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/****************************************************************************
**
** Copyright (C) 2016 The Qt Company Ltd.
** Contact: https://www.qt.io/licensing/
**
** This file is part of Qt Creator.
**
** Commercial License Usage
** Licensees holding valid commercial Qt licenses may use this file in
** accordance with the commercial license agreement provided with the
** Software or, alternatively, in accordance with the terms contained in
** a written agreement between you and The Qt Company. For licensing terms
** and conditions see https://www.qt.io/terms-conditions. For further
** information use the contact form at https://www.qt.io/contact-us.
**
** GNU General Public License Usage
** Alternatively, this file may be used under the terms of the GNU
** General Public License version 3 as published by the Free Software
** Foundation with exceptions as appearing in the file LICENSE.GPL3-EXCEPT
** included in the packaging of this file. Please review the following
** information to ensure the GNU General Public License requirements will
** be met: https://www.gnu.org/licenses/gpl-3.0.html.
**
****************************************************************************/
#include "memoryusagemodel.h"
#include "qmlprofilermodelmanager.h"
#include "qmlprofilereventtypes.h"
#include <utils/qtcassert.h>
namespace QmlProfiler {
namespace Internal {
MemoryUsageModel::MemoryUsageModel(QmlProfilerModelManager *manager,
Timeline::TimelineModelAggregator *parent) :
QmlProfilerTimelineModel(manager, MemoryAllocation, MaximumRangeType, ProfileMemory, parent)
{
// Register additional features. The base class already registers the main feature.
// Don't register initializer, finalizer, or clearer as the base class has done so already.
modelManager()->registerFeatures(Constants::QML_JS_RANGE_FEATURES ^ (1 << ProfileCompiling),
std::bind(&QmlProfilerTimelineModel::loadEvent, this,
std::placeholders::_1, std::placeholders::_2));
}
qint64 MemoryUsageModel::rowMaxValue(int rowNumber) const
{
Q_UNUSED(rowNumber);
return m_maxSize;
}
int MemoryUsageModel::expandedRow(int index) const
{
int type = selectionId(index);
return (type == HeapPage || type == LargeItem) ? 1 : 2;
}
int MemoryUsageModel::collapsedRow(int index) const
{
return expandedRow(index);
}
int MemoryUsageModel::typeId(int index) const
{
return m_data[index].typeId;
}
QRgb MemoryUsageModel::color(int index) const
{
return colorBySelectionId(index);
}
float MemoryUsageModel::relativeHeight(int index) const
{
return qMin(1.0f, (float)m_data[index].size / (float)m_maxSize);
}
QVariantMap MemoryUsageModel::location(int index) const
{
return locationFromTypeId(index);
}
QVariantList MemoryUsageModel::labels() const
{
QVariantList result;
QVariantMap element;
element.insert(QLatin1String("description"), tr("Memory Allocation"));
element.insert(QLatin1String("id"), HeapPage);
result << element;
element.clear();
element.insert(QLatin1String("description"), tr("Memory Usage"));
element.insert(QLatin1String("id"), SmallItem);
result << element;
return result;
}
static int toSameSignedInt(qint64 number)
{
if (number > std::numeric_limits<int>::max())
return std::numeric_limits<int>::max();
if (number < std::numeric_limits<int>::min())
return std::numeric_limits<int>::min();
return static_cast<int>(number);
}
QVariantMap MemoryUsageModel::details(int index) const
{
QVariantMap result;
const Item *ev = &m_data[index];
if (ev->allocated >= -ev->deallocated)
result.insert(QLatin1String("displayName"), tr("Memory Allocated"));
else
result.insert(QLatin1String("displayName"), tr("Memory Freed"));
result.insert(tr("Total"), tr("%n byte(s)", nullptr, toSameSignedInt(ev->size)));
if (ev->allocations > 0) {
result.insert(tr("Allocated"), tr("%n byte(s)", nullptr, toSameSignedInt(ev->allocated)));
result.insert(tr("Allocations"), ev->allocations);
}
if (ev->deallocations > 0) {
result.insert(tr("Deallocated"),
tr("%n byte(s)", nullptr, toSameSignedInt(-ev->deallocated)));
result.insert(tr("Deallocations"), ev->deallocations);
}
QString memoryTypeName;
switch (selectionId(index)) {
case HeapPage: memoryTypeName = tr("Heap Allocation"); break;
case LargeItem: memoryTypeName = tr("Large Item Allocation"); break;
case SmallItem: memoryTypeName = tr("Heap Usage"); break;
default: Q_UNREACHABLE();
}
result.insert(tr("Type"), memoryTypeName);
result.insert(tr("Location"), modelManager()->eventType(ev->typeId).displayName());
return result;
}
void MemoryUsageModel::loadEvent(const QmlEvent &event, const QmlEventType &type)
{
if (type.message() != MemoryAllocation) {
if (type.rangeType() != MaximumRangeType) {
m_continuation = ContinueNothing;
if (event.rangeStage() == RangeStart)
m_rangeStack.push(RangeStackFrame(event.typeIndex(), event.timestamp()));
else if (event.rangeStage() == RangeEnd) {
QTC_ASSERT(!m_rangeStack.isEmpty(), return);
QTC_ASSERT(m_rangeStack.top().originTypeIndex == event.typeIndex(), return);
m_rangeStack.pop();
}
}
return;
}
auto canContinue = [&](EventContinuation continuation) {
QTC_ASSERT(continuation != ContinueNothing, return false);
if ((m_continuation & continuation) == 0)
return false;
int currentIndex = (continuation == ContinueAllocation ? m_currentJSHeapIndex :
m_currentUsageIndex);
if (m_rangeStack.isEmpty()) {
qint64 amount = event.number<qint64>(0);
// outside of ranges show monotonous allocation or deallocation
return (amount >= 0 && m_data[currentIndex].allocated >= 0)
|| (amount < 0 && m_data[currentIndex].deallocated > 0);
} else {
return m_data[currentIndex].typeId == m_rangeStack.top().originTypeIndex
&& m_rangeStack.top().startTime < startTime(currentIndex);
}
};
if (type.detailType() == SmallItem || type.detailType() == LargeItem) {
if (canContinue(ContinueUsage)) {
m_data[m_currentUsageIndex].update(event.number<qint64>(0));
m_currentUsage = m_data[m_currentUsageIndex].size;
} else {
Item allocation(
m_rangeStack.empty() ? event.typeIndex() :
m_rangeStack.top().originTypeIndex,
m_currentUsage);
allocation.update(event.number<qint64>(0));
m_currentUsage = allocation.size;
if (m_currentUsageIndex != -1) {
qint64 duration = event.timestamp() - startTime(m_currentUsageIndex);
if (duration > 0) {
insertEnd(m_currentUsageIndex, duration - 1);
m_currentUsageIndex = insertStart(event.timestamp(), SmallItem);
m_data.insert(m_currentUsageIndex, allocation);
} else {
// Ignore ranges of 0 duration. We only need to keep track of the sizes.
m_data[m_currentUsageIndex] = allocation;
}
} else {
m_currentUsageIndex = insertStart(event.timestamp(), SmallItem);
m_data.insert(m_currentUsageIndex, allocation);
}
m_continuation = m_continuation | ContinueUsage;
}
}
if (type.detailType() == HeapPage || type.detailType() == LargeItem) {
if (canContinue(ContinueAllocation)
&& type.detailType() == selectionId(m_currentJSHeapIndex)) {
m_data[m_currentJSHeapIndex].update(event.number<qint64>(0));
m_currentSize = m_data[m_currentJSHeapIndex].size;
} else {
Item allocation(
m_rangeStack.empty() ? event.typeIndex() :
m_rangeStack.top().originTypeIndex,
m_currentSize);
allocation.update(event.number<qint64>(0));
m_currentSize = allocation.size;
if (m_currentSize > m_maxSize)
m_maxSize = m_currentSize;
if (m_currentJSHeapIndex != -1) {
qint64 duration = event.timestamp() - startTime(m_currentJSHeapIndex);
if (duration > 0){
insertEnd(m_currentJSHeapIndex, duration - 1);
m_currentJSHeapIndex = insertStart(event.timestamp(), type.detailType());
m_data.insert(m_currentJSHeapIndex, allocation);
} else {
// Ignore ranges of 0 duration. We only need to keep track of the sizes.
m_data[m_currentJSHeapIndex] = allocation;
}
} else {
m_currentJSHeapIndex = insertStart(event.timestamp(), type.detailType());
m_data.insert(m_currentJSHeapIndex, allocation);
}
m_continuation = m_continuation | ContinueAllocation;
}
}
}
void MemoryUsageModel::finalize()
{
if (m_currentJSHeapIndex != -1) {
insertEnd(m_currentJSHeapIndex,
modelManager()->traceEnd() - startTime(m_currentJSHeapIndex));
}
if (m_currentUsageIndex != -1)
insertEnd(m_currentUsageIndex, modelManager()->traceEnd() - startTime(m_currentUsageIndex));
computeNesting();
setExpandedRowCount(3);
setCollapsedRowCount(3);
QmlProfilerTimelineModel::finalize();
}
void MemoryUsageModel::clear()
{
m_data.clear();
m_maxSize = 1;
m_currentSize = 0;
m_currentUsage = 0;
m_currentUsageIndex = -1;
m_currentJSHeapIndex = -1;
m_continuation = ContinueNothing;
m_rangeStack.clear();
QmlProfilerTimelineModel::clear();
}
bool MemoryUsageModel::handlesTypeId(int typeId) const
{
Q_UNUSED(typeId);
// We don't want the memory ranges allocated by some QML/JS function to be highlighted when
// propagating a typeId selection to the timeline. The actual range should be highlighted.
return false;
}
MemoryUsageModel::Item::Item(int typeId, qint64 baseAmount) :
size(baseAmount), allocated(0), deallocated(0), allocations(0), deallocations(0),
typeId(typeId)
{
}
void MemoryUsageModel::Item::update(qint64 amount)
{
size += amount;
if (amount < 0) {
deallocated += amount;
++deallocations;
} else {
allocated += amount;
++allocations;
}
}
} // namespace Internal
} // namespace QmlProfiler
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