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nodejs/tools/inspector_protocol/encoding/encoding_test.cc
Michaël Zasso 5aaa7fee2e tools: update inspector_protocol to 0aafd2
Co-authored-by: Ben Noordhuis <info@bnoordhuis.nl>
PR-URL: https://github.com/nodejs/node/pull/27770
Reviewed-By: Ben Noordhuis <info@bnoordhuis.nl>
Reviewed-By: Eugene Ostroukhov <eostroukhov@google.com>
Reviewed-By: Rich Trott <rtrott@gmail.com>
2019-06-01 09:28:34 +02:00

1839 lines
70 KiB
C++

// Copyright 2018 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "encoding.h"
#include <array>
#include <clocale>
#include <cmath>
#include <cstdlib>
#include <cstring>
#include <iomanip>
#include <iostream>
#include <sstream>
#include <string>
#include "encoding_test_helper.h"
using testing::ElementsAreArray;
namespace v8_inspector_protocol_encoding {
class TestPlatform : public json::Platform {
bool StrToD(const char* str, double* result) const override {
// This is not thread-safe
// (see https://en.cppreference.com/w/cpp/locale/setlocale)
// but good enough for a unittest.
const char* saved_locale = std::setlocale(LC_NUMERIC, nullptr);
char* end;
*result = std::strtod(str, &end);
std::setlocale(LC_NUMERIC, saved_locale);
if (errno == ERANGE) {
// errno must be reset, e.g. see the example here:
// https://en.cppreference.com/w/cpp/string/byte/strtof
errno = 0;
return false;
}
return end == str + strlen(str);
}
std::unique_ptr<char[]> DToStr(double value) const override {
std::stringstream ss;
ss.imbue(std::locale("C"));
ss << value;
std::string str = ss.str();
std::unique_ptr<char[]> result(new char[str.size() + 1]);
memcpy(result.get(), str.c_str(), str.size() + 1);
return result;
}
};
const json::Platform& GetTestPlatform() {
static TestPlatform* platform = new TestPlatform;
return *platform;
}
// =============================================================================
// span - sequence of bytes
// =============================================================================
template <typename T>
class SpanTest : public ::testing::Test {};
using TestTypes = ::testing::Types<uint8_t, uint16_t>;
TYPED_TEST_SUITE(SpanTest, TestTypes);
TYPED_TEST(SpanTest, Empty) {
span<TypeParam> empty;
EXPECT_TRUE(empty.empty());
EXPECT_EQ(0u, empty.size());
EXPECT_EQ(0u, empty.size_bytes());
EXPECT_EQ(empty.begin(), empty.end());
}
TYPED_TEST(SpanTest, SingleItem) {
TypeParam single_item = 42;
span<TypeParam> singular(&single_item, 1);
EXPECT_FALSE(singular.empty());
EXPECT_EQ(1u, singular.size());
EXPECT_EQ(sizeof(TypeParam), singular.size_bytes());
EXPECT_EQ(singular.begin() + 1, singular.end());
EXPECT_EQ(42, singular[0]);
}
TYPED_TEST(SpanTest, FiveItems) {
std::vector<TypeParam> test_input = {31, 32, 33, 34, 35};
span<TypeParam> five_items(test_input.data(), 5);
EXPECT_FALSE(five_items.empty());
EXPECT_EQ(5u, five_items.size());
EXPECT_EQ(sizeof(TypeParam) * 5, five_items.size_bytes());
EXPECT_EQ(five_items.begin() + 5, five_items.end());
EXPECT_EQ(31, five_items[0]);
EXPECT_EQ(32, five_items[1]);
EXPECT_EQ(33, five_items[2]);
EXPECT_EQ(34, five_items[3]);
EXPECT_EQ(35, five_items[4]);
span<TypeParam> three_items = five_items.subspan(2);
EXPECT_EQ(3u, three_items.size());
EXPECT_EQ(33, three_items[0]);
EXPECT_EQ(34, three_items[1]);
EXPECT_EQ(35, three_items[2]);
span<TypeParam> two_items = five_items.subspan(2, 2);
EXPECT_EQ(2u, two_items.size());
EXPECT_EQ(33, two_items[0]);
EXPECT_EQ(34, two_items[1]);
}
TEST(SpanFromTest, FromConstCharAndLiteral) {
// Testing this is useful because strlen(nullptr) is undefined.
EXPECT_EQ(nullptr, SpanFrom(nullptr).data());
EXPECT_EQ(0u, SpanFrom(nullptr).size());
const char* kEmpty = "";
EXPECT_EQ(kEmpty, reinterpret_cast<const char*>(SpanFrom(kEmpty).data()));
EXPECT_EQ(0u, SpanFrom(kEmpty).size());
const char* kFoo = "foo";
EXPECT_EQ(kFoo, reinterpret_cast<const char*>(SpanFrom(kFoo).data()));
EXPECT_EQ(3u, SpanFrom(kFoo).size());
EXPECT_EQ(3u, SpanFrom("foo").size());
}
// =============================================================================
// Status and Error codes
// =============================================================================
TEST(StatusTest, StatusToASCIIString) {
Status ok_status;
EXPECT_EQ("OK", ok_status.ToASCIIString());
Status json_error(Error::JSON_PARSER_COLON_EXPECTED, 42);
EXPECT_EQ("JSON: colon expected at position 42", json_error.ToASCIIString());
Status cbor_error(Error::CBOR_TRAILING_JUNK, 21);
EXPECT_EQ("CBOR: trailing junk at position 21", cbor_error.ToASCIIString());
}
namespace cbor {
// =============================================================================
// Detecting CBOR content
// =============================================================================
TEST(IsCBORMessage, SomeSmokeTests) {
std::vector<uint8_t> empty;
EXPECT_FALSE(IsCBORMessage(SpanFrom(empty)));
std::vector<uint8_t> hello = {'H', 'e', 'l', 'o', ' ', 't',
'h', 'e', 'r', 'e', '!'};
EXPECT_FALSE(IsCBORMessage(SpanFrom(hello)));
std::vector<uint8_t> example = {0xd8, 0x5a, 0, 0, 0, 0};
EXPECT_TRUE(IsCBORMessage(SpanFrom(example)));
std::vector<uint8_t> one = {0xd8, 0x5a, 0, 0, 0, 1, 1};
EXPECT_TRUE(IsCBORMessage(SpanFrom(one)));
}
// =============================================================================
// Encoding individual CBOR items
// cbor::CBORTokenizer - for parsing individual CBOR items
// =============================================================================
//
// EncodeInt32 / CBORTokenTag::INT32
//
TEST(EncodeDecodeInt32Test, Roundtrips23) {
// This roundtrips the int32_t value 23 through the pair of EncodeInt32 /
// CBORTokenizer; this is interesting since 23 is encoded as a single byte.
std::vector<uint8_t> encoded;
EncodeInt32(23, &encoded);
// first three bits: major type = 0; remaining five bits: additional info =
// value 23.
EXPECT_THAT(encoded, ElementsAreArray(std::array<uint8_t, 1>{{23}}));
// Reverse direction: decode with CBORTokenizer.
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::INT32, tokenizer.TokenTag());
EXPECT_EQ(23, tokenizer.GetInt32());
tokenizer.Next();
EXPECT_EQ(CBORTokenTag::DONE, tokenizer.TokenTag());
}
TEST(EncodeDecodeInt32Test, RoundtripsUint8) {
// This roundtrips the int32_t value 42 through the pair of EncodeInt32 /
// CBORTokenizer. This is different from Roundtrip23 because 42 is encoded
// in an extra byte after the initial one.
std::vector<uint8_t> encoded;
EncodeInt32(42, &encoded);
// first three bits: major type = 0;
// remaining five bits: additional info = 24, indicating payload is uint8.
EXPECT_THAT(encoded, ElementsAreArray(std::array<uint8_t, 2>{{24, 42}}));
// Reverse direction: decode with CBORTokenizer.
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::INT32, tokenizer.TokenTag());
EXPECT_EQ(42, tokenizer.GetInt32());
tokenizer.Next();
EXPECT_EQ(CBORTokenTag::DONE, tokenizer.TokenTag());
}
TEST(EncodeDecodeInt32Test, RoundtripsUint16) {
// 500 is encoded as a uint16 after the initial byte.
std::vector<uint8_t> encoded;
EncodeInt32(500, &encoded);
// 1 for initial byte, 2 for uint16.
EXPECT_EQ(3u, encoded.size());
// first three bits: major type = 0;
// remaining five bits: additional info = 25, indicating payload is uint16.
EXPECT_EQ(25, encoded[0]);
EXPECT_EQ(0x01, encoded[1]);
EXPECT_EQ(0xf4, encoded[2]);
// Reverse direction: decode with CBORTokenizer.
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::INT32, tokenizer.TokenTag());
EXPECT_EQ(500, tokenizer.GetInt32());
tokenizer.Next();
EXPECT_EQ(CBORTokenTag::DONE, tokenizer.TokenTag());
}
TEST(EncodeDecodeInt32Test, RoundtripsInt32Max) {
// std::numeric_limits<int32_t> is encoded as a uint32 after the initial byte.
std::vector<uint8_t> encoded;
EncodeInt32(std::numeric_limits<int32_t>::max(), &encoded);
// 1 for initial byte, 4 for the uint32.
// first three bits: major type = 0;
// remaining five bits: additional info = 26, indicating payload is uint32.
EXPECT_THAT(
encoded,
ElementsAreArray(std::array<uint8_t, 5>{{26, 0x7f, 0xff, 0xff, 0xff}}));
// Reverse direction: decode with CBORTokenizer.
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::INT32, tokenizer.TokenTag());
EXPECT_EQ(std::numeric_limits<int32_t>::max(), tokenizer.GetInt32());
tokenizer.Next();
EXPECT_EQ(CBORTokenTag::DONE, tokenizer.TokenTag());
}
TEST(EncodeDecodeInt32Test, CantRoundtripUint32) {
// 0xdeadbeef is a value which does not fit below
// std::numerical_limits<int32_t>::max(), so we can't encode
// it with EncodeInt32. However, CBOR does support this, so we
// encode it here manually with the internal routine, just to observe
// that it's considered an invalid int32 by CBORTokenizer.
std::vector<uint8_t> encoded;
internals::WriteTokenStart(MajorType::UNSIGNED, 0xdeadbeef, &encoded);
// 1 for initial byte, 4 for the uint32.
// first three bits: major type = 0;
// remaining five bits: additional info = 26, indicating payload is uint32.
EXPECT_THAT(
encoded,
ElementsAreArray(std::array<uint8_t, 5>{{26, 0xde, 0xad, 0xbe, 0xef}}));
// Now try to decode; we treat this as an invalid INT32.
CBORTokenizer tokenizer(SpanFrom(encoded));
// 0xdeadbeef is > std::numerical_limits<int32_t>::max().
EXPECT_EQ(CBORTokenTag::ERROR_VALUE, tokenizer.TokenTag());
EXPECT_EQ(Error::CBOR_INVALID_INT32, tokenizer.Status().error);
}
TEST(EncodeDecodeInt32Test, DecodeErrorCases) {
struct TestCase {
std::vector<uint8_t> data;
std::string msg;
};
std::vector<TestCase> tests{
{TestCase{
{24},
"additional info = 24 would require 1 byte of payload (but it's 0)"},
TestCase{{27, 0xaa, 0xbb, 0xcc},
"additional info = 27 would require 8 bytes of payload (but "
"it's 3)"},
TestCase{{29}, "additional info = 29 isn't recognized"}}};
for (const TestCase& test : tests) {
SCOPED_TRACE(test.msg);
CBORTokenizer tokenizer(SpanFrom(test.data));
EXPECT_EQ(CBORTokenTag::ERROR_VALUE, tokenizer.TokenTag());
EXPECT_EQ(Error::CBOR_INVALID_INT32, tokenizer.Status().error);
}
}
TEST(EncodeDecodeInt32Test, RoundtripsMinus24) {
// This roundtrips the int32_t value -24 through the pair of EncodeInt32 /
// CBORTokenizer; this is interesting since -24 is encoded as
// a single byte as NEGATIVE, and it tests the specific encoding
// (note how for unsigned the single byte covers values up to 23).
// Additional examples are covered in RoundtripsAdditionalExamples.
std::vector<uint8_t> encoded;
EncodeInt32(-24, &encoded);
// first three bits: major type = 1; remaining five bits: additional info =
// value 23.
EXPECT_THAT(encoded, ElementsAreArray(std::array<uint8_t, 1>{{1 << 5 | 23}}));
// Reverse direction: decode with CBORTokenizer.
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::INT32, tokenizer.TokenTag());
EXPECT_EQ(-24, tokenizer.GetInt32());
tokenizer.Next();
EXPECT_EQ(CBORTokenTag::DONE, tokenizer.TokenTag());
}
TEST(EncodeDecodeInt32Test, RoundtripsAdditionalNegativeExamples) {
std::vector<int32_t> examples = {-1,
-10,
-24,
-25,
-300,
-30000,
-300 * 1000,
-1000 * 1000,
-1000 * 1000 * 1000,
std::numeric_limits<int32_t>::min()};
for (int32_t example : examples) {
SCOPED_TRACE(std::string("example ") + std::to_string(example));
std::vector<uint8_t> encoded;
EncodeInt32(example, &encoded);
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::INT32, tokenizer.TokenTag());
EXPECT_EQ(example, tokenizer.GetInt32());
tokenizer.Next();
EXPECT_EQ(CBORTokenTag::DONE, tokenizer.TokenTag());
}
}
//
// EncodeString16 / CBORTokenTag::STRING16
//
TEST(EncodeDecodeString16Test, RoundtripsEmpty) {
// This roundtrips the empty utf16 string through the pair of EncodeString16 /
// CBORTokenizer.
std::vector<uint8_t> encoded;
EncodeString16(span<uint16_t>(), &encoded);
EXPECT_EQ(1u, encoded.size());
// first three bits: major type = 2; remaining five bits: additional info =
// size 0.
EXPECT_EQ(2 << 5, encoded[0]);
// Reverse direction: decode with CBORTokenizer.
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::STRING16, tokenizer.TokenTag());
span<uint8_t> decoded_string16_wirerep = tokenizer.GetString16WireRep();
EXPECT_TRUE(decoded_string16_wirerep.empty());
tokenizer.Next();
EXPECT_EQ(CBORTokenTag::DONE, tokenizer.TokenTag());
}
// On the wire, we STRING16 is encoded as little endian (least
// significant byte first). The host may or may not be little endian,
// so this routine follows the advice in
// https://commandcenter.blogspot.com/2012/04/byte-order-fallacy.html.
std::vector<uint16_t> String16WireRepToHost(span<uint8_t> in) {
// must be even number of bytes.
CHECK_EQ(in.size() & 1, 0u);
std::vector<uint16_t> host_out;
for (size_t ii = 0; ii < in.size(); ii += 2)
host_out.push_back(in[ii + 1] << 8 | in[ii]);
return host_out;
}
TEST(EncodeDecodeString16Test, RoundtripsHelloWorld) {
// This roundtrips the hello world message which is given here in utf16
// characters. 0xd83c, 0xdf0e: UTF16 encoding for the "Earth Globe Americas"
// character, 🌎.
std::array<uint16_t, 10> msg{
{'H', 'e', 'l', 'l', 'o', ',', ' ', 0xd83c, 0xdf0e, '.'}};
std::vector<uint8_t> encoded;
EncodeString16(span<uint16_t>(msg.data(), msg.size()), &encoded);
// This will be encoded as BYTE_STRING of length 20, so the 20 is encoded in
// the additional info part of the initial byte. Payload is two bytes for each
// UTF16 character.
uint8_t initial_byte = /*major type=*/2 << 5 | /*additional info=*/20;
std::array<uint8_t, 21> encoded_expected = {
{initial_byte, 'H', 0, 'e', 0, 'l', 0, 'l', 0, 'o', 0,
',', 0, ' ', 0, 0x3c, 0xd8, 0x0e, 0xdf, '.', 0}};
EXPECT_THAT(encoded, ElementsAreArray(encoded_expected));
// Now decode to complete the roundtrip.
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::STRING16, tokenizer.TokenTag());
std::vector<uint16_t> decoded =
String16WireRepToHost(tokenizer.GetString16WireRep());
EXPECT_THAT(decoded, ElementsAreArray(msg));
tokenizer.Next();
EXPECT_EQ(CBORTokenTag::DONE, tokenizer.TokenTag());
// For bonus points, we look at the decoded message in UTF8 as well so we can
// easily see it on the terminal screen.
std::string utf8_decoded = UTF16ToUTF8(SpanFrom(decoded));
EXPECT_EQ("Hello, 🌎.", utf8_decoded);
}
TEST(EncodeDecodeString16Test, Roundtrips500) {
// We roundtrip a message that has 250 16 bit values. Each of these are just
// set to their index. 250 is interesting because the cbor spec uses a
// BYTE_STRING of length 500 for one of their examples of how to encode the
// start of it (section 2.1) so it's easy for us to look at the first three
// bytes closely.
std::vector<uint16_t> two_fifty;
for (uint16_t ii = 0; ii < 250; ++ii)
two_fifty.push_back(ii);
std::vector<uint8_t> encoded;
EncodeString16(span<uint16_t>(two_fifty.data(), two_fifty.size()), &encoded);
EXPECT_EQ(3u + 250u * 2, encoded.size());
// Now check the first three bytes:
// Major type: 2 (BYTE_STRING)
// Additional information: 25, indicating size is represented by 2 bytes.
// Bytes 1 and 2 encode 500 (0x01f4).
EXPECT_EQ(2 << 5 | 25, encoded[0]);
EXPECT_EQ(0x01, encoded[1]);
EXPECT_EQ(0xf4, encoded[2]);
// Now decode to complete the roundtrip.
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::STRING16, tokenizer.TokenTag());
std::vector<uint16_t> decoded =
String16WireRepToHost(tokenizer.GetString16WireRep());
EXPECT_THAT(decoded, ElementsAreArray(two_fifty));
tokenizer.Next();
EXPECT_EQ(CBORTokenTag::DONE, tokenizer.TokenTag());
}
TEST(EncodeDecodeString16Test, ErrorCases) {
struct TestCase {
std::vector<uint8_t> data;
std::string msg;
};
std::vector<TestCase> tests{
{TestCase{{2 << 5 | 1, 'a'},
"length must be divisible by 2 (but it's 1)"},
TestCase{{2 << 5 | 29}, "additional info = 29 isn't recognized"},
TestCase{{2 << 5 | 9, 1, 2, 3, 4, 5, 6, 7, 8},
"length (9) points just past the end of the test case"},
TestCase{{2 << 5 | 27, 0x80, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
'a', 'b', 'c'},
"large length pointing past the end of the test case"}}};
for (const TestCase& test : tests) {
SCOPED_TRACE(test.msg);
CBORTokenizer tokenizer(SpanFrom(test.data));
EXPECT_EQ(CBORTokenTag::ERROR_VALUE, tokenizer.TokenTag());
EXPECT_EQ(Error::CBOR_INVALID_STRING16, tokenizer.Status().error);
}
}
//
// EncodeString8 / CBORTokenTag::STRING8
//
TEST(EncodeDecodeString8Test, RoundtripsHelloWorld) {
// This roundtrips the hello world message which is given here in utf8
// characters. 🌎 is a four byte utf8 character.
std::string utf8_msg = "Hello, 🌎.";
std::vector<uint8_t> msg(utf8_msg.begin(), utf8_msg.end());
std::vector<uint8_t> encoded;
EncodeString8(SpanFrom(utf8_msg), &encoded);
// This will be encoded as STRING of length 12, so the 12 is encoded in
// the additional info part of the initial byte. Payload is one byte per
// utf8 byte.
uint8_t initial_byte = /*major type=*/3 << 5 | /*additional info=*/12;
std::array<uint8_t, 13> encoded_expected = {{initial_byte, 'H', 'e', 'l', 'l',
'o', ',', ' ', 0xF0, 0x9f, 0x8c,
0x8e, '.'}};
EXPECT_THAT(encoded, ElementsAreArray(encoded_expected));
// Now decode to complete the roundtrip.
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::STRING8, tokenizer.TokenTag());
std::vector<uint8_t> decoded(tokenizer.GetString8().begin(),
tokenizer.GetString8().end());
EXPECT_THAT(decoded, ElementsAreArray(msg));
tokenizer.Next();
EXPECT_EQ(CBORTokenTag::DONE, tokenizer.TokenTag());
}
TEST(EncodeDecodeString8Test, ErrorCases) {
struct TestCase {
std::vector<uint8_t> data;
std::string msg;
};
std::vector<TestCase> tests{
{TestCase{{3 << 5 | 29}, "additional info = 29 isn't recognized"},
TestCase{{3 << 5 | 9, 1, 2, 3, 4, 5, 6, 7, 8},
"length (9) points just past the end of the test case"},
TestCase{{3 << 5 | 27, 0x80, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
'a', 'b', 'c'},
"large length pointing past the end of the test case"}}};
for (const TestCase& test : tests) {
SCOPED_TRACE(test.msg);
CBORTokenizer tokenizer(SpanFrom(test.data));
EXPECT_EQ(CBORTokenTag::ERROR_VALUE, tokenizer.TokenTag());
EXPECT_EQ(Error::CBOR_INVALID_STRING8, tokenizer.Status().error);
}
}
TEST(EncodeFromLatin1Test, ConvertsToUTF8IfNeeded) {
std::vector<std::pair<std::string, std::string>> examples = {
{"Hello, world.", "Hello, world."},
{"Above: \xDC"
"ber",
"Above: Über"},
{"\xA5 500 are about \xA3 3.50; a y with umlaut is \xFF",
"¥ 500 are about £ 3.50; a y with umlaut is ÿ"}};
for (const auto& example : examples) {
const std::string& latin1 = example.first;
const std::string& expected_utf8 = example.second;
std::vector<uint8_t> encoded;
EncodeFromLatin1(SpanFrom(latin1), &encoded);
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::STRING8, tokenizer.TokenTag());
std::vector<uint8_t> decoded(tokenizer.GetString8().begin(),
tokenizer.GetString8().end());
std::string decoded_str(decoded.begin(), decoded.end());
EXPECT_THAT(decoded_str, testing::Eq(expected_utf8));
}
}
TEST(EncodeFromUTF16Test, ConvertsToUTF8IfEasy) {
std::vector<uint16_t> ascii = {'e', 'a', 's', 'y'};
std::vector<uint8_t> encoded;
EncodeFromUTF16(span<uint16_t>(ascii.data(), ascii.size()), &encoded);
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::STRING8, tokenizer.TokenTag());
std::vector<uint8_t> decoded(tokenizer.GetString8().begin(),
tokenizer.GetString8().end());
std::string decoded_str(decoded.begin(), decoded.end());
EXPECT_THAT(decoded_str, testing::Eq("easy"));
}
TEST(EncodeFromUTF16Test, EncodesAsString16IfNeeded) {
// Since this message contains non-ASCII characters, the routine is
// forced to encode as UTF16. We see this below by checking that the
// token tag is STRING16.
std::vector<uint16_t> msg = {'H', 'e', 'l', 'l', 'o',
',', ' ', 0xd83c, 0xdf0e, '.'};
std::vector<uint8_t> encoded;
EncodeFromUTF16(span<uint16_t>(msg.data(), msg.size()), &encoded);
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::STRING16, tokenizer.TokenTag());
std::vector<uint16_t> decoded =
String16WireRepToHost(tokenizer.GetString16WireRep());
std::string utf8_decoded = UTF16ToUTF8(SpanFrom(decoded));
EXPECT_EQ("Hello, 🌎.", utf8_decoded);
}
//
// EncodeBinary / CBORTokenTag::BINARY
//
TEST(EncodeDecodeBinaryTest, RoundtripsHelloWorld) {
std::vector<uint8_t> binary = {'H', 'e', 'l', 'l', 'o', ',', ' ',
'w', 'o', 'r', 'l', 'd', '.'};
std::vector<uint8_t> encoded;
EncodeBinary(span<uint8_t>(binary.data(), binary.size()), &encoded);
// So, on the wire we see that the binary blob travels unmodified.
EXPECT_THAT(
encoded,
ElementsAreArray(std::array<uint8_t, 15>{
{(6 << 5 | 22), // tag 22 indicating base64 interpretation in JSON
(2 << 5 | 13), // BYTE_STRING (type 2) of length 13
'H', 'e', 'l', 'l', 'o', ',', ' ', 'w', 'o', 'r', 'l', 'd', '.'}}));
std::vector<uint8_t> decoded;
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::BINARY, tokenizer.TokenTag());
EXPECT_EQ(0, static_cast<int>(tokenizer.Status().error));
decoded = std::vector<uint8_t>(tokenizer.GetBinary().begin(),
tokenizer.GetBinary().end());
EXPECT_THAT(decoded, ElementsAreArray(binary));
tokenizer.Next();
EXPECT_EQ(CBORTokenTag::DONE, tokenizer.TokenTag());
}
TEST(EncodeDecodeBinaryTest, ErrorCases) {
struct TestCase {
std::vector<uint8_t> data;
std::string msg;
};
std::vector<TestCase> tests{{TestCase{
{6 << 5 | 22, // tag 22 indicating base64 interpretation in JSON
2 << 5 | 27, // BYTE_STRING (type 2), followed by 8 bytes length
0x80, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00},
"large length pointing past the end of the test case"}}};
for (const TestCase& test : tests) {
SCOPED_TRACE(test.msg);
CBORTokenizer tokenizer(SpanFrom(test.data));
EXPECT_EQ(CBORTokenTag::ERROR_VALUE, tokenizer.TokenTag());
EXPECT_EQ(Error::CBOR_INVALID_BINARY, tokenizer.Status().error);
}
}
//
// EncodeDouble / CBORTokenTag::DOUBLE
//
TEST(EncodeDecodeDoubleTest, RoundtripsWikipediaExample) {
// https://en.wikipedia.org/wiki/Double-precision_floating-point_format
// provides the example of a hex representation 3FD5 5555 5555 5555, which
// approximates 1/3.
const double kOriginalValue = 1.0 / 3;
std::vector<uint8_t> encoded;
EncodeDouble(kOriginalValue, &encoded);
// first three bits: major type = 7; remaining five bits: additional info =
// value 27. This is followed by 8 bytes of payload (which match Wikipedia).
EXPECT_THAT(
encoded,
ElementsAreArray(std::array<uint8_t, 9>{
{7 << 5 | 27, 0x3f, 0xd5, 0x55, 0x55, 0x55, 0x55, 0x55, 0x55}}));
// Reverse direction: decode and compare with original value.
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::DOUBLE, tokenizer.TokenTag());
EXPECT_THAT(tokenizer.GetDouble(), testing::DoubleEq(kOriginalValue));
tokenizer.Next();
EXPECT_EQ(CBORTokenTag::DONE, tokenizer.TokenTag());
}
TEST(EncodeDecodeDoubleTest, RoundtripsAdditionalExamples) {
std::vector<double> examples = {0.0,
1.0,
-1.0,
3.1415,
std::numeric_limits<double>::min(),
std::numeric_limits<double>::max(),
std::numeric_limits<double>::infinity(),
std::numeric_limits<double>::quiet_NaN()};
for (double example : examples) {
SCOPED_TRACE(std::string("example ") + std::to_string(example));
std::vector<uint8_t> encoded;
EncodeDouble(example, &encoded);
CBORTokenizer tokenizer(SpanFrom(encoded));
EXPECT_EQ(CBORTokenTag::DOUBLE, tokenizer.TokenTag());
if (std::isnan(example))
EXPECT_TRUE(std::isnan(tokenizer.GetDouble()));
else
EXPECT_THAT(tokenizer.GetDouble(), testing::DoubleEq(example));
tokenizer.Next();
EXPECT_EQ(CBORTokenTag::DONE, tokenizer.TokenTag());
}
}
// =============================================================================
// cbor::NewCBOREncoder - for encoding from a streaming parser
// =============================================================================
void EncodeUTF8ForTest(const std::string& key, std::vector<uint8_t>* out) {
EncodeString8(SpanFrom(key), out);
}
TEST(JSONToCBOREncoderTest, SevenBitStrings) {
// When a string can be represented as 7 bit ASCII, the encoder will use the
// STRING (major Type 3) type, so the actual characters end up as bytes on the
// wire.
std::vector<uint8_t> encoded;
Status status;
std::unique_ptr<StreamingParserHandler> encoder =
NewCBOREncoder(&encoded, &status);
std::vector<uint16_t> utf16 = {'f', 'o', 'o'};
encoder->HandleString16(span<uint16_t>(utf16.data(), utf16.size()));
EXPECT_EQ(Error::OK, status.error);
// Here we assert that indeed, seven bit strings are represented as
// bytes on the wire, "foo" is just "foo".
EXPECT_THAT(encoded,
ElementsAreArray(std::array<uint8_t, 4>{
{/*major type 3*/ 3 << 5 | /*length*/ 3, 'f', 'o', 'o'}}));
}
TEST(JsonCborRoundtrip, EncodingDecoding) {
// Hits all the cases except binary and error in StreamingParserHandler, first
// parsing a JSON message into CBOR, then parsing it back from CBOR into JSON.
std::string json =
"{"
"\"string\":\"Hello, \\ud83c\\udf0e.\","
"\"double\":3.1415,"
"\"int\":1,"
"\"negative int\":-1,"
"\"bool\":true,"
"\"null\":null,"
"\"array\":[1,2,3]"
"}";
std::vector<uint8_t> encoded;
Status status;
std::unique_ptr<StreamingParserHandler> encoder =
NewCBOREncoder(&encoded, &status);
span<uint8_t> ascii_in = SpanFrom(json);
json::ParseJSON(GetTestPlatform(), ascii_in, encoder.get());
std::vector<uint8_t> expected = {
0xd8, // envelope
0x5a, // byte string with 32 bit length
0, 0, 0, 94, // length is 94 bytes
};
expected.push_back(0xbf); // indef length map start
EncodeString8(SpanFrom("string"), &expected);
// This is followed by the encoded string for "Hello, 🌎."
// So, it's the same bytes that we tested above in
// EncodeDecodeString16Test.RoundtripsHelloWorld.
expected.push_back(/*major type=*/2 << 5 | /*additional info=*/20);
for (uint8_t ch : std::array<uint8_t, 20>{
{'H', 0, 'e', 0, 'l', 0, 'l', 0, 'o', 0,
',', 0, ' ', 0, 0x3c, 0xd8, 0x0e, 0xdf, '.', 0}})
expected.push_back(ch);
EncodeString8(SpanFrom("double"), &expected);
EncodeDouble(3.1415, &expected);
EncodeString8(SpanFrom("int"), &expected);
EncodeInt32(1, &expected);
EncodeString8(SpanFrom("negative int"), &expected);
EncodeInt32(-1, &expected);
EncodeString8(SpanFrom("bool"), &expected);
expected.push_back(7 << 5 | 21); // RFC 7049 Section 2.3, Table 2: true
EncodeString8(SpanFrom("null"), &expected);
expected.push_back(7 << 5 | 22); // RFC 7049 Section 2.3, Table 2: null
EncodeString8(SpanFrom("array"), &expected);
expected.push_back(0xd8); // envelope
expected.push_back(0x5a); // byte string with 32 bit length
// the length is 5 bytes (that's up to end indef length array below).
for (uint8_t ch : std::array<uint8_t, 4>{{0, 0, 0, 5}})
expected.push_back(ch);
expected.push_back(0x9f); // RFC 7049 Section 2.2.1, indef length array start
expected.push_back(1); // Three UNSIGNED values (easy since Major Type 0)
expected.push_back(2);
expected.push_back(3);
expected.push_back(0xff); // End indef length array
expected.push_back(0xff); // End indef length map
EXPECT_TRUE(status.ok());
EXPECT_THAT(encoded, ElementsAreArray(expected));
// And now we roundtrip, decoding the message we just encoded.
std::string decoded;
std::unique_ptr<StreamingParserHandler> json_encoder =
NewJSONEncoder(&GetTestPlatform(), &decoded, &status);
ParseCBOR(span<uint8_t>(encoded.data(), encoded.size()), json_encoder.get());
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ(json, decoded);
}
TEST(JsonCborRoundtrip, MoreRoundtripExamples) {
std::vector<std::string> examples = {
// Tests that after closing a nested objects, additional key/value pairs
// are considered.
"{\"foo\":{\"bar\":1},\"baz\":2}", "{\"foo\":[1,2,3],\"baz\":2}"};
for (const std::string& json : examples) {
SCOPED_TRACE(std::string("example: ") + json);
std::vector<uint8_t> encoded;
Status status;
std::unique_ptr<StreamingParserHandler> encoder =
NewCBOREncoder(&encoded, &status);
span<uint8_t> ascii_in = SpanFrom(json);
ParseJSON(GetTestPlatform(), ascii_in, encoder.get());
std::string decoded;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &decoded, &status);
ParseCBOR(span<uint8_t>(encoded.data(), encoded.size()), json_writer.get());
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ(json, decoded);
}
}
TEST(JSONToCBOREncoderTest, HelloWorldBinary_WithTripToJson) {
// The StreamingParserHandler::HandleBinary is a special case: The JSON parser
// will never call this method, because JSON does not natively support the
// binary type. So, we can't fully roundtrip. However, the other direction
// works: binary will be rendered in JSON, as a base64 string. So, we make
// calls to the encoder directly here, to construct a message, and one of
// these calls is ::HandleBinary, to which we pass a "binary" string
// containing "Hello, world.".
std::vector<uint8_t> encoded;
Status status;
std::unique_ptr<StreamingParserHandler> encoder =
NewCBOREncoder(&encoded, &status);
encoder->HandleMapBegin();
// Emit a key.
std::vector<uint16_t> key = {'f', 'o', 'o'};
encoder->HandleString16(SpanFrom(key));
// Emit the binary payload, an arbitrary array of bytes that happens to
// be the ascii message "Hello, world.".
encoder->HandleBinary(SpanFrom(std::vector<uint8_t>{
'H', 'e', 'l', 'l', 'o', ',', ' ', 'w', 'o', 'r', 'l', 'd', '.'}));
encoder->HandleMapEnd();
EXPECT_EQ(Error::OK, status.error);
// Now drive the json writer via the CBOR decoder.
std::string decoded;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &decoded, &status);
ParseCBOR(SpanFrom(encoded), json_writer.get());
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ(Status::npos(), status.pos);
// "Hello, world." in base64 is "SGVsbG8sIHdvcmxkLg==".
EXPECT_EQ("{\"foo\":\"SGVsbG8sIHdvcmxkLg==\"}", decoded);
}
// =============================================================================
// cbor::ParseCBOR - for receiving streaming parser events for CBOR messages
// =============================================================================
TEST(ParseCBORTest, ParseEmptyCBORMessage) {
// An envelope starting with 0xd8, 0x5a, with the byte length
// of 2, containing a map that's empty (0xbf for map
// start, and 0xff for map end).
std::vector<uint8_t> in = {0xd8, 0x5a, 0, 0, 0, 2, 0xbf, 0xff};
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(in.data(), in.size()), json_writer.get());
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ("{}", out);
}
TEST(ParseCBORTest, ParseCBORHelloWorld) {
const uint8_t kPayloadLen = 27;
std::vector<uint8_t> bytes = {0xd8, 0x5a, 0, 0, 0, kPayloadLen};
bytes.push_back(0xbf); // start indef length map.
EncodeString8(SpanFrom("msg"), &bytes); // key: msg
// Now write the value, the familiar "Hello, 🌎." where the globe is expressed
// as two utf16 chars.
bytes.push_back(/*major type=*/2 << 5 | /*additional info=*/20);
for (uint8_t ch : std::array<uint8_t, 20>{
{'H', 0, 'e', 0, 'l', 0, 'l', 0, 'o', 0,
',', 0, ' ', 0, 0x3c, 0xd8, 0x0e, 0xdf, '.', 0}})
bytes.push_back(ch);
bytes.push_back(0xff); // stop byte
EXPECT_EQ(kPayloadLen, bytes.size() - 6);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ("{\"msg\":\"Hello, \\ud83c\\udf0e.\"}", out);
}
TEST(ParseCBORTest, UTF8IsSupportedInKeys) {
const uint8_t kPayloadLen = 11;
std::vector<uint8_t> bytes = {cbor::InitialByteForEnvelope(),
cbor::InitialByteFor32BitLengthByteString(),
0,
0,
0,
kPayloadLen};
bytes.push_back(cbor::EncodeIndefiniteLengthMapStart());
// Two UTF16 chars.
EncodeString8(SpanFrom("🌎"), &bytes);
// Can be encoded as a single UTF16 char.
EncodeString8(SpanFrom(""), &bytes);
bytes.push_back(cbor::EncodeStop());
EXPECT_EQ(kPayloadLen, bytes.size() - 6);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ("{\"\\ud83c\\udf0e\":\"\\u263e\"}", out);
}
TEST(ParseCBORTest, NoInputError) {
std::vector<uint8_t> in = {};
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(in.data(), in.size()), json_writer.get());
EXPECT_EQ(Error::CBOR_NO_INPUT, status.error);
EXPECT_EQ("", out);
}
TEST(ParseCBORTest, InvalidStartByteError) {
// Here we test that some actual json, which usually starts with {,
// is not considered CBOR. CBOR messages must start with 0x5a, the
// envelope start byte.
std::string json = "{\"msg\": \"Hello, world.\"}";
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(SpanFrom(json), json_writer.get());
EXPECT_EQ(Error::CBOR_INVALID_START_BYTE, status.error);
EXPECT_EQ("", out);
}
TEST(ParseCBORTest, UnexpectedEofExpectedValueError) {
constexpr uint8_t kPayloadLen = 5;
std::vector<uint8_t> bytes = {0xd8, 0x5a, 0, 0, 0, kPayloadLen, // envelope
0xbf}; // map start
// A key; so value would be next.
EncodeString8(SpanFrom("key"), &bytes);
EXPECT_EQ(kPayloadLen, bytes.size() - 6);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::CBOR_UNEXPECTED_EOF_EXPECTED_VALUE, status.error);
EXPECT_EQ(bytes.size(), status.pos);
EXPECT_EQ("", out);
}
TEST(ParseCBORTest, UnexpectedEofInArrayError) {
constexpr uint8_t kPayloadLen = 8;
std::vector<uint8_t> bytes = {0xd8, 0x5a, 0, 0, 0, kPayloadLen, // envelope
0xbf}; // The byte for starting a map.
// A key; so value would be next.
EncodeString8(SpanFrom("array"), &bytes);
bytes.push_back(0x9f); // byte for indefinite length array start.
EXPECT_EQ(kPayloadLen, bytes.size() - 6);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::CBOR_UNEXPECTED_EOF_IN_ARRAY, status.error);
EXPECT_EQ(bytes.size(), status.pos);
EXPECT_EQ("", out);
}
TEST(ParseCBORTest, UnexpectedEofInMapError) {
constexpr uint8_t kPayloadLen = 1;
std::vector<uint8_t> bytes = {0xd8, 0x5a, 0, 0, 0, kPayloadLen, // envelope
0xbf}; // The byte for starting a map.
EXPECT_EQ(kPayloadLen, bytes.size() - 6);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::CBOR_UNEXPECTED_EOF_IN_MAP, status.error);
EXPECT_EQ(7u, status.pos);
EXPECT_EQ("", out);
}
TEST(ParseCBORTest, InvalidMapKeyError) {
constexpr uint8_t kPayloadLen = 2;
std::vector<uint8_t> bytes = {0xd8, 0x5a, 0,
0, 0, kPayloadLen, // envelope
0xbf, // map start
7 << 5 | 22}; // null (not a valid map key)
EXPECT_EQ(kPayloadLen, bytes.size() - 6);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::CBOR_INVALID_MAP_KEY, status.error);
EXPECT_EQ(7u, status.pos);
EXPECT_EQ("", out);
}
std::vector<uint8_t> MakeNestedCBOR(int depth) {
std::vector<uint8_t> bytes;
std::vector<EnvelopeEncoder> envelopes;
for (int ii = 0; ii < depth; ++ii) {
envelopes.emplace_back();
envelopes.back().EncodeStart(&bytes);
bytes.push_back(0xbf); // indef length map start
EncodeString8(SpanFrom("key"), &bytes);
}
EncodeString8(SpanFrom("innermost_value"), &bytes);
for (int ii = 0; ii < depth; ++ii) {
bytes.push_back(0xff); // stop byte, finishes map.
envelopes.back().EncodeStop(&bytes);
envelopes.pop_back();
}
return bytes;
}
TEST(ParseCBORTest, StackLimitExceededError) {
{ // Depth 3: no stack limit exceeded error and is easy to inspect.
std::vector<uint8_t> bytes = MakeNestedCBOR(3);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ(Status::npos(), status.pos);
EXPECT_EQ("{\"key\":{\"key\":{\"key\":\"innermost_value\"}}}", out);
}
{ // Depth 300: no stack limit exceeded.
std::vector<uint8_t> bytes = MakeNestedCBOR(300);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ(Status::npos(), status.pos);
}
// We just want to know the length of one opening map so we can compute
// where the error is encountered. So we look at a small example and find
// the second envelope start.
std::vector<uint8_t> small_example = MakeNestedCBOR(3);
size_t opening_segment_size = 1; // Start after the first envelope start.
while (opening_segment_size < small_example.size() &&
small_example[opening_segment_size] != 0xd8)
opening_segment_size++;
{ // Depth 301: limit exceeded.
std::vector<uint8_t> bytes = MakeNestedCBOR(301);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::CBOR_STACK_LIMIT_EXCEEDED, status.error);
EXPECT_EQ(opening_segment_size * 301, status.pos);
}
{ // Depth 320: still limit exceeded, and at the same pos as for 1001
std::vector<uint8_t> bytes = MakeNestedCBOR(320);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::CBOR_STACK_LIMIT_EXCEEDED, status.error);
EXPECT_EQ(opening_segment_size * 301, status.pos);
}
}
TEST(ParseCBORTest, UnsupportedValueError) {
constexpr uint8_t kPayloadLen = 6;
std::vector<uint8_t> bytes = {0xd8, 0x5a, 0, 0, 0, kPayloadLen, // envelope
0xbf}; // map start
EncodeString8(SpanFrom("key"), &bytes);
size_t error_pos = bytes.size();
bytes.push_back(6 << 5 | 5); // tags aren't supported yet.
EXPECT_EQ(kPayloadLen, bytes.size() - 6);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::CBOR_UNSUPPORTED_VALUE, status.error);
EXPECT_EQ(error_pos, status.pos);
EXPECT_EQ("", out);
}
TEST(ParseCBORTest, InvalidString16Error) {
constexpr uint8_t kPayloadLen = 11;
std::vector<uint8_t> bytes = {0xd8, 0x5a, 0, 0, 0, kPayloadLen, // envelope
0xbf}; // map start
EncodeString8(SpanFrom("key"), &bytes);
size_t error_pos = bytes.size();
// a BYTE_STRING of length 5 as value; since we interpret these as string16,
// it's going to be invalid as each character would need two bytes, but
// 5 isn't divisible by 2.
bytes.push_back(2 << 5 | 5);
for (int ii = 0; ii < 5; ++ii)
bytes.push_back(' ');
EXPECT_EQ(kPayloadLen, bytes.size() - 6);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::CBOR_INVALID_STRING16, status.error);
EXPECT_EQ(error_pos, status.pos);
EXPECT_EQ("", out);
}
TEST(ParseCBORTest, InvalidString8Error) {
constexpr uint8_t kPayloadLen = 6;
std::vector<uint8_t> bytes = {0xd8, 0x5a, 0, 0, 0, kPayloadLen, // envelope
0xbf}; // map start
EncodeString8(SpanFrom("key"), &bytes);
size_t error_pos = bytes.size();
// a STRING of length 5 as value, but we're at the end of the bytes array
// so it can't be decoded successfully.
bytes.push_back(3 << 5 | 5);
EXPECT_EQ(kPayloadLen, bytes.size() - 6);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::CBOR_INVALID_STRING8, status.error);
EXPECT_EQ(error_pos, status.pos);
EXPECT_EQ("", out);
}
TEST(ParseCBORTest, InvalidBinaryError) {
constexpr uint8_t kPayloadLen = 9;
std::vector<uint8_t> bytes = {0xd8, 0x5a, 0, 0, 0, kPayloadLen, // envelope
0xbf}; // map start
EncodeString8(SpanFrom("key"), &bytes);
size_t error_pos = bytes.size();
bytes.push_back(6 << 5 | 22); // base64 hint for JSON; indicates binary
bytes.push_back(2 << 5 | 10); // BYTE_STRING (major type 2) of length 10
// Just two garbage bytes, not enough for the binary.
bytes.push_back(0x31);
bytes.push_back(0x23);
EXPECT_EQ(kPayloadLen, bytes.size() - 6);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::CBOR_INVALID_BINARY, status.error);
EXPECT_EQ(error_pos, status.pos);
EXPECT_EQ("", out);
}
TEST(ParseCBORTest, InvalidDoubleError) {
constexpr uint8_t kPayloadLen = 8;
std::vector<uint8_t> bytes = {0xd8, 0x5a, 0, 0, 0, kPayloadLen, // envelope
0xbf}; // map start
EncodeString8(SpanFrom("key"), &bytes);
size_t error_pos = bytes.size();
bytes.push_back(7 << 5 | 27); // initial byte for double
// Just two garbage bytes, not enough to represent an actual double.
bytes.push_back(0x31);
bytes.push_back(0x23);
EXPECT_EQ(kPayloadLen, bytes.size() - 6);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::CBOR_INVALID_DOUBLE, status.error);
EXPECT_EQ(error_pos, status.pos);
EXPECT_EQ("", out);
}
TEST(ParseCBORTest, InvalidSignedError) {
constexpr uint8_t kPayloadLen = 14;
std::vector<uint8_t> bytes = {0xd8, 0x5a, 0, 0, 0, kPayloadLen, // envelope
0xbf}; // map start
EncodeString8(SpanFrom("key"), &bytes);
size_t error_pos = bytes.size();
// uint64_t max is a perfectly fine value to encode as CBOR unsigned,
// but we don't support this since we only cover the int32_t range.
internals::WriteTokenStart(MajorType::UNSIGNED,
std::numeric_limits<uint64_t>::max(), &bytes);
EXPECT_EQ(kPayloadLen, bytes.size() - 6);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::CBOR_INVALID_INT32, status.error);
EXPECT_EQ(error_pos, status.pos);
EXPECT_EQ("", out);
}
TEST(ParseCBORTest, TrailingJunk) {
constexpr uint8_t kPayloadLen = 35;
std::vector<uint8_t> bytes = {0xd8, 0x5a, 0, 0, 0, kPayloadLen, // envelope
0xbf}; // map start
EncodeString8(SpanFrom("key"), &bytes);
EncodeString8(SpanFrom("value"), &bytes);
bytes.push_back(0xff); // Up to here, it's a perfectly fine msg.
size_t error_pos = bytes.size();
EncodeString8(SpanFrom("trailing junk"), &bytes);
internals::WriteTokenStart(MajorType::UNSIGNED,
std::numeric_limits<uint64_t>::max(), &bytes);
EXPECT_EQ(kPayloadLen, bytes.size() - 6);
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(span<uint8_t>(bytes.data(), bytes.size()), json_writer.get());
EXPECT_EQ(Error::CBOR_TRAILING_JUNK, status.error);
EXPECT_EQ(error_pos, status.pos);
EXPECT_EQ("", out);
}
// =============================================================================
// cbor::AppendString8EntryToMap - for limited in-place editing of messages
// =============================================================================
template <typename T>
class AppendString8EntryToMapTest : public ::testing::Test {};
using ContainerTestTypes = ::testing::Types<std::vector<uint8_t>, std::string>;
TYPED_TEST_SUITE(AppendString8EntryToMapTest, ContainerTestTypes);
TYPED_TEST(AppendString8EntryToMapTest, AppendsEntrySuccessfully) {
constexpr uint8_t kPayloadLen = 12;
std::vector<uint8_t> bytes = {0xd8, 0x5a, 0, 0, 0, kPayloadLen, // envelope
0xbf}; // map start
size_t pos_before_payload = bytes.size() - 1;
EncodeString8(SpanFrom("key"), &bytes);
EncodeString8(SpanFrom("value"), &bytes);
bytes.push_back(0xff); // A perfectly fine cbor message.
EXPECT_EQ(kPayloadLen, bytes.size() - pos_before_payload);
TypeParam msg(bytes.begin(), bytes.end());
Status status =
AppendString8EntryToCBORMap(SpanFrom("foo"), SpanFrom("bar"), &msg);
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ(Status::npos(), status.pos);
std::string out;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(SpanFrom(msg), json_writer.get());
EXPECT_EQ("{\"key\":\"value\",\"foo\":\"bar\"}", out);
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ(Status::npos(), status.pos);
}
TYPED_TEST(AppendString8EntryToMapTest, AppendThreeEntries) {
std::vector<uint8_t> encoded = {
0xd8, 0x5a, 0, 0, 0, 2, EncodeIndefiniteLengthMapStart(), EncodeStop()};
EXPECT_EQ(Error::OK, AppendString8EntryToCBORMap(SpanFrom("key"),
SpanFrom("value"), &encoded)
.error);
EXPECT_EQ(Error::OK, AppendString8EntryToCBORMap(SpanFrom("key1"),
SpanFrom("value1"), &encoded)
.error);
EXPECT_EQ(Error::OK, AppendString8EntryToCBORMap(SpanFrom("key2"),
SpanFrom("value2"), &encoded)
.error);
TypeParam msg(encoded.begin(), encoded.end());
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> json_writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
ParseCBOR(SpanFrom(msg), json_writer.get());
EXPECT_EQ("{\"key\":\"value\",\"key1\":\"value1\",\"key2\":\"value2\"}", out);
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ(Status::npos(), status.pos);
}
TYPED_TEST(AppendString8EntryToMapTest, MapStartExpected_Error) {
std::vector<uint8_t> bytes = {
0xd8, 0x5a, 0, 0, 0, 1, EncodeIndefiniteLengthArrayStart()};
TypeParam msg(bytes.begin(), bytes.end());
Status status =
AppendString8EntryToCBORMap(SpanFrom("key"), SpanFrom("value"), &msg);
EXPECT_EQ(Error::CBOR_MAP_START_EXPECTED, status.error);
EXPECT_EQ(6u, status.pos);
}
TYPED_TEST(AppendString8EntryToMapTest, MapStopExpected_Error) {
std::vector<uint8_t> bytes = {
0xd8, 0x5a, 0, 0, 0, 2, EncodeIndefiniteLengthMapStart(), 42};
TypeParam msg(bytes.begin(), bytes.end());
Status status =
AppendString8EntryToCBORMap(SpanFrom("key"), SpanFrom("value"), &msg);
EXPECT_EQ(Error::CBOR_MAP_STOP_EXPECTED, status.error);
EXPECT_EQ(7u, status.pos);
}
TYPED_TEST(AppendString8EntryToMapTest, InvalidEnvelope_Error) {
{ // Second byte is wrong.
std::vector<uint8_t> bytes = {
0x5a, 0, 0, 0, 2, EncodeIndefiniteLengthMapStart(), EncodeStop(), 0};
TypeParam msg(bytes.begin(), bytes.end());
Status status =
AppendString8EntryToCBORMap(SpanFrom("key"), SpanFrom("value"), &msg);
EXPECT_EQ(Error::CBOR_INVALID_ENVELOPE, status.error);
EXPECT_EQ(0u, status.pos);
}
{ // Second byte is wrong.
std::vector<uint8_t> bytes = {
0xd8, 0x7a, 0, 0, 0, 2, EncodeIndefiniteLengthMapStart(), EncodeStop()};
TypeParam msg(bytes.begin(), bytes.end());
Status status =
AppendString8EntryToCBORMap(SpanFrom("key"), SpanFrom("value"), &msg);
EXPECT_EQ(Error::CBOR_INVALID_ENVELOPE, status.error);
EXPECT_EQ(0u, status.pos);
}
{ // Invalid envelope size example.
std::vector<uint8_t> bytes = {
0xd8, 0x5a, 0, 0, 0, 3, EncodeIndefiniteLengthMapStart(), EncodeStop(),
};
TypeParam msg(bytes.begin(), bytes.end());
Status status =
AppendString8EntryToCBORMap(SpanFrom("key"), SpanFrom("value"), &msg);
EXPECT_EQ(Error::CBOR_INVALID_ENVELOPE, status.error);
EXPECT_EQ(0u, status.pos);
}
{ // Invalid envelope size example.
std::vector<uint8_t> bytes = {
0xd8, 0x5a, 0, 0, 0, 1, EncodeIndefiniteLengthMapStart(), EncodeStop(),
};
TypeParam msg(bytes.begin(), bytes.end());
Status status =
AppendString8EntryToCBORMap(SpanFrom("key"), SpanFrom("value"), &msg);
EXPECT_EQ(Error::CBOR_INVALID_ENVELOPE, status.error);
EXPECT_EQ(0u, status.pos);
}
}
} // namespace cbor
namespace json {
// =============================================================================
// json::NewJSONEncoder - for encoding streaming parser events as JSON
// =============================================================================
void WriteUTF8AsUTF16(StreamingParserHandler* writer, const std::string& utf8) {
writer->HandleString16(SpanFrom(UTF8ToUTF16(SpanFrom(utf8))));
}
TEST(JsonStdStringWriterTest, HelloWorld) {
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
writer->HandleMapBegin();
WriteUTF8AsUTF16(writer.get(), "msg1");
WriteUTF8AsUTF16(writer.get(), "Hello, 🌎.");
std::string key = "msg1-as-utf8";
std::string value = "Hello, 🌎.";
writer->HandleString8(SpanFrom(key));
writer->HandleString8(SpanFrom(value));
WriteUTF8AsUTF16(writer.get(), "msg2");
WriteUTF8AsUTF16(writer.get(), "\\\b\r\n\t\f\"");
WriteUTF8AsUTF16(writer.get(), "nested");
writer->HandleMapBegin();
WriteUTF8AsUTF16(writer.get(), "double");
writer->HandleDouble(3.1415);
WriteUTF8AsUTF16(writer.get(), "int");
writer->HandleInt32(-42);
WriteUTF8AsUTF16(writer.get(), "bool");
writer->HandleBool(false);
WriteUTF8AsUTF16(writer.get(), "null");
writer->HandleNull();
writer->HandleMapEnd();
WriteUTF8AsUTF16(writer.get(), "array");
writer->HandleArrayBegin();
writer->HandleInt32(1);
writer->HandleInt32(2);
writer->HandleInt32(3);
writer->HandleArrayEnd();
writer->HandleMapEnd();
EXPECT_TRUE(status.ok());
EXPECT_EQ(
"{\"msg1\":\"Hello, \\ud83c\\udf0e.\","
"\"msg1-as-utf8\":\"Hello, \\ud83c\\udf0e.\","
"\"msg2\":\"\\\\\\b\\r\\n\\t\\f\\\"\","
"\"nested\":{\"double\":3.1415,\"int\":-42,"
"\"bool\":false,\"null\":null},\"array\":[1,2,3]}",
out);
}
TEST(JsonStdStringWriterTest, RepresentingNonFiniteValuesAsNull) {
// JSON can't represent +Infinity, -Infinity, or NaN.
// So in practice it's mapped to null.
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
writer->HandleMapBegin();
writer->HandleString8(SpanFrom("Infinity"));
writer->HandleDouble(std::numeric_limits<double>::infinity());
writer->HandleString8(SpanFrom("-Infinity"));
writer->HandleDouble(-std::numeric_limits<double>::infinity());
writer->HandleString8(SpanFrom("NaN"));
writer->HandleDouble(std::numeric_limits<double>::quiet_NaN());
writer->HandleMapEnd();
EXPECT_TRUE(status.ok());
EXPECT_EQ("{\"Infinity\":null,\"-Infinity\":null,\"NaN\":null}", out);
}
TEST(JsonStdStringWriterTest, BinaryEncodedAsJsonString) {
// The encoder emits binary submitted to StreamingParserHandler::HandleBinary
// as base64. The following three examples are taken from
// https://en.wikipedia.org/wiki/Base64.
{
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
writer->HandleBinary(SpanFrom(std::vector<uint8_t>({'M', 'a', 'n'})));
EXPECT_TRUE(status.ok());
EXPECT_EQ("\"TWFu\"", out);
}
{
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
writer->HandleBinary(SpanFrom(std::vector<uint8_t>({'M', 'a'})));
EXPECT_TRUE(status.ok());
EXPECT_EQ("\"TWE=\"", out);
}
{
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
writer->HandleBinary(SpanFrom(std::vector<uint8_t>({'M'})));
EXPECT_TRUE(status.ok());
EXPECT_EQ("\"TQ==\"", out);
}
{ // "Hello, world.", verified with base64decode.org.
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
writer->HandleBinary(SpanFrom(std::vector<uint8_t>(
{'H', 'e', 'l', 'l', 'o', ',', ' ', 'w', 'o', 'r', 'l', 'd', '.'})));
EXPECT_TRUE(status.ok());
EXPECT_EQ("\"SGVsbG8sIHdvcmxkLg==\"", out);
}
}
TEST(JsonStdStringWriterTest, HandlesErrors) {
// When an error is sent via HandleError, it saves it in the provided
// status and clears the output.
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> writer =
NewJSONEncoder(&GetTestPlatform(), &out, &status);
writer->HandleMapBegin();
WriteUTF8AsUTF16(writer.get(), "msg1");
writer->HandleError(Status{Error::JSON_PARSER_VALUE_EXPECTED, 42});
EXPECT_EQ(Error::JSON_PARSER_VALUE_EXPECTED, status.error);
EXPECT_EQ(42u, status.pos);
EXPECT_EQ("", out);
}
// We'd use Gmock but unfortunately it only handles copyable return types.
class MockPlatform : public Platform {
public:
// Not implemented.
bool StrToD(const char* str, double* result) const override { return false; }
// A map with pre-registered responses for DToSTr.
std::map<double, std::string> dtostr_responses_;
std::unique_ptr<char[]> DToStr(double value) const override {
auto it = dtostr_responses_.find(value);
CHECK(it != dtostr_responses_.end());
const std::string& str = it->second;
std::unique_ptr<char[]> response(new char[str.size() + 1]);
memcpy(response.get(), str.c_str(), str.size() + 1);
return response;
}
};
TEST(JsonStdStringWriterTest, DoubleToString) {
// This "broken" platform responds without the leading 0 before the
// decimal dot, so it'd be invalid JSON.
MockPlatform platform;
platform.dtostr_responses_[.1] = ".1";
platform.dtostr_responses_[-.7] = "-.7";
std::string out;
Status status;
std::unique_ptr<StreamingParserHandler> writer =
NewJSONEncoder(&platform, &out, &status);
writer->HandleArrayBegin();
writer->HandleDouble(.1);
writer->HandleDouble(-.7);
writer->HandleArrayEnd();
EXPECT_EQ("[0.1,-0.7]", out);
}
// =============================================================================
// json::ParseJSON - for receiving streaming parser events for JSON
// =============================================================================
class Log : public StreamingParserHandler {
public:
void HandleMapBegin() override { log_ << "map begin\n"; }
void HandleMapEnd() override { log_ << "map end\n"; }
void HandleArrayBegin() override { log_ << "array begin\n"; }
void HandleArrayEnd() override { log_ << "array end\n"; }
void HandleString8(span<uint8_t> chars) override {
log_ << "string8: " << std::string(chars.begin(), chars.end()) << "\n";
}
void HandleString16(span<uint16_t> chars) override {
log_ << "string16: " << UTF16ToUTF8(chars) << "\n";
}
void HandleBinary(span<uint8_t> bytes) override {
// JSON doesn't have native support for arbitrary bytes, so our parser will
// never call this.
CHECK(false);
}
void HandleDouble(double value) override {
log_ << "double: " << value << "\n";
}
void HandleInt32(int32_t value) override { log_ << "int: " << value << "\n"; }
void HandleBool(bool value) override { log_ << "bool: " << value << "\n"; }
void HandleNull() override { log_ << "null\n"; }
void HandleError(Status status) override { status_ = status; }
std::string str() const { return status_.ok() ? log_.str() : ""; }
Status status() const { return status_; }
private:
std::ostringstream log_;
Status status_;
};
class JsonParserTest : public ::testing::Test {
protected:
Log log_;
};
TEST_F(JsonParserTest, SimpleDictionary) {
std::string json = "{\"foo\": 42}";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_TRUE(log_.status().ok());
EXPECT_EQ(
"map begin\n"
"string16: foo\n"
"int: 42\n"
"map end\n",
log_.str());
}
TEST_F(JsonParserTest, Whitespace) {
std::string json = "\n {\n\"msg\"\n: \v\"Hello, world.\"\t\r}\t";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_TRUE(log_.status().ok());
EXPECT_EQ(
"map begin\n"
"string16: msg\n"
"string16: Hello, world.\n"
"map end\n",
log_.str());
}
TEST_F(JsonParserTest, NestedDictionary) {
std::string json = "{\"foo\": {\"bar\": {\"baz\": 1}, \"bar2\": 2}}";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_TRUE(log_.status().ok());
EXPECT_EQ(
"map begin\n"
"string16: foo\n"
"map begin\n"
"string16: bar\n"
"map begin\n"
"string16: baz\n"
"int: 1\n"
"map end\n"
"string16: bar2\n"
"int: 2\n"
"map end\n"
"map end\n",
log_.str());
}
TEST_F(JsonParserTest, Doubles) {
std::string json = "{\"foo\": 3.1415, \"bar\": 31415e-4}";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_TRUE(log_.status().ok());
EXPECT_EQ(
"map begin\n"
"string16: foo\n"
"double: 3.1415\n"
"string16: bar\n"
"double: 3.1415\n"
"map end\n",
log_.str());
}
TEST_F(JsonParserTest, Unicode) {
// Globe character. 0xF0 0x9F 0x8C 0x8E in utf8, 0xD83C 0xDF0E in utf16.
std::string json = "{\"msg\": \"Hello, \\uD83C\\uDF0E.\"}";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_TRUE(log_.status().ok());
EXPECT_EQ(
"map begin\n"
"string16: msg\n"
"string16: Hello, 🌎.\n"
"map end\n",
log_.str());
}
TEST_F(JsonParserTest, Unicode_ParseUtf16) {
// Globe character. utf8: 0xF0 0x9F 0x8C 0x8E; utf16: 0xD83C 0xDF0E.
// Crescent moon character. utf8: 0xF0 0x9F 0x8C 0x99; utf16: 0xD83C 0xDF19.
// We provide the moon with json escape, but the earth as utf16 input.
// Either way they arrive as utf8 (after decoding in log_.str()).
std::vector<uint16_t> json =
UTF8ToUTF16(SpanFrom("{\"space\": \"🌎 \\uD83C\\uDF19.\"}"));
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_TRUE(log_.status().ok());
EXPECT_EQ(
"map begin\n"
"string16: space\n"
"string16: 🌎 🌙.\n"
"map end\n",
log_.str());
}
TEST_F(JsonParserTest, Unicode_ParseUtf8) {
// Used below:
// гласность - example for 2 byte utf8, Russian word "glasnost"
// 屋 - example for 3 byte utf8, Chinese word for "house"
// 🌎 - example for 4 byte utf8: 0xF0 0x9F 0x8C 0x8E; utf16: 0xD83C 0xDF0E.
// 🌙 - example for escapes: utf8: 0xF0 0x9F 0x8C 0x99; utf16: 0xD83C 0xDF19.
// We provide the moon with json escape, but the earth as utf8 input.
// Either way they arrive as utf8 (after decoding in log_.str()).
std::string json =
"{"
"\"escapes\": \"\\uD83C\\uDF19\","
"\"2 byte\":\"гласность\","
"\"3 byte\":\"\","
"\"4 byte\":\"🌎\""
"}";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_TRUE(log_.status().ok());
EXPECT_EQ(
"map begin\n"
"string16: escapes\n"
"string16: 🌙\n"
"string16: 2 byte\n"
"string16: гласность\n"
"string16: 3 byte\n"
"string16: 屋\n"
"string16: 4 byte\n"
"string16: 🌎\n"
"map end\n",
log_.str());
}
TEST_F(JsonParserTest, UnprocessedInputRemainsError) {
// Trailing junk after the valid JSON.
std::string json = "{\"foo\": 3.1415} junk";
size_t junk_idx = json.find("junk");
EXPECT_NE(junk_idx, std::string::npos);
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_EQ(Error::JSON_PARSER_UNPROCESSED_INPUT_REMAINS, log_.status().error);
EXPECT_EQ(junk_idx, log_.status().pos);
EXPECT_EQ("", log_.str());
}
std::string MakeNestedJson(int depth) {
std::string json;
for (int ii = 0; ii < depth; ++ii)
json += "{\"foo\":";
json += "42";
for (int ii = 0; ii < depth; ++ii)
json += "}";
return json;
}
TEST_F(JsonParserTest, StackLimitExceededError_BelowLimit) {
// kStackLimit is 300 (see json_parser.cc). First let's
// try with a small nested example.
std::string json_3 = MakeNestedJson(3);
ParseJSON(GetTestPlatform(), SpanFrom(json_3), &log_);
EXPECT_TRUE(log_.status().ok());
EXPECT_EQ(
"map begin\n"
"string16: foo\n"
"map begin\n"
"string16: foo\n"
"map begin\n"
"string16: foo\n"
"int: 42\n"
"map end\n"
"map end\n"
"map end\n",
log_.str());
}
TEST_F(JsonParserTest, StackLimitExceededError_AtLimit) {
// Now with kStackLimit (300).
std::string json_limit = MakeNestedJson(300);
ParseJSON(GetTestPlatform(),
span<uint8_t>(reinterpret_cast<const uint8_t*>(json_limit.data()),
json_limit.size()),
&log_);
EXPECT_TRUE(log_.status().ok());
}
TEST_F(JsonParserTest, StackLimitExceededError_AboveLimit) {
// Now with kStackLimit + 1 (301) - it exceeds in the innermost instance.
std::string exceeded = MakeNestedJson(301);
ParseJSON(GetTestPlatform(), SpanFrom(exceeded), &log_);
EXPECT_EQ(Error::JSON_PARSER_STACK_LIMIT_EXCEEDED, log_.status().error);
EXPECT_EQ(strlen("{\"foo\":") * 301, log_.status().pos);
}
TEST_F(JsonParserTest, StackLimitExceededError_WayAboveLimit) {
// Now way past the limit. Still, the point of exceeding is 301.
std::string far_out = MakeNestedJson(320);
ParseJSON(GetTestPlatform(), SpanFrom(far_out), &log_);
EXPECT_EQ(Error::JSON_PARSER_STACK_LIMIT_EXCEEDED, log_.status().error);
EXPECT_EQ(strlen("{\"foo\":") * 301, log_.status().pos);
}
TEST_F(JsonParserTest, NoInputError) {
std::string json = "";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_EQ(Error::JSON_PARSER_NO_INPUT, log_.status().error);
EXPECT_EQ(0u, log_.status().pos);
EXPECT_EQ("", log_.str());
}
TEST_F(JsonParserTest, InvalidTokenError) {
std::string json = "|";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_EQ(Error::JSON_PARSER_INVALID_TOKEN, log_.status().error);
EXPECT_EQ(0u, log_.status().pos);
EXPECT_EQ("", log_.str());
}
TEST_F(JsonParserTest, InvalidNumberError) {
// Mantissa exceeds max (the constant used here is int64_t max).
std::string json = "1E9223372036854775807";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_EQ(Error::JSON_PARSER_INVALID_NUMBER, log_.status().error);
EXPECT_EQ(0u, log_.status().pos);
EXPECT_EQ("", log_.str());
}
TEST_F(JsonParserTest, InvalidStringError) {
// \x22 is an unsupported escape sequence
std::string json = "\"foo\\x22\"";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_EQ(Error::JSON_PARSER_INVALID_STRING, log_.status().error);
EXPECT_EQ(0u, log_.status().pos);
EXPECT_EQ("", log_.str());
}
TEST_F(JsonParserTest, UnexpectedArrayEndError) {
std::string json = "[1,2,]";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_EQ(Error::JSON_PARSER_UNEXPECTED_ARRAY_END, log_.status().error);
EXPECT_EQ(5u, log_.status().pos);
EXPECT_EQ("", log_.str());
}
TEST_F(JsonParserTest, CommaOrArrayEndExpectedError) {
std::string json = "[1,2 2";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_EQ(Error::JSON_PARSER_COMMA_OR_ARRAY_END_EXPECTED,
log_.status().error);
EXPECT_EQ(5u, log_.status().pos);
EXPECT_EQ("", log_.str());
}
TEST_F(JsonParserTest, StringLiteralExpectedError) {
// There's an error because the key bar, a string, is not terminated.
std::string json = "{\"foo\": 3.1415, \"bar: 31415e-4}";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_EQ(Error::JSON_PARSER_STRING_LITERAL_EXPECTED, log_.status().error);
EXPECT_EQ(16u, log_.status().pos);
EXPECT_EQ("", log_.str());
}
TEST_F(JsonParserTest, ColonExpectedError) {
std::string json = "{\"foo\", 42}";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_EQ(Error::JSON_PARSER_COLON_EXPECTED, log_.status().error);
EXPECT_EQ(6u, log_.status().pos);
EXPECT_EQ("", log_.str());
}
TEST_F(JsonParserTest, UnexpectedMapEndError) {
std::string json = "{\"foo\": 42, }";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_EQ(Error::JSON_PARSER_UNEXPECTED_MAP_END, log_.status().error);
EXPECT_EQ(12u, log_.status().pos);
EXPECT_EQ("", log_.str());
}
TEST_F(JsonParserTest, CommaOrMapEndExpectedError) {
// The second separator should be a comma.
std::string json = "{\"foo\": 3.1415: \"bar\": 0}";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_EQ(Error::JSON_PARSER_COMMA_OR_MAP_END_EXPECTED, log_.status().error);
EXPECT_EQ(14u, log_.status().pos);
EXPECT_EQ("", log_.str());
}
TEST_F(JsonParserTest, ValueExpectedError) {
std::string json = "}";
ParseJSON(GetTestPlatform(), SpanFrom(json), &log_);
EXPECT_EQ(Error::JSON_PARSER_VALUE_EXPECTED, log_.status().error);
EXPECT_EQ(0u, log_.status().pos);
EXPECT_EQ("", log_.str());
}
template <typename T>
class ConvertJSONToCBORTest : public ::testing::Test {};
using ContainerTestTypes = ::testing::Types<std::vector<uint8_t>, std::string>;
TYPED_TEST_SUITE(ConvertJSONToCBORTest, ContainerTestTypes);
TYPED_TEST(ConvertJSONToCBORTest, RoundTripValidJson) {
std::string json_in = "{\"msg\":\"Hello, world.\",\"lst\":[1,2,3]}";
TypeParam json(json_in.begin(), json_in.end());
TypeParam cbor;
{
Status status = ConvertJSONToCBOR(GetTestPlatform(), SpanFrom(json), &cbor);
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ(Status::npos(), status.pos);
}
TypeParam roundtrip_json;
{
Status status =
ConvertCBORToJSON(GetTestPlatform(), SpanFrom(cbor), &roundtrip_json);
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ(Status::npos(), status.pos);
}
EXPECT_EQ(json, roundtrip_json);
}
TYPED_TEST(ConvertJSONToCBORTest, RoundTripValidJson16) {
std::vector<uint16_t> json16 = {
'{', '"', 'm', 's', 'g', '"', ':', '"', 'H', 'e', 'l', 'l',
'o', ',', ' ', 0xd83c, 0xdf0e, '.', '"', ',', '"', 'l', 's', 't',
'"', ':', '[', '1', ',', '2', ',', '3', ']', '}'};
TypeParam cbor;
{
Status status = ConvertJSONToCBOR(
GetTestPlatform(), span<uint16_t>(json16.data(), json16.size()), &cbor);
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ(Status::npos(), status.pos);
}
TypeParam roundtrip_json;
{
Status status =
ConvertCBORToJSON(GetTestPlatform(), SpanFrom(cbor), &roundtrip_json);
EXPECT_EQ(Error::OK, status.error);
EXPECT_EQ(Status::npos(), status.pos);
}
std::string json = "{\"msg\":\"Hello, \\ud83c\\udf0e.\",\"lst\":[1,2,3]}";
TypeParam expected_json(json.begin(), json.end());
EXPECT_EQ(expected_json, roundtrip_json);
}
} // namespace json
} // namespace v8_inspector_protocol_encoding