drawing-surface.cpp revision 28f74a03fc1d9ebe507ee0c8f6c361c06c2ea27e
/**
* @file
* Cairo surface that remembers its origin.
*//*
* Authors:
* Krzysztof KosiƄski <tweenk.pl@gmail.com>
*
* Copyright (C) 2011 Authors
* Released under GNU GPL, read the file 'COPYING' for more information
*/
//#include <iostream>
#include "display/drawing-surface.h"
#include "display/drawing-context.h"
#include "display/cairo-utils.h"
namespace Inkscape {
using Geom::X;
using Geom::Y;
/**
* @class DrawingSurface
* Drawing surface that remembers its origin.
*
* This is a very minimalistic wrapper over cairo_surface_t. The main
* extra functionality provided by this class is that it automates
* the mapping from "logical space" (coordinates in the rendering)
* and the "physical space" (surface pixels). For example, patterns
* have to be rendered on tiles which have possibly non-integer
* widths and heights.
*
* This class has delayed allocation functionality - it creates
* the Cairo surface it wraps on the first call to createRawContext()
* of when a DrawingContext is constructed.
*/
/**
* Creates a surface with the given physical extents.
* When a drawing context is created for this surface, its pixels
* will cover the area under the given rectangle.
*/
DrawingSurface::DrawingSurface(Geom::IntRect const &area)
: _surface(NULL)
, _origin(area.min())
, _scale(1, 1)
, _pixels(area.dimensions())
{}
/**
* Creates a surface with the given logical and physical extents.
* When a drawing context is created for this surface, its pixels
* will cover the area under the given rectangle. IT will contain
* the number of pixels specified by the second argument.
* @param logbox Logical extents of the surface
* @param pixdims Pixel dimensions of the surface.
*/
DrawingSurface::DrawingSurface(Geom::Rect const &logbox, Geom::IntPoint const &pixdims)
: _surface(NULL)
, _origin(logbox.min())
, _scale(pixdims[X] / logbox.width(), pixdims[Y] / logbox.height())
, _pixels(pixdims)
{}
/**
* Wrap a cairo_surface_t.
* This constructor will take an extra reference on @a surface, which will
* be released on destruction.
*/
DrawingSurface::DrawingSurface(cairo_surface_t *surface, Geom::Point const &origin)
: _surface(surface)
, _origin(origin)
, _scale(1, 1)
{
cairo_surface_reference(surface);
_pixels[X] = cairo_image_surface_get_width(surface);
_pixels[Y] = cairo_image_surface_get_height(surface);
}
DrawingSurface::~DrawingSurface()
{
if (_surface)
cairo_surface_destroy(_surface);
}
/// Get the logical extents of the surface.
Geom::Rect
DrawingSurface::area() const
{
Geom::Rect r = Geom::Rect::from_xywh(_origin, dimensions());
return r;
}
/// Get the pixel dimensions of the surface
Geom::IntPoint
DrawingSurface::pixels() const
{
return _pixels;
}
/// Get the logical width and weight of the surface as a point.
Geom::Point
DrawingSurface::dimensions() const
{
Geom::Point logical_dims(_pixels[X] / _scale[X], _pixels[Y] / _scale[Y]);
return logical_dims;
}
Geom::Point
DrawingSurface::origin() const
{
return _origin;
}
Geom::Scale
DrawingSurface::scale() const
{
return _scale;
}
/// Get the transformation applied to the drawing context on construction.
Geom::Affine
DrawingSurface::drawingTransform() const
{
Geom::Affine ret = _scale * Geom::Translate(-_origin);
return ret;
}
cairo_surface_type_t
DrawingSurface::type() const
{
// currently hardcoded
return CAIRO_SURFACE_TYPE_IMAGE;
}
/// Drop contents of the surface and release the underlying Cairo object.
void
DrawingSurface::dropContents()
{
if (_surface) {
cairo_surface_destroy(_surface);
_surface = NULL;
}
}
/**
* Create a drawing context for this surface.
* It's better to use the surface constructor of DrawingContext.
*/
cairo_t *
DrawingSurface::createRawContext()
{
// deferred allocation
if (!_surface) {
_surface = cairo_image_surface_create(CAIRO_FORMAT_ARGB32, _pixels[X], _pixels[Y]);
}
cairo_t *ct = cairo_create(_surface);
if (_scale != Geom::Scale::identity()) {
cairo_scale(ct, _scale[X], _scale[Y]);
}
cairo_translate(ct, -_origin[X], -_origin[Y]);
return ct;
}
Geom::IntRect
DrawingSurface::pixelArea() const
{
Geom::IntRect ret = Geom::IntRect::from_xywh(_origin.round(), _pixels);
return ret;
}
//////////////////////////////////////////////////////////////////////////////
DrawingCache::DrawingCache(Geom::IntRect const &area)
: DrawingSurface(area)
, _clean_region(cairo_region_create())
, _pending_area(area)
{}
DrawingCache::~DrawingCache()
{
cairo_region_destroy(_clean_region);
}
void
DrawingCache::markDirty(Geom::IntRect const &area)
{
cairo_rectangle_int_t dirty = _convertRect(area);
cairo_region_subtract_rectangle(_clean_region, &dirty);
}
void
DrawingCache::markClean(Geom::IntRect const &area)
{
Geom::OptIntRect r = Geom::intersect(area, pixelArea());
if (!r) return;
cairo_rectangle_int_t clean = _convertRect(*r);
cairo_region_union_rectangle(_clean_region, &clean);
}
/// Call this during the update phase to schedule a transformation of the cache.
void
DrawingCache::scheduleTransform(Geom::IntRect const &new_area, Geom::Affine const &trans)
{
_pending_area = new_area;
_pending_transform *= trans;
}
/// Transforms the cache according to the transform specified during the update phase.
/// Call this during render phase, before painting.
void
DrawingCache::prepare()
{
Geom::IntRect old_area = pixelArea();
bool is_identity = _pending_transform.isIdentity();
if (is_identity && _pending_area == old_area) return; // no change
bool is_integer_translation = false;
if (!is_identity && _pending_transform.isTranslation()) {
Geom::IntPoint t = _pending_transform.translation().round();
if (Geom::are_near(Geom::Point(t), _pending_transform.translation())) {
is_integer_translation = true;
cairo_region_translate(_clean_region, t[X], t[Y]);
if (old_area + t == _pending_area) {
// if the areas match, the only thing to do
// is to ensure that the clean area is not too large
cairo_rectangle_int_t limit = _convertRect(_pending_area);
cairo_region_intersect_rectangle(_clean_region, &limit);
_origin += t;
_pending_transform.setIdentity();
return;
}
}
}
// otherwise, we need to transform the cache
Geom::IntPoint old_origin = old_area.min();
cairo_surface_t *old_surface = _surface;
_surface = NULL;
_pixels = _pending_area.dimensions();
_origin = _pending_area.min();
cairo_t *ct = createRawContext();
if (!is_identity) {
ink_cairo_transform(ct, _pending_transform);
}
cairo_set_source_surface(ct, old_surface, old_origin[X], old_origin[Y]);
cairo_set_operator(ct, CAIRO_OPERATOR_SOURCE);
cairo_paint(ct);
cairo_surface_destroy(old_surface);
cairo_destroy(ct);
if (!is_identity && !is_integer_translation) {
// dirty everything
cairo_region_destroy(_clean_region);
_clean_region = cairo_region_create();
} else {
cairo_rectangle_int_t limit = _convertRect(_pending_area);
cairo_region_intersect_rectangle(_clean_region, &limit);
}
//std::cout << _pending_transform << old_area << _pending_area << std::endl;
_pending_transform.setIdentity();
}
/**
* Paints the clean area from cache and modifies the @a area
* parameter to the bounds of the region that must be repainted.
*/
void
DrawingCache::paintFromCache(DrawingContext &ct, Geom::OptIntRect &area)
{
if (!area) return;
// We subtract the clean region from the area, then get the bounds
// of the resulting region. This is the area that needs to be repainted
// by the item.
// Then we subtract the area that needs to be repainted from the
// original area and paint the resulting region from cache.
cairo_rectangle_int_t area_c = _convertRect(*area);
cairo_region_t *dirty_region = cairo_region_create_rectangle(&area_c);
cairo_region_t *cache_region = cairo_region_copy(dirty_region);
cairo_region_subtract(dirty_region, _clean_region);
if (cairo_region_is_empty(dirty_region)) {
area = Geom::OptIntRect();
} else {
cairo_rectangle_int_t to_repaint;
cairo_region_get_extents(dirty_region, &to_repaint);
area = _convertRect(to_repaint);
cairo_region_subtract_rectangle(cache_region, &to_repaint);
}
cairo_region_destroy(dirty_region);
if (!cairo_region_is_empty(cache_region)) {
int nr = cairo_region_num_rectangles(cache_region);
cairo_rectangle_int_t tmp;
for (int i = 0; i < nr; ++i) {
cairo_region_get_rectangle(cache_region, i, &tmp);
ct.rectangle(_convertRect(tmp));
}
ct.setSource(this);
ct.fill();
}
cairo_region_destroy(cache_region);
}
// debugging utility
void
DrawingCache::_dumpCache(Geom::OptIntRect const &area)
{
static int dumpnr = 0;
cairo_surface_t *surface = ink_cairo_surface_copy(_surface);
DrawingContext ct(surface, _origin);
if (!cairo_region_is_empty(_clean_region)) {
Inkscape::DrawingContext::Save save(ct);
int nr = cairo_region_num_rectangles(_clean_region);
cairo_rectangle_int_t tmp;
for (int i = 0; i < nr; ++i) {
cairo_region_get_rectangle(_clean_region, i, &tmp);
ct.rectangle(_convertRect(tmp));
}
ct.setSource(0,1,0,0.1);
ct.fill();
}
ct.rectangle(*area);
ct.setSource(1,0,0,0.1);
ct.fill();
char *fn = g_strdup_printf("dump%d.png", dumpnr++);
cairo_surface_write_to_png(surface, fn);
cairo_surface_destroy(surface);
g_free(fn);
}
cairo_rectangle_int_t
DrawingCache::_convertRect(Geom::IntRect const &area)
{
cairo_rectangle_int_t ret;
ret.x = area.left();
ret.y = area.top();
ret.width = area.width();
ret.height = area.height();
return ret;
}
Geom::IntRect
DrawingCache::_convertRect(cairo_rectangle_int_t const &r)
{
Geom::IntRect ret = Geom::IntRect::from_xywh(
r.x, r.y,
r.width, r.height);
return ret;
}
} // end namespace Inkscape
/*
Local Variables:
mode:c++
c-file-style:"stroustrup"
c-file-offsets:((innamespace . 0)(inline-open . 0)(case-label . +))
indent-tabs-mode:nil
fill-column:99
End:
*/
// vim: filetype=cpp:expandtab:shiftwidth=4:tabstop=8:softtabstop=4:fileencoding=utf-8:textwidth=99 :