view src/graph_engine_skia.cpp @ 489:23c7667b3ec0 Android_Skia

Fix a potential bug when destroy a rdman. When a rdman is dirty, free shapes and coords works specially. Objects are append to a free list. They are not real freed until rdman being clean. redraw_man_destroy() free shapes and coords with free functions of them. If rdman is dirty when destroy it, objects would be leaked. The changeset make rdman clean before free shapes and coords to make objects being freed correctly.
author Thinker K.F. Li <thinker@branda.to>
date Sun, 22 Nov 2009 20:41:27 +0800
parents d984a6672be7
children 9e36e06fcc18
line wrap: on
line source

/*! \page ge_layer Graphic Engine Layer
 *
 * Graphic Engine Layer is an abstract of graphic engine; likes Cairo
 * and Skia.  It provides portability for the rest of MadButterfly.
 *
 * The basic stratage of interface of graphic engine layer is defined
 * according purpose of MadButterfly.  For example, MadButterfly wants
 * a function that can clear a canvas, we define a clear function.
 * Never define a indirectly way to finish the function.  Never define
 * a way to finish the function for the reason that some engine
 * require you to finish the task in that procedure.  It avoids
 * binding graphic engine layer with any behavior of a graphic engine,
 * and provides more compatible with other engines, to define
 * interface of graphic engine layer according purpose of
 * MadButterfly.
 *
 * \section ge_mem Graphic Engine Layer Memory Management
 *
 * MadButterfly is responsible for management of objects and memory
 * blocks returned by graphic engine layer, even for graphic engines
 * that have management model.  MadButterfly supposes memory blocks
 * only be released when they are no more used.  MadBufferfly is
 * responsible for release them.  So, even a graphic engine has
 * reference count with objects, MadButterfly still keep a reference
 * for every object returned by the engine until no one will use it.
 *
 * \section ge_transform Transformation of Coordination System
 *
 * Points of pathes are transformed when it is added to the canvas
 * with the transformation matrix at the time.  So, changes of
 * transformation matrix of an canvas will not affect points that had
 * been added.  It only affects points been added when the matrix is
 * setted.
 */
#include <stdio.h>
#include <SkCanvas.h>
#include <SkBitmap.h>
#include <SkShader.h>
#include <SkDevice.h>
#include <SkGradientShader.h>
#include <SkXfermode.h>
#include <SkColorFilter.h>

#define C_START extern "C" {
#define C_END }

C_START

#include "mb_graph_engine_skia.h"
#include "mb_shapes.h"
#include "mb_img_ldr.h"

/*! \brief Source pattern
 *
 * For Skia, source pattern is SkShader with some decoration.  Since
 * SkShade will repeative tiling or extenting edge color, it can not
 * stop tiling and extenting for fixed size bitmap.  So, we need to
 * translate mbe_paint() into a drawing of a rectangle.
 */
struct _mbe_pattern_t {
    SkShader *shader;
    int w, h;
    int has_size;
    co_aix matrix[6];
};

struct _mbe_scaled_font_t {
    struct _mb_font_face_t *face;
    co_aix fnt_mtx[6];
    co_aix ctm[6];
};
struct _mbe_font_face_t {};
/*! \brief MadButterfly Graphic Engine Context.
 *
 * A context comprises source pattern, target surface, path,
 * line-width, and transform matrix.
 */
struct _mbe_t {
    SkCanvas *canvas;
    SkPath *path, *subpath;
    SkPaint *paint;
    SkRegion *saved_region;
    
    struct _mbe_states_t *states;
};

struct _mbe_states_t {
    mbe_pattern_t *ptn;
    int ptn_owned;
    co_aix line_width;
    co_aix matrix[6];
    struct _mbe_states_t *next;
};

#ifndef ASSERT
#define ASSERT(x)
#endif

#define PI 3.1415926535897931

#define CO_AIX_2_SKSCALAR(a) ((SkScalar)a)
#define SKSCALAR_2_CO_AIX(a) ((co_aix)(a))
#define MB_MATRIX_2_SKMATRIX(sk, mb) {			\
	(sk).setScaleX(CO_AIX_2_SKSCALAR((mb)[0]));	\
	(sk).setSkewX(CO_AIX_2_SKSCALAR((mb)[1]));	\
	(sk).setTranslateX(CO_AIX_2_SKSCALAR((mb)[2]));	\
	(sk).setSkewY(CO_AIX_2_SKSCALAR((mb)[3]));	\
	(sk).setScaleY(CO_AIX_2_SKSCALAR((mb)[4]));	\
	(sk).setTranslateY(CO_AIX_2_SKSCALAR((mb)[5]));	\
    }
#define SKMATRIX_2_MB_MATRIX(mb, sk) {				\
	(mb)[0] = SKSCALAR_2_CO_AIX((sk).getScaleX());		\
	(mb)[1] = SKSCALAR_2_CO_AIX((sk).getSkewX());		\
	(mb)[2] = SKSCALAR_2_CO_AIX((sk).getTranslateX());	\
	(mb)[3] = SKSCALAR_2_CO_AIX((sk).getSkewY());		\
	(mb)[4] = SKSCALAR_2_CO_AIX((sk).getScaleY());		\
	(mb)[5] = SKSCALAR_2_CO_AIX((sk).getTranslateY());	\
    }
#define MBSTOP_2_SKCOLOR(c)			\
    ((((int)((c)->a * 255)) << 24) |		\
     (((int)((c)->r * 255)) << 16) |		\
     (((int)((c)->g * 255)) << 8) |		\
     (((int)((c)->b * 255))))

static const co_aix id_matrix[6] = { 1, 0, 0, 0, 1, 0 };

static void
_prepare_sized_pattern(mbe_t *mbe, mbe_pattern_t *ptn) {
    SkCanvas *canvas = mbe->canvas;
    SkPath path;
    co_aix x, y;
    co_aix reverse[6];
    
    *mbe->saved_region = canvas->getTotalClip();
    
    compute_reverse(ptn->matrix, reverse);
    x = 0; y = 0;
    matrix_trans_pos(reverse, &x, &y);
    path.moveTo(CO_AIX_2_SKSCALAR(x), CO_AIX_2_SKSCALAR(y));
    x = 0; y = ptn->h;
    matrix_trans_pos(reverse, &x, &y);
    path.moveTo(CO_AIX_2_SKSCALAR(x), CO_AIX_2_SKSCALAR(y));
    x = ptn->w; y = ptn->h;
    matrix_trans_pos(reverse, &x, &y);
    path.moveTo(CO_AIX_2_SKSCALAR(x), CO_AIX_2_SKSCALAR(y));
    path.close();
    
    canvas->clipPath(path, SkRegion::kIntersect_Op);
}

static void
_finish_sized_pattern(mbe_t *mbe) {
    SkCanvas *canvas = mbe->canvas;
    
    canvas->setClipRegion(*mbe->saved_region);
}

static void
_canvas_device_region(SkCanvas *canvas, SkRegion *region) {
    SkDevice *device;
    int w, h;

    device = canvas->getDevice();
    w = device->width();
    h = device->height();
    region->setRect(0, 0, w, h);
}

static void
_update_path(mbe_t *mbe) {
    SkPath *path = mbe->path;
    SkPath *subpath = mbe->subpath;
    SkMatrix canvas_matrix;
    SkPoint point;

    MB_MATRIX_2_SKMATRIX(canvas_matrix, mbe->states->matrix);
    path->addPath(*subpath, canvas_matrix);
    
    subpath->getLastPt(&point);
    subpath->rewind();
    subpath->moveTo(point);
}

/*
 * When a function want to use the paint associated with a canvas to
 * draw, it should call _prepare_paint() can make the paint ready.
 * And, call _finish_paint() when the paint is no more used.
 */
static void
_prepare_paint(mbe_t *mbe, SkPaint::Style style) {
    SkPaint *paint = mbe->paint;
    mbe_pattern_t *ptn = mbe->states->ptn;
    SkShader *shader = ptn->shader;
    co_aix matrix[6];
    SkMatrix skmatrix;

    paint->setStyle(style);
    
    /* Local matrix of SkShader is a mapping from source pattern to
     * user space.  Unlikely, for Cairo is a mapping from user space
     * to source pattern.
     */
    matrix_mul(mbe->states->matrix, ptn->matrix, matrix);
    MB_MATRIX_2_SKMATRIX(skmatrix, matrix);
    shader->setLocalMatrix(skmatrix);
    paint->setShader(shader);

    if(style == SkPaint::kStroke_Style)
	paint->setStrokeWidth(CO_AIX_2_SKSCALAR(mbe->states->line_width));

    if(ptn->has_size)
	_prepare_sized_pattern(mbe, ptn);
}

static void
_finish_paint(mbe_t *mbe) {
    mbe_pattern_t *ptn = mbe->states->ptn;
    
    mbe->paint->reset();
    if(ptn->has_size)
	_finish_sized_pattern(mbe);
}

mbe_pattern_t *mbe_pattern_create_for_surface(mbe_surface_t *surface) {
    mbe_pattern_t *ptn;
    SkBitmap *bitmap = (SkBitmap *)surface;

    ptn = (mbe_pattern_t *)malloc(sizeof(mbe_pattern_t));
    ptn->shader = SkShader::CreateBitmapShader(*bitmap,
					       SkShader::kClamp_TileMode,
					       SkShader::kClamp_TileMode);
    if(ptn->shader == NULL) {
	free(ptn);
	return NULL;
    }
    
    ptn->has_size = 1;
    ptn->w = bitmap->width();
    ptn->h = bitmap->height();

    memcpy(ptn->matrix, id_matrix, sizeof(co_aix) * 6);
    
    return ptn;
}

mbe_pattern_t *
mbe_pattern_create_radial(co_aix cx0, co_aix cy0, co_aix radius0,
			  co_aix cx1, co_aix cy1, co_aix radius1,
			  grad_stop_t *stops, int stop_cnt) {
    mbe_pattern_t *ptn;
    SkColor *colors;
    SkScalar *poses;
    grad_stop_t *stop;
    SkPoint center;
    int i;

    ptn = (mbe_pattern_t *)malloc(sizeof(mbe_pattern_t));
    colors = new SkColor[stop_cnt];
    poses = new SkScalar[stop_cnt];
    if(ptn == NULL || colors == NULL || poses == NULL)
	goto fail;

    center.set(CO_AIX_2_SKSCALAR(cx1), CO_AIX_2_SKSCALAR(cy1));
    
    stop = stops;
    for(i = 0; i < stop_cnt; i++) {
	colors[i] = MBSTOP_2_SKCOLOR(stop);
	poses[i] = CO_AIX_2_SKSCALAR(stop->offset);
    }

    /*
     * cx0, cy0 and radius0 is not used.  Since Skia is still not
     * support two circles radial.  And, SVG 1.2 is also not support
     * two circles.
     */
    ptn->shader =
	SkGradientShader::CreateRadial(center, CO_AIX_2_SKSCALAR(radius1),
				       colors, poses, stop_cnt,
				       SkShader::kClamp_TileMode);
    if(ptn->shader == NULL)
	goto fail;

    memcpy(ptn->matrix, id_matrix, sizeof(co_aix) * 6);
    
    delete colors;
    delete poses;
    return ptn;
    
 fail:
    if(ptn) free(ptn);
    if(colors) delete colors;
    if(poses) delete poses;
    return NULL;
}

mbe_pattern_t *
mbe_pattern_create_linear(co_aix x0, co_aix y0,
			  co_aix x1, co_aix y1,
			  grad_stop_t *stops, int stop_cnt) {
    mbe_pattern_t *ptn;
    SkColor *colors;
    SkScalar *poses;
    grad_stop_t *stop;
    SkPoint points[2];
    int i;

    ptn = (mbe_pattern_t *)malloc(sizeof(mbe_pattern_t));
    colors = new SkColor[stop_cnt];
    poses = new SkScalar[stop_cnt];
    if(ptn == NULL || colors == NULL || poses == NULL)
	goto fail;

    points[0].set(CO_AIX_2_SKSCALAR(x0), CO_AIX_2_SKSCALAR(y0));
    points[1].set(CO_AIX_2_SKSCALAR(x1), CO_AIX_2_SKSCALAR(y1));
    
    stop = stops;
    for(i = 0; i < stop_cnt; i++) {
	colors[i] = MBSTOP_2_SKCOLOR(stop);
	poses[i] = CO_AIX_2_SKSCALAR(stop->offset);
    }

    /*
     * cx0, cy0 and radius0 is not used.  Since Skia is still not
     * support two circles radial.  And, SVG 1.2 is also not support
     * two circles.
     */
    ptn->shader =
	SkGradientShader::CreateLinear(points, colors, poses, stop_cnt,
				       SkShader::kClamp_TileMode);
    if(ptn->shader == NULL)
	goto fail;

    memcpy(ptn->matrix, id_matrix, sizeof(co_aix) * 6);
    
    delete colors;
    delete poses;
    return ptn;
    
 fail:
    if(ptn) free(ptn);
    if(colors) delete colors;
    if(poses) delete poses;
    return NULL;
}

void mbe_pattern_set_matrix(mbe_pattern_t *ptn, const co_aix matrix[6]) {
    SkMatrix skmatrix;

    MB_MATRIX_2_SKMATRIX(skmatrix, matrix);

    ptn->shader->setLocalMatrix(skmatrix);
}

void mbe_pattern_destroy(mbe_pattern_t *ptn) {
    if(ptn->shader)
	delete ptn->shader;
    free(ptn);
}

int mbe_image_surface_get_stride(mbe_surface_t *surface) {
    return ((SkBitmap *)surface)->rowBytes();
}

int mbe_image_surface_get_height(mbe_surface_t *surface) {
    return ((SkBitmap *)surface)->height();
}

int mbe_image_surface_get_width(mbe_surface_t *surface) {
    return ((SkBitmap *)surface)->width();
}

unsigned char *mbe_image_surface_get_data(mbe_surface_t *surface) {
    return (unsigned char *)((SkBitmap *)surface)->getPixels();
}

mbe_surface_t *mbe_image_surface_create_from_png(const char *filename) {}

mbe_surface_t *
mbe_image_surface_create_for_data(unsigned char *data,
				  mb_img_fmt_t fmt,
				  int width, int height,
				  int stride) {
    SkBitmap *bitmap;
    SkBitmap::Config cfg;

    switch(fmt) {
    case MB_IFMT_ARGB32:
	cfg = SkBitmap::kARGB_8888_Config; break;
	
    case MB_IFMT_A8:
	cfg = SkBitmap::kA8_Config; break;
	
    case MB_IFMT_A1:
	cfg = SkBitmap::kA1_Config; break;
	
    case MB_IFMT_RGB16_565:
	cfg = SkBitmap::kRGB_565_Config; break;
	
    case MB_IFMT_RGB24:
    default:
	return NULL;
    }
    
    bitmap = new SkBitmap();
    if(bitmap == NULL)
	return NULL;
    
    bitmap->setConfig(cfg, width, height, stride);
    bitmap->setPixels(data);

    return (mbe_surface_t *)bitmap;
}

mb_img_fmt_t mbe_image_surface_get_format(mbe_surface_t *surface) {
    SkBitmap *bitmap = (SkBitmap *)surface;
    mb_img_fmt_t fmt;
    SkBitmap::Config cfg;
    
    cfg = bitmap->getConfig();
    switch(cfg) {
    case SkBitmap::kARGB_8888_Config:
	fmt = MB_IFMT_ARGB32; break;

    case SkBitmap::kA8_Config:
	fmt = MB_IFMT_A8; break;

    case SkBitmap::kA1_Config:
	fmt = MB_IFMT_A1; break;

    case SkBitmap::kRGB_565_Config:
	fmt = MB_IFMT_RGB16_565; break;

    default:
	fmt = MB_IFMT_DUMMY;
    }

    return fmt;
}

mbe_surface_t *
mbe_image_surface_create(mb_img_fmt_t fmt, int width, int height) {
    SkBitmap *bitmap;
    SkBitmap::Config cfg;

    switch(fmt) {
    case MB_IFMT_ARGB32:
	cfg = SkBitmap::kARGB_8888_Config; break;
	
    case MB_IFMT_A8:
	cfg = SkBitmap::kA8_Config; break;
	
    case MB_IFMT_A1:
	cfg = SkBitmap::kA1_Config; break;
	
    case MB_IFMT_RGB16_565:
	cfg = SkBitmap::kRGB_565_Config; break;
	
    case MB_IFMT_RGB24:
    default:
	return NULL;
    }
    
    bitmap = new SkBitmap();
    if(bitmap == NULL)
	return NULL;
    
    bitmap->setConfig(cfg, width, height);
    bitmap->allocPixels();

    return (mbe_surface_t *)bitmap;
}

mbe_scaled_font_t *mbe_scaled_font_reference(mbe_scaled_font_t *scaled) {
}

void mbe_scaled_font_destroy(mbe_scaled_font_t *scaled) {}
mbe_font_face_t *mbe_font_face_reference(mbe_font_face_t *face) {}
mbe_scaled_font_t *
mbe_scaled_font_create(mbe_font_face_t *face, co_aix fnt_mtx[6],
		       co_aix ctm[6]) {}
mbe_scaled_font_t *mbe_get_scaled_font(mbe_t *canvas) {}
void mbe_scaled_font_text_extents(mbe_scaled_font_t *scaled,
					 const char *txt,
					 mbe_text_extents_t *extents) {}

void mbe_font_face_destroy(mbe_font_face_t *face) {}

void mbe_paint_with_alpha(mbe_t *canvas, co_aix alpha) {
    SkPaint *paint = canvas->paint;
    SkColorFilter *filter;
    SkColor color;

    color = ((uint32_t)(alpha * 255)) << 24;
    filter =
	SkColorFilter::CreatePorterDuffFilter(color,
					      SkPorterDuff::kSrcOver_Mode);
    mbe_paint(canvas);
    
}

void mbe_surface_destroy(mbe_surface_t *surface) {}
void mbe_set_source_rgba(mbe_t *canvas,
				co_aix r, co_aix g, co_aix b, co_aix a) {}
void mbe_set_scaled_font(mbe_t *canvas,
				const mbe_scaled_font_t *scaled) {}
void mbe_set_source_rgb(mbe_t *canvas, co_aix r, co_aix g, co_aix b) {}

void mbe_set_line_width(mbe_t *canvas, co_aix width) {
    canvas->states->line_width = width;
}

mbe_font_face_t *mbe_get_font_face(mbe_t *canvas) {}

void mbe_fill_preserve(mbe_t *canvas) {
    mbe_pattern_t *ptn = canvas->states->ptn;
    SkPaint *paint = canvas->paint;
    SkPath *path = canvas->path;
    SkRegion *saved_clip = NULL;
    co_aix x, y;

    ASSERT(paint);
    ASSERT(ptn);
    ASSERT(path);

    if(!canvas->subpath->isEmpty())
	_update_path(canvas);
    
    _prepare_paint(canvas, SkPaint::kFill_Style);

    canvas->canvas->drawPath(*path, *paint);

    _finish_paint(canvas);
}

void mbe_set_source(mbe_t *canvas, mbe_pattern_t *source) {
    canvas->states->ptn = source;
}

void mbe_reset_clip(mbe_t *canvas) {
    SkRegion clip;

    _canvas_device_region(canvas->canvas, &clip);
    canvas->canvas->setClipRegion(clip);
}

mbe_surface_t *mbe_get_target(mbe_t *canvas) {
    return (mbe_surface_t *)&canvas->canvas->getDevice()->accessBitmap(false);
}

void mbe_close_path(mbe_t *canvas) {
    canvas->subpath->close();
}

void mbe_text_path(mbe_t *canvas, const char *txt) {}

void mbe_rectangle(mbe_t *canvas, co_aix x, co_aix y,
			  co_aix width, co_aix height) {
    SkPath *subpath = canvas->subpath;
    
    subpath->addRect(CO_AIX_2_SKSCALAR(x), CO_AIX_2_SKSCALAR(y),
		     CO_AIX_2_SKSCALAR(x + width),
		     CO_AIX_2_SKSCALAR(y + height));
}

int mbe_in_stroke(mbe_t *canvas, co_aix x, co_aix y) {
    return 0;
}

void mbe_new_path(mbe_t *canvas) {
    canvas->subpath->reset();
}

void mbe_curve_to(mbe_t *canvas, co_aix x1, co_aix y1,
			 co_aix x2, co_aix y2,
			 co_aix x3, co_aix y3) {
    SkPath *subpath = canvas->subpath;

    subpath->cubicTo(CO_AIX_2_SKSCALAR(x1), CO_AIX_2_SKSCALAR(y1),
		     CO_AIX_2_SKSCALAR(x2), CO_AIX_2_SKSCALAR(y2),
		     CO_AIX_2_SKSCALAR(x3), CO_AIX_2_SKSCALAR(y3));
}

void mbe_restore(mbe_t *canvas) {
    struct _mbe_states_t *states;

    _update_path(canvas);
    
    states = canvas->states;
    ASSERT(states->next);
    canvas->states = states->next;
    free(states);
}

void mbe_move_to(mbe_t *canvas, co_aix x, co_aix y) {
    canvas->subpath->moveTo(CO_AIX_2_SKSCALAR(x),
			 CO_AIX_2_SKSCALAR(y));
}

void mbe_line_to(mbe_t *canvas, co_aix x, co_aix y) {
    canvas->subpath->lineTo(CO_AIX_2_SKSCALAR(x),
			    CO_AIX_2_SKSCALAR(y));
}

int mbe_in_fill(mbe_t *canvas, co_aix x, co_aix y) {
    SkRegion region, dev_region;
    bool in_fill;

    if(!canvas->subpath->isEmpty())
	_update_path(canvas);
    
    _canvas_device_region(canvas->canvas, &dev_region);
    region.setPath(*canvas->path, dev_region);
    
    in_fill = region.contains(x, y);

    return in_fill;
}

void mbe_stroke(mbe_t *canvas) {
    SkPath *path = canvas->path;
    SkPaint *paint = canvas->paint;

    ASSERT(ptn);
    ASSERT(path);
    ASSERT(paint);

    if(!canvas->subpath->isEmpty())
	_update_path(canvas);

    _prepare_paint(canvas, SkPaint::kStroke_Style);

    canvas->canvas->drawPath(*path, *paint);

    _finish_paint(canvas);

    path->reset();
}

mbe_t *mbe_create(mbe_surface_t *target) {
    mbe_t *mbe;
    struct _mbe_states_t *states;
    SkBitmap *bitmap = (SkBitmap *)target;

    mbe = (mbe_t *)malloc(sizeof(mbe_t));
    if(mbe == NULL)
	return NULL;
    
    mbe->states = (struct _mbe_states_t *)
	malloc(sizeof(struct _mbe_states_t));
    states = mbe->states;
    if(states == NULL) {
	free(mbe);
	return NULL;
    }
    
    mbe->canvas = new SkCanvas(*bitmap);
    mbe->path = new SkPath();
    mbe->subpath = new SkPath();
    mbe->saved_region = new SkRegion();
    mbe->paint = new SkPaint();
    states->ptn = NULL;
    states->ptn_owned = 0;
    states->line_width = 0;
    states->next = NULL;

    if(mbe->canvas == NULL || mbe->path == NULL ||
       mbe->subpath == NULL || mbe->paint == NULL ||
       mbe->saved_region == NULL)
	goto fail;

    memcpy(states->matrix, id_matrix, sizeof(co_aix) * 6);
    
    return mbe;

 fail:
    if(mbe->canvas) delete mbe->canvas;
    if(mbe->path) delete mbe->path;
    if(mbe->subpath) delete mbe->subpath;
    if(mbe->paint) delete mbe->paint;
    if(mbe->saved_region) delete mbe->saved_region;
    free(states);
    free(mbe);
    
    return NULL;
}

void mbe_destroy(mbe_t *canvas) {
    struct _mbe_states_t *states;
    
    delete canvas->canvas;
    delete canvas->path;
    delete canvas->subpath;
    delete canvas->paint;
    delete canvas->saved_region;
    while(canvas->states) {
	states = canvas->states;
	canvas->states = states->next;
	
	if(states->ptn && states->ptn_owned)
	    mbe_pattern_destroy(states->ptn);
	free(states);
    }
    free(canvas);
}

void mbe_paint(mbe_t *canvas) {
    SkPaint *paint = canvas->paint;

    ASSERT(paint);
    
    _prepare_paint(canvas, SkPaint::kFill_Style);
    
    canvas->canvas->drawPaint(*paint);

    _finish_paint(canvas);
}

void mbe_save(mbe_t *canvas) {
    struct _mbe_states_t *states;

    states = (struct _mbe_states_t *)malloc(sizeof(struct _mbe_states_t));
    ASSERT(states);
    
    memcpy(states, canvas->states, sizeof(struct _mbe_states_t));
    states->next = canvas->states;
    canvas->states = states;
}

void mbe_fill(mbe_t *canvas) {
    mbe_fill_preserve(canvas);
    canvas->path->reset();
}

void mbe_clip(mbe_t *canvas) {
    if(!canvas->subpath->isEmpty())
	_update_path(canvas);
    
    canvas->canvas->clipPath(*canvas->path, SkRegion::kIntersect_Op);
    canvas->path->reset();
}

mbe_font_face_t * mbe_query_font_face(const char *family,
					     int slant, int weight) {}
void mbe_free_font_face(mbe_font_face_t *face) {}

void mbe_clear(mbe_t *canvas) {
    SkColor color = 0;

    canvas->canvas->drawColor(color, SkPorterDuff::kClear_Mode);
}

void mbe_copy_source(mbe_t *canvas) {
    SkPaint *paint = canvas->paint;
    SkXfermode *mode;

    _prepare_paint(canvas, SkPaint::kFill_Style);
    mode = SkPorterDuff::CreateXfermode(SkPorterDuff::kSrc_Mode);
    paint->setXfermode(mode);
    mode->unref();

    canvas->canvas->drawPaint(*paint);

    _finish_paint(canvas);
}

void mbe_transform(mbe_t *mbe, co_aix matrix[6]) {
    _update_path(mbe);
    
    matrix_mul(matrix, mbe->states->matrix, mbe->states->matrix);
}

void mbe_arc(mbe_t *mbe, co_aix x, co_aix y, co_aix radius,
		    co_aix angle_start, co_aix angle_stop) {
    SkPoint point;
    SkPath *subpath = mbe->subpath;
    SkRect rect;
    SkScalar x0, y0;
    SkScalar ang_start, ang_stop;
    SkScalar sweep;
    SkScalar r;			/* radius */

    subpath->getLastPt(&point);
    x0 = point.fX;
    y0 = point.fX;
    r = CO_AIX_2_SKSCALAR(radius);
    ang_start = CO_AIX_2_SKSCALAR(angle_start * 180 / PI);
    ang_stop = CO_AIX_2_SKSCALAR(angle_stop * 180 / PI);
    
    /* Skia can only draw an arc in clockwise directly.  We negative
     * start and stop point to draw the arc in the mirror along x-axis
     * in a sub-path.  Then, the sub-path are reflected along x-axis,
     * again.  We get a right path, and add it to the path of mbe_t.
     */
    if(ang_start > ang_stop) {
	SkPath tmppath;
	SkMatrix matrix;
	co_aix reflect[6] = { 1, 0, 0,
			      0, -1, 0};
	
	rect.set(-r, -r, r, r);
	sweep = ang_start - ang_stop;
	tmppath.arcTo(rect, -ang_start, sweep, false);

	reflect[2] = x;
	reflect[5] = y;
	MB_MATRIX_2_SKMATRIX(matrix, reflect);
	subpath->addPath(tmppath, matrix);
    } else {
	rect.set(x0 - r, y0 - r, x0 + r, y0 + r);
	sweep = ang_stop - ang_start;
	subpath->arcTo(rect, ang_start, sweep, false);
    }
}


C_END