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build1/epsilon-master/poincare/src/layout/horizontal_layout.cpp 18 KB
6663b6c9   adorian   projet complet av...
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  #include "horizontal_layout.h"
  #include "empty_layout.h"
  extern "C" {
  #include <assert.h>
  #include <kandinsky.h>
  #include <stdlib.h>
  }
  
  namespace Poincare {
  
  ExpressionLayout * HorizontalLayout::clone() const {
    HorizontalLayout * layout = new HorizontalLayout(const_cast<ExpressionLayout **>(children()), numberOfChildren(), true);
    return layout;
  }
  
  void HorizontalLayout::deleteBeforeCursor(ExpressionLayoutCursor * cursor) {
    if (cursor->pointedExpressionLayout() == this
        && cursor->position() == ExpressionLayoutCursor::Position::Left
        && m_parent == nullptr)
    {
      // Case: Left and this is the main layout. Return.
      return;
    }
    if (cursor->pointedExpressionLayout() == this
        && cursor->position() == ExpressionLayoutCursor::Position::Right
        && m_parent == nullptr
        && numberOfChildren() == 0)
    {
      // Case: Right and this is the main layout with no children. Return.
      return;
    }
    if (cursor->position() == ExpressionLayoutCursor::Position::Left) {
      int indexOfPointedExpression = indexOfChild(cursor->pointedExpressionLayout());
      if (indexOfPointedExpression >= 0) {
        /* Case: Left of a child.
         * Point Right of the previous child. If there is no previous child, point
         * Left of this. Perform another backspace. */
        if (indexOfPointedExpression == 0) {
          cursor->setPointedExpressionLayout(this);
        } else if (indexOfPointedExpression > 0) {
          cursor->setPointedExpressionLayout(editableChild(indexOfPointedExpression - 1));
          cursor->setPosition(ExpressionLayoutCursor::Position::Right);
        }
        cursor->performBackspace();
        return;
      }
    }
    assert(cursor->pointedExpressionLayout() == this);
    if (cursor->position() == ExpressionLayoutCursor::Position::Right) {
      // Case: Right. Point to the last child and perform backspace.
      cursor->setPointedExpressionLayout(editableChild(numberOfChildren() - 1));
      cursor->performBackspace();
      return;
    }
    ExpressionLayout::deleteBeforeCursor(cursor);
  }
  
  void HorizontalLayout::replaceChild(const ExpressionLayout * oldChild, ExpressionLayout * newChild, bool deleteOldChild) {
    privateReplaceChild(oldChild, newChild, deleteOldChild, nullptr);
  }
  
  void HorizontalLayout::replaceChildAndMoveCursor(const ExpressionLayout * oldChild, ExpressionLayout * newChild, bool deleteOldChild, ExpressionLayoutCursor * cursor) {
    privateReplaceChild(oldChild, newChild, deleteOldChild, cursor);
  }
  
  void HorizontalLayout::privateReplaceChild(const ExpressionLayout * oldChild, ExpressionLayout * newChild, bool deleteOldChild, ExpressionLayoutCursor * cursor) {
    bool oldWasAncestorOfNewLayout = false;
    if (newChild->hasAncestor(this)) {
      newChild->editableParent()->detachChild(newChild);
      oldWasAncestorOfNewLayout = true;
    }
    int oldChildIndex = indexOfChild(oldChild);
    if (newChild->isEmpty()) {
      if (numberOfChildren() > 1) {
        /* If the new layout is empty and the horizontal layout has other
         * children, just delete the old child. */
        if (!newChild->hasAncestor(oldChild)) {
          delete newChild;
        }
        removeChildAtIndex(oldChildIndex, deleteOldChild);
        if (cursor == nullptr) {
          return;
        }
        if (oldChildIndex == 0) {
          cursor->setPointedExpressionLayout(this);
          cursor->setPosition(ExpressionLayoutCursor::Position::Left);
          return;
        }
        cursor->setPointedExpressionLayout(editableChild(oldChildIndex -1));
        cursor->setPosition(ExpressionLayoutCursor::Position::Right);
        return;
      }
      /* If the new layout is empty and it was the only horizontal layout child,
       * replace the horizontal layout with this empty layout (only if this is not
       * the main layout, so only if the layout has a parent). */
      if (m_parent) {
        if (!deleteOldChild) {
          removeChildAtIndex(indexOfChild(oldChild), false);
        }
        if (cursor) {
          replaceWithAndMoveCursor(newChild, true, cursor);
          return;
        }
        replaceWith(newChild, deleteOldChild);
        return;
      }
      /* If this is the main horizontal layout, the old child its only child and
       * the new child is Empty, remove the old child and delete the new child. */
      assert(m_parent == nullptr);
      removeChildAtIndex(0, deleteOldChild);
      delete newChild;
      if (cursor == nullptr) {
        return;
      }
      cursor->setPointedExpressionLayout(this);
      cursor->setPosition(ExpressionLayoutCursor::Position::Left);
      return;
    }
    /* If the new child is also an horizontal layout, steal the children of the
     * new layout then destroy it. */
    if (newChild->isHorizontal()) {
      int indexForInsertion = indexOfChild(oldChild);
      if (cursor != nullptr) {
        /* If the old layout is not an ancestor of the new layout, or if the
         * cursor was on the right of the new layout, place the cursor on the
         * right of the new layout, which is left of the next sibling or right of
         * the parent. */
        if (!oldWasAncestorOfNewLayout || cursor->position() == ExpressionLayoutCursor::Position::Right) {
          if (oldChildIndex == numberOfChildren() - 1) {
            cursor->setPointedExpressionLayout(this);
            cursor->setPosition(ExpressionLayoutCursor::Position::Right);
          } else {
            cursor->setPointedExpressionLayout(editableChild(oldChildIndex + 1));
            cursor->setPosition(ExpressionLayoutCursor::Position::Left);
          }
        } else {
          /* Else place the cursor on the left of the new layout, which is right
           * of the previous sibling or left of the parent. */
          if (oldChildIndex == 0) {
            cursor->setPointedExpressionLayout(this);
            cursor->setPosition(ExpressionLayoutCursor::Position::Left);
          } else {
            cursor->setPointedExpressionLayout(editableChild(oldChildIndex - 1));
            cursor->setPosition(ExpressionLayoutCursor::Position::Right);
          }
        }
      }
      bool oldChildRemovedAtMerge = oldChild->isEmpty();
      mergeChildrenAtIndex(static_cast<HorizontalLayout *>(newChild), indexForInsertion + 1, true);
      if (!oldChildRemovedAtMerge) {
        removeChildAtIndex(indexForInsertion, deleteOldChild);
      }
      return;
    }
    // Else, just replace the child.
    if (cursor != nullptr && !oldWasAncestorOfNewLayout) {
      cursor->setPosition(ExpressionLayoutCursor::Position::Right);
    }
    ExpressionLayout::replaceChild(oldChild, newChild, deleteOldChild);
    if (cursor == nullptr) {
      return;
    }
    cursor->setPointedExpressionLayout(newChild);
  }
  
  void HorizontalLayout::addOrMergeChildAtIndex(ExpressionLayout * eL, int index, bool removeEmptyChildren) {
    if (eL->isHorizontal()) {
      mergeChildrenAtIndex(static_cast<HorizontalLayout *>(eL), index, removeEmptyChildren);
    } else {
      addChildAtIndex(eL, index);
    }
  }
  
  ExpressionLayoutCursor HorizontalLayout::cursorLeftOf(ExpressionLayoutCursor cursor, bool * shouldRecomputeLayout) {
    // Case: Left. Ask the parent.
    if (cursor.pointedExpressionLayout() == this) {
      if (cursor.position() == ExpressionLayoutCursor::Position::Left) {
        if (m_parent) {
          return m_parent->cursorLeftOf(cursor, shouldRecomputeLayout);
        }
        return ExpressionLayoutCursor();
      }
      assert(cursor.position() == ExpressionLayoutCursor::Position::Right);
      /* Case: Right.
       * Go to the last child if there is one, and move Left.
       * Else go Left and ask the parent. */
      if (numberOfChildren() < 1) {
        cursor.setPosition(ExpressionLayoutCursor::Position::Left);
        if (m_parent) {
          return m_parent->cursorLeftOf(cursor, shouldRecomputeLayout);
        }
        return ExpressionLayoutCursor();
      }
      ExpressionLayout * lastChild = editableChild(numberOfChildren()-1);
      assert(lastChild != nullptr);
      cursor.setPointedExpressionLayout(lastChild);
      return lastChild->cursorLeftOf(cursor, shouldRecomputeLayout);
    }
  
    // Case: The cursor is Left of a child.
    assert(cursor.position() == ExpressionLayoutCursor::Position::Left);
    int childIndex = indexOfChild(cursor.pointedExpressionLayout());
    assert(childIndex >= 0);
    if (childIndex == 0) {
      // Case: the child is the leftmost. Ask the parent.
      if (m_parent) {
        cursor.setPointedExpressionLayout(this);
        return m_parent->cursorLeftOf(cursor, shouldRecomputeLayout);
      }
      return ExpressionLayoutCursor();
    }
    // Case: the child is not the leftmost. Go to its left sibling and move Left.
    cursor.setPointedExpressionLayout(editableChild(childIndex-1));
    cursor.setPosition(ExpressionLayoutCursor::Position::Right);
    return editableChild(childIndex-1)->cursorLeftOf(cursor, shouldRecomputeLayout);
  }
  
  ExpressionLayoutCursor HorizontalLayout::cursorRightOf(ExpressionLayoutCursor cursor, bool * shouldRecomputeLayout) {
    // Case: Right. Ask the parent.
    if (cursor.pointedExpressionLayout() == this) {
      if (cursor.position() == ExpressionLayoutCursor::Position::Right) {
        if (m_parent) {
          return m_parent->cursorRightOf(cursor, shouldRecomputeLayout);
        }
        return ExpressionLayoutCursor();
      }
      assert(cursor.position() == ExpressionLayoutCursor::Position::Left);
      /* Case: Left.
       * Go to the first child if there is one, and move Right.
       * Else go Right and ask the parent. */
      if (numberOfChildren() < 1) {
        cursor.setPosition(ExpressionLayoutCursor::Position::Right);
        if (m_parent) {
          return m_parent->cursorRightOf(cursor, shouldRecomputeLayout);
        }
        return ExpressionLayoutCursor();
      }
      ExpressionLayout * firstChild = editableChild(0);
      assert(firstChild != nullptr);
      cursor.setPointedExpressionLayout(firstChild);
      return firstChild->cursorRightOf(cursor, shouldRecomputeLayout);
    }
  
    // Case: The cursor is Right of a child.
    assert(cursor.position() == ExpressionLayoutCursor::Position::Right);
    int childIndex = indexOfChild(cursor.pointedExpressionLayout());
    assert(childIndex >= 0);
    if (childIndex == numberOfChildren() - 1) {
      // Case: the child is the rightmost. Ask the parent.
      if (m_parent) {
        cursor.setPointedExpressionLayout(this);
        return m_parent->cursorRightOf(cursor, shouldRecomputeLayout);
      }
      return ExpressionLayoutCursor();
    }
    /* Case: the child is not the rightmost. Go to its right sibling and move
     * Right. */
    cursor.setPointedExpressionLayout(editableChild(childIndex+1));
    cursor.setPosition(ExpressionLayoutCursor::Position::Left);
    return editableChild(childIndex+1)->cursorRightOf(cursor, shouldRecomputeLayout);
  }
  
  void HorizontalLayout::addChildrenAtIndex(const ExpressionLayout * const * operands, int numberOfOperands, int indexForInsertion, bool removeEmptyChildren) {
    int newIndex = removeEmptyChildBeforeInsertionAtIndex(indexForInsertion, !operands[0]->mustHaveLeftSibling());
    DynamicLayoutHierarchy::addChildrenAtIndex(operands, numberOfOperands, newIndex, removeEmptyChildren);
  }
  
  bool HorizontalLayout::addChildAtIndex(ExpressionLayout * operand, int index) {
    int newIndex = removeEmptyChildBeforeInsertionAtIndex(index, !operand->mustHaveLeftSibling());
    return DynamicLayoutHierarchy::addChildAtIndex(operand, newIndex);
  }
  
  void HorizontalLayout::removeChildAtIndex(int index, bool deleteAfterRemoval) {
    privateRemoveChildAtIndex(index, deleteAfterRemoval, false);
  }
  
  void HorizontalLayout::mergeChildrenAtIndex(DynamicLayoutHierarchy * eL, int index, bool removeEmptyChildren) {
    /* Before the merge, remove ay empty child that would be on the left or on the
     * right of the inserted layout.
     * If the layout to insert starts with a vertical offset layout, any empty
     * layout child directly on the left of the inserted layout (if there is one)
     * should not be removed: it will be the base for the VerticalOffsetLayout. */
    bool shouldRemoveOnLeft = eL->numberOfChildren() > 0 ? !(eL->child(0)->mustHaveLeftSibling()) : true;
    int newIndex = removeEmptyChildBeforeInsertionAtIndex(index, shouldRemoveOnLeft);
    DynamicLayoutHierarchy::mergeChildrenAtIndex(eL, newIndex, removeEmptyChildren);
  }
  
  int HorizontalLayout::writeTextInBuffer(char * buffer, int bufferSize) const {
    if (numberOfChildren() == 0) {
      if (bufferSize == 0) {
        return -1;
      }
      buffer[0] = 0;
      return 0;
    }
    return LayoutEngine::writeInfixExpressionLayoutTextInBuffer(this, buffer, bufferSize, "");
  }
  
  ExpressionLayoutCursor HorizontalLayout::equivalentCursor(ExpressionLayoutCursor cursor) {
    ExpressionLayoutCursor result;
    ExpressionLayout * newPointedLayout = nullptr;
    ExpressionLayoutCursor::Position newPosition = ExpressionLayoutCursor::Position::Left;
    if (cursor.pointedExpressionLayout() == this) {
      // First or last child, if any
      if(numberOfChildren() == 0) {
        return result;
      } else {
        newPointedLayout = editableChild(cursor.position() == ExpressionLayoutCursor::Position::Left ? 0 : numberOfChildren() - 1);
        newPosition = cursor.position();
      }
    } else {
      // Left or right child
      int indexOfPointedLayout = indexOfChild(cursor.pointedExpressionLayout());
      if (indexOfPointedLayout < 0) {
        return result;
      } else if (cursor.position() == ExpressionLayoutCursor::Position::Left) {
        if (indexOfPointedLayout == 0) {
          newPointedLayout = this;
          newPosition = ExpressionLayoutCursor::Position::Left;
        } else {
          newPointedLayout = editableChild(indexOfPointedLayout - 1);
          newPosition = ExpressionLayoutCursor::Position::Right;
        }
      } else {
        assert(cursor.position() == ExpressionLayoutCursor::Position::Right);
        if (indexOfPointedLayout == numberOfChildren() - 1) {
          newPointedLayout = this;
          newPosition = ExpressionLayoutCursor::Position::Right;
        } else {
          newPointedLayout = editableChild(indexOfPointedLayout + 1);
          newPosition = ExpressionLayoutCursor::Position::Left;
        }
      }
    }
    result.setPointedExpressionLayout(newPointedLayout);
    result.setPosition(newPosition);
    return result;
  }
  
  KDSize HorizontalLayout::computeSize() {
    KDCoordinate totalWidth = 0;
    int i = 0;
    KDCoordinate max_under_baseline = 0;
    KDCoordinate max_above_baseline = 0;
    while (ExpressionLayout * c = editableChild(i++)) {
      KDSize childSize = c->size();
      totalWidth += childSize.width();
      if (childSize.height() - c->baseline() > max_under_baseline) {
        max_under_baseline = childSize.height() - c->baseline() ;
      }
      if (c->baseline() > max_above_baseline) {
        max_above_baseline = c->baseline();
      }
    }
    return KDSize(totalWidth, max_under_baseline + max_above_baseline);
  }
  
  void HorizontalLayout::computeBaseline() {
    m_baseline = 0;
    for (int i = 0; i < numberOfChildren(); i++) {
      if (editableChild(i)->baseline() > m_baseline) {
        m_baseline = editableChild(i)->baseline();
      }
    }
    m_baselined = true;
  }
  
  KDPoint HorizontalLayout::positionOfChild(ExpressionLayout * child) {
    KDCoordinate x = 0;
    KDCoordinate y = 0;
    int index = indexOfChild(child);
    if (index > 0) {
      ExpressionLayout * previousChild = editableChild(index-1);
      assert(previousChild != nullptr);
      x = previousChild->origin().x() + previousChild->size().width();
    }
    y = baseline() - child->baseline();
    return KDPoint(x, y);
  }
  
  void HorizontalLayout::privateAddSibling(ExpressionLayoutCursor * cursor, ExpressionLayout * sibling, bool moveCursor) {
    // Add the "sibling" as a child.
    if (cursor->position() == ExpressionLayoutCursor::Position::Left) {
      int indexForInsertion = 0;
      /* If the first child is empty, remove it before adding the layout, unless
       * the new sibling needs the empty layout as a base. */
      if (numberOfChildren() > 0 && editableChild(0)->isEmpty()) {
        if (sibling->mustHaveLeftSibling()) {
          indexForInsertion = 1;
        } else {
          /* We force the removing of the child even followed by a neighbourg
           * requiring a left sibling as we are about to add a sibling in first
           * position anyway. */
          privateRemoveChildAtIndex(0, true, true);
        }
      }
      if (moveCursor) {
        if (numberOfChildren() > indexForInsertion) {
          cursor->setPointedExpressionLayout(editableChild(indexForInsertion));
        } else {
          cursor->setPointedExpressionLayout(this);
          cursor->setPosition(ExpressionLayoutCursor::Position::Right);
        }
      }
      addOrMergeChildAtIndex(sibling, indexForInsertion, false);
      return;
    }
    assert(cursor->position() == ExpressionLayoutCursor::Position::Right);
    // If the last child is empty, remove it before adding the layout.
    int childrenCount = numberOfChildren();
    if (childrenCount > 0 && editableChild(childrenCount - 1)->isEmpty() && !sibling->mustHaveLeftSibling()) {
      /* Force remove the last child. */
      privateRemoveChildAtIndex(childrenCount - 1, true, true);
    }
    addOrMergeChildAtIndex(sibling, numberOfChildren(), false);
    if (moveCursor) {
      cursor->setPointedExpressionLayout(this);
    }
  }
  
  void HorizontalLayout::privateRemoveChildAtIndex(int index, bool deleteAfterRemoval, bool forceRemove) {
    /* Remove the child before potentially adding an EmptyLayout. Indeed, adding
     * a new child would remove any EmptyLayout surrounding the new child and in
     * the case the child to be removed was an Empty layout, it would result in
     * removing it twice if we remove it afterwards. */
    DynamicLayoutHierarchy::removeChildAtIndex(index, deleteAfterRemoval);
    /* If the child to remove is at index 0 and its right sibling must have a left
     * sibling (e.g. it is a VerticalOffsetLayout), replace the child with an
     * EmptyLayout instead of removing it. */
    if (!forceRemove && index == 0 && numberOfChildren() > 0 && child(0)->mustHaveLeftSibling()) {
      addChildAtIndex(new EmptyLayout(), 0);
    }
  }
  
  int HorizontalLayout::removeEmptyChildBeforeInsertionAtIndex(int index, bool shouldRemoveOnLeft) {
    int newIndex = index;
    /* If empty, remove the child that would be on the right of the inserted
     * layout. */
    if (newIndex < numberOfChildren()
        && child(newIndex)->isEmpty())
    {
      privateRemoveChildAtIndex(newIndex, true, true);
    }
    /* If empty, remove the child that would be on the left of the inserted
     * layout. */
    if (shouldRemoveOnLeft
        && newIndex - 1 >= 0
        && newIndex - 1 <= numberOfChildren() -1
        && child(newIndex - 1)->isEmpty())
    {
      privateRemoveChildAtIndex(newIndex-1, true, true);
      newIndex = index - 1;
    }
    return newIndex;
  }
  
  }