Pane.cpp

// Copyright (c) Microsoft Corporation.
// Licensed under the MIT license.

#include "pch.h"
#include "Pane.h"
#include "Profile.h"
#include "CascadiaSettings.h"

using namespace winrt::Windows::Foundation;
using namespace winrt::Windows::UI;
using namespace winrt::Windows::UI::Xaml;
using namespace winrt::Windows::UI::Core;
using namespace winrt::Windows::UI::Xaml::Media;
using namespace winrt::Microsoft::Terminal::Settings;
using namespace winrt::Microsoft::Terminal::TerminalControl;
using namespace winrt::Microsoft::Terminal::TerminalConnection;
using namespace winrt::TerminalApp;
using namespace TerminalApp;

static const int PaneBorderSize = 2;
static const int CombinedPaneBorderSize = 2 * PaneBorderSize;
static const float Half = 0.50f;

winrt::Windows::UI::Xaml::Media::SolidColorBrush Pane::s_focusedBorderBrush = { nullptr };
winrt::Windows::UI::Xaml::Media::SolidColorBrush Pane::s_unfocusedBorderBrush = { nullptr };

Pane::Pane(const GUID& profile, const TermControl& control, const bool lastFocused) :
    _control{ control },
    _lastActive{ lastFocused },
    _profile{ profile }
{
    _root.Children().Append(_border);
    _border.Child(_control);

    _connectionStateChangedToken = _control.ConnectionStateChanged({ this, &Pane::_ControlConnectionStateChangedHandler });

    // On the first Pane's creation, lookup resources we'll use to theme the
    // Pane, including the brushed to use for the focused/unfocused border
    // color.
    if (s_focusedBorderBrush == nullptr || s_unfocusedBorderBrush == nullptr)
    {
        _SetupResources();
    }

    // Register an event with the control to have it inform us when it gains focus.
    _gotFocusRevoker = control.GotFocus(winrt::auto_revoke, { this, &Pane::_ControlGotFocusHandler });

    // When our border is tapped, make sure to transfer focus to our control.
    // LOAD-BEARING: This will NOT work if the border's BorderBrush is set to
    // Colors::Transparent! The border won't get Tapped events, and they'll fall
    // through to something else.
    _border.Tapped([this](auto&, auto& e) {
        _FocusFirstChild();
        e.Handled(true);
    });
}

// Method Description:
// - Update the size of this pane. Resizes each of our columns so they have the
//   same relative sizes, given the newSize.
// - Because we're just manually setting the row/column sizes in pixels, we have
//   to be told our new size, we can't just use our own OnSized event, because
//   that _won't fire when we get smaller_.
// Arguments:
// - newSize: the amount of space that this pane has to fill now.
// Return Value:
// - <none>
void Pane::ResizeContent(const Size& newSize)
{
    const auto width = newSize.Width;
    const auto height = newSize.Height;

    _CreateRowColDefinitions(newSize);

    if (_splitState == SplitState::Vertical)
    {
        const auto paneSizes = _CalcChildrenSizes(width);

        const Size firstSize{ paneSizes.first, height };
        const Size secondSize{ paneSizes.second, height };
        _firstChild->ResizeContent(firstSize);
        _secondChild->ResizeContent(secondSize);
    }
    else if (_splitState == SplitState::Horizontal)
    {
        const auto paneSizes = _CalcChildrenSizes(height);

        const Size firstSize{ width, paneSizes.first };
        const Size secondSize{ width, paneSizes.second };
        _firstChild->ResizeContent(firstSize);
        _secondChild->ResizeContent(secondSize);
    }
}

// Method Description:
// - Recalculates and reapplies sizes of all descendant panes.
// Arguments:
// - <none>
// Return Value:
// - <none>
void Pane::Relayout()
{
    ResizeContent(_root.ActualSize());
}

// Method Description:
// - Adjust our child percentages to increase the size of one of our children
//   and decrease the size of the other.
// - Adjusts the separation amount by 5%
// - Does nothing if the direction doesn't match our current split direction
// Arguments:
// - direction: the direction to move our separator. If it's down or right,
//   we'll be increasing the size of the first of our children. Else, we'll be
//   decreasing the size of our first child.
// Return Value:
// - false if we couldn't resize this pane in the given direction, else true.
bool Pane::_Resize(const Direction& direction)
{
    if (!DirectionMatchesSplit(direction, _splitState))
    {
        return false;
    }

    float amount = .05f;
    if (direction == Direction::Right || direction == Direction::Down)
    {
        amount = -amount;
    }

    // Make sure we're not making a pane explode here by resizing it to 0 characters.
    const bool changeWidth = _splitState == SplitState::Vertical;

    const Size actualSize{ gsl::narrow_cast<float>(_root.ActualWidth()),
                           gsl::narrow_cast<float>(_root.ActualHeight()) };
    // actualDimension is the size in DIPs of this pane in the direction we're
    // resizing.
    const auto actualDimension = changeWidth ? actualSize.Width : actualSize.Height;

    _desiredSplitPosition = _ClampSplitPosition(changeWidth, _desiredSplitPosition - amount, actualDimension);

    // Resize our columns to match the new percentages.
    ResizeContent(actualSize);

    return true;
}

// Method Description:
// - Moves the separator between panes, as to resize each child on either size
//   of the separator. Tries to move a separator in the given direction. The
//   separator moved is the separator that's closest depth-wise to the
//   currently focused pane, that's also in the correct direction to be moved.
//   If there isn't such a separator, then this method returns false, as we
//   couldn't handle the resize.
// Arguments:
// - direction: The direction to move the separator in.
// Return Value:
// - true if we or a child handled this resize request.
bool Pane::ResizePane(const Direction& direction)
{
    // If we're a leaf, do nothing. We can't possibly have a descendant with a
    // separator the correct direction.
    if (_IsLeaf())
    {
        return false;
    }

    // Check if either our first or second child is the currently focused leaf.
    // If it is, and the requested resize direction matches our separator, then
    // we're the pane that needs to adjust its separator.
    // If our separator is the wrong direction, then we can't handle it.
    const bool firstIsFocused = _firstChild->_IsLeaf() && _firstChild->_lastActive;
    const bool secondIsFocused = _secondChild->_IsLeaf() && _secondChild->_lastActive;
    if (firstIsFocused || secondIsFocused)
    {
        return _Resize(direction);
    }

    // If neither of our children were the focused leaf, then recurse into
    // our children and see if they can handle the resize.
    // For each child, if it has a focused descendant, try having that child
    // handle the resize.
    // If the child wasn't able to handle the resize, it's possible that
    // there were no descendants with a separator the correct direction. If
    // our separator _is_ the correct direction, then we should be the pane
    // to resize. Otherwise, just return false, as we couldn't handle it
    // either.
    if ((!_firstChild->_IsLeaf()) && _firstChild->_HasFocusedChild())
    {
        return _firstChild->ResizePane(direction) || _Resize(direction);
    }

    if ((!_secondChild->_IsLeaf()) && _secondChild->_HasFocusedChild())
    {
        return _secondChild->ResizePane(direction) || _Resize(direction);
    }

    return false;
}

// Method Description:
// - Attempts to handle moving focus to one of our children. If our split
//   direction isn't appropriate for the move direction, then we'll return
//   false, to try and let our parent handle the move. If our child we'd move
//   focus to is already focused, we'll also return false, to again let our
//   parent try and handle the focus movement.
// Arguments:
// - direction: The direction to move the focus in.
// Return Value:
// - true if we handled this focus move request.
bool Pane::_NavigateFocus(const Direction& direction)
{
    if (!DirectionMatchesSplit(direction, _splitState))
    {
        return false;
    }

    const bool focusSecond = (direction == Direction::Right) || (direction == Direction::Down);

    const auto newlyFocusedChild = focusSecond ? _secondChild : _firstChild;

    // If the child we want to move focus to is _already_ focused, return false,
    // to try and let our parent figure it out.
    if (newlyFocusedChild->_HasFocusedChild())
    {
        return false;
    }

    // Transfer focus to our child, and update the focus of our tree.
    newlyFocusedChild->_FocusFirstChild();
    UpdateVisuals();

    return true;
}

// Method Description:
// - Attempts to move focus to one of our children. If we have a focused child,
//   we'll try to move the focus in the direction requested.
//   - If there isn't a pane that exists as a child of this pane in the correct
//     direction, we'll return false. This will indicate to our parent that they
//     should try and move the focus themselves. In this way, the focus can move
//     up and down the tree to the correct pane.
// - This method is _very_ similar to ResizePane. Both are trying to find the
//   right separator to move (focus) in a direction.
// Arguments:
// - direction: The direction to move the focus in.
// Return Value:
// - true if we or a child handled this focus move request.
bool Pane::NavigateFocus(const Direction& direction)
{
    // If we're a leaf, do nothing. We can't possibly have a descendant with a
    // separator the correct direction.
    if (_IsLeaf())
    {
        return false;
    }

    // Check if either our first or second child is the currently focused leaf.
    // If it is, and the requested move direction matches our separator, then
    // we're the pane that needs to handle this focus move.
    const bool firstIsFocused = _firstChild->_IsLeaf() && _firstChild->_lastActive;
    const bool secondIsFocused = _secondChild->_IsLeaf() && _secondChild->_lastActive;
    if (firstIsFocused || secondIsFocused)
    {
        return _NavigateFocus(direction);
    }

    // If neither of our children were the focused leaf, then recurse into
    // our children and see if they can handle the focus move.
    // For each child, if it has a focused descendant, try having that child
    // handle the focus move.
    // If the child wasn't able to handle the focus move, it's possible that
    // there were no descendants with a separator the correct direction. If
    // our separator _is_ the correct direction, then we should be the pane
    // to move focus into our other child. Otherwise, just return false, as
    // we couldn't handle it either.
    if ((!_firstChild->_IsLeaf()) && _firstChild->_HasFocusedChild())
    {
        return _firstChild->NavigateFocus(direction) || _NavigateFocus(direction);
    }

    if ((!_secondChild->_IsLeaf()) && _secondChild->_HasFocusedChild())
    {
        return _secondChild->NavigateFocus(direction) || _NavigateFocus(direction);
    }

    return false;
}

// Method Description:
// - Called when our attached control is closed. Triggers listeners to our close
//   event, if we're a leaf pane.
// - If this was called, and we became a parent pane (due to work on another
//   thread), this function will do nothing (allowing the control's new parent
//   to handle the event instead).
// Arguments:
// - <none>
// Return Value:
// - <none>
void Pane::_ControlConnectionStateChangedHandler(const TermControl& /*sender*/, const winrt::Windows::Foundation::IInspectable& /*args*/)
{
    std::unique_lock lock{ _createCloseLock };
    // It's possible that this event handler started being executed, then before
    // we got the lock, another thread created another child. So our control is
    // actually no longer _our_ control, and instead could be a descendant.
    //
    // When the control's new Pane takes ownership of the control, the new
    // parent will register it's own event handler. That event handler will get
    // fired after this handler returns, and will properly cleanup state.
    if (!_IsLeaf())
    {
        return;
    }

    const auto newConnectionState = _control.ConnectionState();

    if (newConnectionState < ConnectionState::Closed)
    {
        // Pane doesn't care if the connection isn't entering a terminal state.
        return;
    }

    const auto& settings = CascadiaSettings::GetCurrentAppSettings();
    auto paneProfile = settings.FindProfile(_profile.value());
    if (paneProfile)
    {
        auto mode = paneProfile->GetCloseOnExitMode();
        if ((mode == CloseOnExitMode::Always) ||
            (mode == CloseOnExitMode::Graceful && newConnectionState == ConnectionState::Closed))
        {
            _ClosedHandlers(nullptr, nullptr);
        }
    }
}

// Event Description:
// - Called when our control gains focus. We'll use this to trigger our GotFocus
//   callback. The tab that's hosting us should have registered a callback which
//   can be used to mark us as active.
// Arguments:
// - <unused>
// Return Value:
// - <none>
void Pane::_ControlGotFocusHandler(winrt::Windows::Foundation::IInspectable const& /* sender */,
                                   RoutedEventArgs const& /* args */)
{
    _GotFocusHandlers(shared_from_this());
}

// Method Description:
// - Fire our Closed event to tell our parent that we should be removed.
// Arguments:
// - <none>
// Return Value:
// - <none>
void Pane::Close()
{
    // Fire our Closed event to tell our parent that we should be removed.
    _ClosedHandlers(nullptr, nullptr);
}

// Method Description:
// - Prepare this pane to be removed from the UI hierarchy by closing all controls
//   and connections beneath it.
void Pane::Shutdown()
{
    // Lock the create/close lock so that another operation won't concurrently
    // modify our tree
    std::unique_lock lock{ _createCloseLock };
    if (_IsLeaf())
    {
        _control.Close();
    }
    else
    {
        _firstChild->Shutdown();
        _secondChild->Shutdown();
    }
}

// Method Description:
// - Get the root UIElement of this pane. There may be a single TermControl as a
//   child, or an entire tree of grids and panes as children of this element.
// Arguments:
// - <none>
// Return Value:
// - the Grid acting as the root of this pane.
Controls::Grid Pane::GetRootElement()
{
    return _root;
}

// Method Description:
// - If this is the last focused pane, returns itself. Returns nullptr if this
//   is a leaf and it's not focused. If it's a parent, it returns nullptr if no
//   children of this pane were the last pane to be focused, or the Pane that
//   _was_ the last pane to be focused (if there was one).
// - This Pane's control might not currently be focused, if the tab itself is
//   not currently focused.
// Return Value:
// - nullptr if we're a leaf and unfocused, or no children were marked
//   `_lastActive`, else returns this
std::shared_ptr<Pane> Pane::GetActivePane()
{
    if (_IsLeaf())
    {
        return _lastActive ? shared_from_this() : nullptr;
    }

    auto firstFocused = _firstChild->GetActivePane();
    if (firstFocused != nullptr)
    {
        return firstFocused;
    }
    return _secondChild->GetActivePane();
}

// Method Description:
// - Gets the TermControl of this pane. If this Pane is not a leaf, this will return nullptr.
// Arguments:
// - <none>
// Return Value:
// - nullptr if this Pane is a parent, otherwise the TermControl of this Pane.
TermControl Pane::GetTerminalControl()
{
    return _IsLeaf() ? _control : nullptr;
}

// Method Description:
// - Recursively remove the "Active" state from this Pane and all it's children.
// - Updates our visuals to match our new state, including highlighting our borders.
// Arguments:
// - <none>
// Return Value:
// - <none>
void Pane::ClearActive()
{
    _lastActive = false;
    if (!_IsLeaf())
    {
        _firstChild->ClearActive();
        _secondChild->ClearActive();
    }
    UpdateVisuals();
}

// Method Description:
// - Sets the "Active" state on this Pane. Only one Pane in a tree of Panes
//   should be "active", and that pane should be a leaf.
// - Updates our visuals to match our new state, including highlighting our borders.
// Arguments:
// - <none>
// Return Value:
// - <none>
void Pane::SetActive()
{
    _lastActive = true;
    UpdateVisuals();
}

// Method Description:
// - Returns nullopt if no children of this pane were the last control to be
//   focused, or the GUID of the profile of the last control to be focused (if
//   there was one).
// Arguments:
// - <none>
// Return Value:
// - nullopt if no children of this pane were the last control to be
//   focused, else the GUID of the profile of the last control to be focused
std::optional<GUID> Pane::GetFocusedProfile()
{
    auto lastFocused = GetActivePane();
    return lastFocused ? lastFocused->_profile : std::nullopt;
}

// Method Description:
// - Returns true if this pane was the last pane to be focused in a tree of panes.
// Arguments:
// - <none>
// Return Value:
// - true iff we were the last pane focused in this tree of panes.
bool Pane::WasLastFocused() const noexcept
{
    return _lastActive;
}

// Method Description:
// - Returns true iff this pane has no child panes.
// Arguments:
// - <none>
// Return Value:
// - true iff this pane has no child panes.
bool Pane::_IsLeaf() const noexcept
{
    return _splitState == SplitState::None;
}

// Method Description:
// - Returns true if this pane is currently focused, or there is a pane which is
//   a child of this pane that is actively focused
// Arguments:
// - <none>
// Return Value:
// - true if the currently focused pane is either this pane, or one of this
//   pane's descendants
bool Pane::_HasFocusedChild() const noexcept
{
    // We're intentionally making this one giant expression, so the compiler
    // will skip the following lookups if one of the lookups before it returns
    // true
    return (_control && _lastActive) ||
           (_firstChild && _firstChild->_HasFocusedChild()) ||
           (_secondChild && _secondChild->_HasFocusedChild());
}

// Method Description:
// - Update the focus state of this pane. We'll make sure to colorize our
//   borders depending on if we are the active pane or not.
// Arguments:
// - <none>
// Return Value:
// - <none>
void Pane::UpdateVisuals()
{
    _border.BorderBrush(_lastActive ? s_focusedBorderBrush : s_unfocusedBorderBrush);
}

// Method Description:
// - Focuses this control if we're a leaf, or attempts to focus the first leaf
//   of our first child, recursively.
// Arguments:
// - <none>
// Return Value:
// - <none>
void Pane::_FocusFirstChild()
{
    if (_IsLeaf())
    {
        _control.Focus(FocusState::Programmatic);
    }
    else
    {
        _firstChild->_FocusFirstChild();
    }
}

// Method Description:
// - Attempts to update the settings of this pane or any children of this pane.
//   * If this pane is a leaf, and our profile guid matches the parameter, then
//     we'll apply the new settings to our control.
//   * If we're not a leaf, we'll recurse on our children.
// Arguments:
// - settings: The new TerminalSettings to apply to any matching controls
// - profile: The GUID of the profile these settings should apply to.
// Return Value:
// - <none>
void Pane::UpdateSettings(const TerminalSettings& settings, const GUID& profile)
{
    if (!_IsLeaf())
    {
        _firstChild->UpdateSettings(settings, profile);
        _secondChild->UpdateSettings(settings, profile);
    }
    else
    {
        if (profile == _profile)
        {
            _control.UpdateSettings(settings);
        }
    }
}

// Method Description:
// - Closes one of our children. In doing so, takes the control from the other
//   child, and makes this pane a leaf node again.
// Arguments:
// - closeFirst: if true, the first child should be closed, and the second
//   should be preserved, and vice-versa for false.
// Return Value:
// - <none>
void Pane::_CloseChild(const bool closeFirst)
{
    // Lock the create/close lock so that another operation won't concurrently
    // modify our tree
    std::unique_lock lock{ _createCloseLock };

    // If we're a leaf, then chances are both our children closed in close
    // succession. We waited on the lock while the other child was closed, so
    // now we don't have a child to close anymore. Return here. When we moved
    // the non-closed child into us, we also set up event handlers that will be
    // triggered when we return from this.
    if (_IsLeaf())
    {
        return;
    }

    auto closedChild = closeFirst ? _firstChild : _secondChild;
    auto remainingChild = closeFirst ? _secondChild : _firstChild;

    // If the only child left is a leaf, that means we're a leaf now.
    if (remainingChild->_IsLeaf())
    {
        // When the remaining child is a leaf, that means both our children were
        // previously leaves, and the only difference in their borders is the
        // border that we gave them. Take a bitwise AND of those two children to
        // remove that border. Other borders the children might have, they
        // inherited from us, so the flag will be set for both children.
        _borders = _firstChild->_borders & _secondChild->_borders;

        // take the control and profile of the pane that _wasn't_ closed.
        _control = remainingChild->_control;
        _profile = remainingChild->_profile;

        // Add our new event handler before revoking the old one.
        _connectionStateChangedToken = _control.ConnectionStateChanged({ this, &Pane::_ControlConnectionStateChangedHandler });

        // Revoke the old event handlers. Remove both the handlers for the panes
        // themselves closing, and remove their handlers for their controls
        // closing. At this point, if the remaining child's control is closed,
        // they'll trigger only our event handler for the control's close.
        _firstChild->Closed(_firstClosedToken);
        _secondChild->Closed(_secondClosedToken);
        closedChild->_control.ConnectionStateChanged(closedChild->_connectionStateChangedToken);
        remainingChild->_control.ConnectionStateChanged(remainingChild->_connectionStateChangedToken);

        // If either of our children was focused, we want to take that focus from
        // them.
        _lastActive = _firstChild->_lastActive || _secondChild->_lastActive;

        // Remove all the ui elements of our children. This'll make sure we can
        // re-attach the TermControl to our Grid.
        _firstChild->_root.Children().Clear();
        _secondChild->_root.Children().Clear();
        _firstChild->_border.Child(nullptr);
        _secondChild->_border.Child(nullptr);

        // Reset our UI:
        _root.Children().Clear();
        _border.Child(nullptr);
        _root.ColumnDefinitions().Clear();
        _root.RowDefinitions().Clear();

        // Reattach the TermControl to our grid.
        _root.Children().Append(_border);
        _border.Child(_control);

        // Make sure to set our _splitState before focusing the control. If you
        // fail to do this, when the tab handles the GotFocus event and asks us
        // what our active control is, we won't technically be a "leaf", and
        // GetTerminalControl will return null.
        _splitState = SplitState::None;

        // re-attach our handler for the control's GotFocus event.
        _gotFocusRevoker = _control.GotFocus(winrt::auto_revoke, { this, &Pane::_ControlGotFocusHandler });

        // If we're inheriting the "last active" state from one of our children,
        // focus our control now. This should trigger our own GotFocus event.
        if (_lastActive)
        {
            _control.Focus(FocusState::Programmatic);
        }

        _UpdateBorders();

        // Release our children.
        _firstChild = nullptr;
        _secondChild = nullptr;
    }
    else
    {
        // Determine which border flag we gave to the child when we first split
        // it, so that we can take just that flag away from them.
        Borders clearBorderFlag = Borders::None;
        if (_splitState == SplitState::Horizontal)
        {
            clearBorderFlag = closeFirst ? Borders::Top : Borders::Bottom;
        }
        else if (_splitState == SplitState::Vertical)
        {
            clearBorderFlag = closeFirst ? Borders::Left : Borders::Right;
        }

        // First stash away references to the old panes and their tokens
        const auto oldFirstToken = _firstClosedToken;
        const auto oldSecondToken = _secondClosedToken;
        const auto oldFirst = _firstChild;
        const auto oldSecond = _secondChild;

        // Steal all the state from our child
        _splitState = remainingChild->_splitState;
        _firstChild = remainingChild->_firstChild;
        _secondChild = remainingChild->_secondChild;

        // Set up new close handlers on the children
        _SetupChildCloseHandlers();

        // Revoke the old event handlers on our new children
        _firstChild->Closed(remainingChild->_firstClosedToken);
        _secondChild->Closed(remainingChild->_secondClosedToken);

        // Revoke event handlers on old panes and controls
        oldFirst->Closed(oldFirstToken);
        oldSecond->Closed(oldSecondToken);
        closedChild->_control.ConnectionStateChanged(closedChild->_connectionStateChangedToken);

        // Reset our UI:
        _root.Children().Clear();
        _border.Child(nullptr);
        _root.ColumnDefinitions().Clear();
        _root.RowDefinitions().Clear();

        // Copy the old UI over to our grid.
        // Start by copying the row/column definitions. Iterate over the
        // rows/cols, and remove each one from the old grid, and attach it to
        // our grid instead.
        while (remainingChild->_root.ColumnDefinitions().Size() > 0)
        {
            auto col = remainingChild->_root.ColumnDefinitions().GetAt(0);
            remainingChild->_root.ColumnDefinitions().RemoveAt(0);
            _root.ColumnDefinitions().Append(col);
        }
        while (remainingChild->_root.RowDefinitions().Size() > 0)
        {
            auto row = remainingChild->_root.RowDefinitions().GetAt(0);
            remainingChild->_root.RowDefinitions().RemoveAt(0);
            _root.RowDefinitions().Append(row);
        }

        // Remove the child's UI elements from the child's grid, so we can
        // attach them to us instead.
        remainingChild->_root.Children().Clear();
        remainingChild->_border.Child(nullptr);

        _root.Children().Append(_firstChild->GetRootElement());
        _root.Children().Append(_secondChild->GetRootElement());

        // Take the flag away from the children that they inherited from their
        // parent, and update their borders to visually match
        WI_ClearAllFlags(_firstChild->_borders, clearBorderFlag);
        WI_ClearAllFlags(_secondChild->_borders, clearBorderFlag);
        _UpdateBorders();
        _firstChild->_UpdateBorders();
        _secondChild->_UpdateBorders();

        // If the closed child was focused, transfer the focus to it's first sibling.
        if (closedChild->_lastActive)
        {
            _FocusFirstChild();
        }

        // Release the pointers that the child was holding.
        remainingChild->_firstChild = nullptr;
        remainingChild->_secondChild = nullptr;
    }
}

winrt::fire_and_forget Pane::_CloseChildRoutine(const bool closeFirst)
{
    auto weakThis{ shared_from_this() };

    co_await winrt::resume_foreground(_root.Dispatcher());

    if (auto pane{ weakThis.get() })
    {
        _CloseChild(closeFirst);
    }
}

// Method Description:
// - Adds event handlers to our children to handle their close events.
// Arguments:
// - <none>
// Return Value:
// - <none>
void Pane::_SetupChildCloseHandlers()
{
    _firstClosedToken = _firstChild->Closed([this](auto&& /*s*/, auto&& /*e*/) {
        _CloseChildRoutine(true);
    });

    _secondClosedToken = _secondChild->Closed([this](auto&& /*s*/, auto&& /*e*/) {
        _CloseChildRoutine(false);
    });
}

// Method Description:
// - Sets up row/column definitions for this pane. There are three total
//   row/cols. The middle one is for the separator. The first and third are for
//   each of the child panes, and are given a size in pixels, based off the
//   available space, and the percent of the space they respectively consume,
//   which is stored in _desiredSplitPosition
// - Does nothing if our split state is currently set to SplitState::None
// Arguments:
// - rootSize: The dimensions in pixels that this pane (and its children should consume.)
// Return Value:
// - <none>
void Pane::_CreateRowColDefinitions(const Size& rootSize)
{
    if (_splitState == SplitState::Vertical)
    {
        _root.ColumnDefinitions().Clear();

        // Create two columns in this grid: one for each pane
        const auto paneSizes = _CalcChildrenSizes(rootSize.Width);

        auto firstColDef = Controls::ColumnDefinition();
        firstColDef.Width(GridLengthHelper::FromValueAndType(paneSizes.first, GridUnitType::Star));

        auto secondColDef = Controls::ColumnDefinition();
        secondColDef.Width(GridLengthHelper::FromValueAndType(paneSizes.second, GridUnitType::Star));

        _root.ColumnDefinitions().Append(firstColDef);
        _root.ColumnDefinitions().Append(secondColDef);
    }
    else if (_splitState == SplitState::Horizontal)
    {
        _root.RowDefinitions().Clear();

        // Create two rows in this grid: one for each pane
        const auto paneSizes = _CalcChildrenSizes(rootSize.Height);

        auto firstRowDef = Controls::RowDefinition();
        firstRowDef.Height(GridLengthHelper::FromValueAndType(paneSizes.first, GridUnitType::Star));

        auto secondRowDef = Controls::RowDefinition();
        secondRowDef.Height(GridLengthHelper::FromValueAndType(paneSizes.second, GridUnitType::Star));

        _root.RowDefinitions().Append(firstRowDef);
        _root.RowDefinitions().Append(secondRowDef);
    }
}

// Method Description:
// - Initializes our UI for a new split in this pane. Sets up row/column
//   definitions, and initializes the separator grid. Does nothing if our split
//   state is currently set to SplitState::None
// Arguments:
// - <none>
// Return Value:
// - <none>
void Pane::_CreateSplitContent()
{
    Size actualSize{ gsl::narrow_cast<float>(_root.ActualWidth()),
                     gsl::narrow_cast<float>(_root.ActualHeight()) };

    _CreateRowColDefinitions(actualSize);
}

// Method Description:
// - Sets the thickness of each side of our borders to match our _borders state.
// Arguments:
// - <none>
// Return Value:
// - <none>
void Pane::_UpdateBorders()
{
    double top = 0, bottom = 0, left = 0, right = 0;

    Thickness newBorders{ 0 };
    if (WI_IsFlagSet(_borders, Borders::Top))
    {
        top = PaneBorderSize;
    }
    if (WI_IsFlagSet(_borders, Borders::Bottom))
    {
        bottom = PaneBorderSize;
    }
    if (WI_IsFlagSet(_borders, Borders::Left))
    {
        left = PaneBorderSize;
    }
    if (WI_IsFlagSet(_borders, Borders::Right))
    {
        right = PaneBorderSize;
    }
    _border.BorderThickness(ThicknessHelper::FromLengths(left, top, right, bottom));
}

// Method Description:
// - Sets the row/column of our child UI elements, to match our current split type.
// Arguments:
// - <none>
// Return Value:
// - <none>
void Pane::_ApplySplitDefinitions()
{
    if (_splitState == SplitState::Vertical)
    {
        Controls::Grid::SetColumn(_firstChild->GetRootElement(), 0);
        Controls::Grid::SetColumn(_secondChild->GetRootElement(), 1);

        _firstChild->_borders = _borders | Borders::Right;
        _secondChild->_borders = _borders | Borders::Left;
        _borders = Borders::None;

        _UpdateBorders();
        _firstChild->_UpdateBorders();
        _secondChild->_UpdateBorders();
    }
    else if (_splitState == SplitState::Horizontal)
    {
        Controls::Grid::SetRow(_firstChild->GetRootElement(), 0);
        Controls::Grid::SetRow(_secondChild->GetRootElement(), 1);

        _firstChild->_borders = _borders | Borders::Bottom;
        _secondChild->_borders = _borders | Borders::Top;
        _borders = Borders::None;

        _UpdateBorders();
        _firstChild->_UpdateBorders();
        _secondChild->_UpdateBorders();
    }
}

// Method Description:
// - Determines whether the pane can be split
// Arguments:
// - splitType: what type of split we want to create.
// Return Value:
// - True if the pane can be split. False otherwise.
bool Pane::CanSplit(SplitState splitType)
{
    if (_IsLeaf())
    {
        return _CanSplit(splitType);
    }

    if (_firstChild->_HasFocusedChild())
    {
        return _firstChild->CanSplit(splitType);
    }

    if (_secondChild->_HasFocusedChild())
    {
        return _secondChild->CanSplit(splitType);
    }

    return false;
}

// Method Description:
// - Split the focused pane in our tree of panes, and place the given
//   TermControl into the newly created pane. If we're the focused pane, then
//   we'll create two new children, and place them side-by-side in our Grid.
// Arguments:
// - splitType: what type of split we want to create.
// - profile: The profile GUID to associate with the newly created pane.
// - control: A TermControl to use in the new pane.
// Return Value:
// - The two newly created Panes
std::pair<std::shared_ptr<Pane>, std::shared_ptr<Pane>> Pane::Split(SplitState splitType, const GUID& profile, const TermControl& control)
{
    if (!_IsLeaf())
    {
        if (_firstChild->_HasFocusedChild())
        {
            return _firstChild->Split(splitType, profile, control);
        }
        else if (_secondChild->_HasFocusedChild())
        {
            return _secondChild->Split(splitType, profile, control);
        }

        return { nullptr, nullptr };
    }

    return _Split(splitType, profile, control);
}

// Method Description:
// - Converts an "automatic" split type into either Vertical or Horizontal,
//   based upon the current dimensions of the Pane.
// - If any of the other SplitState values are passed in, they're returned
//   unmodified.
// Arguments:
// - splitType: The SplitState to attempt to convert
// Return Value:
// - None if splitType was None, otherwise one of Horizontal or Vertical
SplitState Pane::_convertAutomaticSplitState(const SplitState& splitType) const
{
    // Careful here! If the pane doesn't yet have a size, these dimensions will
    // be 0, and we'll always return Vertical.

    if (splitType == SplitState::Automatic)
    {
        // If the requested split type was "auto", determine which direction to
        // split based on our current dimensions
        const Size actualSize{ gsl::narrow_cast<float>(_root.ActualWidth()),
                               gsl::narrow_cast<float>(_root.ActualHeight()) };
        return actualSize.Width >= actualSize.Height ? SplitState::Vertical : SplitState::Horizontal;
    }
    return splitType;
}

// Method Description:
// - Determines whether the pane can be split.
// Arguments:
// - splitType: what type of split we want to create.
// Return Value:
// - True if the pane can be split. False otherwise.
bool Pane::_CanSplit(SplitState splitType)
{
    const Size actualSize{ gsl::narrow_cast<float>(_root.ActualWidth()),
                           gsl::narrow_cast<float>(_root.ActualHeight()) };

    const Size minSize = _GetMinSize();

    auto actualSplitType = _convertAutomaticSplitState(splitType);

    if (actualSplitType == SplitState::None)
    {
        return false;
    }

    if (actualSplitType == SplitState::Vertical)
    {
        const auto widthMinusSeparator = actualSize.Width - CombinedPaneBorderSize;
        const auto newWidth = widthMinusSeparator * Half;

        return newWidth > minSize.Width;
    }

    if (actualSplitType == SplitState::Horizontal)
    {
        const auto heightMinusSeparator = actualSize.Height - CombinedPaneBorderSize;
        const auto newHeight = heightMinusSeparator * Half;

        return newHeight > minSize.Height;
    }

    return false;
}

// Method Description:
// - Does the bulk of the work of creating a new split. Initializes our UI,
//   creates a new Pane to host the control, registers event handlers.
// Arguments:
// - splitType: what type of split we should create.
// - profile: The profile GUID to associate with the newly created pane.
// - control: A TermControl to use in the new pane.
// Return Value:
// - The two newly created Panes
std::pair<std::shared_ptr<Pane>, std::shared_ptr<Pane>> Pane::_Split(SplitState splitType, const GUID& profile, const TermControl& control)
{
    if (splitType == SplitState::None)
    {
        return { nullptr, nullptr };
    }

    auto actualSplitType = _convertAutomaticSplitState(splitType);

    // Lock the create/close lock so that another operation won't concurrently
    // modify our tree
    std::unique_lock lock{ _createCloseLock };

    // revoke our handler - the child will take care of the control now.
    _control.ConnectionStateChanged(_connectionStateChangedToken);
    _connectionStateChangedToken.value = 0;

    // Remove our old GotFocus handler from the control. We don't what the
    // control telling us that it's now focused, we want it telling its new
    // parent.
    _gotFocusRevoker.revoke();

    _splitState = actualSplitType;
    _desiredSplitPosition = Half;

    // Remove any children we currently have. We can't add the existing
    // TermControl to a new grid until we do this.
    _root.Children().Clear();
    _border.Child(nullptr);

    // Create two new Panes
    //   Move our control, guid into the first one.
    //   Move the new guid, control into the second.
    _firstChild = std::make_shared<Pane>(_profile.value(), _control);
    _profile = std::nullopt;
    _control = { nullptr };
    _secondChild = std::make_shared<Pane>(profile, control);

    _CreateSplitContent();

    _root.Children().Append(_firstChild->GetRootElement());
    _root.Children().Append(_secondChild->GetRootElement());

    _ApplySplitDefinitions();

    // Register event handlers on our children to handle their Close events
    _SetupChildCloseHandlers();

    _lastActive = false;

    return { _firstChild, _secondChild };
}

// Method Description:
// - Gets the size in pixels of each of our children, given the full size they
//   should fill. Since these children own their own separators (borders), this
//   size is their portion of our _entire_ size. If specified size is lower than
//   required then children will be of minimum size. Snaps first child to grid
//   but not the second.
// Arguments:
// - fullSize: the amount of space in pixels that should be filled by our
//   children and their separators. Can be arbitrarily low.
// Return Value:
// - a pair with the size of our first child and the size of our second child,
//   respectively.
std::pair<float, float> Pane::_CalcChildrenSizes(const float fullSize) const
{
    const auto widthOrHeight = _splitState == SplitState::Vertical;
    const auto snappedSizes = _CalcSnappedChildrenSizes(widthOrHeight, fullSize).lower;

    // Keep the first pane snapped and give the second pane all remaining size
    return {
        snappedSizes.first,
        fullSize - snappedSizes.first
    };
}

// Method Description:
// - Gets the size in pixels of each of our children, given the full size they should
//   fill. Each child is snapped to char grid as close as possible. If called multiple
//   times with fullSize argument growing, then both returned sizes are guaranteed to be
//   non-decreasing (it's a monotonically increasing function). This is important so that
//   user doesn't get any pane shrank when they actually expand the window or parent pane.
//   That is also required by the layout algorithm.
// Arguments:
// - widthOrHeight: if true, operates on width, otherwise on height.
// - fullSize: the amount of space in pixels that should be filled by our children and
//   their separator. Can be arbitrarily low.
// Return Value:
// - a structure holding the result of this calculation. The 'lower' field represents the
//   children sizes that would fit in the fullSize, but might (and usually do) not fill it
//   completely. The 'higher' field represents the size of the children if they slightly exceed
//   the fullSize, but are snapped. If the children can be snapped and also exactly match
//   the fullSize, then both this fields have the same value that represent this situation.
Pane::SnapChildrenSizeResult Pane::_CalcSnappedChildrenSizes(const bool widthOrHeight, const float fullSize) const
{
    if (_IsLeaf())
    {
        THROW_HR(E_FAIL);
    }

    //   First we build a tree of nodes corresponding to the tree of our descendant panes.
    // Each node represents a size of given pane. At the beginning, each node has the minimum
    // size that the corresponding pane can have; so has the our (root) node. We then gradually
    // expand our node (which in turn expands some of the child nodes) until we hit the desired
    // size. Since each expand step (done in _AdvanceSnappedDimension()) guarantees that all the
    // sizes will be snapped, our return values is also snapped.
    //   Why do we do it this, iterative way? Why can't we just split the given size by
    // _desiredSplitPosition and snap it latter? Because it's hardly doable, if possible, to also
    // fulfill the monotonicity requirement that way. As the fullSize increases, the proportional
    // point that separates children panes also moves and cells sneak in the available area in
    // unpredictable way, regardless which child has the snap priority or whether we snap them
    // upward, downward or to nearest.
    //   With present way we run the same sequence of actions regardless to the fullSize value and
    // only just stop at various moments when the built sizes reaches it.  Eventually, this could
    // be optimized for simple cases like when both children are both leaves with the same character
    // size, but it doesn't seem to be beneficial.

    auto sizeTree = _CreateMinSizeTree(widthOrHeight);
    LayoutSizeNode lastSizeTree{ sizeTree };

    while (sizeTree.size < fullSize)
    {
        lastSizeTree = sizeTree;
        _AdvanceSnappedDimension(widthOrHeight, sizeTree);

        if (sizeTree.size == fullSize)
        {
            // If we just hit exactly the requested value, then just return the
            // current state of children.
            return { { sizeTree.firstChild->size, sizeTree.secondChild->size },
                     { sizeTree.firstChild->size, sizeTree.secondChild->size } };
        }
    }

    // We exceeded the requested size in the loop above, so lastSizeTree will have
    // the last good sizes (so that children fit in) and sizeTree has the next possible
    // snapped sizes. Return them as lower and higher snap possibilities.
    return { { lastSizeTree.firstChild->size, lastSizeTree.secondChild->size },
             { sizeTree.firstChild->size, sizeTree.secondChild->size } };
}

// Method Description:
// - Adjusts given dimension (width or height) so that all descendant terminals
//   align with their character grids as close as possible. Snaps to closes match
//   (either upward or downward). Also makes sure to fit in minimal sizes of the panes.
// Arguments:
// - widthOrHeight: if true operates on width, otherwise on height
// - dimension: a dimension (width or height) to snap
// Return Value:
// - A value corresponding to the next closest snap size for this Pane, either upward or downward
float Pane::CalcSnappedDimension(const bool widthOrHeight, const float dimension) const
{
    const auto [lower, higher] = _CalcSnappedDimension(widthOrHeight, dimension);
    return dimension - lower < higher - dimension ? lower : higher;
}

// Method Description:
// - Adjusts given dimension (width or height) so that all descendant terminals
//   align with their character grids as close as possible. Also makes sure to
//   fit in minimal sizes of the panes.
// Arguments:
// - widthOrHeight: if true operates on width, otherwise on height
// - dimension: a dimension (width or height) to be snapped
// Return Value:
// - pair of floats, where first value is the size snapped downward (not greater then
//   requested size) and second is the size snapped upward (not lower than requested size).
//   If requested size is already snapped, then both returned values equal this value.
Pane::SnapSizeResult Pane::_CalcSnappedDimension(const bool widthOrHeight, const float dimension) const
{
    if (_IsLeaf())
    {
        // If we're a leaf pane, align to the grid of controlling terminal

        const auto minSize = _GetMinSize();
        const auto minDimension = widthOrHeight ? minSize.Width : minSize.Height;

        if (dimension <= minDimension)
        {
            return { minDimension, minDimension };
        }

        float lower = _control.SnapDimensionToGrid(widthOrHeight, dimension);
        if (widthOrHeight)
        {
            lower += WI_IsFlagSet(_borders, Borders::Left) ? PaneBorderSize : 0;
            lower += WI_IsFlagSet(_borders, Borders::Right) ? PaneBorderSize : 0;
        }
        else
        {
            lower += WI_IsFlagSet(_borders, Borders::Top) ? PaneBorderSize : 0;
            lower += WI_IsFlagSet(_borders, Borders::Bottom) ? PaneBorderSize : 0;
        }

        if (lower == dimension)
        {
            // If we happen to be already snapped, then just return this size
            // as both lower and higher values.
            return { lower, lower };
        }
        else
        {
            const auto cellSize = _control.CharacterDimensions();
            const auto higher = lower + (widthOrHeight ? cellSize.Width : cellSize.Height);
            return { lower, higher };
        }
    }
    else if (_splitState == (widthOrHeight ? SplitState::Horizontal : SplitState::Vertical))
    {
        // If we're resizing along separator axis, snap to the closest possibility
        // given by our children panes.

        const auto firstSnapped = _firstChild->_CalcSnappedDimension(widthOrHeight, dimension);
        const auto secondSnapped = _secondChild->_CalcSnappedDimension(widthOrHeight, dimension);
        return {
            std::max(firstSnapped.lower, secondSnapped.lower),
            std::min(firstSnapped.higher, secondSnapped.higher)
        };
    }
    else
    {
        // If we're resizing perpendicularly to separator axis, calculate the sizes
        // of child panes that would fit the given size. We use same algorithm that
        // is used for real resize routine, but exclude the remaining empty space that
        // would appear after the second pane. This will be the 'downward' snap possibility,
        // while the 'upward' will be given as a side product of the layout function.

        const auto childSizes = _CalcSnappedChildrenSizes(widthOrHeight, dimension);
        return {
            childSizes.lower.first + childSizes.lower.second,
            childSizes.higher.first + childSizes.higher.second
        };
    }
}

// Method Description:
// - Increases size of given LayoutSizeNode to match next possible 'snap'. In case of leaf
//   pane this means the next cell of the terminal. Otherwise it means that one of its children
//   advances (recursively). It expects the given node and its descendants to have either
//   already snapped or minimum size.
// Arguments:
// - widthOrHeight: if true operates on width, otherwise on height.
// - sizeNode: a layouting node that corresponds to this pane.
// Return Value:
// - <none>
void Pane::_AdvanceSnappedDimension(const bool widthOrHeight, LayoutSizeNode& sizeNode) const
{
    if (_IsLeaf())
    {
        // We're a leaf pane, so just add one more row or column (unless isMinimumSize
        // is true, see below).

        if (sizeNode.isMinimumSize)
        {
            // If the node is of its minimum size, this size might not be snapped (it might
            // be, say, half a character, or fixed 10 pixels), so snap it upward. It might
            // however be already snapped, so add 1 to make sure it really increases
            // (not strictly necessary but to avoid surprises).
            sizeNode.size = _CalcSnappedDimension(widthOrHeight, sizeNode.size + 1).higher;
        }
        else
        {
            const auto cellSize = _control.CharacterDimensions();
            sizeNode.size += widthOrHeight ? cellSize.Width : cellSize.Height;
        }
    }
    else
    {
        // We're a parent pane, so we have to advance dimension of our children panes. In
        // fact, we advance only one child (chosen later) to keep the growth fine-grained.

        // To choose which child pane to advance, we actually need to know their advanced sizes
        // in advance (oh), to see which one would 'fit' better. Often, this is already cached
        // by the previous invocation of this function in nextFirstChild and nextSecondChild
        // fields of given node. If not, we need to calculate them now.
        if (sizeNode.nextFirstChild == nullptr)
        {
            sizeNode.nextFirstChild = std::make_unique<LayoutSizeNode>(*sizeNode.firstChild);
            _firstChild->_AdvanceSnappedDimension(widthOrHeight, *sizeNode.nextFirstChild);
        }
        if (sizeNode.nextSecondChild == nullptr)
        {
            sizeNode.nextSecondChild = std::make_unique<LayoutSizeNode>(*sizeNode.secondChild);
            _secondChild->_AdvanceSnappedDimension(widthOrHeight, *sizeNode.nextSecondChild);
        }

        const auto nextFirstSize = sizeNode.nextFirstChild->size;
        const auto nextSecondSize = sizeNode.nextSecondChild->size;

        // Choose which child pane to advance.
        bool advanceFirstOrSecond;
        if (_splitState == (widthOrHeight ? SplitState::Horizontal : SplitState::Vertical))
        {
            // If we're growing along separator axis, choose the child that
            // wants to be smaller than the other, so that the resulting size
            // will be the smallest.
            advanceFirstOrSecond = nextFirstSize < nextSecondSize;
        }
        else
        {
            // If we're growing perpendicularly to separator axis, choose a
            // child so that their size ratio is closer to that we're trying
            // to maintain (this is, the relative separator position is closer
            // to the _desiredSplitPosition field).

            const auto firstSize = sizeNode.firstChild->size;
            const auto secondSize = sizeNode.secondChild->size;

            // Because we rely on equality check, these calculations have to be
            // immune to floating point errors. In common situation where both panes
            // have the same character sizes and _desiredSplitPosition is 0.5 (or
            // some simple fraction) both ratios will often be the same, and if so
            // we always take the left child. It could be right as well, but it's
            // important that it's consistent: that it would always go
            // 1 -> 2 -> 1 -> 2 -> 1 -> 2 and not like 1 -> 1 -> 2 -> 2 -> 2 -> 1
            // which would look silly to the user but which occur if there was
            // a non-floating-point-safe math.
            const auto deviation1 = nextFirstSize - (nextFirstSize + secondSize) * _desiredSplitPosition;
            const auto deviation2 = -1 * (firstSize - (firstSize + nextSecondSize) * _desiredSplitPosition);
            advanceFirstOrSecond = deviation1 <= deviation2;
        }

        // Here we advance one of our children. Because we already know the appropriate
        // (advanced) size that given child would need to have, we simply assign that size
        // to it. We then advance its 'next*' size (nextFirstChild or nextSecondChild) so
        // the invariant holds (as it will likely be used by the next invocation of this
        // function). The other child's next* size remains unchanged because its size
        // haven't changed either.
        if (advanceFirstOrSecond)
        {
            *sizeNode.firstChild = *sizeNode.nextFirstChild;
            _firstChild->_AdvanceSnappedDimension(widthOrHeight, *sizeNode.nextFirstChild);
        }
        else
        {
            *sizeNode.secondChild = *sizeNode.nextSecondChild;
            _secondChild->_AdvanceSnappedDimension(widthOrHeight, *sizeNode.nextSecondChild);
        }

        // Since the size of one of our children has changed we need to update our size as well.
        if (_splitState == (widthOrHeight ? SplitState::Horizontal : SplitState::Vertical))
        {
            sizeNode.size = std::max(sizeNode.firstChild->size, sizeNode.secondChild->size);
        }
        else
        {
            sizeNode.size = sizeNode.firstChild->size + sizeNode.secondChild->size;
        }
    }

    // Because we have grown, we're certainly no longer of our
    // minimal size (if we've ever been).
    sizeNode.isMinimumSize = false;
}

// Method Description:
// - Get the absolute minimum size that this pane can be resized to and still
//   have 1x1 character visible, in each of its children. If we're a leaf, we'll
//   include the space needed for borders _within_ us.
// Arguments:
// - <none>
// Return Value:
// - The minimum size that this pane can be resized to and still have a visible
//   character.
Size Pane::_GetMinSize() const
{
    if (_IsLeaf())
    {
        auto controlSize = _control.MinimumSize();
        auto newWidth = controlSize.Width;
        auto newHeight = controlSize.Height;

        newWidth += WI_IsFlagSet(_borders, Borders::Left) ? PaneBorderSize : 0;
        newWidth += WI_IsFlagSet(_borders, Borders::Right) ? PaneBorderSize : 0;
        newHeight += WI_IsFlagSet(_borders, Borders::Top) ? PaneBorderSize : 0;
        newHeight += WI_IsFlagSet(_borders, Borders::Bottom) ? PaneBorderSize : 0;

        return { newWidth, newHeight };
    }
    else
    {
        const auto firstSize = _firstChild->_GetMinSize();
        const auto secondSize = _secondChild->_GetMinSize();

        const auto minWidth = _splitState == SplitState::Vertical ?
                                  firstSize.Width + secondSize.Width :
                                  std::max(firstSize.Width, secondSize.Width);
        const auto minHeight = _splitState == SplitState::Horizontal ?
                                   firstSize.Height + secondSize.Height :
                                   std::max(firstSize.Height, secondSize.Height);

        return { minWidth, minHeight };
    }
}

// Method Description:
// - Builds a tree of LayoutSizeNode that matches the tree of panes. Each node
//   has minimum size that the corresponding pane can have.
// Arguments:
// - widthOrHeight: if true operates on width, otherwise on height
// Return Value:
// - Root node of built tree that matches this pane.
Pane::LayoutSizeNode Pane::_CreateMinSizeTree(const bool widthOrHeight) const
{
    const auto size = _GetMinSize();
    LayoutSizeNode node(widthOrHeight ? size.Width : size.Height);
    if (!_IsLeaf())
    {
        node.firstChild = std::make_unique<LayoutSizeNode>(_firstChild->_CreateMinSizeTree(widthOrHeight));
        node.secondChild = std::make_unique<LayoutSizeNode>(_secondChild->_CreateMinSizeTree(widthOrHeight));
    }

    return node;
}

// Method Description:
// - Adjusts split position so that no child pane is smaller then its
//   minimum size
// Arguments:
// - widthOrHeight: if true, operates on width, otherwise on height.
// - requestedValue: split position value to be clamped
// - totalSize: size (width or height) of the parent pane
// Return Value:
// - split position (value in range <0.0, 1.0>)
float Pane::_ClampSplitPosition(const bool widthOrHeight, const float requestedValue, const float totalSize) const
{
    const auto firstMinSize = _firstChild->_GetMinSize();
    const auto secondMinSize = _secondChild->_GetMinSize();

    const auto firstMinDimension = widthOrHeight ? firstMinSize.Width : firstMinSize.Height;
    const auto secondMinDimension = widthOrHeight ? secondMinSize.Width : secondMinSize.Height;

    const auto minSplitPosition = firstMinDimension / totalSize;
    const auto maxSplitPosition = 1.0f - (secondMinDimension / totalSize);

    return std::clamp(requestedValue, minSplitPosition, maxSplitPosition);
}

// Function Description:
// - Attempts to load some XAML resources that the Pane will need. This includes:
//   * The Color we'll use for active Panes's borders - SystemAccentColor
//   * The Brush we'll use for inactive Panes - TabViewBackground (to match the
//     color of the titlebar)
// Arguments:
// - <none>
// Return Value:
// - <none>
void Pane::_SetupResources()
{
    const auto res = Application::Current().Resources();
    const auto accentColorKey = winrt::box_value(L"SystemAccentColor");
    if (res.HasKey(accentColorKey))
    {
        const auto colorFromResources = res.Lookup(accentColorKey);
        // If SystemAccentColor is _not_ a Color for some reason, use
        // Transparent as the color, so we don't do this process again on
        // the next pane (by leaving s_focusedBorderBrush nullptr)
        auto actualColor = winrt::unbox_value_or<Color>(colorFromResources, Colors::Black());
        s_focusedBorderBrush = SolidColorBrush(actualColor);
    }
    else
    {
        // DON'T use Transparent here - if it's "Transparent", then it won't
        // be able to hittest for clicks, and then clicking on the border
        // will eat focus.
        s_focusedBorderBrush = SolidColorBrush{ Colors::Black() };
    }

    const auto tabViewBackgroundKey = winrt::box_value(L"TabViewBackground");
    if (res.HasKey(tabViewBackgroundKey))
    {
        winrt::Windows::Foundation::IInspectable obj = res.Lookup(tabViewBackgroundKey);
        s_unfocusedBorderBrush = obj.try_as<winrt::Windows::UI::Xaml::Media::SolidColorBrush>();
    }
    else
    {
        // DON'T use Transparent here - if it's "Transparent", then it won't
        // be able to hittest for clicks, and then clicking on the border
        // will eat focus.
        s_unfocusedBorderBrush = SolidColorBrush{ Colors::Black() };
    }
}

DEFINE_EVENT(Pane, GotFocus, _GotFocusHandlers, winrt::delegate<std::shared_ptr<Pane>>);