paulxstretch/deps/juce/modules/juce_gui_basics/desktop/juce_Displays.cpp
essej 25bd5d8adb git subrepo clone --branch=sono6good https://github.com/essej/JUCE.git deps/juce
subrepo:
  subdir:   "deps/juce"
  merged:   "b13f9084e"
upstream:
  origin:   "https://github.com/essej/JUCE.git"
  branch:   "sono6good"
  commit:   "b13f9084e"
git-subrepo:
  version:  "0.4.3"
  origin:   "https://github.com/ingydotnet/git-subrepo.git"
  commit:   "2f68596"
2022-04-18 17:51:22 -04:00

439 lines
16 KiB
C++

/*
==============================================================================
This file is part of the JUCE library.
Copyright (c) 2020 - Raw Material Software Limited
JUCE is an open source library subject to commercial or open-source
licensing.
By using JUCE, you agree to the terms of both the JUCE 6 End-User License
Agreement and JUCE Privacy Policy (both effective as of the 16th June 2020).
End User License Agreement: www.juce.com/juce-6-licence
Privacy Policy: www.juce.com/juce-privacy-policy
Or: You may also use this code under the terms of the GPL v3 (see
www.gnu.org/licenses).
JUCE IS PROVIDED "AS IS" WITHOUT ANY WARRANTY, AND ALL WARRANTIES, WHETHER
EXPRESSED OR IMPLIED, INCLUDING MERCHANTABILITY AND FITNESS FOR PURPOSE, ARE
DISCLAIMED.
==============================================================================
*/
namespace juce
{
Displays::Displays (Desktop& desktop)
{
init (desktop);
}
void Displays::init (Desktop& desktop)
{
findDisplays (desktop.getGlobalScaleFactor());
}
const Displays::Display* Displays::getDisplayForRect (Rectangle<int> rect, bool isPhysical) const noexcept
{
int maxArea = -1;
const Display* foundDisplay = nullptr;
for (auto& display : displays)
{
auto displayArea = display.totalArea;
if (isPhysical)
displayArea = (displayArea.withZeroOrigin() * display.scale) + display.topLeftPhysical;
displayArea = displayArea.getIntersection (rect);
auto area = displayArea.getWidth() * displayArea.getHeight();
if (area >= maxArea)
{
maxArea = area;
foundDisplay = &display;
}
}
return foundDisplay;
}
const Displays::Display* Displays::getDisplayForPoint (Point<int> point, bool isPhysical) const noexcept
{
auto minDistance = std::numeric_limits<int>::max();
const Display* foundDisplay = nullptr;
for (auto& display : displays)
{
auto displayArea = display.totalArea;
if (isPhysical)
displayArea = (displayArea.withZeroOrigin() * display.scale) + display.topLeftPhysical;
if (displayArea.contains (point))
return &display;
auto distance = displayArea.getCentre().getDistanceFrom (point);
if (distance <= minDistance)
{
minDistance = distance;
foundDisplay = &display;
}
}
return foundDisplay;
}
Rectangle<int> Displays::physicalToLogical (Rectangle<int> rect, const Display* useScaleFactorOfDisplay) const noexcept
{
return physicalToLogical (rect.toFloat(), useScaleFactorOfDisplay).toNearestInt();
}
Rectangle<float> Displays::physicalToLogical (Rectangle<float> rect, const Display* useScaleFactorOfDisplay) const noexcept
{
const auto* display = useScaleFactorOfDisplay != nullptr ? useScaleFactorOfDisplay
: getDisplayForRect (rect.toNearestInt(), true);
if (display == nullptr)
return rect;
auto globalScale = Desktop::getInstance().getGlobalScaleFactor();
return ((rect - display->topLeftPhysical.toFloat()) / (display->scale / globalScale))
+ (display->totalArea.getTopLeft().toFloat() * globalScale);
}
Rectangle<int> Displays::logicalToPhysical (Rectangle<int> rect, const Display* useScaleFactorOfDisplay) const noexcept
{
return logicalToPhysical (rect.toFloat(), useScaleFactorOfDisplay).toNearestInt();
}
Rectangle<float> Displays::logicalToPhysical (Rectangle<float> rect, const Display* useScaleFactorOfDisplay) const noexcept
{
const auto* display = useScaleFactorOfDisplay != nullptr ? useScaleFactorOfDisplay
: getDisplayForRect (rect.toNearestInt(), false);
if (display == nullptr)
return rect;
auto globalScale = Desktop::getInstance().getGlobalScaleFactor();
return ((rect.toFloat() - (display->totalArea.getTopLeft().toFloat() * globalScale)) * (display->scale / globalScale))
+ display->topLeftPhysical.toFloat();
}
template <typename ValueType>
Point<ValueType> Displays::physicalToLogical (Point<ValueType> point, const Display* useScaleFactorOfDisplay) const noexcept
{
const auto* display = useScaleFactorOfDisplay != nullptr ? useScaleFactorOfDisplay
: getDisplayForPoint (point.roundToInt(), true);
if (display == nullptr)
return point;
auto globalScale = Desktop::getInstance().getGlobalScaleFactor();
Point<ValueType> logicalTopLeft (static_cast<ValueType> (display->totalArea.getX()), static_cast<ValueType> (display->totalArea.getY()));
Point<ValueType> physicalTopLeft (static_cast<ValueType> (display->topLeftPhysical.getX()), static_cast<ValueType> (display->topLeftPhysical.getY()));
return ((point - physicalTopLeft) / (display->scale / globalScale)) + (logicalTopLeft * globalScale);
}
template <typename ValueType>
Point<ValueType> Displays::logicalToPhysical (Point<ValueType> point, const Display* useScaleFactorOfDisplay) const noexcept
{
const auto* display = useScaleFactorOfDisplay != nullptr ? useScaleFactorOfDisplay
: getDisplayForPoint (point.roundToInt(), false);
if (display == nullptr)
return point;
auto globalScale = Desktop::getInstance().getGlobalScaleFactor();
Point<ValueType> logicalTopLeft (static_cast<ValueType> (display->totalArea.getX()), static_cast<ValueType> (display->totalArea.getY()));
Point<ValueType> physicalTopLeft (static_cast<ValueType> (display->topLeftPhysical.getX()), static_cast<ValueType> (display->topLeftPhysical.getY()));
return ((point - (logicalTopLeft * globalScale)) * (display->scale / globalScale)) + physicalTopLeft;
}
const Displays::Display* Displays::getPrimaryDisplay() const noexcept
{
JUCE_ASSERT_MESSAGE_MANAGER_IS_LOCKED
for (auto& d : displays)
if (d.isMain)
return &d;
return nullptr;
}
RectangleList<int> Displays::getRectangleList (bool userAreasOnly) const
{
JUCE_ASSERT_MESSAGE_MANAGER_IS_LOCKED
RectangleList<int> rl;
for (auto& d : displays)
rl.addWithoutMerging (userAreasOnly ? d.userArea : d.totalArea);
return rl;
}
Rectangle<int> Displays::getTotalBounds (bool userAreasOnly) const
{
return getRectangleList (userAreasOnly).getBounds();
}
void Displays::refresh()
{
Array<Display> oldDisplays;
oldDisplays.swapWith (displays);
init (Desktop::getInstance());
if (oldDisplays != displays)
{
for (auto i = ComponentPeer::getNumPeers(); --i >= 0;)
if (auto* peer = ComponentPeer::getPeer (i))
peer->handleScreenSizeChange();
}
}
bool operator== (const Displays::Display& d1, const Displays::Display& d2) noexcept;
bool operator== (const Displays::Display& d1, const Displays::Display& d2) noexcept
{
return d1.isMain == d2.isMain
&& d1.totalArea == d2.totalArea
&& d1.userArea == d2.userArea
&& d1.topLeftPhysical == d2.topLeftPhysical
&& d1.scale == d2.scale
&& d1.dpi == d2.dpi;
}
bool operator!= (const Displays::Display& d1, const Displays::Display& d2) noexcept;
bool operator!= (const Displays::Display& d1, const Displays::Display& d2) noexcept { return ! (d1 == d2); }
//==============================================================================
// These methods are used for converting the totalArea and userArea Rectangles in Display from physical to logical
// pixels. We do this by constructing a graph of connected displays where the root node has position (0, 0); this can be
// safely converted to logical pixels using its scale factor and we can then traverse the graph and work out the logical pixels
// for all the other connected displays. We need to do this as the logical bounds of a display depend not only on its scale
// factor but also the scale factor of the displays connected to it.
/**
Represents a node in our graph of displays.
*/
struct DisplayNode
{
/** The Display object that this represents. */
Displays::Display* display;
/** True if this represents the 'root' display with position (0, 0). */
bool isRoot = false;
/** The parent node of this node in our display graph. This will have a correct logicalArea. */
DisplayNode* parent = nullptr;
/** The logical area to be calculated. This will be valid after processDisplay() has
been called on this node.
*/
Rectangle<double> logicalArea;
};
/** Recursive - will calculate and set the logicalArea member of current. */
static void processDisplay (DisplayNode* currentNode, Array<DisplayNode>& allNodes)
{
const auto physicalArea = currentNode->display->totalArea.toDouble();
const auto scale = currentNode->display->scale;
if (! currentNode->isRoot)
{
const auto logicalWidth = physicalArea.getWidth() / scale;
const auto logicalHeight = physicalArea.getHeight() / scale;
const auto physicalParentArea = currentNode->parent->display->totalArea.toDouble();
const auto logicalParentArea = currentNode->parent->logicalArea; // logical area of parent has already been calculated
const auto parentScale = currentNode->parent->display->scale;
Rectangle<double> logicalArea (0.0, 0.0, logicalWidth, logicalHeight);
if (physicalArea.getRight() == physicalParentArea.getX()) logicalArea.setPosition ({ logicalParentArea.getX() - logicalWidth, physicalArea.getY() / parentScale }); // on left
else if (physicalArea.getX() == physicalParentArea.getRight()) logicalArea.setPosition ({ logicalParentArea.getRight(), physicalArea.getY() / parentScale }); // on right
else if (physicalArea.getBottom() == physicalParentArea.getY()) logicalArea.setPosition ({ physicalArea.getX() / parentScale, logicalParentArea.getY() - logicalHeight }); // on top
else if (physicalArea.getY() == physicalParentArea.getBottom()) logicalArea.setPosition ({ physicalArea.getX() / parentScale, logicalParentArea.getBottom() }); // on bottom
else jassertfalse;
currentNode->logicalArea = logicalArea;
}
else
{
// If currentNode is the root (position (0, 0)) then we can just scale the physical area
currentNode->logicalArea = physicalArea / scale;
currentNode->parent = currentNode;
}
// Find child nodes
Array<DisplayNode*> children;
for (auto& node : allNodes)
{
// Already calculated
if (node.parent != nullptr)
continue;
const auto otherPhysicalArea = node.display->totalArea.toDouble();
// If the displays are touching on any side
if (otherPhysicalArea.getX() == physicalArea.getRight() || otherPhysicalArea.getRight() == physicalArea.getX()
|| otherPhysicalArea.getY() == physicalArea.getBottom() || otherPhysicalArea.getBottom() == physicalArea.getY())
{
node.parent = currentNode;
children.add (&node);
}
}
// Recursively process all child nodes
for (auto child : children)
processDisplay (child, allNodes);
}
/** This is called when the displays Array has been filled out with the info for all connected displays and the
totalArea and userArea Rectangles need to be converted from physical to logical coordinates.
*/
void Displays::updateToLogical()
{
if (displays.size() == 1)
{
auto& display = displays.getReference (0);
display.totalArea = (display.totalArea.toDouble() / display.scale).toNearestInt();
display.userArea = (display.userArea.toDouble() / display.scale).toNearestInt();
return;
}
Array<DisplayNode> displayNodes;
for (auto& d : displays)
{
DisplayNode node;
node.display = &d;
if (d.totalArea.getTopLeft() == Point<int>())
node.isRoot = true;
displayNodes.add (node);
}
auto* root = [&displayNodes]() -> DisplayNode*
{
for (auto& node : displayNodes)
if (node.isRoot)
return &node;
auto minDistance = std::numeric_limits<int>::max();
DisplayNode* retVal = nullptr;
for (auto& node : displayNodes)
{
auto distance = node.display->totalArea.getTopLeft().getDistanceFrom ({});
if (distance < minDistance)
{
minDistance = distance;
retVal = &node;
}
}
if (retVal != nullptr)
retVal->isRoot = true;
return retVal;
}();
// Must have a root node!
jassert (root != nullptr);
// Recursively traverse the display graph from the root and work out logical bounds
processDisplay (root, displayNodes);
for (auto& node : displayNodes)
{
// All of the nodes should have a parent
jassert (node.parent != nullptr);
auto relativeUserArea = (node.display->userArea.toDouble() - node.display->totalArea.toDouble().getTopLeft()) / node.display->scale;
// Now set Display::totalArea and ::userArea using the logical area that we have calculated
node.display->topLeftPhysical = node.display->totalArea.getTopLeft();
node.display->totalArea = node.logicalArea.toNearestInt();
node.display->userArea = (relativeUserArea + node.logicalArea.getTopLeft()).toNearestInt();
}
}
#ifndef DOXYGEN
// explicit template instantiations
template Point<int> Displays::physicalToLogical (Point<int>, const Display*) const noexcept;
template Point<float> Displays::physicalToLogical (Point<float>, const Display*) const noexcept;
template Point<int> Displays::logicalToPhysical (Point<int>, const Display*) const noexcept;
template Point<float> Displays::logicalToPhysical (Point<float>, const Display*) const noexcept;
#endif
//==============================================================================
// Deprecated methods
const Displays::Display& Displays::getDisplayContaining (Point<int> position) const noexcept
{
JUCE_ASSERT_MESSAGE_MANAGER_IS_LOCKED
const auto* best = &displays.getReference (0);
auto bestDistance = std::numeric_limits<int>::max();
for (auto& d : displays)
{
if (d.totalArea.contains (position))
{
best = &d;
break;
}
auto distance = d.totalArea.getCentre().getDistanceFrom (position);
if (distance < bestDistance)
{
bestDistance = distance;
best = &d;
}
}
return *best;
}
const Displays::Display& Displays::findDisplayForRect (Rectangle<int> rect, bool isPhysical) const noexcept
{
if (auto* display = getDisplayForRect (rect, isPhysical))
return *display;
return emptyDisplay;
}
const Displays::Display& Displays::findDisplayForPoint (Point<int> point, bool isPhysical) const noexcept
{
if (auto* display = getDisplayForPoint (point, isPhysical))
return *display;
return emptyDisplay;
}
const Displays::Display& Displays::getMainDisplay() const noexcept
{
if (auto* display = getPrimaryDisplay())
return *display;
return emptyDisplay;
}
} // namespace juce