CardData*
MtgJsonAllSetsData::createCardData( int multiverseId ) const
{
// Unfortunately this is a slow linear search.
for( const std::string& setCode : mAllSetCodes )
{
// In parse() this was vetted to be safe and yield an Array-type value.
const Value& cardsValue = mDoc[setCode]["cards"];
// This is a linear search looking for the multiverse id.
for( Value::ConstValueIterator iter = cardsValue.Begin();
iter != cardsValue.End(); ++iter )
{
if( iter->HasMember("multiverseid") )
{
const Value& multiverseIdValue = (*iter)["multiverseid"];
if( multiverseIdValue.IsInt() )
{
int muid = multiverseIdValue.GetInt();
if( muid == multiverseId )
{
mLogger->debug( "found muid ", muid );
return new MtgJsonCardData( setCode, *iter );
}
}
}
}
}
mLogger->warn( "unable to find card multiverseId {}", multiverseId );
return nullptr;
}
Value::ConstValueIterator
MtgJsonAllSetsData::findCardValueByName( Value::ConstValueIterator first,
Value::ConstValueIterator last,
const std::string& name ) const
{
Value::ConstValueIterator iter = first;
for( Value::ConstValueIterator iter = first; iter != last; ++iter )
{
std::string nameStr( (*iter)["name"].GetString() );
if( StringUtil::icompare( nameStr, name ) )
{
mLogger->debug( "found name {}", name );
return iter;
}
else if( iter->HasMember("names") )
{
// Here we check if the card has multiple names, i.e. split
// cards. If so, create a split card name and normalize the
// name parameter and see if they match.
std::string splitCardName = MtgJson::createSplitCardName( (*iter)["names"] );
std::string nameNormalized = MtgJson::normalizeSplitCardName( name );
if( StringUtil::icompare( nameNormalized, splitCardName ) )
{
mLogger->debug( "found split name {}", name );
return iter;
}
}
}
return last;
}
bool JSASTProgram::Parse(const rapidjson::Value& value)
{
JSASTNode::Parse(value);
for (Value::ConstMemberIterator itr = value.MemberBegin();
itr != value.MemberEnd(); ++itr)
{
String name = itr->name.GetString();
if (name == "body")
{
ParseStatementArray(itr->value, body_);
}
if (name == "comments")
{
if (itr->value.IsArray())
{
for (Value::ConstValueIterator citr = itr->value.Begin();
citr != itr->value.End();
citr++)
{
JSASTComment* comment = new JSASTComment();
assert(citr->IsObject());
comment->Parse(*citr);
comments_.Push(comment);
}
}
}
}
return true;
}
void AEPreferences::Read()
{
rapidjson::Document document;
String filepath = GetPreferencesFullPath();
File jsonFile(context_, filepath);
if (!jsonFile.IsOpen())
return;
String json;
jsonFile.ReadText(json);
if (!json.Length())
return;
if (document.Parse<0>(json.CString()).HasParseError())
{
LOGERRORF("Could not parse JSON data from %s", filepath.CString());
return;
}
Clear();
const Value::Member* recent_files = document.FindMember("recent_files");
if (recent_files && recent_files->value.IsArray())
{
for (Value::ConstValueIterator itr = recent_files->value.Begin(); itr != recent_files->value.End(); itr++)
{
if (!(*itr).IsString())
continue;
String path(itr->GetString());
recentProjects_.Push(path.CString());
}
}
const Value::Member* android_sdk_path = document.FindMember("android_sdk_path");
if (android_sdk_path && android_sdk_path->value.IsString())
androidSDKPath_ = android_sdk_path->value.GetString();
const Value::Member* jdk_root_path = document.FindMember("jdk_root_path");
if (jdk_root_path && jdk_root_path->value.IsString())
jdkRootPath_ = jdk_root_path->value.GetString();
const Value::Member* ant_path = document.FindMember("ant_path");
if (ant_path && ant_path->value.IsString())
antPath_ = ant_path->value.GetString();
UpdateRecentFiles(false);
}
/*
* Class: com_vmc_ipc_proxy_IpcProxy
* Method: takeNavDataSnapshot
* Signature: ()Lcom/vmc/ipc/proxy/NavData;
*/
JNIEXPORT jobjectArray JNICALL Java_com_vmc_ipc_proxy_IpcProxy_takeNavDataSnapshot
(JNIEnv *env, jobject jobj,jobject navdata){
// LOGI("-->Java_com_vmc_ipc_proxy_IpcProxy_takeNavDataSnapshot");
jobjectArray args = 0;
jstring str;
std::map<std::string,std::string> &map = cmd::StartServerStatusEnum();
int i = 0,len = map.size();
std::map<std::string,std::string>::iterator iter;
args = (env)->NewObjectArray(len,(env)->FindClass("java/lang/String"),0);
#if 0
for (Value::ConstValueIterator itr = g_serverStatus.Begin(); itr != g_serverStatus.End(); ++itr)
{
str = (env)->NewStringUTF(itr->GetString() );
(env)->SetObjectArrayElement(args, i, str);
i++;
}
#endif
for(iter = map.begin();iter != map.end(); iter++)
{
std::string s = iter->first;
s += ":";
s += iter->second;
str = (env)->NewStringUTF(s.c_str() );
(env)->SetObjectArrayElement(args, i, str);
i++;
}
cmd::EndServerStatusEnum();
#if 0
for (rapidjson::Value::ConstMemberIterator itr = g_serverStatus.MemberBegin(); itr != g_serverStatus.MemberEnd(); ++itr)
{
std::string s = itr->name.GetString();
s += ",";
s += itr->value.GetString();
(env)->SetObjectArrayElement(args, i, s.c_str());
i++;
printf("Type of member %s is %s\n", itr->name.GetString(), itr->value.GetString());
}
#endif
#if 0
for( i=0; i < len; i++ )
{
str = (env)->NewStringUTF(sa[i] );
(env)->SetObjectArrayElement(args, i, str);
}
#endif
return args;
}
//将支持api保存到mSupportedApiSet
void Device::loadSupportedApiList(const Document &replyJson)
{
mSupportedApiSet.clear();
if (replyJson == NULL || replyJson.IsNull())
return;
if (replyJson.HasMember("error"))
{
return;
}
Value::ConstArray a = replyJson["result"].GetArray()[0].GetArray();
for (Value::ConstValueIterator itr = a.Begin(); itr != a.End(); ++itr)
{
mSupportedApiSet.insert(itr->GetString());
}
}
//设置曝光模式
void CLiveview::OnCbnSelchangeCombo3()
{
int nIndex = mExpoCombo.GetCurSel();
CString sel;
mExpoCombo.GetLBText(nIndex, sel);
Document d = indevice->setExposureMode(sel);
if (indevice->isJsonOk(d))
{
//获取支持的ISO
mIsoCombo.ResetContent();
const Document replyJson3 = indevice->getAvailableIsoSpeedRate();
if (indevice->isJsonOk(replyJson3))
{
CString curIso = replyJson3["result"].GetArray()[0].GetString();
Value::ConstArray a = replyJson3["result"].GetArray()[1].GetArray();
for (Value::ConstValueIterator itr = a.Begin(); itr != a.End(); ++itr)
{
mIsoCombo.AddString(itr->GetString());
}
mIsoCombo.SelectString(0, curIso);
}
}
}
void JSONArray::_parseRapidJSONArray(void *value) {
rapidjson::Value *rapidjsonValue = (rapidjson::Value *)value;
for (Value::ConstValueIterator currentValue = rapidjsonValue->Begin(); currentValue != rapidjsonValue->End(); ++currentValue)
switch (currentValue->GetType()) {
case kNullType:
break;
case kFalseType:
case kTrueType:
this->appendValue(shared_ptr<JSONNumber> (new JSONNumber(kTrueType ? true: false)));
break;
case kObjectType: {
shared_ptr<JSONObject> obj(new JSONObject());
obj->_parseRapidJSONObject((void*)currentValue);
this->appendValue(obj);
}
break;
case kArrayType: {
shared_ptr<JSONArray> obj(new JSONArray());
obj->_parseRapidJSONArray((void*)currentValue);
this->appendValue(obj);
}
break;
case kStringType:
this->appendValue(shared_ptr<JSONString> (new JSONString(currentValue->GetString())));
break;
case kNumberType:
if (rapidjsonValue->IsDouble()) {
this->appendValue(shared_ptr<JSONNumber> (new JSONNumber(currentValue->GetDouble())));
} else if (rapidjsonValue->IsInt() || currentValue->IsInt64()) {
this->appendValue(shared_ptr<JSONNumber> (new JSONNumber(currentValue->GetInt())));
} else if (currentValue->IsUint() || currentValue->IsUint64()) {
this->appendValue(shared_ptr<JSONNumber> (new JSONNumber(currentValue->GetUint())));
}
break;
}
}
TEST(Value, Array) {
Value x(kArrayType);
const Value& y = x;
Value::AllocatorType allocator;
EXPECT_EQ(kArrayType, x.GetType());
EXPECT_TRUE(x.IsArray());
EXPECT_TRUE(x.Empty());
EXPECT_EQ(0u, x.Size());
EXPECT_TRUE(y.IsArray());
EXPECT_TRUE(y.Empty());
EXPECT_EQ(0u, y.Size());
EXPECT_FALSE(x.IsNull());
EXPECT_FALSE(x.IsBool());
EXPECT_FALSE(x.IsFalse());
EXPECT_FALSE(x.IsTrue());
EXPECT_FALSE(x.IsString());
EXPECT_FALSE(x.IsObject());
// PushBack()
Value v;
x.PushBack(v, allocator);
v.SetBool(true);
x.PushBack(v, allocator);
v.SetBool(false);
x.PushBack(v, allocator);
v.SetInt(123);
x.PushBack(v, allocator);
EXPECT_FALSE(x.Empty());
EXPECT_EQ(4u, x.Size());
EXPECT_FALSE(y.Empty());
EXPECT_EQ(4u, y.Size());
EXPECT_TRUE(x[SizeType(0)].IsNull());
EXPECT_TRUE(x[1u].IsTrue());
EXPECT_TRUE(x[2u].IsFalse());
EXPECT_TRUE(x[3u].IsInt());
EXPECT_EQ(123, x[3u].GetInt());
EXPECT_TRUE(y[SizeType(0)].IsNull());
EXPECT_TRUE(y[1u].IsTrue());
EXPECT_TRUE(y[2u].IsFalse());
EXPECT_TRUE(y[3u].IsInt());
EXPECT_EQ(123, y[3u].GetInt());
// iterator
Value::ValueIterator itr = x.Begin();
EXPECT_TRUE(itr != x.End());
EXPECT_TRUE(itr->IsNull());
++itr;
EXPECT_TRUE(itr != x.End());
EXPECT_TRUE(itr->IsTrue());
++itr;
EXPECT_TRUE(itr != x.End());
EXPECT_TRUE(itr->IsFalse());
++itr;
EXPECT_TRUE(itr != x.End());
EXPECT_TRUE(itr->IsInt());
EXPECT_EQ(123, itr->GetInt());
// const iterator
Value::ConstValueIterator citr = y.Begin();
EXPECT_TRUE(citr != y.End());
EXPECT_TRUE(citr->IsNull());
++citr;
EXPECT_TRUE(citr != y.End());
EXPECT_TRUE(citr->IsTrue());
++citr;
EXPECT_TRUE(citr != y.End());
EXPECT_TRUE(citr->IsFalse());
++citr;
EXPECT_TRUE(citr != y.End());
EXPECT_TRUE(citr->IsInt());
EXPECT_EQ(123, citr->GetInt());
// PopBack()
x.PopBack();
EXPECT_EQ(3u, x.Size());
EXPECT_TRUE(y[SizeType(0)].IsNull());
EXPECT_TRUE(y[1].IsTrue());
EXPECT_TRUE(y[2].IsFalse());
// Clear()
x.Clear();
EXPECT_TRUE(x.Empty());
EXPECT_EQ(0u, x.Size());
EXPECT_TRUE(y.Empty());
EXPECT_EQ(0u, y.Size());
// SetArray()
Value z;
z.SetArray();
EXPECT_TRUE(z.IsArray());
EXPECT_TRUE(z.Empty());
}
int main(int, char*[]) {
////////////////////////////////////////////////////////////////////////////
// 1. Parse a JSON text string to a document.
const char json[] = " { \"hello\" : \"world\", \"t\" : true , \"f\" : false, \"n\": null, \"i\":123, \"pi\": 3.1416, \"a\":[1, 2, 3, 4] } ";
printf("Original JSON:\n %s\n", json);
Document document; // Default template parameter uses UTF8 and MemoryPoolAllocator.
#if 0
// "normal" parsing, decode strings to new buffers. Can use other input stream via ParseStream().
if (document.Parse(json).HasParseError())
return 1;
#else
// In-situ parsing, decode strings directly in the source string. Source must be string.
char buffer[sizeof(json)];
memcpy(buffer, json, sizeof(json));
if (document.ParseInsitu(buffer).HasParseError())
return 1;
#endif
printf("\nParsing to document succeeded.\n");
////////////////////////////////////////////////////////////////////////////
// 2. Access values in document.
printf("\nAccess values in document:\n");
assert(document.IsObject()); // Document is a JSON value represents the root of DOM. Root can be either an object or array.
assert(document.HasMember("hello"));
assert(document["hello"].IsString());
printf("hello = %s\n", document["hello"].GetString());
// Since version 0.2, you can use single lookup to check the existing of member and its value:
Value::MemberIterator hello = document.FindMember("hello");
assert(hello != document.MemberEnd());
assert(hello->value.IsString());
assert(strcmp("world", hello->value.GetString()) == 0);
(void)hello;
assert(document["t"].IsBool()); // JSON true/false are bool. Can also uses more specific function IsTrue().
printf("t = %s\n", document["t"].GetBool() ? "true" : "false");
assert(document["f"].IsBool());
printf("f = %s\n", document["f"].GetBool() ? "true" : "false");
printf("n = %s\n", document["n"].IsNull() ? "null" : "?");
assert(document["i"].IsNumber()); // Number is a JSON type, but C++ needs more specific type.
assert(document["i"].IsInt()); // In this case, IsUint()/IsInt64()/IsUInt64() also return true.
printf("i = %d\n", document["i"].GetInt()); // Alternative (int)document["i"]
assert(document["pi"].IsNumber());
assert(document["pi"].IsDouble());
printf("pi = %g\n", document["pi"].GetDouble());
{
const Value& a = document["a"]; // Using a reference for consecutive access is handy and faster.
assert(a.IsArray());
for (SizeType i = 0; i < a.Size(); i++) // rapidjson uses SizeType instead of size_t.
printf("a[%d] = %d\n", i, a[i].GetInt());
int y = a[0].GetInt();
(void)y;
// Iterating array with iterators
printf("a = ");
for (Value::ConstValueIterator itr = a.Begin(); itr != a.End(); ++itr)
printf("%d ", itr->GetInt());
printf("\n");
}
// Iterating object members
static const char* kTypeNames[] = { "Null", "False", "True", "Object", "Array", "String", "Number" };
for (Value::ConstMemberIterator itr = document.MemberBegin(); itr != document.MemberEnd(); ++itr)
printf("Type of member %s is %s\n", itr->name.GetString(), kTypeNames[itr->value.GetType()]);
////////////////////////////////////////////////////////////////////////////
// 3. Modify values in document.
// Change i to a bigger number
{
uint64_t f20 = 1; // compute factorial of 20
for (uint64_t j = 1; j <= 20; j++)
f20 *= j;
document["i"] = f20; // Alternate form: document["i"].SetUint64(f20)
assert(!document["i"].IsInt()); // No longer can be cast as int or uint.
}
// Adding values to array.
{
Value& a = document["a"]; // This time we uses non-const reference.
Document::AllocatorType& allocator = document.GetAllocator();
for (int i = 5; i <= 10; i++)
a.PushBack(i, allocator); // May look a bit strange, allocator is needed for potentially realloc. We normally uses the document's.
// Fluent API
a.PushBack("Lua", allocator).PushBack("Mio", allocator);
}
// Making string values.
// This version of SetString() just store the pointer to the string.
// So it is for literal and string that exists within value's life-cycle.
{
document["hello"] = "rapidjson"; // This will invoke strlen()
// Faster version:
// document["hello"].SetString("rapidjson", 9);
}
// This version of SetString() needs an allocator, which means it will allocate a new buffer and copy the the string into the buffer.
Value author;
{
char buffer[10];
int len = sprintf(buffer, "%s %s", "Milo", "Yip"); // synthetic example of dynamically created string.
author.SetString(buffer, static_cast<size_t>(len), document.GetAllocator());
// Shorter but slower version:
// document["hello"].SetString(buffer, document.GetAllocator());
// Constructor version:
// Value author(buffer, len, document.GetAllocator());
// Value author(buffer, document.GetAllocator());
memset(buffer, 0, sizeof(buffer)); // For demonstration purpose.
}
// Variable 'buffer' is unusable now but 'author' has already made a copy.
document.AddMember("author", author, document.GetAllocator());
assert(author.IsNull()); // Move semantic for assignment. After this variable is assigned as a member, the variable becomes null.
////////////////////////////////////////////////////////////////////////////
// 4. Stringify JSON
printf("\nModified JSON with reformatting:\n");
StringBuffer sb;
PrettyWriter<StringBuffer> writer(sb);
document.Accept(writer); // Accept() traverses the DOM and generates Handler events.
puts(sb.GetString());
return 0;
}
/* ****************************************************************************
*
* parseContextAttributeCompoundValueStandAlone -
*/
std::string parseContextAttributeCompoundValueStandAlone
(
Document& document,
ContextAttribute* caP,
orion::ValueType valueType
)
{
caP->compoundValueP = new orion::CompoundValueNode();
caP->compoundValueP->name = "TOP";
caP->compoundValueP->container = caP->compoundValueP;
caP->compoundValueP->valueType = caP->valueType; // Convert to other type?
caP->compoundValueP->path = "/";
caP->compoundValueP->rootP = caP->compoundValueP;
caP->compoundValueP->level = 0;
caP->compoundValueP->siblingNo = 0;
orion::CompoundValueNode* parent = caP->compoundValueP;
//
// Children of the node
//
if (caP->valueType == orion::ValueTypeVector)
{
int counter = 0;
for (Value::ConstValueIterator iter = document.Begin(); iter != document.End(); ++iter)
{
std::string nodeType = jsonParseTypeNames[iter->GetType()];
orion::CompoundValueNode* cvnP = new orion::CompoundValueNode();
char itemNo[4];
snprintf(itemNo, sizeof(itemNo), "%03d", counter);
cvnP->valueType = stringToCompoundType(nodeType);
cvnP->container = parent;
cvnP->rootP = parent->rootP;
cvnP->level = parent->level + 1;
cvnP->siblingNo = counter;
cvnP->path = parent->path + "[" + itemNo + "]";
if (nodeType == "String")
{
cvnP->stringValue = iter->GetString();
}
else if (nodeType == "Number")
{
cvnP->numberValue = iter->GetDouble();
}
else if ((nodeType == "True") || (nodeType == "False"))
{
cvnP->boolValue = (nodeType == "True")? true : false;
}
else if (nodeType == "Null")
{
cvnP->valueType = orion::ValueTypeNone;
}
else if (nodeType == "Object")
{
cvnP->path += "/";
cvnP->valueType = orion::ValueTypeObject;
}
else if (nodeType == "Array")
{
cvnP->path += "/";
cvnP->valueType = orion::ValueTypeVector;
}
parent->childV.push_back(cvnP);
//
// Start recursive calls if Object or Array
//
if ((nodeType == "Object") || (nodeType == "Array"))
{
parseContextAttributeCompoundValue(iter, caP, cvnP);
}
else if (!caP->typeGiven)
{
caP->type = defaultType(caP->valueType);
}
++counter;
}
}
else if (caP->valueType == orion::ValueTypeObject)
{
int counter = 0;
for (Value::ConstMemberIterator iter = document.MemberBegin(); iter != document.MemberEnd(); ++iter)
{
std::string nodeType = jsonParseTypeNames[iter->value.GetType()];
orion::CompoundValueNode* cvnP = new orion::CompoundValueNode();
cvnP->name = iter->name.GetString();
cvnP->valueType = stringToCompoundType(nodeType);
cvnP->container = parent;
cvnP->rootP = parent->rootP;
cvnP->level = parent->level + 1;
cvnP->siblingNo = counter;
cvnP->path = parent->path + cvnP->name;
if (nodeType == "String")
{
cvnP->stringValue = iter->value.GetString();
}
else if (nodeType == "Number")
{
cvnP->numberValue = iter->value.GetDouble();
}
else if ((nodeType == "True") || (nodeType == "False"))
{
cvnP->boolValue = (nodeType == "True")? true : false;
}
else if (nodeType == "Null")
{
cvnP->valueType = orion::ValueTypeNone;
}
else if (nodeType == "Object")
{
cvnP->path += "/";
cvnP->valueType = orion::ValueTypeObject;
}
else if (nodeType == "Array")
{
cvnP->path += "/";
cvnP->valueType = orion::ValueTypeVector;
}
parent->childV.push_back(cvnP);
//
// Start recursive calls if Object or Array
//
if ((nodeType == "Object") || (nodeType == "Array"))
{
parseContextAttributeCompoundValue(iter, caP, cvnP);
}
else if (!caP->typeGiven)
{
caP->type = defaultType(caP->valueType);
}
++counter;
}
}
return "OK";
}
/* ****************************************************************************
*
* parseContextAttributeCompoundValue -
*/
std::string parseContextAttributeCompoundValue
(
const Value::ConstValueIterator& node,
ContextAttribute* caP,
orion::CompoundValueNode* parent
)
{
if (node->IsObject())
{
int counter = 0;
for (Value::ConstMemberIterator iter = node->MemberBegin(); iter != node->MemberEnd(); ++iter)
{
std::string nodeType = jsonParseTypeNames[iter->value.GetType()];
orion::CompoundValueNode* cvnP = new orion::CompoundValueNode();
cvnP->valueType = stringToCompoundType(nodeType);
cvnP->name = iter->name.GetString();
cvnP->container = parent;
cvnP->rootP = parent->rootP;
cvnP->level = parent->level + 1;
cvnP->siblingNo = counter;
cvnP->path = parent->path + cvnP->name;
if (nodeType == "String")
{
cvnP->stringValue = iter->value.GetString();
}
else if (nodeType == "Number")
{
cvnP->numberValue = iter->value.GetDouble();
}
else if ((nodeType == "True") || (nodeType == "False"))
{
cvnP->boolValue = (nodeType == "True")? true : false;
}
else if (nodeType == "Null")
{
cvnP->valueType = orion::ValueTypeNone;
}
else if (nodeType == "Object")
{
cvnP->path += "/";
cvnP->valueType = orion::ValueTypeObject;
}
else if (nodeType == "Array")
{
cvnP->path += "/";
cvnP->valueType = orion::ValueTypeVector;
}
parent->childV.push_back(cvnP);
//
// Recursive call if Object or Array
//
if ((nodeType == "Object") || (nodeType == "Array"))
{
parseContextAttributeCompoundValue(iter, caP, cvnP);
}
++counter;
}
}
else if (node->IsArray())
{
int counter = 0;
for (Value::ConstValueIterator iter = node->Begin(); iter != node->End(); ++iter)
{
std::string nodeType = jsonParseTypeNames[iter->GetType()];
orion::CompoundValueNode* cvnP = new orion::CompoundValueNode();
char itemNo[4];
snprintf(itemNo, sizeof(itemNo), "%03d", counter);
cvnP->valueType = stringToCompoundType(nodeType);
cvnP->container = parent;
cvnP->rootP = parent->rootP;
cvnP->level = parent->level + 1;
cvnP->siblingNo = counter;
cvnP->path = parent->path + "[" + itemNo + "]";
if (nodeType == "String")
{
cvnP->stringValue = iter->GetString();
}
else if (nodeType == "Number")
{
cvnP->numberValue = iter->GetDouble();
}
else if ((nodeType == "True") || (nodeType == "False"))
{
cvnP->boolValue = (nodeType == "True")? true : false;
}
else if (nodeType == "Null")
{
cvnP->valueType = orion::ValueTypeNone;
}
else if (nodeType == "Object")
{
cvnP->path += "/";
cvnP->valueType = orion::ValueTypeObject;
}
else if (nodeType == "Array")
{
cvnP->path += "/";
cvnP->valueType = orion::ValueTypeVector;
}
parent->childV.push_back(cvnP);
//
// Recursive call if Object or Array
//
if ((nodeType == "Object") || (nodeType == "Array"))
{
parseContextAttributeCompoundValue(iter, caP, cvnP);
}
++counter;
}
}
return "OK";
}
TEST(Value, Array) {
Value x(kArrayType);
const Value& y = x;
Value::AllocatorType allocator;
EXPECT_EQ(kArrayType, x.GetType());
EXPECT_TRUE(x.IsArray());
EXPECT_TRUE(x.Empty());
EXPECT_EQ(0u, x.Size());
EXPECT_TRUE(y.IsArray());
EXPECT_TRUE(y.Empty());
EXPECT_EQ(0u, y.Size());
EXPECT_FALSE(x.IsNull());
EXPECT_FALSE(x.IsBool());
EXPECT_FALSE(x.IsFalse());
EXPECT_FALSE(x.IsTrue());
EXPECT_FALSE(x.IsString());
EXPECT_FALSE(x.IsObject());
// PushBack()
Value v;
x.PushBack(v, allocator);
v.SetBool(true);
x.PushBack(v, allocator);
v.SetBool(false);
x.PushBack(v, allocator);
v.SetInt(123);
x.PushBack(v, allocator);
//x.PushBack((const char*)"foo", allocator); // should not compile
x.PushBack("foo", allocator);
EXPECT_FALSE(x.Empty());
EXPECT_EQ(5u, x.Size());
EXPECT_FALSE(y.Empty());
EXPECT_EQ(5u, y.Size());
EXPECT_TRUE(x[SizeType(0)].IsNull());
EXPECT_TRUE(x[1].IsTrue());
EXPECT_TRUE(x[2].IsFalse());
EXPECT_TRUE(x[3].IsInt());
EXPECT_EQ(123, x[3].GetInt());
EXPECT_TRUE(y[SizeType(0)].IsNull());
EXPECT_TRUE(y[1].IsTrue());
EXPECT_TRUE(y[2].IsFalse());
EXPECT_TRUE(y[3].IsInt());
EXPECT_EQ(123, y[3].GetInt());
EXPECT_TRUE(y[4].IsString());
EXPECT_STREQ("foo", y[4].GetString());
#if RAPIDJSON_HAS_CXX11_RVALUE_REFS
// PushBack(GenericValue&&, Allocator&);
{
Value y(kArrayType);
y.PushBack(Value(true), allocator);
y.PushBack(std::move(Value(kArrayType).PushBack(Value(1), allocator).PushBack("foo", allocator)), allocator);
EXPECT_EQ(2u, y.Size());
EXPECT_TRUE(y[0].IsTrue());
EXPECT_TRUE(y[1].IsArray());
EXPECT_EQ(2u, y[1].Size());
EXPECT_TRUE(y[1][0].IsInt());
EXPECT_TRUE(y[1][1].IsString());
}
#endif
// iterator
Value::ValueIterator itr = x.Begin();
EXPECT_TRUE(itr != x.End());
EXPECT_TRUE(itr->IsNull());
++itr;
EXPECT_TRUE(itr != x.End());
EXPECT_TRUE(itr->IsTrue());
++itr;
EXPECT_TRUE(itr != x.End());
EXPECT_TRUE(itr->IsFalse());
++itr;
EXPECT_TRUE(itr != x.End());
EXPECT_TRUE(itr->IsInt());
EXPECT_EQ(123, itr->GetInt());
++itr;
EXPECT_TRUE(itr != x.End());
EXPECT_TRUE(itr->IsString());
EXPECT_STREQ("foo", itr->GetString());
// const iterator
Value::ConstValueIterator citr = y.Begin();
EXPECT_TRUE(citr != y.End());
EXPECT_TRUE(citr->IsNull());
++citr;
EXPECT_TRUE(citr != y.End());
EXPECT_TRUE(citr->IsTrue());
++citr;
EXPECT_TRUE(citr != y.End());
EXPECT_TRUE(citr->IsFalse());
++citr;
EXPECT_TRUE(citr != y.End());
EXPECT_TRUE(citr->IsInt());
EXPECT_EQ(123, citr->GetInt());
++citr;
EXPECT_TRUE(citr != y.End());
EXPECT_TRUE(citr->IsString());
EXPECT_STREQ("foo", citr->GetString());
// PopBack()
x.PopBack();
EXPECT_EQ(4u, x.Size());
EXPECT_TRUE(y[SizeType(0)].IsNull());
EXPECT_TRUE(y[1].IsTrue());
EXPECT_TRUE(y[2].IsFalse());
EXPECT_TRUE(y[3].IsInt());
// Clear()
x.Clear();
EXPECT_TRUE(x.Empty());
EXPECT_EQ(0u, x.Size());
EXPECT_TRUE(y.Empty());
EXPECT_EQ(0u, y.Size());
// Erase(ValueIterator)
// Use array of array to ensure removed elements' destructor is called.
// [[0],[1],[2],...]
for (int i = 0; i < 10; i++)
x.PushBack(Value(kArrayType).PushBack(i, allocator).Move(), allocator);
// Erase the first
itr = x.Erase(x.Begin());
EXPECT_EQ(x.Begin(), itr);
EXPECT_EQ(9u, x.Size());
for (int i = 0; i < 9; i++)
EXPECT_EQ(i + 1, x[static_cast<SizeType>(i)][0].GetInt());
// Ease the last
itr = x.Erase(x.End() - 1);
EXPECT_EQ(x.End(), itr);
EXPECT_EQ(8u, x.Size());
for (int i = 0; i < 8; i++)
EXPECT_EQ(i + 1, x[static_cast<SizeType>(i)][0].GetInt());
// Erase the middle
itr = x.Erase(x.Begin() + 4);
EXPECT_EQ(x.Begin() + 4, itr);
EXPECT_EQ(7u, x.Size());
for (int i = 0; i < 4; i++)
EXPECT_EQ(i + 1, x[static_cast<SizeType>(i)][0].GetInt());
for (int i = 4; i < 7; i++)
EXPECT_EQ(i + 2, x[static_cast<SizeType>(i)][0].GetInt());
// Erase(ValueIterator, ValueIterator)
// Exhaustive test with all 0 <= first < n, first <= last <= n cases
const unsigned n = 10;
for (unsigned first = 0; first < n; first++) {
for (unsigned last = first; last <= n; last++) {
x.Clear();
for (unsigned i = 0; i < n; i++)
x.PushBack(Value(kArrayType).PushBack(i, allocator).Move(), allocator);
itr = x.Erase(x.Begin() + first, x.Begin() + last);
if (last == n)
EXPECT_EQ(x.End(), itr);
else
EXPECT_EQ(x.Begin() + first, itr);
size_t removeCount = last - first;
EXPECT_EQ(n - removeCount, x.Size());
for (unsigned i = 0; i < first; i++)
EXPECT_EQ(i, x[i][0].GetUint());
for (unsigned i = first; i < n - removeCount; i++)
EXPECT_EQ(i + removeCount, x[static_cast<SizeType>(i)][0].GetUint());
}
}
// Working in gcc without C++11, but VS2013 cannot compile. To be diagnosed.
// http://en.wikipedia.org/wiki/Erase-remove_idiom
x.Clear();
for (int i = 0; i < 10; i++)
if (i % 2 == 0)
x.PushBack(i, allocator);
else
x.PushBack(Value(kNullType).Move(), allocator);
const Value null(kNullType);
x.Erase(std::remove(x.Begin(), x.End(), null), x.End());
EXPECT_EQ(5u, x.Size());
for (int i = 0; i < 5; i++)
EXPECT_EQ(i * 2, x[static_cast<SizeType>(i)]);
// SetArray()
Value z;
z.SetArray();
EXPECT_TRUE(z.IsArray());
EXPECT_TRUE(z.Empty());
}
bool PlayFabRequestHandler::DecodeRequest(int httpStatus, HttpRequest* request, void* userData, PlayFabBaseModel& outResult, PlayFabError& outError)
{
std::string response = request->GetReponse();
Document rawResult;
rawResult.Parse<0>(response.c_str());
// Check for bad responses
if (response.length() == 0 // Null response
|| rawResult.GetParseError() != NULL) // Non-Json response
{
// If we get here, we failed to connect meaningfully to the server - Assume a timeout
outError.HttpCode = 408;
outError.ErrorCode = PlayFabErrorConnectionTimeout;
// For text returns, use the non-json response if possible, else default to no response
outError.ErrorName = outError.ErrorMessage = outError.HttpStatus = response.length() == 0 ? "Request Timeout or null response" : response;
return false;
}
// Check if the returned json indicates an error
const Value::Member* errorCodeJson = rawResult.FindMember("errorCode");
if (errorCodeJson != NULL)
{
// There was an error, BUMMER
if (!errorCodeJson->value.IsNumber())
{
// unexpected json formatting - If we get here, we failed to connect meaningfully to the server - Assume a timeout
outError.HttpCode = 408;
outError.ErrorCode = PlayFabErrorConnectionTimeout;
// For text returns, use the non-json response if possible, else default to no response
outError.ErrorName = outError.ErrorMessage = outError.HttpStatus = response.length() == 0 ? "Request Timeout or null response" : response;
return false;
}
// TODO: what happens when the error is not in the enum?
outError.ErrorCode = static_cast<PlayFabErrorCode>(errorCodeJson->value.GetInt());
const Value::Member* codeJson = rawResult.FindMember("code");
if (codeJson != NULL && codeJson->value.IsNumber())
outError.HttpCode = codeJson->value.GetInt();
const Value::Member* statusJson = rawResult.FindMember("status");
if (statusJson != NULL && statusJson->value.IsString())
outError.HttpStatus = statusJson->value.GetString();
const Value::Member* errorNameJson = rawResult.FindMember("error");
if (errorNameJson != NULL && errorNameJson->value.IsString())
outError.ErrorName = errorNameJson->value.GetString();
const Value::Member* errorMessageJson = rawResult.FindMember("errorMessage");
if (errorMessageJson != NULL && errorMessageJson->value.IsString())
outError.ErrorMessage = errorMessageJson->value.GetString();
const Value::Member* errorDetailsJson = rawResult.FindMember("errorDetails");
if (errorDetailsJson != NULL && errorDetailsJson->value.IsObject())
{
const Value& errorDetailsObj = errorDetailsJson->value;
for (Value::ConstMemberIterator itr = errorDetailsObj.MemberBegin(); itr != errorDetailsObj.MemberEnd(); ++itr)
{
if (itr->name.IsString() && itr->value.IsArray())
{
const Value& errorList = itr->value;
for (Value::ConstValueIterator erroListIter = errorList.Begin(); erroListIter != errorList.End(); ++erroListIter)
outError.ErrorDetails.insert(std::pair<std::string, std::string>(itr->name.GetString(), erroListIter->GetString()));
}
}
}
// We encountered no errors parsing the error
return false;
}
const Value::Member* data = rawResult.FindMember("data");
if (data == NULL || !data->value.IsObject())
return false;
return outResult.readFromValue(data->value);
}
list loadCOCO( const std::string & name, int fold ) {
using namespace rapidjson;
// Load the annotations
char buf[1024];
sprintf( buf, COCO_ANNOT.c_str(), name.c_str() );
// Read the json file
Document doc;
std::ifstream t(buf);
std::string json_str = std::string(std::istreambuf_iterator<char>(t),std::istreambuf_iterator<char>());
doc.Parse( (char*)json_str.c_str() );
// Go through all instance labels
std::unordered_map< uint64_t, std::vector<int> > categories;
std::unordered_map< uint64_t, std::vector<float> > areas;
std::unordered_map< uint64_t, std::vector<Polygons> > segments;
const Value & instances = doc["instances"];
for ( Value::ConstValueIterator i = instances.Begin(); i != instances.End(); i++ ) {
// Get the image id
Value::ConstMemberIterator cmi_image_id = i->FindMember("image_id");
eassert( cmi_image_id != i->MemberEnd() );
const int image_id = cmi_image_id->value.GetInt();
// Get the category id
Value::ConstMemberIterator cmi_category_id = i->FindMember("category_id");
eassert( cmi_category_id != i->MemberEnd() );
const int category_id = cmi_category_id->value.GetInt();
// Get the category id
Value::ConstMemberIterator cmi_area = i->FindMember("area");
eassert( cmi_area != i->MemberEnd() );
const float area = cmi_area->value.GetDouble();
// Read the polygon
Value::ConstMemberIterator cmi_segmentation = i->FindMember("segmentation");
eassert( cmi_segmentation != i->MemberEnd() );
const Value & segmentations = cmi_segmentation->value;
// For now just use the first segmentation for each object
Polygons polygons;
for( Value::ConstValueIterator segmentation = segmentations.Begin(); segmentation!=segmentations.End(); segmentation++ ){
Polygon polygon = RMatrixXf( segmentation->Size() / 2, 2 );
float * ppolygon = polygon.data();
for ( Value::ConstValueIterator j = segmentation->Begin(); j != segmentation->End(); j++ )
*(ppolygon++) = j->GetDouble();
polygons.push_back( polygon );
}
if( !ONLY_CONNECTED || polygons.size() == 1 ) {
categories[ image_id ].push_back( category_id );
segments[ image_id ].push_back( polygons );
areas[ image_id ].push_back( area );
}
}
// Load all images
Value::ConstValueIterator B = doc["images"].Begin(), E = doc["images"].End();
const int N = E-B;
Value::ConstValueIterator i0 = B+(fold*N/N_FOLDS), i1 = B+((fold+1)*N/N_FOLDS);
std::vector< std::shared_ptr<Image8u> > images( i1 - i0 );
#pragma omp parallel for
for ( int k=0; k<i1-i0; k++ ) {
Value::ConstValueIterator i = i0+k;
// Get the file name and path
Value::ConstMemberIterator cmi_file_name = i->FindMember("file_name");
eassert( cmi_file_name != i->MemberEnd() );
const std::string file_name = cmi_file_name->value.GetString();
Value::ConstMemberIterator cmi_file_path = i->FindMember("file_path");
eassert( cmi_file_path != i->MemberEnd() );
const std::string file_path = cmi_file_path->value.GetString();
// Add the image entry
images[i-i0] = imreadShared( coco_dir+"/"+file_path+"/"+file_name );
}
// Create the python struct with the result
list r;
for ( Value::ConstValueIterator i = i0; i != i1; i++ ) {
// Get the image id
Value::ConstMemberIterator cmi_image_id = i->FindMember("id");
eassert( cmi_image_id != i->MemberEnd() );
const int image_id = cmi_image_id->value.GetInt();
// Add the image entry
const int N = categories[ image_id ].size();
if( N > 0 ){
dict entry;
entry["id"] = image_id;
entry["image"] = images[i - i0];
entry["categories"] = categories[ image_id ];
entry["areas"] = areas[ image_id ];
entry["segmentation"] = segments[ image_id ];
r.append( entry );
}
// else
// printf("Image '%d' doesn't have any annotations!\n", image_id );
}
return r;
}
void CLiveview::start()
{
Document replyJson;
//如果支持startRecMode
if (indevice->isCameraApiAvailable("startRecMode")) {
replyJson = indevice->startRecMode();
//重新获取可用API
replyJson = indevice->getAvailableApiList();
indevice->loadAvailableCameraApiList(replyJson);
}
//开始liveview 开两个子线程 一个获取图片 一个画出来
if (indevice->isCameraApiAvailable("startLiveview")) {
CreateThread(0, 0, retrieveJPG, this, 0, 0);
CreateThread(0, 0, drawJPEG, this, 0, 0);
}
//获取支持的拍摄模式
mComMod.ResetContent();
const Document replyJson2 = indevice->getAvailableShootMode();
if (indevice->isJsonOk(replyJson2))
{
indevice->curShootMode = replyJson2["result"].GetArray()[0].GetString();
indevice->recording = false;
Value::ConstArray a = replyJson2["result"].GetArray()[1].GetArray();
for (Value::ConstValueIterator itr = a.Begin(); itr != a.End(); ++itr)
{
indevice->mAvailableShootMod.push_back(itr->GetString());
mComMod.AddString(itr->GetString());
}
mComMod.SelectString(0, indevice->curShootMode);
}
//获取支持的ISO
mIsoCombo.ResetContent();
const Document replyJson3 = indevice->getAvailableIsoSpeedRate();
if (indevice->isJsonOk(replyJson3))
{
CString curIso = replyJson3["result"].GetArray()[0].GetString();
Value::ConstArray a = replyJson3["result"].GetArray()[1].GetArray();
for (Value::ConstValueIterator itr = a.Begin(); itr != a.End(); ++itr)
{
mIsoCombo.AddString(itr->GetString());
}
mIsoCombo.SelectString(0, curIso);
}
//获取支持的曝光模式
mExpoCombo.ResetContent();
const Document replyJson4 = indevice->getAvailableExposureMode();
if (indevice->isJsonOk(replyJson4))
{
CString curExpo = replyJson4["result"].GetArray()[0].GetString();
Value::ConstArray a = replyJson4["result"].GetArray()[1].GetArray();
for (Value::ConstValueIterator itr = a.Begin(); itr != a.End(); ++itr)
{
mExpoCombo.AddString(itr->GetString());
}
mExpoCombo.SelectString(0, curExpo);
}
indevice->getAvailableStillSize();
indevice->setStillSize();
indevice->setPostviewImageSize();
//获取是否支持调节焦距
if (!indevice->isCameraApiAvailable("actZoom"))
{
mBtnZoomIn.EnableWindow(0);
mBtnZoomOut.EnableWindow(0);
}
FreshUI();
}
void iterateArray(Value::ConstValueIterator& itr,
Value::ConstValueIterator& itrEnd, StringBuffer *buffer,
Writer<StringBuffer> *writer, stringstream& ss) {
for (; itr != itrEnd; itr++) {
if (itr->IsObject()) {
Value::ConstMemberIterator itr_ = itr->MemberBegin();
Value::ConstMemberIterator itrEnd_ = itr->MemberEnd();
iterateObject(itr_, itrEnd_, buffer, writer, ss);
} else if (itr->IsArray()) {
Value::ConstValueIterator itr_ = itr->Begin();
Value::ConstValueIterator itrEnd_ = itr->End();
iterateArray(itr_, itrEnd_, buffer, writer, ss);
} else if (itr->IsBool()) {
ss << DELIM << itr->GetBool();
} else if (itr->IsInt()) {
ss << DELIM << itr->GetInt();
} else if (itr->IsInt64()) {
ss << DELIM << itr->GetInt64();
} else if (itr->IsDouble()) {
ss << DELIM << itr->GetDouble();
} else if (itr->IsString()) {
ss << DELIM << "\"" << itr->GetString() << "\"";
} else {
throw runtime_error(string("Case missing from tokenizer"));
}
}
}
std::vector<SlotType>
MtgJsonAllSetsData::getBoosterSlots( const std::string& code ) const
{
std::vector<SlotType> boosterSlots;
if( mBoosterSetCodes.count(code) == 0 )
{
mLogger->warn( "No booster member in set {}, returning empty booster slots", code );
return boosterSlots;
}
// In parse() this was vetted to be safe and yield an Array-type value.
const Value& boosterValue = mDoc[code]["booster"];
mLogger->debug( "{:-^40}", "assembling booster slots" );
for( Value::ConstValueIterator iter = boosterValue.Begin(); iter != boosterValue.End(); ++iter )
{
if( iter->IsArray() )
{
// create a set of any strings in the array
std::set<std::string> slotArraySet;
for( unsigned i = 0; i < iter->Size(); ++i )
{
const Value& val = (*iter)[i];
if( val.IsString() )
{
slotArraySet.insert( val.GetString() );
mLogger->debug( "booster slot array[{}]: {}", i, val.GetString() );
}
else
{
mLogger->warn( "Non-string in booster slot array, ignoring!" );
}
}
const std::set<std::string> rareMythicRareSlot { "rare", "mythic rare" };
if( slotArraySet == rareMythicRareSlot )
boosterSlots.push_back( SLOT_RARE_OR_MYTHIC_RARE );
else
mLogger->warn( "Unrecognized booster slot array, ignoring!" );
}
else if( iter->IsString() )
{
std::string slotStr( iter->GetString() );
mLogger->debug( "booster slot string: {}", slotStr );
if( slotStr == "common" )
boosterSlots.push_back( SLOT_COMMON );
else if( slotStr == "uncommon" )
boosterSlots.push_back( SLOT_UNCOMMON );
else if( slotStr == "rare" )
boosterSlots.push_back( SLOT_RARE );
else if( slotStr == "timeshifted purple" )
boosterSlots.push_back( SLOT_TIMESHIFTED_PURPLE );
else if( slotStr == "land" ) { /* do nothing */ }
else if( slotStr == "marketing" ) { /* do nothing */ }
else
mLogger->warn( "Unrecognized booster slot type {}, ignoring!", slotStr );
}
else
{
mLogger->warn( "Non-string booster slot type, ignoring!" );
}
}
return boosterSlots;
}
std::multimap<RarityType,std::string>
MtgJsonAllSetsData::getCardPool( const std::string& code ) const
{
std::multimap<RarityType,std::string> rarityMap;
if( mAllSetCodes.count(code) == 0 )
{
mLogger->warn( "Unable to find set {}, returning empty card pool", code );
return rarityMap;
}
// In parse() this was vetted to be safe and yield an Array-type value.
const Value& cardsValue = mDoc[code]["cards"];
mLogger->debug( "{:-^40}", "assembling card pool" );
for( Value::ConstValueIterator iter = cardsValue.Begin(); iter != cardsValue.End(); ++iter )
{
Value::ConstMemberIterator nameIter = iter->FindMember( "name" );
Value::ConstMemberIterator rarityIter = iter->FindMember( "rarity" );
if( nameIter != iter->MemberEnd() && nameIter->value.IsString() &&
rarityIter != iter->MemberEnd() && rarityIter->value.IsString() )
{
std::string nameStr( nameIter->value.GetString() );
std::string rarityStr( rarityIter->value.GetString() );
mLogger->debug( "json: {} : {}", nameStr, rarityStr );
// Some cards have multiple entries (i.e. split/flip/double-sided),
// so make sure they are only represented once. Done by skipping
// over cards whose name doesn't match the first entry of the
// 'names' array (if it exists).
if( iter->HasMember("names") )
{
const Value& names = (*iter)["names"];
if( names.IsArray() && !names.Empty() && (nameStr != names[0]) )
{
continue;
}
// Modify the name for split cards.
if( MtgJson::isSplitCard( *iter ) )
{
nameStr = MtgJson::createSplitCardName( names );
}
}
// Some cards have variations with multiple entries that should
// only be counted once. Done by checking if there are
// variations and checking a card's number for a non-digit,
// non-'a' ending.
if( iter->HasMember("variations") && iter->HasMember("number") )
{
const Value& numberValue = (*iter)["number"];
if( numberValue.IsString() )
{
const std::string numberStr( numberValue.GetString() );
const char c = numberStr.back();
if( !std::isdigit( c ) && (c != 'a') )
{
continue;
}
}
}
RarityType rarity = MtgJson::getRarityFromString( rarityStr );
if( rarity != RARITY_UNKNOWN )
rarityMap.insert( std::make_pair( rarity, nameStr ) );
else
mLogger->warn( "Unknown rarity type {}, ignoring!", rarityStr );
}
else
{
mLogger->notice( "card entry without name or rarity in set {}", code );
}
}
return rarityMap;
}
