void widgetResizeImpl(widget *self, int w, int h)
{
const size minSize = widgetGetMinSize(self);
const size maxSize = widgetGetMaxSize(self);
// Create an event
eventResize evtResize;
evtResize.event = widgetCreateEvent(EVT_RESIZE);
// Save the current size in the event
evtResize.oldSize = self->size;
assert(minSize.x <= w);
assert(minSize.y <= h);
assert(w <= maxSize.x);
assert(h <= maxSize.y);
self->size.x = w;
self->size.y = h;
// Re-create the cairo context at this new size
widgetCairoCreate(&self->cr, CAIRO_FORMAT_ARGB32, w, h);
// If a mask is enabled; re-create it also
if (self->maskEnabled)
{
widgetCairoCreate(&self->maskCr, CAIRO_FORMAT_A1, w, h);
// Re-draw the mask (only done on resize)
widgetDrawMask(self);
}
// If OpenGL is enabled disable and re-enable it
if (self->openGLEnabled)
{
widgetDisableGL(self);
widgetEnableGL(self);
}
// Set the needs redraw flag
self->needsRedraw = true;
// If we have any children, we need to redo their layout
if (vectorSize(self->children))
{
widgetDoLayout(self);
}
// Fire any EVT_RESIZE callbacks
widgetFireCallbacks(self, (event *) &evtResize);
}
bool tableDoLayoutImpl(widget *self)
{
table *selfTable = TABLE(self);
const int numChildren = vectorSize(self->children);
const int numRows = tableGetRowCount(selfTable);
const int numColumns = tableGetColumnCount(selfTable);
int i;
int dx, dy;
int *minColumnWidth = alloca(sizeof(int) * numColumns);
int *maxColumnWidth = alloca(sizeof(int) * numColumns);
int *minRowHeight = alloca(sizeof(int) * numRows);
int *maxRowHeight = alloca(sizeof(int) * numRows);
// Syntatic sugar
int *columnWidth = minColumnWidth;
int *rowHeight = minRowHeight;
// Get the minimum and maximum cell sizes
tableGetMinimumCellSizes(selfTable, minRowHeight, minColumnWidth);
tableGetMaximumCellSizes(selfTable, maxRowHeight, maxColumnWidth);
// Calculate how much space we have left to fill
dx = self->size.x - tablePartialSum(minColumnWidth, 0, numColumns);
dy = self->size.y - tablePartialSum(minRowHeight, 0, numRows);
// Increase the column size until we run out of space
for (i = 0; dx; i = (i + 1) % numColumns)
{
// If the column is not maxed out, increases its size by one
if (columnWidth[i] < maxColumnWidth[i])
{
columnWidth[i]++;
dx--;
}
}
// Increase the row size until we run out of space
for (i = 0; dy; i = (i + 1) % numRows)
{
// If the row is not maxed out, increase its size by one
if (rowHeight[i] < minRowHeight[i])
{
rowHeight[i]++;
dy--;
}
}
// Now we need to position the children, taking padding into account
for (i = 0; i < numChildren; i++)
{
// Get the child and its position info
widget *child = vectorAt(self->children, i);
const childPositionInfo *pos = vectorAt(selfTable->childPositions, i);
size maxChildSize = widgetGetMaxSize(child);
// left is the sum of all of the preceding columns
int left = tablePartialSum(columnWidth, 0, pos->column);
// top is the sum of all of the preceding rows
int top = tablePartialSum(rowHeight, 0, pos->row);
// cellWidth is the sum of the columns we span
int cellWidth = tablePartialSum(columnWidth, pos->column - 1, pos->colspan);
// cellHeight is the sum of the rows we span
int cellHeight = tablePartialSum(rowHeight, pos->row - 1, pos->rowspan);
// Final width and height of the child
int w, h;
// Final x,y offsets of the child
int x, y;
// If we are not the last row/column, subtract the row/column padding
if (pos->column + pos->colspan - 1 != numColumns)
{
cellWidth -= selfTable->columnPadding;
}
if (pos->row + pos->rowspan - 1 != numRows)
{
cellHeight -= selfTable->rowPadding;
}
// Compute the final width and height of the child
w = MIN(cellWidth, maxChildSize.x);
h = MIN(cellHeight, maxChildSize.y);
// Pad out any remaining space
switch (pos->hAlignment)
{
case LEFT:
x = left;
break;
case CENTRE:
x = left + (cellWidth - w) / 2;
break;
case RIGHT:
x = left + cellWidth - w;
break;
}
switch (pos->vAlignment)
{
case TOP:
y = top;
break;
case MIDDLE:
y = top + (cellHeight - h) / 2;
break;
case BOTTOM:
y = top + cellHeight - h;
break;
}
// Resize and reposition the widget
widgetResize(child, w, h);
widgetReposition(child, x, y);
}
return true;
}
/**
* Computes the maximum row/column size for each row/column in the table. It is
* important to note that the widths/heights are inclusive of padding. Therefore
* all but the rightmost column and bottom row will have either self->rowPadding
* or self->columnPadding added onto their sizes.
*
* @param self The table to get the minimum cell sizes of.
* @param maxRowHeight The array to place the maximum row heights for the table
* into; assumed to be tableGetRowCount(self) in size.
* @param maxColumnWidth The array to place the maximum column widths for the
* table into; assumed to be tableGetColumnCount(self)
* in size.
*/
static void tableGetMaximumCellSizes(const table *self, int *maxRowHeight,
int *maxColumnWidth)
{
int i;
int spanningIndex;
const int numChildren = vectorSize(WIDGET(self)->children);
const int numRows = tableGetRowCount(self);
const int numColumns = tableGetColumnCount(self);
size *maxChildSize = alloca(sizeof(size) * numChildren);
// Zero the min row/column sizes
memset(maxRowHeight, '\0', sizeof(int) * numRows);
memset(maxColumnWidth, '\0', sizeof(int) * numColumns);
// Get the maximum row/column sizes for single-spanning cells
for (i = 0; i < numChildren; i++)
{
const childPositionInfo *pos = vectorAt(self->childPositions, i);
const int row = pos->row - 1;
const int col = pos->column - 1;
// Get the maximum size of the cell
maxChildSize[i] = widgetGetMaxSize(vectorAt(WIDGET(self)->children, i));
// If the row has a rowspan of 1; see if it is the highest thus far
if (pos->rowspan == 1)
{
maxRowHeight[row] = MAX(maxRowHeight[row], maxChildSize[i].y);
}
// If the column has a colspan of 1; see if it is the widest thus far
if (pos->colspan == 1)
{
maxColumnWidth[col] = MAX(maxColumnWidth[col], maxChildSize[i].x);
}
}
// Handle spanning rows
while ((spanningIndex = tableGetMostOversizedRow(self,
maxRowHeight,
maxChildSize)) != -1)
{
int i;
const childPositionInfo *pos = vectorAt(self->childPositions, spanningIndex);
// Calculate how much larger we need to make the spanned rows
int delta = maxChildSize[spanningIndex].y - tablePartialSum(maxRowHeight,
pos->row - 1,
pos->rowspan);
// Loop over the rows spanned increasing their height by 1
for (i = pos->row; delta; i = pos->row + (i + 1) % pos->rowspan, delta--)
{
maxRowHeight[i]++;
}
}
// Handle spanning columns
while ((spanningIndex = tableGetMostOversizedColumn(self,
maxColumnWidth,
maxChildSize)) != -1)
{
int i;
const childPositionInfo *pos = vectorAt(self->childPositions, spanningIndex);
// Calculate how much larger we need to make the spanned columns
int delta = maxChildSize[spanningIndex].x - tablePartialSum(maxColumnWidth,
pos->column - 1,
pos->colspan);
for (i = pos->column; delta; i = pos->column + (i + 1) % pos->colspan, delta--)
{
maxColumnWidth[i]++;
}
}
}
