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// Copyright (C) 2024 The Qt Company Ltd.
// SPDX-License-Identifier: LicenseRef-Qt-Commercial OR LGPL-3.0-only OR GPL-2.0-only OR GPL-3.0-only
#include "qv4compileddata_p.h"
#include <private/inlinecomponentutils_p.h>
#include <private/qqmlscriptdata_p.h>
#include <private/qqmltypenamecache_p.h>
#include <private/qv4resolvedtypereference_p.h>
#include <QtQml/qqmlfile.h>
#include <QtCore/qdir.h>
#include <QtCore/qscopeguard.h>
#include <QtCore/qstandardpaths.h>
QT_BEGIN_NAMESPACE
namespace QV4 {
namespace CompiledData {
/*!
\internal
This function creates a temporary key vector and sorts it to guarantuee a stable
hash. This is used to calculate a check-sum on dependent meta-objects.
*/
bool ResolvedTypeReferenceMap::addToHash(
QCryptographicHash *hash, QHash<quintptr, QByteArray> *checksums) const
{
std::vector<int> keys (size());
int i = 0;
for (auto it = constBegin(), end = constEnd(); it != end; ++it) {
keys[i] = it.key();
++i;
}
std::sort(keys.begin(), keys.end());
for (int key: keys) {
if (!this->operator[](key)->addToHash(hash, checksums))
return false;
}
return true;
}
CompilationUnit::CompilationUnit(
const Unit *unitData, const QString &fileName, const QString &finalUrlString)
{
setUnitData(unitData, nullptr, fileName, finalUrlString);
}
CompilationUnit::~CompilationUnit()
{
qDeleteAll(resolvedTypes);
if (data) {
if (data->qmlUnit() != qmlData)
free(const_cast<QmlUnit *>(qmlData));
qmlData = nullptr;
if (!(data->flags & QV4::CompiledData::Unit::StaticData))
free(const_cast<Unit *>(data));
}
data = nullptr;
#if Q_BYTE_ORDER == Q_BIG_ENDIAN
delete [] constants;
constants = nullptr;
#endif
}
QString CompilationUnit::localCacheFilePath(const QUrl &url)
{
static const QByteArray envCachePath = qgetenv("QML_DISK_CACHE_PATH");
const QString localSourcePath = QQmlFile::urlToLocalFileOrQrc(url);
const QString cacheFileSuffix
= QFileInfo(localSourcePath + QLatin1Char('c')).completeSuffix();
QCryptographicHash fileNameHash(QCryptographicHash::Sha1);
fileNameHash.addData(localSourcePath.toUtf8());
QString directory = envCachePath.isEmpty()
? QStandardPaths::writableLocation(QStandardPaths::CacheLocation)
+ QLatin1String("/qmlcache/")
: QString::fromLocal8Bit(envCachePath) + QLatin1String("/");
QDir::root().mkpath(directory);
return directory + QString::fromUtf8(fileNameHash.result().toHex())
+ QLatin1Char('.') + cacheFileSuffix;
}
bool CompilationUnit::loadFromDisk(
const QUrl &url, const QDateTime &sourceTimeStamp, QString *errorString)
{
if (!QQmlFile::isLocalFile(url)) {
*errorString = QStringLiteral("File has to be a local file.");
return false;
}
const QString sourcePath = QQmlFile::urlToLocalFileOrQrc(url);
auto cacheFile = std::make_unique<CompilationUnitMapper>();
const QStringList cachePaths = { sourcePath + QLatin1Char('c'), localCacheFilePath(url) };
for (const QString &cachePath : cachePaths) {
Unit *mappedUnit = cacheFile->get(cachePath, sourceTimeStamp, errorString);
if (!mappedUnit)
continue;
const Unit *oldData = unitData();
const Unit * const oldDataPtr
= (oldData && !(oldData->flags & Unit::StaticData))
? oldData
: nullptr;
auto dataPtrRevert = qScopeGuard([this, oldData](){
setUnitData(oldData);
});
setUnitData(mappedUnit);
if (mappedUnit->sourceFileIndex != 0) {
if (mappedUnit->sourceFileIndex >=
mappedUnit->stringTableSize + dynamicStrings.size()) {
*errorString = QStringLiteral("QML source file index is invalid.");
continue;
}
if (sourcePath !=
QQmlFile::urlToLocalFileOrQrc(stringAt(mappedUnit->sourceFileIndex))) {
*errorString = QStringLiteral("QML source file has moved to a different location.");
continue;
}
}
dataPtrRevert.dismiss();
free(const_cast<Unit*>(oldDataPtr));
backingFile = std::move(cacheFile);
return true;
}
return false;
}
bool CompilationUnit::saveToDisk(const QUrl &unitUrl, QString *errorString)
{
if (unitData()->sourceTimeStamp == 0) {
*errorString = QStringLiteral("Missing time stamp for source file");
return false;
}
if (!QQmlFile::isLocalFile(unitUrl)) {
*errorString = QStringLiteral("File has to be a local file.");
return false;
}
return SaveableUnitPointer(unitData()).saveToDisk<char>(
[&unitUrl, errorString](const char *data, quint32 size) {
const QString cachePath = localCacheFilePath(unitUrl);
if (SaveableUnitPointer::writeDataToFile(
cachePath, data, size, errorString)) {
CompilationUnitMapper::invalidate(cachePath);
return true;
}
return false;
});
}
QStringList CompilationUnit::moduleRequests() const
{
QStringList requests;
requests.reserve(data->moduleRequestTableSize);
for (uint i = 0; i < data->moduleRequestTableSize; ++i)
requests << stringAt(data->moduleRequestTable()[i]);
return requests;
}
ResolvedTypeReference *CompilationUnit::resolvedType(QMetaType type) const
{
for (ResolvedTypeReference *ref : std::as_const(resolvedTypes)) {
if (ref->type().typeId() == type)
return ref;
}
return nullptr;
}
int CompilationUnit::totalBindingsCount() const
{
if (!icRootName)
return m_totalBindingsCount;
return inlineComponentData[*icRootName].totalBindingCount;
}
int CompilationUnit::totalObjectCount() const
{
if (!icRootName)
return m_totalObjectCount;
return inlineComponentData[*icRootName].totalObjectCount;
}
template<typename F>
void processInlinComponentType(
const QQmlType &type,
const QQmlRefPointer<QV4::CompiledData::CompilationUnit> &compilationUnit,
F &&populateIcData)
{
if (type.isInlineComponentType()) {
QString icRootName;
if (compilationUnit->icRootName) {
icRootName = type.elementName();
std::swap(*compilationUnit->icRootName, icRootName);
} else {
compilationUnit->icRootName = std::make_unique<QString>(type.elementName());
}
populateIcData();
if (icRootName.isEmpty())
compilationUnit->icRootName.reset();
else
std::swap(*compilationUnit->icRootName, icRootName);
} else {
populateIcData();
}
}
void CompiledData::CompilationUnit::finalizeCompositeType(const QQmlType &type)
{
// Add to type registry of composites
if (propertyCaches.needsVMEMetaObject(/*root object*/0)) {
// qmlType is only valid for types that have references to themselves.
if (type.isValid()) {
qmlType = type;
} else {
qmlType = QQmlMetaType::findCompositeType(
finalUrl(), this, (unitData()->flags & CompiledData::Unit::IsSingleton)
? QQmlMetaType::Singleton
: QQmlMetaType::NonSingleton);
}
QQmlMetaType::registerInternalCompositeType(this);
} else {
const QV4::CompiledData::Object *obj = objectAt(/*root object*/0);
auto *typeRef = resolvedTypes.value(obj->inheritedTypeNameIndex);
Q_ASSERT(typeRef);
if (const auto compilationUnit = typeRef->compilationUnit())
qmlType = compilationUnit->qmlType;
else
qmlType = typeRef->type();
}
// Collect some data for instantiation later.
using namespace icutils;
std::vector<QV4::CompiledData::InlineComponent> allICs {};
for (int i=0; i != objectCount(); ++i) {
const CompiledObject *obj = objectAt(i);
for (auto it = obj->inlineComponentsBegin(); it != obj->inlineComponentsEnd(); ++it) {
allICs.push_back(*it);
}
}
NodeList nodes;
nodes.resize(allICs.size());
std::iota(nodes.begin(), nodes.end(), 0);
AdjacencyList adjacencyList;
adjacencyList.resize(nodes.size());
fillAdjacencyListForInlineComponents(this, adjacencyList, nodes, allICs);
bool hasCycle = false;
auto nodesSorted = topoSort(nodes, adjacencyList, hasCycle);
Q_ASSERT(!hasCycle); // would have already been discovered by qqmlpropertycachcecreator
// We need to first iterate over all inline components,
// as the containing component might create instances of them
// and in that case we need to add its object count
for (auto nodeIt = nodesSorted.rbegin(); nodeIt != nodesSorted.rend(); ++nodeIt) {
const auto &ic = allICs.at(nodeIt->index());
const int lastICRoot = ic.objectIndex;
for (int i = ic.objectIndex; i<objectCount(); ++i) {
const QV4::CompiledData::Object *obj = objectAt(i);
bool leftCurrentInlineComponent
= (i != lastICRoot
&& obj->hasFlag(QV4::CompiledData::Object::IsInlineComponentRoot))
|| !obj->hasFlag(QV4::CompiledData::Object::IsPartOfInlineComponent);
if (leftCurrentInlineComponent)
break;
const QString lastICRootName = stringAt(ic.nameIndex);
inlineComponentData[lastICRootName].totalBindingCount
+= obj->nBindings;
if (auto *typeRef = resolvedTypes.value(obj->inheritedTypeNameIndex)) {
const auto type = typeRef->type();
if (type.isValid() && type.parserStatusCast() != -1)
++inlineComponentData[lastICRootName].totalParserStatusCount;
++inlineComponentData[lastICRootName].totalObjectCount;
if (const auto compilationUnit = typeRef->compilationUnit()) {
// if the type is an inline component type, we have to extract the information
// from it.
// This requires that inline components are visited in the correct order.
processInlinComponentType(type, compilationUnit, [&]() {
auto &icData = inlineComponentData[lastICRootName];
icData.totalBindingCount += compilationUnit->totalBindingsCount();
icData.totalParserStatusCount += compilationUnit->totalParserStatusCount();
icData.totalObjectCount += compilationUnit->totalObjectCount();
});
}
}
}
}
int bindingCount = 0;
int parserStatusCount = 0;
int objectCount = 0;
for (quint32 i = 0, count = this->objectCount(); i < count; ++i) {
const QV4::CompiledData::Object *obj = objectAt(i);
if (obj->hasFlag(QV4::CompiledData::Object::IsPartOfInlineComponent))
continue;
bindingCount += obj->nBindings;
if (auto *typeRef = resolvedTypes.value(obj->inheritedTypeNameIndex)) {
const auto type = typeRef->type();
if (type.isValid() && type.parserStatusCast() != -1)
++parserStatusCount;
++objectCount;
if (const auto compilationUnit = typeRef->compilationUnit()) {
processInlinComponentType(type, compilationUnit, [&](){
bindingCount += compilationUnit->totalBindingsCount();
parserStatusCount += compilationUnit->totalParserStatusCount();
objectCount += compilationUnit->totalObjectCount();
});
}
}
}
m_totalBindingsCount = bindingCount;
m_totalParserStatusCount = parserStatusCount;
m_totalObjectCount = objectCount;
}
int CompilationUnit::totalParserStatusCount() const
{
if (!icRootName)
return m_totalParserStatusCount;
return inlineComponentData[*icRootName].totalParserStatusCount;
}
bool CompilationUnit::verifyChecksum(const DependentTypesHasher &dependencyHasher) const
{
if (!dependencyHasher) {
for (size_t i = 0; i < sizeof(data->dependencyMD5Checksum); ++i) {
if (data->dependencyMD5Checksum[i] != 0)
return false;
}
return true;
}
const QByteArray checksum = dependencyHasher();
return checksum.size() == sizeof(data->dependencyMD5Checksum)
&& memcmp(data->dependencyMD5Checksum, checksum.constData(),
sizeof(data->dependencyMD5Checksum)) == 0;
}
QQmlType CompilationUnit::qmlTypeForComponent(const QString &inlineComponentName) const
{
if (inlineComponentName.isEmpty())
return qmlType;
return inlineComponentData[inlineComponentName].qmlType;
}
} // namespace CompiledData
} // namespace QV4
QT_END_NAMESPACE
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