DarkflameServer/tests/AMFDeserializeTests.cpp

410 lines
12 KiB
C++
Raw Normal View History

#include <chrono>
#include <fstream>
#include <iostream>
#include <memory>
#include "AMFDeserialize.h"
#include "AMFFormat.h"
#include "CommonCxxTests.h"
std::unique_ptr<AMFValue> ReadFromBitStream(RakNet::BitStream* bitStream) {
AMFDeserialize deserializer;
std::unique_ptr<AMFValue> returnValue(deserializer.Read(bitStream));
return returnValue;
}
int ReadAMFUndefinedFromBitStream() {
CBITSTREAM
bitStream.Write<uint8_t>(0x00);
std::unique_ptr<AMFValue> res(ReadFromBitStream(&bitStream));
ASSERT_EQ(res->GetValueType(), AMFValueType::AMFUndefined);
return 0;
}
int ReadAMFNullFromBitStream() {
CBITSTREAM
bitStream.Write<uint8_t>(0x01);
std::unique_ptr<AMFValue> res(ReadFromBitStream(&bitStream));
ASSERT_EQ(res->GetValueType(), AMFValueType::AMFNull);
return 0;
}
int ReadAMFFalseFromBitStream() {
CBITSTREAM
bitStream.Write<uint8_t>(0x02);
std::unique_ptr<AMFValue> res(ReadFromBitStream(&bitStream));
ASSERT_EQ(res->GetValueType(), AMFValueType::AMFFalse);
return 0;
}
int ReadAMFTrueFromBitStream() {
CBITSTREAM
bitStream.Write<uint8_t>(0x03);
std::unique_ptr<AMFValue> res(ReadFromBitStream(&bitStream));
ASSERT_EQ(res->GetValueType(), AMFValueType::AMFTrue);
return 0;
}
int ReadAMFIntegerFromBitStream() {
CBITSTREAM
{
bitStream.Write<uint8_t>(0x04);
// 127 == 01111111
bitStream.Write<uint8_t>(127);
std::unique_ptr<AMFValue> res(ReadFromBitStream(&bitStream));
ASSERT_EQ(res->GetValueType(), AMFValueType::AMFInteger);
// Check that the max value of a byte can be read correctly
ASSERT_EQ(static_cast<AMFIntegerValue*>(res.get())->GetIntegerValue(), 127);
}
bitStream.Reset();
{
bitStream.Write<uint8_t>(0x04);
bitStream.Write<uint32_t>(UINT32_MAX);
std::unique_ptr<AMFValue> res(ReadFromBitStream(&bitStream));
ASSERT_EQ(res->GetValueType(), AMFValueType::AMFInteger);
// Check that we can read the maximum value correctly
ASSERT_EQ(static_cast<AMFIntegerValue*>(res.get())->GetIntegerValue(), 536870911);
}
bitStream.Reset();
{
bitStream.Write<uint8_t>(0x04);
// 131 == 10000011
bitStream.Write<uint8_t>(131);
// 255 == 11111111
bitStream.Write<uint8_t>(255);
// 127 == 01111111
bitStream.Write<uint8_t>(127);
std::unique_ptr<AMFValue> res(ReadFromBitStream(&bitStream));
ASSERT_EQ(res->GetValueType(), AMFValueType::AMFInteger);
// Check that short max can be read correctly
ASSERT_EQ(static_cast<AMFIntegerValue*>(res.get())->GetIntegerValue(), UINT16_MAX);
}
bitStream.Reset();
{
bitStream.Write<uint8_t>(0x04);
// 255 == 11111111
bitStream.Write<uint8_t>(255);
// 127 == 01111111
bitStream.Write<uint8_t>(127);
std::unique_ptr<AMFValue> res(ReadFromBitStream(&bitStream));
ASSERT_EQ(res->GetValueType(), AMFValueType::AMFInteger);
// Check that 2 byte max can be read correctly
ASSERT_EQ(static_cast<AMFIntegerValue*>(res.get())->GetIntegerValue(), 16383);
}
return 0;
}
int ReadAMFDoubleFromBitStream() {
CBITSTREAM
bitStream.Write<uint8_t>(0x05);
bitStream.Write<double>(25346.4f);
std::unique_ptr<AMFValue> res(ReadFromBitStream(&bitStream));
ASSERT_EQ(res->GetValueType(), AMFValueType::AMFDouble);
ASSERT_EQ(static_cast<AMFDoubleValue*>(res.get())->GetDoubleValue(), 25346.4f);
return 0;
}
int ReadAMFStringFromBitStream() {
CBITSTREAM
bitStream.Write<uint8_t>(0x06);
bitStream.Write<uint8_t>(0x0F);
std::string toWrite = "stateID";
for (auto e : toWrite) bitStream.Write<char>(e);
std::unique_ptr<AMFValue> res(ReadFromBitStream(&bitStream));
ASSERT_EQ(res->GetValueType(), AMFValueType::AMFString);
ASSERT_EQ(static_cast<AMFStringValue*>(res.get())->GetStringValue(), "stateID");
return 0;
}
int ReadAMFArrayFromBitStream() {
CBITSTREAM
// Test empty AMFArray
bitStream.Write<uint8_t>(0x09);
bitStream.Write<uint8_t>(0x01);
bitStream.Write<uint8_t>(0x01);
{
std::unique_ptr<AMFValue> res(ReadFromBitStream(&bitStream));
ASSERT_EQ(res->GetValueType(), AMFValueType::AMFArray);
ASSERT_EQ(static_cast<AMFArrayValue*>(res.get())->GetAssociativeMap().size(), 0);
ASSERT_EQ(static_cast<AMFArrayValue*>(res.get())->GetDenseArray().size(), 0);
}
bitStream.Reset();
// Test a key'd value and dense value
bitStream.Write<uint8_t>(0x09);
bitStream.Write<uint8_t>(0x03);
bitStream.Write<uint8_t>(0x15);
for (auto e : "BehaviorID") if (e != '\0') bitStream.Write<char>(e);
bitStream.Write<uint8_t>(0x06);
bitStream.Write<uint8_t>(0x0B);
for (auto e : "10447") if (e != '\0') bitStream.Write<char>(e);
bitStream.Write<uint8_t>(0x01);
bitStream.Write<uint8_t>(0x06);
bitStream.Write<uint8_t>(0x0B);
for (auto e : "10447") if (e != '\0') bitStream.Write<char>(e);
{
std::unique_ptr<AMFValue> res(ReadFromBitStream(&bitStream));
ASSERT_EQ(res->GetValueType(), AMFValueType::AMFArray);
ASSERT_EQ(static_cast<AMFArrayValue*>(res.get())->GetAssociativeMap().size(), 1);
ASSERT_EQ(static_cast<AMFArrayValue*>(res.get())->GetDenseArray().size(), 1);
ASSERT_EQ(static_cast<AMFStringValue*>(static_cast<AMFArrayValue*>(res.get())->FindValue("BehaviorID"))->GetStringValue(), "10447");
ASSERT_EQ(static_cast<AMFStringValue*>(static_cast<AMFArrayValue*>(res.get())->GetDenseArray()[0])->GetStringValue(), "10447");
}
// Test a dense array
return 0;
}
/**
* This test checks that if we recieve an unimplemented AMFValueType
* we correctly throw an error and can actch it.
*/
int TestUnimplementedAMFValues() {
std::vector<AMFValueType> unimplementedValues = {
AMFValueType::AMFXMLDoc,
AMFValueType::AMFDate,
AMFValueType::AMFObject,
AMFValueType::AMFXML,
AMFValueType::AMFByteArray,
AMFValueType::AMFVectorInt,
AMFValueType::AMFVectorUInt,
AMFValueType::AMFVectorDouble,
AMFValueType::AMFVectorObject,
AMFValueType::AMFDictionary
};
// Run unimplemented tests to check that errors are thrown if
// unimplemented AMF values are attempted to be parsed.
std::ifstream fileStream;
fileStream.open("AMFBitStreamUnimplementedTest.bin", std::ios::binary);
// Read a test BitStream from a file
std::vector<char> baseBitStream;
char byte = 0;
while (fileStream.get(byte)) {
baseBitStream.push_back(byte);
}
fileStream.close();
for (auto amfValueType : unimplementedValues) {
RakNet::BitStream testBitStream;
for (auto element : baseBitStream) {
testBitStream.Write(element);
}
testBitStream.Write(amfValueType);
bool caughtException = false;
try {
ReadFromBitStream(&testBitStream);
} catch (AMFValueType unimplementedValueType) {
caughtException = true;
}
std::cout << "Testing unimplemented value " << amfValueType << " Did we catch an exception: " << (caughtException ? "YES" : "NO") << std::endl;
ASSERT_EQ(caughtException, true);
}
return 0;
}
int TestLiveCapture() {
std::ifstream testFileStream;
testFileStream.open("AMFBitStreamTest.bin", std::ios::binary);
// Read a test BitStream from a file
RakNet::BitStream testBitStream;
char byte = 0;
while (testFileStream.get(byte)) {
testBitStream.Write<char>(byte);
}
testFileStream.close();
auto resultFromFn = ReadFromBitStream(&testBitStream);
auto result = static_cast<AMFArrayValue*>(resultFromFn.get());
// Test the outermost array
ASSERT_EQ(dynamic_cast<AMFStringValue*>(result->FindValue("BehaviorID"))->GetStringValue(), "10447");
ASSERT_EQ(dynamic_cast<AMFStringValue*>(result->FindValue("objectID"))->GetStringValue(), "288300744895913279")
// Test the execution state array
auto executionState = dynamic_cast<AMFArrayValue*>(result->FindValue("executionState"));
ASSERT_NE(executionState, nullptr);
auto strips = dynamic_cast<AMFArrayValue*>(executionState->FindValue("strips"))->GetDenseArray();
ASSERT_EQ(strips.size(), 1);
auto stripsPosition0 = dynamic_cast<AMFArrayValue*>(strips[0]);
auto actionIndex = dynamic_cast<AMFDoubleValue*>(stripsPosition0->FindValue("actionIndex"));
ASSERT_EQ(actionIndex->GetDoubleValue(), 0.0f);
auto stripIDExecution = dynamic_cast<AMFDoubleValue*>(stripsPosition0->FindValue("id"));
ASSERT_EQ(stripIDExecution->GetDoubleValue(), 0.0f);
auto stateIDExecution = dynamic_cast<AMFDoubleValue*>(executionState->FindValue("stateID"));
ASSERT_EQ(stateIDExecution->GetDoubleValue(), 0.0f);
auto states = dynamic_cast<AMFArrayValue*>(result->FindValue("states"))->GetDenseArray();
ASSERT_EQ(states.size(), 1);
auto firstState = dynamic_cast<AMFArrayValue*>(states[0]);
auto stateID = dynamic_cast<AMFDoubleValue*>(firstState->FindValue("id"));
ASSERT_EQ(stateID->GetDoubleValue(), 0.0f);
auto stripsInState = dynamic_cast<AMFArrayValue*>(firstState->FindValue("strips"))->GetDenseArray();
ASSERT_EQ(stripsInState.size(), 1);
auto firstStrip = dynamic_cast<AMFArrayValue*>(stripsInState[0]);
auto actionsInFirstStrip = dynamic_cast<AMFArrayValue*>(firstStrip->FindValue("actions"))->GetDenseArray();
ASSERT_EQ(actionsInFirstStrip.size(), 3);
auto actionID = dynamic_cast<AMFDoubleValue*>(firstStrip->FindValue("id"));
ASSERT_EQ(actionID->GetDoubleValue(), 0.0f)
auto uiArray = dynamic_cast<AMFArrayValue*>(firstStrip->FindValue("ui"));
auto xPos = dynamic_cast<AMFDoubleValue*>(uiArray->FindValue("x"));
auto yPos = dynamic_cast<AMFDoubleValue*>(uiArray->FindValue("y"));
ASSERT_EQ(xPos->GetDoubleValue(), 103.0f);
ASSERT_EQ(yPos->GetDoubleValue(), 82.0f);
auto stripID = dynamic_cast<AMFDoubleValue*>(firstStrip->FindValue("id"));
ASSERT_EQ(stripID->GetDoubleValue(), 0.0f)
auto firstAction = dynamic_cast<AMFArrayValue*>(actionsInFirstStrip[0]);
auto firstType = dynamic_cast<AMFStringValue*>(firstAction->FindValue("Type"));
ASSERT_EQ(firstType->GetStringValue(), "OnInteract");
auto firstCallback = dynamic_cast<AMFStringValue*>(firstAction->FindValue("__callbackID__"));
ASSERT_EQ(firstCallback->GetStringValue(), "");
auto secondAction = dynamic_cast<AMFArrayValue*>(actionsInFirstStrip[1]);
auto secondType = dynamic_cast<AMFStringValue*>(secondAction->FindValue("Type"));
ASSERT_EQ(secondType->GetStringValue(), "FlyUp");
auto secondCallback = dynamic_cast<AMFStringValue*>(secondAction->FindValue("__callbackID__"));
ASSERT_EQ(secondCallback->GetStringValue(), "");
auto secondDistance = dynamic_cast<AMFDoubleValue*>(secondAction->FindValue("Distance"));
ASSERT_EQ(secondDistance->GetDoubleValue(), 25.0f);
auto thirdAction = dynamic_cast<AMFArrayValue*>(actionsInFirstStrip[2]);
auto thirdType = dynamic_cast<AMFStringValue*>(thirdAction->FindValue("Type"));
ASSERT_EQ(thirdType->GetStringValue(), "FlyDown");
auto thirdCallback = dynamic_cast<AMFStringValue*>(thirdAction->FindValue("__callbackID__"));
ASSERT_EQ(thirdCallback->GetStringValue(), "");
auto thirdDistance = dynamic_cast<AMFDoubleValue*>(thirdAction->FindValue("Distance"));
ASSERT_EQ(thirdDistance->GetDoubleValue(), 25.0f);
return 0;
}
int TestNullStream() {
auto result = ReadFromBitStream(nullptr);
ASSERT_EQ(result.get(), nullptr);
return 0;
}
int AMFDeserializeTests(int argc, char** const argv) {
std::cout << "Checking that using a null bitstream doesnt cause exception" << std::endl;
if (TestNullStream()) return 1;
std::cout << "passed nullptr test, checking basic tests" << std::endl;
if (ReadAMFUndefinedFromBitStream() != 0) return 1;
if (ReadAMFNullFromBitStream() != 0) return 1;
if (ReadAMFFalseFromBitStream() != 0) return 1;
if (ReadAMFTrueFromBitStream() != 0) return 1;
if (ReadAMFIntegerFromBitStream() != 0) return 1;
if (ReadAMFDoubleFromBitStream() != 0) return 1;
if (ReadAMFStringFromBitStream() != 0) return 1;
if (ReadAMFArrayFromBitStream() != 0) return 1;
std::cout << "Passed basic test, checking live capture" << std::endl;
if (TestLiveCapture() != 0) return 1;
std::cout << "Passed live capture, checking unimplemented amf values" << std::endl;
if (TestUnimplementedAMFValues() != 0) return 1;
std::cout << "Passed all tests." << std::endl;
return 0;
}
/**
* Below is the AMF that is in the AMFBitStreamTest.bin file that we are reading in
* from a bitstream to test.
args: amf3!
{
"objectID": "288300744895913279",
"BehaviorID": "10447",
"executionState": amf3!
{
"strips": amf3!
[
amf3!
{
"actionIndex": 0.0,
"id": 0.0,
},
],
"stateID": 0.0,
},
"states": amf3!
[
amf3!
{
"id": 0.0,
"strips": amf3!
[
amf3!
{
"actions": amf3!
[
amf3!
{
"Type": "OnInteract",
"__callbackID__": "",
},
amf3!
{
"Distance": 25.0,
"Type": "FlyUp",
"__callbackID__": "",
},
amf3!
{
"Distance": 25.0,
"Type": "FlyDown",
"__callbackID__": "",
},
],
"id": 0.0,
"ui": amf3!
{
"x": 103.0,
"y": 82.0,
},
},
],
},
],
}
*/