000D CR '\r', or U+0020 SPACE ' '.
       {" a bcd", "i\xB7\x1D"},
       {"ab\t\tc=", "i\xB7"},
       {"ab c\ndefgh", "i\xB7\x1Dy\xF8!"},
       {"a\tb\nc\f d\r", "i\xB7\x1D"},

       // U+000B VT '\v' is _not_ valid whitespace to be stripped.
       {"ab\vcd", nullptr},

       // Empty string should yield an empty result.
       {"", ""},
   };
   for (const auto& test_case : kTestCases) {
     SCOPED_TRACE(::testing::Message()
                  << EscapeAllExceptUnreserved(test_case.in));
     std::string output;
     bool success =
         Base64Decode(test_case.in, &output, Base64DecodePolicy::kForgiving);
     bool expected_success = test_case.expected_out != nullptr;
     EXPECT_EQ(success, expected_success);
     if (expected_success) {
       EXPECT_EQ(output, test_case.expected_out);
     }
   }
 }

 TEST(Base64Test, Binary) {
   const uint8_t kData[] = {0x00, 0x01, 0xFE, 0xFF};

   std::string binary_encoded = Base64Encode(kData);

   // Check that encoding the same data through the StringPiece interface gives
   // the same results.
   std::string string_piece_encoded;
   Base64Encode(StringPiece(reinterpret_cast<const char*>(kData), sizeof(kData)),
                &string_piece_encoded);

   EXPECT_EQ(binary_encoded, string_piece_encoded);

   EXPECT_THAT(Base64Decode(binary_encoded),
               testing::Optional(testing::ElementsAreArray(kData)));
   EXPECT_FALSE(Base64Decode("invalid base64!"));

   std::string encoded_with_prefix = "PREFIX";
   Base64EncodeAppend(kData, &encoded_with_prefix);
   EXPECT_EQ(encoded_with_prefix, "PREFIX" + binary_encoded);
 }

 TEST(Base64Test, InPlace) {
   const std::string kText = "hello world";
   const std::string kBase64Text = "aGVsbG8gd29ybGQ=";
   std::string text(kText);

   Base64Encode(text, &text);
   EXPECT_EQ(kBase64Text, text);

   bool ok = Base64Decode(text, &text);
   EXPECT_TRUE(ok);
   EXPECT_EQ(text, kText);
 }

 TEST(Base64Test, Overflow) {
   // `Base64Encode` makes the input larger, which means inputs whose base64
   // output overflows `size_t`. Actually allocating a span of this size will
   // likely fail, but we test it with a fake span and assume a correct
   // implementation will check for overflow before touching the input.
   //
   // Note that, with or without an overflow check, the function will still
   // crash. This test is only meaningful because `EXPECT_CHECK_DEATH` looks for
   // a `CHECK`-based failure.
   uint8_t b;
   auto large_span = base::make_span(&b, MODP_B64_MAX_INPUT_LEN + 1);
   EXPECT_CHECK_DEATH(Base64Encode(large_span));

   std::string output = "PREFIX";
   EXPECT_CHECK_DEATH(Base64EncodeAppend(large_span, &output));

   // `modp_b64_encode_data_len` is a macro, so check `MODP_B64_MAX_INPUT_LEN` is
   // correct be verifying the computation doesn't overflow.
   base::CheckedNumeric<size_t> max_len = MODP_B64_MAX_INPUT_LEN;
   EXPECT_TRUE(modp_b64_encode_data_len(max_len).IsValid());
 }

 }  // namespace base
	// Copyright 2012 The Chromium Authors
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "base/base64.h"

	#include "base/numerics/checked_math.h"
	#include "base/strings/escape.h"
	#include "base/test/gtest_util.h"
	#include "testing/gmock/include/gmock/gmock.h"
	#include "testing/gtest/include/gtest/gtest.h"
	#include "third_party/modp_b64/modp_b64.h"

	namespace base {

	TEST(Base64Test, Basic) {
	const std::string kText = "hello world";
	const std::string kBase64Text = "aGVsbG8gd29ybGQ=";

	std::string encoded;
	std::string decoded;
	bool ok;

	Base64Encode(kText, &encoded);
	EXPECT_EQ(kBase64Text, encoded);

	ok = Base64Decode(encoded, &decoded);
	EXPECT_TRUE(ok);
	EXPECT_EQ(kText, decoded);
	}

	TEST(Base64Test, Forgiving) {
	struct {
	const char* in;

	// nullptr indicates a decode failure.
	const char* expected_out;
	} kTestCases[] = {
	// Failures that should apply in all decoding modes:
	//
	// - Characters not in the base64 alphabet
	{"abc&", nullptr},
	{"ab-d", nullptr},
	// - input len % 4 == 1
	{"abcde", nullptr},
	{"a", nullptr},

	// Invalid padding causes failure if kForgiving is set.
	{"abcd=", nullptr},
	{"abcd==", nullptr},
	{"abcd===", nullptr},
	{"abcd====", nullptr},
	{"abcd==============", nullptr},
	{"=", nullptr},
	{"====", nullptr},

	// Otherwise, inputs that are multiples of 4 always succeed, this matches
	// kStrict mode.
	{"abcd", "i\xB7\x1D"},
	{"abc=", "i\xB7"},
	{"abcdefgh", "i\xB7\x1Dy\xF8!"},

	// kForgiving mode allows for omitting padding (to a multiple of 4) if
	// len % 4 != 1.
	{"abcdef", "i\xB7\x1Dy"},
	{"abc", "i\xB7"},
	{"ab", "i"},

	// Whitespace should be allowed if kForgiving is set, matching
	// https://infra.spec.whatwg.org/#ascii-whitespace:
	// ASCII whitespace is U+0009 TAB '\t', U+000A LF '\n', U+000C FF '\f',
	// U+000D CR '\r', or U+0020 SPACE ' '.
	{" a bcd", "i\xB7\x1D"},
	{"ab\t\tc=", "i\xB7"},
	{"ab c\ndefgh", "i\xB7\x1Dy\xF8!"},
	{"a\tb\nc\f d\r", "i\xB7\x1D"},

	// U+000B VT '\v' is _not_ valid whitespace to be stripped.
	{"ab\vcd", nullptr},

	// Empty string should yield an empty result.
	{"", ""},
	};
	for (const auto& test_case : kTestCases) {
	SCOPED_TRACE(::testing::Message()
	<< EscapeAllExceptUnreserved(test_case.in));
	std::string output;
	bool success =
	Base64Decode(test_case.in, &output, Base64DecodePolicy::kForgiving);
	bool expected_success = test_case.expected_out != nullptr;
	EXPECT_EQ(success, expected_success);
	if (expected_success) {
	EXPECT_EQ(output, test_case.expected_out);
	}
	}
	}

	TEST(Base64Test, Binary) {
	const uint8_t kData[] = {0x00, 0x01, 0xFE, 0xFF};

	std::string binary_encoded = Base64Encode(kData);

	// Check that encoding the same data through the StringPiece interface gives
	// the same results.
	std::string string_piece_encoded;
	Base64Encode(StringPiece(reinterpret_cast<const char*>(kData), sizeof(kData)),
	&string_piece_encoded);

	EXPECT_EQ(binary_encoded, string_piece_encoded);

	EXPECT_THAT(Base64Decode(binary_encoded),
	testing::Optional(testing::ElementsAreArray(kData)));
	EXPECT_FALSE(Base64Decode("invalid base64!"));

	std::string encoded_with_prefix = "PREFIX";
	Base64EncodeAppend(kData, &encoded_with_prefix);
	EXPECT_EQ(encoded_with_prefix, "PREFIX" + binary_encoded);
	}

	TEST(Base64Test, InPlace) {
	const std::string kText = "hello world";
	const std::string kBase64Text = "aGVsbG8gd29ybGQ=";
	std::string text(kText);

	Base64Encode(text, &text);
	EXPECT_EQ(kBase64Text, text);

	bool ok = Base64Decode(text, &text);
	EXPECT_TRUE(ok);
	EXPECT_EQ(text, kText);
	}

	TEST(Base64Test, Overflow) {
	// `Base64Encode` makes the input larger, which means inputs whose base64
	// output overflows `size_t`. Actually allocating a span of this size will
	// likely fail, but we test it with a fake span and assume a correct
	// implementation will check for overflow before touching the input.
	//
	// Note that, with or without an overflow check, the function will still
	// crash. This test is only meaningful because `EXPECT_CHECK_DEATH` looks for
	// a `CHECK`-based failure.
	uint8_t b;
	auto large_span = base::make_span(&b, MODP_B64_MAX_INPUT_LEN + 1);
	EXPECT_CHECK_DEATH(Base64Encode(large_span));

	std::string output = "PREFIX";
	EXPECT_CHECK_DEATH(Base64EncodeAppend(large_span, &output));

	// `modp_b64_encode_data_len` is a macro, so check `MODP_B64_MAX_INPUT_LEN` is
	// correct be verifying the computation doesn't overflow.
	base::CheckedNumeric<size_t> max_len = MODP_B64_MAX_INPUT_LEN;
	EXPECT_TRUE(modp_b64_encode_data_len(max_len).IsValid());
	}

	} // namespace base