scummvm/graphics/VectorRendererSpec.cpp
2012-02-20 22:38:35 +01:00

2099 lines
59 KiB
C++

/* ScummVM - Graphic Adventure Engine
*
* ScummVM is the legal property of its developers, whose names
* are too numerous to list here. Please refer to the COPYRIGHT
* file distributed with this source distribution.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*
*/
#include "common/util.h"
#include "common/system.h"
#include "common/frac.h"
#include "graphics/surface.h"
#include "graphics/colormasks.h"
#include "gui/ThemeEngine.h"
#include "graphics/VectorRenderer.h"
#include "graphics/VectorRendererSpec.h"
#define VECTOR_RENDERER_FAST_TRIANGLES
/** Fixed point SQUARE ROOT **/
inline frac_t fp_sqroot(uint32 x) {
#if 0
// Use the FPU to compute the square root and then convert it to fixed
// point data. On systems with a fast FPU, this can be a lot faster than
// the integer based code below - on my system roughly 50x! However, on
// systems without an FPU, the converse might be true.
// For now, we only use the integer based code.
return doubleToFrac(sqrt((double)x));
#else
// The code below wants to use a lot of registers, which is not good on
// x86 processors. By taking advantage of the fact the the input value is
// an integer, it might be possible to improve this. Furthermore, we could
// take advantage of the fact that we call this function several times on
// decreasing values. By feeding it the sqrt of the previous old x, as well
// as the old x, it should be possible to compute the correct sqrt with far
// fewer than 23 iterations.
register uint32 root, remHI, remLO, testDIV, count;
root = 0;
remHI = 0;
remLO = x << 16;
count = 23;
do {
remHI = (remHI << 2) | (remLO >> 30);
remLO <<= 2;
root <<= 1;
testDIV = (root << 1) + 1;
if (remHI >= testDIV) {
remHI -= testDIV;
root++;
}
} while (count--);
return root;
#endif
}
/*
HELPER MACROS for Bresenham's circle drawing algorithm
Note the proper spelling on this header.
*/
#define BE_ALGORITHM() do { \
if (f >= 0) { \
y--; \
ddF_y += 2; \
f += ddF_y; \
py -= pitch; \
} \
px += pitch; \
ddF_x += 2; \
f += ddF_x + 1; \
} while(0)
#define BE_DRAWCIRCLE_TOP(ptr1,ptr2,x,y,px,py) do { \
*(ptr1 + (y) - (px)) = color; \
*(ptr1 + (x) - (py)) = color; \
*(ptr2 - (x) - (py)) = color; \
*(ptr2 - (y) - (px)) = color; \
} while (0)
#define BE_DRAWCIRCLE_BOTTOM(ptr3,ptr4,x,y,px,py) do { \
*(ptr3 - (y) + (px)) = color; \
*(ptr3 - (x) + (py)) = color; \
*(ptr4 + (x) + (py)) = color; \
*(ptr4 + (y) + (px)) = color; \
} while (0)
#define BE_DRAWCIRCLE(ptr1,ptr2,ptr3,ptr4,x,y,px,py) do { \
BE_DRAWCIRCLE_TOP(ptr1,ptr2,x,y,px,py); \
BE_DRAWCIRCLE_BOTTOM(ptr3,ptr4,x,y,px,py); \
} while (0)
#define BE_DRAWCIRCLE_BCOLOR(ptr1,ptr2,ptr3,ptr4,x,y,px,py) do { \
*(ptr1 + (y) - (px)) = color1; \
*(ptr1 + (x) - (py)) = color1; \
*(ptr2 - (x) - (py)) = color1; \
*(ptr2 - (y) - (px)) = color1; \
*(ptr3 - (y) + (px)) = color1; \
*(ptr3 - (x) + (py)) = color1; \
*(ptr4 + (x) + (py)) = color2; \
*(ptr4 + (y) + (px)) = color2; \
} while (0)
#define BE_DRAWCIRCLE_XCOLOR_TOP(ptr1,ptr2,x,y,px,py) do { \
*(ptr1 + (y) - (px)) = color1; \
*(ptr1 + (x) - (py)) = color2; \
*(ptr2 - (x) - (py)) = color2; \
*(ptr2 - (y) - (px)) = color1; \
} while (0)
#define BE_DRAWCIRCLE_XCOLOR_BOTTOM(ptr3,ptr4,x,y,px,py) do { \
*(ptr3 - (y) + (px)) = color3; \
*(ptr3 - (x) + (py)) = color4; \
*(ptr4 + (x) + (py)) = color4; \
*(ptr4 + (y) + (px)) = color3; \
} while (0)
#define BE_DRAWCIRCLE_XCOLOR(ptr1,ptr2,ptr3,ptr4,x,y,px,py) do { \
BE_DRAWCIRCLE_XCOLOR_TOP(ptr1,ptr2,x,y,px,py); \
BE_DRAWCIRCLE_XCOLOR_BOTTOM(ptr3,ptr4,x,y,px,py); \
} while (0)
#define BE_RESET() do { \
f = 1 - r; \
ddF_x = 0; ddF_y = -2 * r; \
x = 0; y = r; px = 0; py = pitch * r; \
} while (0)
#define TRIANGLE_MAINX() \
if (error_term >= 0) { \
ptr_right += pitch; \
ptr_left += pitch; \
error_term += dysub; \
} else { \
error_term += ddy; \
} \
ptr_right++; \
ptr_left--;
#define TRIANGLE_MAINY() \
if (error_term >= 0) { \
ptr_right++; \
ptr_left--; \
error_term += dxsub; \
} else { \
error_term += ddx; \
} \
ptr_right += pitch; \
ptr_left += pitch;
/** HELPER MACROS for WU's circle drawing algorithm **/
#define WU_DRAWCIRCLE_TOP(ptr1,ptr2,x,y,px,py,a) do { \
this->blendPixelPtr(ptr1 + (y) - (px), color, a); \
this->blendPixelPtr(ptr1 + (x) - (py), color, a); \
this->blendPixelPtr(ptr2 - (x) - (py), color, a); \
this->blendPixelPtr(ptr2 - (y) - (px), color, a); \
} while (0)
#define WU_DRAWCIRCLE_BOTTOM(ptr3,ptr4,x,y,px,py,a) do { \
this->blendPixelPtr(ptr3 - (y) + (px), color, a); \
this->blendPixelPtr(ptr3 - (x) + (py), color, a); \
this->blendPixelPtr(ptr4 + (x) + (py), color, a); \
this->blendPixelPtr(ptr4 + (y) + (px), color, a); \
} while (0)
#define WU_DRAWCIRCLE(ptr1,ptr2,ptr3,ptr4,x,y,px,py,a) do { \
WU_DRAWCIRCLE_TOP(ptr1,ptr2,x,y,px,py,a); \
WU_DRAWCIRCLE_BOTTOM(ptr3,ptr4,x,y,px,py,a); \
} while (0)
// Color depending on y
// Note: this is only for the outer pixels
#define WU_DRAWCIRCLE_XCOLOR_TOP(ptr1,ptr2,x,y,px,py,a,func) do { \
this->func(ptr1 + (y) - (px), color1, a); \
this->func(ptr1 + (x) - (py), color2, a); \
this->func(ptr2 - (x) - (py), color2, a); \
this->func(ptr2 - (y) - (px), color1, a); \
} while (0)
#define WU_DRAWCIRCLE_XCOLOR_BOTTOM(ptr3,ptr4,x,y,px,py,a,func) do { \
this->func(ptr3 - (y) + (px), color3, a); \
this->func(ptr3 - (x) + (py), color4, a); \
this->func(ptr4 + (x) + (py), color4, a); \
this->func(ptr4 + (y) + (px), color3, a); \
} while (0)
#define WU_DRAWCIRCLE_XCOLOR(ptr1,ptr2,ptr3,ptr4,x,y,px,py,a,func) do { \
WU_DRAWCIRCLE_XCOLOR_TOP(ptr1,ptr2,x,y,px,py,a,func); \
WU_DRAWCIRCLE_XCOLOR_BOTTOM(ptr3,ptr4,x,y,px,py,a,func); \
} while (0)
// Color depending on corner (tl,tr,bl: color1, br: color2)
// Note: this is only for the outer pixels
#define WU_DRAWCIRCLE_BCOLOR(ptr1,ptr2,ptr3,ptr4,x,y,px,py,a) do { \
this->blendPixelPtr(ptr1 + (y) - (px), color1, a); \
this->blendPixelPtr(ptr1 + (x) - (py), color1, a); \
this->blendPixelPtr(ptr2 - (x) - (py), color1, a); \
this->blendPixelPtr(ptr2 - (y) - (px), color1, a); \
this->blendPixelPtr(ptr3 - (y) + (px), color1, a); \
this->blendPixelPtr(ptr3 - (x) + (py), color1, a); \
this->blendPixelPtr(ptr4 + (x) + (py), color2, a); \
this->blendPixelPtr(ptr4 + (y) + (px), color2, a); \
} while (0)
// optimized Wu's algorithm
#define WU_ALGORITHM() do { \
oldT = T; \
T = fp_sqroot(rsq - y*y) ^ 0xFFFF; \
py += pitch; \
if (T < oldT) { \
x--; px -= pitch; \
} \
a2 = (T >> 8); \
a1 = ~a2; \
} while (0)
namespace Graphics {
/**
* Fills several pixels in a row with a given color.
*
* This is a replacement function for Common::fill, using an unrolled
* loop to maximize performance on most architectures.
* This function may (and should) be overloaded in any child renderers
* for portable platforms with platform-specific assembly code.
*
* This fill operation is extensively used throughout the renderer, so this
* counts as one of the main bottlenecks. Please replace it with assembly
* when possible!
*
* @param first Pointer to the first pixel to fill.
* @param last Pointer to the last pixel to fill.
* @param color Color of the pixel
*/
template<typename PixelType>
void colorFill(PixelType *first, PixelType *last, PixelType color) {
register int count = (last - first);
if (!count)
return;
register int n = (count + 7) >> 3;
switch (count % 8) {
case 0: do {
*first++ = color;
case 7: *first++ = color;
case 6: *first++ = color;
case 5: *first++ = color;
case 4: *first++ = color;
case 3: *first++ = color;
case 2: *first++ = color;
case 1: *first++ = color;
} while (--n > 0);
}
}
VectorRenderer *createRenderer(int mode) {
#ifdef DISABLE_FANCY_THEMES
assert(mode == GUI::ThemeEngine::kGfxStandard16bit);
#endif
PixelFormat format = g_system->getOverlayFormat();
switch (mode) {
case GUI::ThemeEngine::kGfxStandard16bit:
return new VectorRendererSpec<OverlayColor>(format);
#ifndef DISABLE_FANCY_THEMES
case GUI::ThemeEngine::kGfxAntialias16bit:
return new VectorRendererAA<OverlayColor>(format);
#endif
default:
break;
}
return 0;
}
template<typename PixelType>
VectorRendererSpec<PixelType>::
VectorRendererSpec(PixelFormat format) :
_format(format),
_redMask((0xFF >> format.rLoss) << format.rShift),
_greenMask((0xFF >> format.gLoss) << format.gShift),
_blueMask((0xFF >> format.bLoss) << format.bShift),
_alphaMask((0xFF >> format.aLoss) << format.aShift) {
_bitmapAlphaColor = _format.RGBToColor(255, 0, 255);
}
/****************************
* Gradient-related methods *
****************************/
template<typename PixelType>
void VectorRendererSpec<PixelType>::
setGradientColors(uint8 r1, uint8 g1, uint8 b1, uint8 r2, uint8 g2, uint8 b2) {
_gradientEnd = _format.RGBToColor(r2, g2, b2);
_gradientStart = _format.RGBToColor(r1, g1, b1);
_gradientBytes[0] = (_gradientEnd & _redMask) - (_gradientStart & _redMask);
_gradientBytes[1] = (_gradientEnd & _greenMask) - (_gradientStart & _greenMask);
_gradientBytes[2] = (_gradientEnd & _blueMask) - (_gradientStart & _blueMask);
}
template<typename PixelType>
inline PixelType VectorRendererSpec<PixelType>::
calcGradient(uint32 pos, uint32 max) {
PixelType output = 0;
pos = (MIN(pos * Base::_gradientFactor, max) << 12) / max;
output |= ((_gradientStart & _redMask) + ((_gradientBytes[0] * pos) >> 12)) & _redMask;
output |= ((_gradientStart & _greenMask) + ((_gradientBytes[1] * pos) >> 12)) & _greenMask;
output |= ((_gradientStart & _blueMask) + ((_gradientBytes[2] * pos) >> 12)) & _blueMask;
output |= _alphaMask;
return output;
}
template<typename PixelType>
void VectorRendererSpec<PixelType>::
precalcGradient(int h) {
PixelType prevcolor = 0, color;
_gradCache.resize(0);
_gradIndexes.resize(0);
for (int i = 0; i < h + 2; i++) {
color = calcGradient(i, h);
if (color != prevcolor || i == 0 || i > h - 1) {
prevcolor = color;
_gradCache.push_back(color);
_gradIndexes.push_back(i);
}
}
}
template<typename PixelType>
void VectorRendererSpec<PixelType>::
gradientFill(PixelType *ptr, int width, int x, int y) {
bool ox = ((y & 1) == 1);
int stripSize;
int curGrad = 0;
while (_gradIndexes[curGrad + 1] <= y)
curGrad++;
stripSize = _gradIndexes[curGrad + 1] - _gradIndexes[curGrad];
int grad = (((y - _gradIndexes[curGrad]) % stripSize) << 2) / stripSize;
// Dithering:
// +--+ +--+ +--+ +--+
// | | | | | *| | *|
// | | | *| |* | |**|
// +--+ +--+ +--+ +--+
// 0 1 2 3
if (grad == 0 ||
_gradCache[curGrad] == _gradCache[curGrad + 1] || // no color change
stripSize < 2) { // the stip is small
colorFill<PixelType>(ptr, ptr + width, _gradCache[curGrad]);
} else if (grad == 3 && ox) {
colorFill<PixelType>(ptr, ptr + width, _gradCache[curGrad + 1]);
} else {
for (int j = x; j < x + width; j++, ptr++) {
bool oy = ((j & 1) == 1);
if ((ox && oy) ||
((grad == 2 || grad == 3) && ox && !oy) ||
(grad == 3 && oy))
*ptr = _gradCache[curGrad + 1];
else
*ptr = _gradCache[curGrad];
}
}
}
template<typename PixelType>
void VectorRendererSpec<PixelType>::
fillSurface() {
byte *ptr = (byte *)_activeSurface->getBasePtr(0, 0);
int h = _activeSurface->h;
int pitch = _activeSurface->pitch;
if (Base::_fillMode == kFillBackground) {
colorFill<PixelType>((PixelType *)ptr, (PixelType *)(ptr + pitch * h), _bgColor);
} else if (Base::_fillMode == kFillForeground) {
colorFill<PixelType>((PixelType *)ptr, (PixelType *)(ptr + pitch * h), _fgColor);
} else if (Base::_fillMode == kFillGradient) {
precalcGradient(h);
for (int i = 0; i < h; i++) {
gradientFill((PixelType *)ptr, _activeSurface->w, 0, i);
ptr += pitch;
}
}
}
template<typename PixelType>
void VectorRendererSpec<PixelType>::
copyFrame(OSystem *sys, const Common::Rect &r) {
sys->copyRectToOverlay(
(const OverlayColor *)_activeSurface->getBasePtr(r.left, r.top),
_activeSurface->pitch / _activeSurface->format.bytesPerPixel,
r.left, r.top, r.width(), r.height()
);
}
template<typename PixelType>
void VectorRendererSpec<PixelType>::
blitSurface(const Graphics::Surface *source, const Common::Rect &r) {
assert(source->w == _activeSurface->w && source->h == _activeSurface->h);
byte *dst_ptr = (byte *)_activeSurface->getBasePtr(r.left, r.top);
const byte *src_ptr = (const byte *)source->getBasePtr(r.left, r.top);
const int dst_pitch = _activeSurface->pitch;
const int src_pitch = source->pitch;
int h = r.height();
const int w = r.width() * sizeof(PixelType);
while (h--) {
memcpy(dst_ptr, src_ptr, w);
dst_ptr += dst_pitch;
src_ptr += src_pitch;
}
}
template<typename PixelType>
void VectorRendererSpec<PixelType>::
blitSubSurface(const Graphics::Surface *source, const Common::Rect &r) {
byte *dst_ptr = (byte *)_activeSurface->getBasePtr(r.left, r.top);
const byte *src_ptr = (const byte *)source->getBasePtr(0, 0);
const int dst_pitch = _activeSurface->pitch;
const int src_pitch = source->pitch;
int h = r.height();
const int w = r.width() * sizeof(PixelType);
while (h--) {
memcpy(dst_ptr, src_ptr, w);
dst_ptr += dst_pitch;
src_ptr += src_pitch;
}
}
template<typename PixelType>
void VectorRendererSpec<PixelType>::
blitAlphaBitmap(const Graphics::Surface *source, const Common::Rect &r) {
int16 x = r.left;
int16 y = r.top;
if (r.width() > source->w)
x = x + (r.width() >> 1) - (source->w >> 1);
if (r.height() > source->h)
y = y + (r.height() >> 1) - (source->h >> 1);
PixelType *dst_ptr = (PixelType *)_activeSurface->getBasePtr(x, y);
const PixelType *src_ptr = (const PixelType *)source->getBasePtr(0, 0);
int dst_pitch = _activeSurface->pitch / _activeSurface->format.bytesPerPixel;
int src_pitch = source->pitch / source->format.bytesPerPixel;
int w, h = source->h;
while (h--) {
w = source->w;
while (w--) {
if (*src_ptr != _bitmapAlphaColor)
*dst_ptr = *src_ptr;
dst_ptr++;
src_ptr++;
}
dst_ptr = dst_ptr - source->w + dst_pitch;
src_ptr = src_ptr - source->w + src_pitch;
}
}
template<typename PixelType>
void VectorRendererSpec<PixelType>::
applyScreenShading(GUI::ThemeEngine::ShadingStyle shadingStyle) {
int pixels = _activeSurface->w * _activeSurface->h;
PixelType *ptr = (PixelType *)_activeSurface->getBasePtr(0, 0);
uint8 r, g, b;
uint lum;
// Mask to clear the last bit of every color component and all unused bits
const uint32 colorMask = ~((1 << _format.rShift) | (1 << _format.gShift) | (1 << _format.bShift) // R/G/B components
| (_format.aLoss == 8 ? 0 : (1 << _format.aShift)) // Alpha component
| ~(_alphaMask | _redMask | _greenMask | _blueMask)); // All unused bits
if (shadingStyle == GUI::ThemeEngine::kShadingDim) {
// TODO: Check how this interacts with kFeatureOverlaySupportsAlpha
for (int i = 0; i < pixels; ++i) {
*ptr = ((*ptr & colorMask) >> 1) | _alphaMask;
++ptr;
}
} else if (shadingStyle == GUI::ThemeEngine::kShadingLuminance) {
while (pixels--) {
_format.colorToRGB(*ptr, r, g, b);
lum = (r >> 2) + (g >> 1) + (b >> 3);
*ptr++ = _format.RGBToColor(lum, lum, lum);
}
}
}
template<typename PixelType>
inline void VectorRendererSpec<PixelType>::
blendPixelPtr(PixelType *ptr, PixelType color, uint8 alpha) {
int idst = *ptr;
int isrc = color;
*ptr = (PixelType)(
(_redMask & ((idst & _redMask) +
((int)(((int)(isrc & _redMask) -
(int)(idst & _redMask)) * alpha) >> 8))) |
(_greenMask & ((idst & _greenMask) +
((int)(((int)(isrc & _greenMask) -
(int)(idst & _greenMask)) * alpha) >> 8))) |
(_blueMask & ((idst & _blueMask) +
((int)(((int)(isrc & _blueMask) -
(int)(idst & _blueMask)) * alpha) >> 8))) |
(idst & _alphaMask));
}
template<typename PixelType>
inline void VectorRendererSpec<PixelType>::
blendPixelDestAlphaPtr(PixelType *ptr, PixelType color, uint8 alpha) {
int idst = *ptr;
// This function is only used for corner pixels in rounded rectangles, so
// the performance hit of this if shouldn't be too high.
// We're also ignoring the cases where dst has intermediate alpha.
if ((idst & _alphaMask) == 0) {
// set color and alpha channels
*ptr = (PixelType)(color & (_redMask | _greenMask | _blueMask)) |
((alpha >> _format.aLoss) << _format.aShift);
} else {
// blend color with background
blendPixelPtr(ptr, color, alpha);
}
}
template<typename PixelType>
inline void VectorRendererSpec<PixelType>::
darkenFill(PixelType *ptr, PixelType *end) {
PixelType mask = (PixelType)((3 << _format.rShift) | (3 << _format.gShift) | (3 << _format.bShift));
if (!g_system->hasFeature(OSystem::kFeatureOverlaySupportsAlpha)) {
// !kFeatureOverlaySupportsAlpha (but might have alpha bits)
while (ptr != end) {
*ptr = ((*ptr & ~mask) >> 2) | _alphaMask;
++ptr;
}
} else {
// kFeatureOverlaySupportsAlpha
// assuming at least 3 alpha bits
mask |= 3 << _format.aShift;
PixelType addA = (PixelType)(255 >> _format.aLoss) << _format.aShift;
addA -= (addA >> 2);
while (ptr != end) {
// Darken the colour, and increase the alpha
// (0% -> 75%, 100% -> 100%)
*ptr = (PixelType)(((*ptr & ~mask) >> 2) + addA);
++ptr;
}
}
}
/********************************************************************
********************************************************************
* Primitive shapes drawing - Public API calls - VectorRendererSpec *
********************************************************************
********************************************************************/
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawString(const Graphics::Font *font, const Common::String &text, const Common::Rect &area,
Graphics::TextAlign alignH, GUI::ThemeEngine::TextAlignVertical alignV, int deltax, bool ellipsis) {
int offset = area.top;
if (font->getFontHeight() < area.height()) {
switch (alignV) {
case GUI::ThemeEngine::kTextAlignVCenter:
offset = area.top + ((area.height() - font->getFontHeight()) >> 1);
break;
case GUI::ThemeEngine::kTextAlignVBottom:
offset = area.bottom - font->getFontHeight();
break;
default:
break;
}
}
font->drawString(_activeSurface, text, area.left, offset, area.width() - deltax, _fgColor, alignH, deltax, ellipsis);
}
/** LINES **/
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawLine(int x1, int y1, int x2, int y2) {
x1 = CLIP(x1, 0, (int)Base::_activeSurface->w);
x2 = CLIP(x2, 0, (int)Base::_activeSurface->w);
y1 = CLIP(y1, 0, (int)Base::_activeSurface->h);
y2 = CLIP(y2, 0, (int)Base::_activeSurface->h);
// we draw from top to bottom
if (y2 < y1) {
SWAP(x1, x2);
SWAP(y1, y2);
}
int dx = ABS(x2 - x1);
int dy = ABS(y2 - y1);
// this is a point, not a line. stoopid.
if (dy == 0 && dx == 0)
return;
if (Base::_strokeWidth == 0)
return;
PixelType *ptr = (PixelType *)_activeSurface->getBasePtr(x1, y1);
int pitch = _activeSurface->pitch / _activeSurface->format.bytesPerPixel;
int st = Base::_strokeWidth >> 1;
if (dy == 0) { // horizontal lines
// these can be filled really fast with a single memset.
colorFill<PixelType>(ptr, ptr + dx + 1, (PixelType)_fgColor);
for (int i = 0, p = pitch; i < st; ++i, p += pitch) {
colorFill<PixelType>(ptr + p, ptr + dx + 1 + p, (PixelType)_fgColor);
colorFill<PixelType>(ptr - p, ptr + dx + 1 - p, (PixelType)_fgColor);
}
} else if (dx == 0) { // vertical lines
// these ones use a static pitch increase.
while (y1++ <= y2) {
colorFill<PixelType>(ptr - st, ptr + st, (PixelType)_fgColor);
ptr += pitch;
}
} else if (ABS(dx) == ABS(dy)) { // diagonal lines
// these ones also use a fixed pitch increase
pitch += (x2 > x1) ? 1 : -1;
while (dy--) {
colorFill<PixelType>(ptr - st, ptr + st, (PixelType)_fgColor);
ptr += pitch;
}
} else { // generic lines, use the standard algorithm...
drawLineAlg(x1, y1, x2, y2, dx, dy, (PixelType)_fgColor);
}
}
/** CIRCLES **/
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawCircle(int x, int y, int r) {
if (x + r > Base::_activeSurface->w || y + r > Base::_activeSurface->h ||
x - r < 0 || y - r < 0 || x == 0 || y == 0 || r <= 0)
return;
if (Base::_fillMode != kFillDisabled && Base::_shadowOffset
&& x + r + Base::_shadowOffset < Base::_activeSurface->w
&& y + r + Base::_shadowOffset < Base::_activeSurface->h) {
drawCircleAlg(x + Base::_shadowOffset + 1, y + Base::_shadowOffset + 1, r, 0, kFillForeground);
}
switch (Base::_fillMode) {
case kFillDisabled:
if (Base::_strokeWidth)
drawCircleAlg(x, y, r, _fgColor, kFillDisabled);
break;
case kFillForeground:
drawCircleAlg(x, y, r, _fgColor, kFillForeground);
break;
case kFillBackground:
if (Base::_strokeWidth > 1) {
drawCircleAlg(x, y, r, _fgColor, kFillForeground);
drawCircleAlg(x, y, r - Base::_strokeWidth, _bgColor, kFillBackground);
} else {
drawCircleAlg(x, y, r, _bgColor, kFillBackground);
drawCircleAlg(x, y, r, _fgColor, kFillDisabled);
}
break;
case kFillGradient:
break;
}
}
/** SQUARES **/
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawSquare(int x, int y, int w, int h) {
if (x + w > Base::_activeSurface->w || y + h > Base::_activeSurface->h ||
w <= 0 || h <= 0 || x < 0 || y < 0)
return;
if (Base::_fillMode != kFillDisabled && Base::_shadowOffset
&& x + w + Base::_shadowOffset < Base::_activeSurface->w
&& y + h + Base::_shadowOffset < Base::_activeSurface->h) {
drawSquareShadow(x, y, w, h, Base::_shadowOffset);
}
switch (Base::_fillMode) {
case kFillDisabled:
if (Base::_strokeWidth)
drawSquareAlg(x, y, w, h, _fgColor, kFillDisabled);
break;
case kFillForeground:
drawSquareAlg(x, y, w, h, _fgColor, kFillForeground);
break;
case kFillBackground:
drawSquareAlg(x, y, w, h, _bgColor, kFillBackground);
drawSquareAlg(x, y, w, h, _fgColor, kFillDisabled);
break;
case kFillGradient:
VectorRendererSpec::drawSquareAlg(x, y, w, h, 0, kFillGradient);
if (Base::_strokeWidth)
drawSquareAlg(x, y, w, h, _fgColor, kFillDisabled);
break;
}
}
/** ROUNDED SQUARES **/
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawRoundedSquare(int x, int y, int r, int w, int h) {
if (x + w > Base::_activeSurface->w || y + h > Base::_activeSurface->h ||
w <= 0 || h <= 0 || x < 0 || y < 0 || r <= 0)
return;
if ((r * 2) > w || (r * 2) > h)
r = MIN(w /2, h / 2);
if (r <= 0)
return;
if (Base::_fillMode != kFillDisabled && Base::_shadowOffset
&& x + w + Base::_shadowOffset + 1 < Base::_activeSurface->w
&& y + h + Base::_shadowOffset + 1 < Base::_activeSurface->h) {
drawRoundedSquareShadow(x, y, r, w, h, Base::_shadowOffset);
}
drawRoundedSquareAlg(x, y, r, w, h, _fgColor, Base::_fillMode);
}
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawTab(int x, int y, int r, int w, int h) {
if (x + w > Base::_activeSurface->w || y + h > Base::_activeSurface->h ||
w <= 0 || h <= 0 || x < 0 || y < 0 || r > w || r > h)
return;
if (r == 0 && Base::_bevel > 0) {
drawBevelTabAlg(x, y, w, h, Base::_bevel, _bevelColor, _fgColor, (Base::_dynamicData >> 16), (Base::_dynamicData & 0xFFFF));
return;
}
if (r == 0) return;
switch (Base::_fillMode) {
case kFillDisabled:
// FIXME: Implement this
return;
case kFillGradient:
case kFillBackground:
// FIXME: This is broken for the AA renderer.
// See the rounded rect alg for how to fix it. (The border should
// be drawn before the interior, both inside drawTabAlg.)
drawTabAlg(x, y, w, h, r, (Base::_fillMode == kFillBackground) ? _bgColor : _fgColor, Base::_fillMode);
if (Base::_strokeWidth)
drawTabAlg(x, y, w, h, r, _fgColor, kFillDisabled, (Base::_dynamicData >> 16), (Base::_dynamicData & 0xFFFF));
break;
case kFillForeground:
drawTabAlg(x, y, w, h, r, (Base::_fillMode == kFillBackground) ? _bgColor : _fgColor, Base::_fillMode);
break;
}
}
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawTriangle(int x, int y, int w, int h, TriangleOrientation orient) {
if (x + w > Base::_activeSurface->w || y + h > Base::_activeSurface->h)
return;
PixelType color = 0;
if (Base::_strokeWidth <= 1) {
if (Base::_fillMode == kFillForeground)
color = _fgColor;
else if (Base::_fillMode == kFillBackground)
color = _bgColor;
} else {
if (Base::_fillMode == kFillDisabled)
return;
color = _fgColor;
}
if (Base::_dynamicData != 0)
orient = (TriangleOrientation)Base::_dynamicData;
if (w == h) {
int newW = w;
switch (orient) {
case kTriangleUp:
case kTriangleDown:
//drawTriangleFast(x, y, newW, (orient == kTriangleDown), color, Base::_fillMode);
drawTriangleVertAlg(x, y, newW, newW, (orient == kTriangleDown), color, Base::_fillMode);
break;
case kTriangleLeft:
case kTriangleRight:
case kTriangleAuto:
break;
}
if (Base::_strokeWidth > 0)
if (Base::_fillMode == kFillBackground || Base::_fillMode == kFillGradient) {
//drawTriangleFast(x, y, newW, (orient == kTriangleDown), _fgColor, kFillDisabled);
drawTriangleVertAlg(x, y, newW, newW, (orient == kTriangleDown), color, Base::_fillMode);
}
} else {
int newW = w;
int newH = h;
switch (orient) {
case kTriangleUp:
case kTriangleDown:
drawTriangleVertAlg(x, y, newW, newH, (orient == kTriangleDown), color, Base::_fillMode);
break;
case kTriangleLeft:
case kTriangleRight:
case kTriangleAuto:
break;
}
if (Base::_strokeWidth > 0) {
if (Base::_fillMode == kFillBackground || Base::_fillMode == kFillGradient) {
drawTriangleVertAlg(x, y, newW, newH, (orient == kTriangleDown), _fgColor, kFillDisabled);
}
}
}
}
/********************************************************************
********************************************************************
* Aliased Primitive drawing ALGORITHMS - VectorRendererSpec
********************************************************************
********************************************************************/
/** TAB ALGORITHM - NON AA */
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawTabAlg(int x1, int y1, int w, int h, int r, PixelType color, VectorRenderer::FillMode fill_m, int baseLeft, int baseRight) {
int f, ddF_x, ddF_y;
int x, y, px, py;
int pitch = _activeSurface->pitch / _activeSurface->format.bytesPerPixel;
int sw = 0, sp = 0, hp = 0;
PixelType *ptr_tl = (PixelType *)Base::_activeSurface->getBasePtr(x1 + r, y1 + r);
PixelType *ptr_tr = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w - r, y1 + r);
PixelType *ptr_fill = (PixelType *)Base::_activeSurface->getBasePtr(x1, y1);
int real_radius = r;
int short_h = h - r + 2;
int long_h = h;
if (fill_m == kFillDisabled) {
while (sw++ < Base::_strokeWidth) {
colorFill<PixelType>(ptr_fill + sp + r, ptr_fill + w + 1 + sp - r, color);
colorFill<PixelType>(ptr_fill + hp - sp + r, ptr_fill + w + hp + 1 - sp - r, color);
sp += pitch;
BE_RESET();
r--;
while (x++ < y) {
BE_ALGORITHM();
BE_DRAWCIRCLE_TOP(ptr_tr, ptr_tl, x, y, px, py);
if (Base::_strokeWidth > 1)
BE_DRAWCIRCLE_TOP(ptr_tr, ptr_tl, x, y, px - pitch, py);
}
}
ptr_fill += pitch * real_radius;
while (short_h--) {
colorFill<PixelType>(ptr_fill, ptr_fill + Base::_strokeWidth, color);
colorFill<PixelType>(ptr_fill + w - Base::_strokeWidth + 1, ptr_fill + w + 1, color);
ptr_fill += pitch;
}
if (baseLeft) {
sw = 0;
ptr_fill = (PixelType *)Base::_activeSurface->getBasePtr(x1, y1 + h + 1);
while (sw++ < Base::_strokeWidth) {
colorFill<PixelType>(ptr_fill - baseLeft, ptr_fill, color);
ptr_fill += pitch;
}
}
if (baseRight) {
sw = 0;
ptr_fill = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w, y1 + h + 1);
while (sw++ < Base::_strokeWidth) {
colorFill<PixelType>(ptr_fill, ptr_fill + baseRight, color);
ptr_fill += pitch;
}
}
} else {
BE_RESET();
precalcGradient(long_h);
PixelType color1, color2;
color1 = color2 = color;
while (x++ < y) {
BE_ALGORITHM();
if (fill_m == kFillGradient) {
color1 = calcGradient(real_radius - x, long_h);
color2 = calcGradient(real_radius - y, long_h);
gradientFill(ptr_tl - x - py, w - 2 * r + 2 * x, x1 + r - x - y, real_radius - y);
gradientFill(ptr_tl - y - px, w - 2 * r + 2 * y, x1 + r - y - x, real_radius - x);
BE_DRAWCIRCLE_XCOLOR_TOP(ptr_tr, ptr_tl, x, y, px, py);
} else {
colorFill<PixelType>(ptr_tl - x - py, ptr_tr + x - py, color);
colorFill<PixelType>(ptr_tl - y - px, ptr_tr + y - px, color);
BE_DRAWCIRCLE_TOP(ptr_tr, ptr_tl, x, y, px, py);
}
}
ptr_fill += pitch * r;
while (short_h--) {
if (fill_m == kFillGradient) {
gradientFill(ptr_fill, w + 1, x1, real_radius++);
} else {
colorFill<PixelType>(ptr_fill, ptr_fill + w + 1, color);
}
ptr_fill += pitch;
}
}
}
/** BEVELED TABS FOR CLASSIC THEME **/
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawBevelTabAlg(int x, int y, int w, int h, int bevel, PixelType top_color, PixelType bottom_color, int baseLeft, int baseRight) {
int pitch = _activeSurface->pitch / _activeSurface->format.bytesPerPixel;
int i, j;
PixelType *ptr_left = (PixelType *)_activeSurface->getBasePtr(x, y);
i = bevel;
while (i--) {
colorFill<PixelType>(ptr_left, ptr_left + w, top_color);
ptr_left += pitch;
}
if (baseLeft > 0) {
i = h - bevel;
ptr_left = (PixelType *)_activeSurface->getBasePtr(x, y);
while (i--) {
colorFill<PixelType>(ptr_left, ptr_left + bevel, top_color);
ptr_left += pitch;
}
}
i = h - bevel;
j = bevel - 1;
ptr_left = (PixelType *)_activeSurface->getBasePtr(x + w - bevel, y);
while (i--) {
colorFill<PixelType>(ptr_left + j, ptr_left + bevel, bottom_color);
if (j > 0) j--;
ptr_left += pitch;
}
i = bevel;
ptr_left = (PixelType *)_activeSurface->getBasePtr(x + w - bevel, y + h - bevel);
while (i--) {
colorFill<PixelType>(ptr_left, ptr_left + baseRight + bevel, bottom_color);
if (baseLeft)
colorFill<PixelType>(ptr_left - w - baseLeft + bevel, ptr_left - w + bevel + bevel, top_color);
ptr_left += pitch;
}
}
/** SQUARE ALGORITHM **/
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawSquareAlg(int x, int y, int w, int h, PixelType color, VectorRenderer::FillMode fill_m) {
PixelType *ptr = (PixelType *)_activeSurface->getBasePtr(x, y);
int pitch = _activeSurface->pitch / _activeSurface->format.bytesPerPixel;
int max_h = h;
if (fill_m != kFillDisabled) {
while (h--) {
if (fill_m == kFillGradient)
color = calcGradient(max_h - h, max_h);
colorFill<PixelType>(ptr, ptr + w, color);
ptr += pitch;
}
} else {
int sw = Base::_strokeWidth, sp = 0, hp = pitch * (h - 1);
while (sw--) {
colorFill<PixelType>(ptr + sp, ptr + w + sp, color);
colorFill<PixelType>(ptr + hp - sp, ptr + w + hp - sp, color);
sp += pitch;
}
while (h--) {
colorFill<PixelType>(ptr, ptr + Base::_strokeWidth, color);
colorFill<PixelType>(ptr + w - Base::_strokeWidth, ptr + w, color);
ptr += pitch;
}
}
}
/** SQUARE ALGORITHM **/
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawBevelSquareAlg(int x, int y, int w, int h, int bevel, PixelType top_color, PixelType bottom_color, bool fill) {
int pitch = _activeSurface->pitch / _activeSurface->format.bytesPerPixel;
int height = h;
PixelType *ptr_fill = (PixelType *)_activeSurface->getBasePtr(x, y);
if (fill) {
assert((_bgColor & ~_alphaMask) == 0); // only support black
while (height--) {
darkenFill(ptr_fill, ptr_fill + w);
ptr_fill += pitch;
}
}
int i, j;
x = MAX(x - bevel, 0);
y = MAX(y - bevel, 0);
w = MIN(w + (bevel * 2), (int)_activeSurface->w);
h = MIN(h + (bevel * 2), (int)_activeSurface->h);
PixelType *ptr_left = (PixelType *)_activeSurface->getBasePtr(x, y);
i = bevel;
while (i--) {
colorFill<PixelType>(ptr_left, ptr_left + w, top_color);
ptr_left += pitch;
}
i = h - bevel;
ptr_left = (PixelType *)_activeSurface->getBasePtr(x, y + bevel);
while (i--) {
colorFill<PixelType>(ptr_left, ptr_left + bevel, top_color);
ptr_left += pitch;
}
i = bevel;
ptr_left = (PixelType *)_activeSurface->getBasePtr(x, y + h - bevel);
while (i--) {
colorFill<PixelType>(ptr_left + i, ptr_left + w, bottom_color);
ptr_left += pitch;
}
i = h - bevel;
j = bevel - 1;
ptr_left = (PixelType *)_activeSurface->getBasePtr(x + w - bevel, y);
while (i--) {
colorFill<PixelType>(ptr_left + j, ptr_left + bevel, bottom_color);
if (j > 0) j--;
ptr_left += pitch;
}
}
/** GENERIC LINE ALGORITHM **/
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawLineAlg(int x1, int y1, int x2, int y2, int dx, int dy, PixelType color) {
PixelType *ptr = (PixelType *)_activeSurface->getBasePtr(x1, y1);
int pitch = _activeSurface->pitch / _activeSurface->format.bytesPerPixel;
int xdir = (x2 > x1) ? 1 : -1;
*ptr = (PixelType)color;
if (dx > dy) {
int ddy = dy * 2;
int dysub = ddy - (dx * 2);
int error_term = ddy - dx;
while (dx--) {
if (error_term >= 0) {
ptr += pitch;
error_term += dysub;
} else {
error_term += ddy;
}
ptr += xdir;
*ptr = (PixelType)color;
}
} else {
int ddx = dx * 2;
int dxsub = ddx - (dy * 2);
int error_term = ddx - dy;
while (dy--) {
if (error_term >= 0) {
ptr += xdir;
error_term += dxsub;
} else {
error_term += ddx;
}
ptr += pitch;
*ptr = (PixelType)color;
}
}
ptr = (PixelType *)_activeSurface->getBasePtr(x2, y2);
*ptr = (PixelType)color;
}
/** VERTICAL TRIANGLE DRAWING ALGORITHM **/
/**
FIXED POINT ARITHMETIC
**/
#define FIXED_POINT 1
#if FIXED_POINT
#define ipart(x) ((x) & ~0xFF)
// This is not really correct since gradient is not percentage, but [0..255]
#define rfpart(x) ((0x100 - ((x) & 0xFF)) * 100 >> 8)
//#define rfpart(x) (0x100 - ((x) & 0xFF))
#else
#define ipart(x) ((int)x)
#define round(x) (ipart(x + 0.5))
#define fpart(x) (x - ipart(x))
#define rfpart(x) (int)((1 - fpart(x)) * 100)
#endif
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawTriangleVertAlg(int x1, int y1, int w, int h, bool inverted, PixelType color, VectorRenderer::FillMode fill_m) {
int pitch = _activeSurface->pitch / _activeSurface->format.bytesPerPixel;
int gradient_h = 0;
if (!inverted) {
pitch = -pitch;
y1 += h;
}
PixelType *ptr_right = (PixelType *)_activeSurface->getBasePtr(x1, y1);
PixelType *floor = ptr_right - 1;
PixelType *ptr_left = (PixelType *)_activeSurface->getBasePtr(x1 + w, y1);
int x2 = x1 + w / 2;
int y2 = y1 + h;
#if FIXED_POINT
int dx = (x2 - x1) << 8;
int dy = (y2 - y1) << 8;
if (abs(dx) > abs(dy)) {
#else
double dx = (double)x2 - (double)x1;
double dy = (double)y2 - (double)y1;
if (fabs(dx) > fabs(dy)) {
#endif
while (floor++ != ptr_left)
blendPixelPtr(floor, color, 50);
#if FIXED_POINT
int gradient = (dy << 8) / dx;
int intery = (y1 << 8) + gradient;
#else
double gradient = dy / dx;
double intery = y1 + gradient;
#endif
for (int x = x1 + 1; x < x2; x++) {
#if FIXED_POINT
if (intery + gradient > ipart(intery) + 0x100) {
#else
if (intery + gradient > ipart(intery) + 1) {
#endif
ptr_right++;
ptr_left--;
}
ptr_left += pitch;
ptr_right += pitch;
intery += gradient;
switch (fill_m) {
case kFillDisabled:
*ptr_left = *ptr_right = color;
break;
case kFillForeground:
case kFillBackground:
colorFill<PixelType>(ptr_right + 1, ptr_left, color);
blendPixelPtr(ptr_right, color, rfpart(intery));
blendPixelPtr(ptr_left, color, rfpart(intery));
break;
case kFillGradient:
colorFill<PixelType>(ptr_right, ptr_left, calcGradient(gradient_h++, h));
blendPixelPtr(ptr_right, color, rfpart(intery));
blendPixelPtr(ptr_left, color, rfpart(intery));
break;
}
}
return;
}
#if FIXED_POINT
if (abs(dx) < abs(dy)) {
#else
if (fabs(dx) < fabs(dy)) {
#endif
ptr_left--;
while (floor++ != ptr_left)
blendPixelPtr(floor, color, 50);
#if FIXED_POINT
int gradient = (dx << 8) / (dy + 0x100);
int interx = (x1 << 8) + gradient;
#else
double gradient = dx / (dy+1);
double interx = x1 + gradient;
#endif
for (int y = y1 + 1; y < y2; y++) {
#if FIXED_POINT
if (interx + gradient > ipart(interx) + 0x100) {
#else
if (interx + gradient > ipart(interx) + 1) {
#endif
ptr_right++;
ptr_left--;
}
ptr_left += pitch;
ptr_right += pitch;
interx += gradient;
switch (fill_m) {
case kFillDisabled:
*ptr_left = *ptr_right = color;
break;
case kFillForeground:
case kFillBackground:
colorFill<PixelType>(ptr_right + 1, ptr_left, color);
blendPixelPtr(ptr_right, color, rfpart(interx));
blendPixelPtr(ptr_left, color, rfpart(interx));
break;
case kFillGradient:
colorFill<PixelType>(ptr_right, ptr_left, calcGradient(gradient_h++, h));
blendPixelPtr(ptr_right, color, rfpart(interx));
blendPixelPtr(ptr_left, color, rfpart(interx));
break;
}
}
return;
}
ptr_left--;
while (floor++ != ptr_left)
blendPixelPtr(floor, color, 50);
#if FIXED_POINT
int gradient = (dx / dy) << 8;
int interx = (x1 << 8) + gradient;
#else
double gradient = dx / dy;
double interx = x1 + gradient;
#endif
for (int y = y1 + 1; y < y2; y++) {
ptr_right++;
ptr_left--;
ptr_left += pitch;
ptr_right += pitch;
interx += gradient;
switch (fill_m) {
case kFillDisabled:
*ptr_left = *ptr_right = color;
break;
case kFillForeground:
case kFillBackground:
colorFill<PixelType>(ptr_right + 1, ptr_left, color);
blendPixelPtr(ptr_right, color, rfpart(interx));
blendPixelPtr(ptr_left, color, rfpart(interx));
break;
case kFillGradient:
colorFill<PixelType>(ptr_right, ptr_left, calcGradient(gradient_h++, h));
blendPixelPtr(ptr_right, color, rfpart(interx));
blendPixelPtr(ptr_left, color, rfpart(interx));
break;
}
}
}
/** VERTICAL TRIANGLE DRAWING - FAST VERSION FOR SQUARED TRIANGLES */
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawTriangleFast(int x1, int y1, int size, bool inverted, PixelType color, VectorRenderer::FillMode fill_m) {
int pitch = _activeSurface->pitch / _activeSurface->format.bytesPerPixel;
if (!inverted) {
pitch = -pitch;
y1 += size;
}
int gradient_h = 0;
PixelType *ptr_right = (PixelType *)_activeSurface->getBasePtr(x1, y1);
PixelType *ptr_left = (PixelType *)_activeSurface->getBasePtr(x1 + size, y1);
int x2 = x1 + size / 2;
int y2 = y1 + size;
int deltaX = abs(x2 - x1);
int deltaY = abs(y2 - y1);
int signX = x1 < x2 ? 1 : -1;
int signY = y1 < y2 ? 1 : -1;
int error = deltaX - deltaY;
colorFill<PixelType>(ptr_right, ptr_left, color);
while (1) {
switch (fill_m) {
case kFillDisabled:
*ptr_left = *ptr_right = color;
break;
case kFillForeground:
case kFillBackground:
colorFill<PixelType>(ptr_right, ptr_left, color);
break;
case kFillGradient:
colorFill<PixelType>(ptr_right, ptr_left, calcGradient(gradient_h++, size));
break;
}
if (x1 == x2 && y1 == y2)
break;
int error2 = error * 2;
if (error2 > -deltaY) {
error -= deltaY;
x1 += signX;
ptr_right += signX;
ptr_left += -signX;
}
if (error2 < deltaX) {
error += deltaX;
y1 += signY;
ptr_right += pitch;
ptr_left += pitch;
}
}
}
/** ROUNDED SQUARE ALGORITHM **/
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawRoundedSquareAlg(int x1, int y1, int r, int w, int h, PixelType color, VectorRenderer::FillMode fill_m) {
int f, ddF_x, ddF_y;
int x, y, px, py;
int pitch = _activeSurface->pitch / _activeSurface->format.bytesPerPixel;
// TODO: Split this up into border, bevel and interior functions
if (fill_m != kFillDisabled) {
PixelType *ptr_tl = (PixelType *)Base::_activeSurface->getBasePtr(x1 + r, y1 + r);
PixelType *ptr_tr = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w - r, y1 + r);
PixelType *ptr_bl = (PixelType *)Base::_activeSurface->getBasePtr(x1 + r, y1 + h - r);
PixelType *ptr_br = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w - r, y1 + h - r);
PixelType *ptr_fill = (PixelType *)Base::_activeSurface->getBasePtr(x1, y1);
int real_radius = r;
int short_h = h - (2 * r) + 2;
int long_h = h;
BE_RESET();
PixelType color1 = color;
if (fill_m == kFillBackground)
color1 = _bgColor;
if (fill_m == kFillGradient) {
PixelType color2, color3, color4;
precalcGradient(long_h);
while (x++ < y) {
BE_ALGORITHM();
color1 = calcGradient(real_radius - x, long_h);
color2 = calcGradient(real_radius - y, long_h);
color3 = calcGradient(long_h - r + x, long_h);
color4 = calcGradient(long_h - r + y, long_h);
gradientFill(ptr_tl - x - py, w - 2 * r + 2 * x, x1 + r - x - y, real_radius - y);
gradientFill(ptr_tl - y - px, w - 2 * r + 2 * y, x1 + r - y - x, real_radius - x);
gradientFill(ptr_bl - x + py, w - 2 * r + 2 * x, x1 + r - x - y, long_h - r + y);
gradientFill(ptr_bl - y + px, w - 2 * r + 2 * y, x1 + r - y - x, long_h - r + x);
BE_DRAWCIRCLE_XCOLOR(ptr_tr, ptr_tl, ptr_bl, ptr_br, x, y, px, py);
}
} else {
while (x++ < y) {
BE_ALGORITHM();
colorFill<PixelType>(ptr_tl - x - py, ptr_tr + x - py, color1);
colorFill<PixelType>(ptr_tl - y - px, ptr_tr + y - px, color1);
colorFill<PixelType>(ptr_bl - x + py, ptr_br + x + py, color1);
colorFill<PixelType>(ptr_bl - y + px, ptr_br + y + px, color1);
// do not remove - messes up the drawing at lower resolutions
BE_DRAWCIRCLE(ptr_tr, ptr_tl, ptr_bl, ptr_br, x, y, px, py);
}
}
ptr_fill += pitch * r;
while (short_h--) {
if (fill_m == kFillGradient) {
gradientFill(ptr_fill, w + 1, x1, real_radius++);
} else {
colorFill<PixelType>(ptr_fill, ptr_fill + w + 1, color1);
}
ptr_fill += pitch;
}
}
if (Base::_strokeWidth) {
int sw = 0, sp = 0, hp = h * pitch;
PixelType *ptr_tl = (PixelType *)Base::_activeSurface->getBasePtr(x1 + r, y1 + r);
PixelType *ptr_tr = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w - r, y1 + r);
PixelType *ptr_bl = (PixelType *)Base::_activeSurface->getBasePtr(x1 + r, y1 + h - r);
PixelType *ptr_br = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w - r, y1 + h - r);
PixelType *ptr_fill = (PixelType *)Base::_activeSurface->getBasePtr(x1, y1);
int real_radius = r;
int short_h = h - (2 * r) + 2;
// TODO: A gradient effect on the bevel
PixelType color1, color2;
color1 = Base::_bevel ? _bevelColor : color;
color2 = color;
while (sw++ < Base::_strokeWidth) {
colorFill<PixelType>(ptr_fill + sp + r, ptr_fill + w + 1 + sp - r, color1);
colorFill<PixelType>(ptr_fill + hp - sp + r, ptr_fill + w + hp + 1 - sp - r, color2);
sp += pitch;
BE_RESET();
r--;
while (x++ < y) {
BE_ALGORITHM();
BE_DRAWCIRCLE_BCOLOR(ptr_tr, ptr_tl, ptr_bl, ptr_br, x, y, px, py);
if (Base::_strokeWidth > 1) {
BE_DRAWCIRCLE_BCOLOR(ptr_tr, ptr_tl, ptr_bl, ptr_br, x - 1, y, px, py);
BE_DRAWCIRCLE_BCOLOR(ptr_tr, ptr_tl, ptr_bl, ptr_br, x, y, px - pitch, py);
}
}
}
ptr_fill += pitch * real_radius;
while (short_h--) {
colorFill<PixelType>(ptr_fill, ptr_fill + Base::_strokeWidth, color1);
colorFill<PixelType>(ptr_fill + w - Base::_strokeWidth + 1, ptr_fill + w + 1, color2);
ptr_fill += pitch;
}
}
}
/** CIRCLE ALGORITHM **/
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawCircleAlg(int x1, int y1, int r, PixelType color, VectorRenderer::FillMode fill_m) {
int f, ddF_x, ddF_y;
int x, y, px, py, sw = 0;
int pitch = _activeSurface->pitch / _activeSurface->format.bytesPerPixel;
PixelType *ptr = (PixelType *)Base::_activeSurface->getBasePtr(x1, y1);
if (fill_m == kFillDisabled) {
while (sw++ < Base::_strokeWidth) {
BE_RESET();
r--;
*(ptr + y) = color;
*(ptr - y) = color;
*(ptr + py) = color;
*(ptr - py) = color;
while (x++ < y) {
BE_ALGORITHM();
BE_DRAWCIRCLE(ptr, ptr, ptr, ptr, x, y, px, py);
if (Base::_strokeWidth > 1) {
BE_DRAWCIRCLE(ptr, ptr, ptr, ptr, x - 1, y, px, py);
BE_DRAWCIRCLE(ptr, ptr, ptr, ptr, x, y, px - pitch, py);
}
}
}
} else {
colorFill<PixelType>(ptr - r, ptr + r, color);
BE_RESET();
while (x++ < y) {
BE_ALGORITHM();
colorFill<PixelType>(ptr - x + py, ptr + x + py, color);
colorFill<PixelType>(ptr - x - py, ptr + x - py, color);
colorFill<PixelType>(ptr - y + px, ptr + y + px, color);
colorFill<PixelType>(ptr - y - px, ptr + y - px, color);
}
}
}
/********************************************************************
********************************************************************
* SHADOW drawing algorithms - VectorRendererSpec *******************
********************************************************************
********************************************************************/
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawSquareShadow(int x, int y, int w, int h, int blur) {
PixelType *ptr = (PixelType *)_activeSurface->getBasePtr(x + w - 1, y + blur);
int pitch = _activeSurface->pitch / _activeSurface->format.bytesPerPixel;
int i, j;
i = h - blur;
while (i--) {
j = blur;
while (j--)
blendPixelPtr(ptr + j, 0, ((blur - j) << 8) / blur);
ptr += pitch;
}
ptr = (PixelType *)_activeSurface->getBasePtr(x + blur, y + h - 1);
while (i++ < blur) {
j = w - blur;
while (j--)
blendPixelPtr(ptr + j, 0, ((blur - i) << 8) / blur);
ptr += pitch;
}
ptr = (PixelType *)_activeSurface->getBasePtr(x + w, y + h);
i = 0;
while (i++ < blur) {
j = blur - 1;
while (j--)
blendPixelPtr(ptr + j, 0, (((blur - j) * (blur - i)) << 8) / (blur * blur));
ptr += pitch;
}
}
template<typename PixelType>
void VectorRendererSpec<PixelType>::
drawRoundedSquareShadow(int x1, int y1, int r, int w, int h, int blur) {
int f, ddF_x, ddF_y;
int x, y, px, py;
int pitch = _activeSurface->pitch / _activeSurface->format.bytesPerPixel;
int alpha = 102;
x1 += blur;
y1 += blur;
PixelType *ptr_tr = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w - r, y1 + r);
PixelType *ptr_bl = (PixelType *)Base::_activeSurface->getBasePtr(x1 + r, y1 + h - r);
PixelType *ptr_br = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w - r, y1 + h - r);
PixelType *ptr_fill = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w - blur, y1 + r);
int short_h = h - (2 * r) + 1;
BE_RESET();
// HACK: As we are drawing circles exploting 8-axis symmetry,
// there are 4 pixels on each circle which are drawn twice.
// this is ok on filled circles, but when blending on surfaces,
// we cannot let it blend twice. awful.
uint32 hb = 0;
while (x++ < y) {
BE_ALGORITHM();
if (((1 << x) & hb) == 0) {
blendFill(ptr_tr - px - r, ptr_tr + y - px, 0, alpha);
blendFill(ptr_bl - y + px, ptr_br + y + px, 0, alpha);
hb |= (1 << x);
}
if (((1 << y) & hb) == 0) {
blendFill(ptr_tr - r - py, ptr_tr + x - py, 0, alpha);
blendFill(ptr_bl - x + py, ptr_br + x + py, 0, alpha);
hb |= (1 << y);
}
}
while (short_h--) {
blendFill(ptr_fill - r, ptr_fill + blur, 0, alpha);
ptr_fill += pitch;
}
}
/******************************************************************************/
#ifndef DISABLE_FANCY_THEMES
/********************************************************************
* ANTIALIASED PRIMITIVES drawing algorithms - VectorRendererAA
********************************************************************/
/** LINES **/
template<typename PixelType>
void VectorRendererAA<PixelType>::
drawLineAlg(int x1, int y1, int x2, int y2, int dx, int dy, PixelType color) {
PixelType *ptr = (PixelType *)Base::_activeSurface->getBasePtr(x1, y1);
int pitch = Base::_activeSurface->pitch / Base::_activeSurface->format.bytesPerPixel;
int xdir = (x2 > x1) ? 1 : -1;
uint16 error_tmp, error_acc, gradient;
uint8 alpha;
*ptr = (PixelType)color;
if (dx > dy) {
gradient = (uint32)(dy << 16) / (uint32)dx;
error_acc = 0;
while (--dx) {
error_tmp = error_acc;
error_acc += gradient;
if (error_acc <= error_tmp)
ptr += pitch;
ptr += xdir;
alpha = (error_acc >> 8);
this->blendPixelPtr(ptr, color, ~alpha);
this->blendPixelPtr(ptr + pitch, color, alpha);
}
} else {
gradient = (uint32)(dx << 16) / (uint32)dy;
error_acc = 0;
while (--dy) {
error_tmp = error_acc;
error_acc += gradient;
if (error_acc <= error_tmp)
ptr += xdir;
ptr += pitch;
alpha = (error_acc >> 8);
this->blendPixelPtr(ptr, color, ~alpha);
this->blendPixelPtr(ptr + xdir, color, alpha);
}
}
Base::putPixel(x2, y2, color);
}
/** TAB ALGORITHM */
template<typename PixelType>
void VectorRendererAA<PixelType>::
drawTabAlg(int x1, int y1, int w, int h, int r, PixelType color, VectorRenderer::FillMode fill_m, int baseLeft, int baseRight) {
int x, y, px, py;
int pitch = Base::_activeSurface->pitch / Base::_activeSurface->format.bytesPerPixel;
int sw = 0, sp = 0, hp = 0;
frac_t T = 0, oldT;
uint8 a1, a2;
uint32 rsq = r*r;
PixelType *ptr_tl = (PixelType *)Base::_activeSurface->getBasePtr(x1 + r, y1 + r);
PixelType *ptr_tr = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w - r, y1 + r);
PixelType *ptr_fill = (PixelType *)Base::_activeSurface->getBasePtr(x1, y1);
int real_radius = r;
if (fill_m == Base::kFillDisabled) {
color = 0;
while (sw++ < Base::_strokeWidth) {
colorFill<PixelType>(ptr_fill + sp + r, ptr_fill + w + 1 + sp - r, color);
colorFill<PixelType>(ptr_fill + hp - sp + r, ptr_fill + w + hp + 1 - sp - r, color);
sp += pitch;
x = r - (sw - 1);
y = 0;
T = 0;
px = pitch * x;
py = 0;
while (x > y++) {
WU_ALGORITHM();
// sw == 1: outside, sw = _strokeWidth: inside
if (sw != Base::_strokeWidth)
a2 = 255;
// inner arc
WU_DRAWCIRCLE_TOP(ptr_tr, ptr_tl, x, y, px, py, a2);
if (sw == 1) // outer arc
WU_DRAWCIRCLE_TOP(ptr_tr, ptr_tl, x, y, px - pitch, py, a1);
}
}
int short_h = h - r + 2;
ptr_fill += pitch * real_radius;
while (short_h--) {
colorFill<PixelType>(ptr_fill, ptr_fill + Base::_strokeWidth, color);
colorFill<PixelType>(ptr_fill + w - Base::_strokeWidth + 1, ptr_fill + w + 1, color);
ptr_fill += pitch;
}
if (baseLeft) {
sw = 0;
ptr_fill = (PixelType *)Base::_activeSurface->getBasePtr(x1, y1 + h + 1);
while (sw++ < Base::_strokeWidth) {
colorFill<PixelType>(ptr_fill - baseLeft, ptr_fill, color);
ptr_fill += pitch;
}
}
if (baseRight) {
sw = 0;
ptr_fill = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w, y1 + h + 1);
while (sw++ < Base::_strokeWidth) {
colorFill<PixelType>(ptr_fill, ptr_fill + baseRight, color);
ptr_fill += pitch;
}
}
} else {
PixelType color1, color2;
color1 = color2 = color;
int long_h = h;
int short_h = h - real_radius + 2;
x = real_radius;
y = 0;
T = 0;
px = pitch * x;
py = 0;
Base::precalcGradient(long_h);
while (x > y++) {
WU_ALGORITHM();
if (fill_m == Base::kFillGradient) {
color1 = Base::calcGradient(real_radius - x, long_h);
color2 = Base::calcGradient(real_radius - y, long_h);
Base::gradientFill(ptr_tl - x - py + 1, w - 2 * r + 2 * x - 1, x1 + r - x - y + 1, real_radius - y);
// Only fill each horizontal line once (or we destroy
// the gradient effect at the edges)
if (T < oldT || y == 1)
Base::gradientFill(ptr_tl - y - px + 1, w - 2 * r + 2 * y - 1, x1 + r - y - x + 1, real_radius - x);
WU_DRAWCIRCLE_XCOLOR_TOP(ptr_tr, ptr_tl, x, y, px, py, a1, Base::blendPixelPtr);
} else {
colorFill<PixelType>(ptr_tl - x - py + 1, ptr_tr + x - py, color);
if (T < oldT || y == 1)
colorFill<PixelType>(ptr_tl - y - px + 1, ptr_tr + y - px, color);
WU_DRAWCIRCLE_TOP(ptr_tr, ptr_tl, x, y, px, py, a1);
}
}
ptr_fill += pitch * r;
while (short_h--) {
if (fill_m == Base::kFillGradient) {
Base::gradientFill(ptr_fill, w + 1, x1, real_radius++);
} else {
colorFill<PixelType>(ptr_fill, ptr_fill + w + 1, color);
}
ptr_fill += pitch;
}
}
}
/** ROUNDED SQUARES **/
template<typename PixelType>
void VectorRendererAA<PixelType>::
drawRoundedSquareAlg(int x1, int y1, int r, int w, int h, PixelType color, VectorRenderer::FillMode fill_m) {
int x, y;
const int pitch = Base::_activeSurface->pitch / Base::_activeSurface->format.bytesPerPixel;
int px, py;
uint32 rsq = r*r;
frac_t T = 0, oldT;
uint8 a1, a2;
// TODO: Split this up into border, bevel and interior functions
if (Base::_strokeWidth) {
PixelType *ptr_tl = (PixelType *)Base::_activeSurface->getBasePtr(x1 + r, y1 + r);
PixelType *ptr_tr = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w - r, y1 + r);
PixelType *ptr_bl = (PixelType *)Base::_activeSurface->getBasePtr(x1 + r, y1 + h - r);
PixelType *ptr_br = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w - r, y1 + h - r);
PixelType *ptr_fill = (PixelType *)Base::_activeSurface->getBasePtr(x1, y1);
int sw = 0, sp = 0;
int short_h = h - 2 * r;
int hp = h * pitch;
int strokeWidth = Base::_strokeWidth;
// If we're going to fill the inside, draw a slightly thicker border
// so we can blend the inside on top of it.
if (fill_m != Base::kFillDisabled) strokeWidth++;
// TODO: A gradient effect on the bevel
PixelType color1, color2;
color1 = Base::_bevel ? Base::_bevelColor : color;
color2 = color;
while (sw++ < strokeWidth) {
colorFill<PixelType>(ptr_fill + sp + r, ptr_fill + w + 1 + sp - r, color1);
colorFill<PixelType>(ptr_fill + hp - sp + r, ptr_fill + w + hp + 1 - sp - r, color2);
sp += pitch;
x = r - (sw - 1);
y = 0;
T = 0;
px = pitch * x;
py = 0;
while (x > y++) {
WU_ALGORITHM();
// sw == 1: outside, sw = _strokeWidth: inside
// We always draw the outer edge AAed, but the inner edge
// only when the inside isn't filled
if (sw != strokeWidth || fill_m != Base::kFillDisabled)
a2 = 255;
// inner arc
WU_DRAWCIRCLE_BCOLOR(ptr_tr, ptr_tl, ptr_bl, ptr_br, (x - 1), y, (px - pitch), py, a2);
if (sw == 1) // outer arc
WU_DRAWCIRCLE_BCOLOR(ptr_tr, ptr_tl, ptr_bl, ptr_br, x, y, px, py, a1);
}
}
ptr_fill += pitch * r;
while (short_h-- >= 0) {
colorFill<PixelType>(ptr_fill, ptr_fill + Base::_strokeWidth, color1);
colorFill<PixelType>(ptr_fill + w - Base::_strokeWidth + 1, ptr_fill + w + 1, color2);
ptr_fill += pitch;
}
}
r -= Base::_strokeWidth;
x1 += Base::_strokeWidth;
y1 += Base::_strokeWidth;
w -= 2*Base::_strokeWidth;
h -= 2*Base::_strokeWidth;
rsq = r*r;
if (w <= 0 || h <= 0)
return; // Only border is visible
if (fill_m != Base::kFillDisabled) {
if (fill_m == Base::kFillBackground)
color = Base::_bgColor;
PixelType *ptr_tl = (PixelType *)Base::_activeSurface->getBasePtr(x1 + r, y1 + r);
PixelType *ptr_tr = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w - r, y1 + r);
PixelType *ptr_bl = (PixelType *)Base::_activeSurface->getBasePtr(x1 + r, y1 + h - r);
PixelType *ptr_br = (PixelType *)Base::_activeSurface->getBasePtr(x1 + w - r, y1 + h - r);
PixelType *ptr_fill = (PixelType *)Base::_activeSurface->getBasePtr(x1, y1);
int short_h = h - 2 * r;
x = r;
y = 0;
T = 0;
px = pitch * x;
py = 0;
if (fill_m == Base::kFillGradient) {
Base::precalcGradient(h);
PixelType color1, color2, color3, color4;
while (x > y++) {
WU_ALGORITHM();
color1 = Base::calcGradient(r - x, h);
color2 = Base::calcGradient(r - y, h);
color3 = Base::calcGradient(h - r + x, h);
color4 = Base::calcGradient(h - r + y, h);
Base::gradientFill(ptr_tl - x - py + 1, w - 2 * r + 2 * x - 1, x1 + r - x - y + 1, r - y);
// Only fill each horizontal line once (or we destroy
// the gradient effect at the edges)
if (T < oldT || y == 1)
Base::gradientFill(ptr_tl - y - px + 1, w - 2 * r + 2 * y - 1, x1 + r - y - x + 1, r - x);
Base::gradientFill(ptr_bl - x + py + 1, w - 2 * r + 2 * x - 1, x1 + r - x - y + 1, h - r + y);
// Only fill each horizontal line once (or we destroy
// the gradient effect at the edges)
if (T < oldT || y == 1)
Base::gradientFill(ptr_bl - y + px + 1, w - 2 * r + 2 * y - 1, x1 + r - y - x + 1, h - r + x);
// This shape is used for dialog backgrounds.
// If we're drawing on top of an empty overlay background,
// and the overlay supports alpha, we have to do AA by
// setting the dest alpha channel, instead of blending with
// dest color channels.
if (!g_system->hasFeature(OSystem::kFeatureOverlaySupportsAlpha))
WU_DRAWCIRCLE_XCOLOR(ptr_tr, ptr_tl, ptr_bl, ptr_br, x, y, px, py, a1, blendPixelPtr);
else
WU_DRAWCIRCLE_XCOLOR(ptr_tr, ptr_tl, ptr_bl, ptr_br, x, y, px, py, a1, blendPixelDestAlphaPtr);
}
ptr_fill += pitch * r;
while (short_h-- >= 0) {
Base::gradientFill(ptr_fill, w + 1, x1, r++);
ptr_fill += pitch;
}
} else {
while (x > 1 + y++) {
WU_ALGORITHM();
colorFill<PixelType>(ptr_tl - x - py + 1, ptr_tr + x - py, color);
if (T < oldT || y == 1)
colorFill<PixelType>(ptr_tl - y - px + 1, ptr_tr + y - px, color);
colorFill<PixelType>(ptr_bl - x + py + 1, ptr_br + x + py, color);
if (T < oldT || y == 1)
colorFill<PixelType>(ptr_bl - y + px + 1, ptr_br + y + px, color);
WU_DRAWCIRCLE(ptr_tr, ptr_tl, ptr_bl, ptr_br, x, y, px, py, a1);
}
ptr_fill += pitch * r;
while (short_h-- >= 0) {
colorFill<PixelType>(ptr_fill, ptr_fill + w + 1, color);
ptr_fill += pitch;
}
}
}
}
/** CIRCLES **/
template<typename PixelType>
void VectorRendererAA<PixelType>::
drawCircleAlg(int x1, int y1, int r, PixelType color, VectorRenderer::FillMode fill_m) {
int x, y, sw = 0;
const int pitch = Base::_activeSurface->pitch / Base::_activeSurface->format.bytesPerPixel;
int px, py;
uint32 rsq = r*r;
frac_t T = 0, oldT;
uint8 a1, a2;
PixelType *ptr = (PixelType *)Base::_activeSurface->getBasePtr(x1, y1);
if (fill_m == VectorRenderer::kFillDisabled) {
while (sw++ < Base::_strokeWidth) {
x = r - (sw - 1);
y = 0;
T = 0;
px = pitch * x;
py = 0;
*(ptr + x) = (PixelType)color;
*(ptr - x) = (PixelType)color;
*(ptr + px) = (PixelType)color;
*(ptr - px) = (PixelType)color;
while (x > y++) {
WU_ALGORITHM();
if (sw != 1 && sw != Base::_strokeWidth)
a2 = a1 = 255;
WU_DRAWCIRCLE(ptr, ptr, ptr, ptr, (x - 1), y, (px - pitch), py, a2);
WU_DRAWCIRCLE(ptr, ptr, ptr, ptr, x, y, px, py, a1);
}
}
} else {
colorFill<PixelType>(ptr - r, ptr + r + 1, color);
x = r;
y = 0;
T = 0;
px = pitch * x;
py = 0;
while (x > y++) {
WU_ALGORITHM();
colorFill<PixelType>(ptr - x + py, ptr + x + py, color);
colorFill<PixelType>(ptr - x - py, ptr + x - py, color);
colorFill<PixelType>(ptr - y + px, ptr + y + px, color);
colorFill<PixelType>(ptr - y - px, ptr + y - px, color);
WU_DRAWCIRCLE(ptr, ptr, ptr, ptr, x, y, px, py, a1);
}
}
}
#endif
}