/* 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.
*
* $URL$
* $Id$
*
*/
/*
* GP2X: Graphics handling.
*
*/
#include "backends/platform/gp2x/gp2x-common.h"
#include "common/util.h"
#include "graphics/font.h"
#include "graphics/fontman.h"
#include "graphics/scaler.h"
#include "graphics/surface.h"
static const OSystem::GraphicsMode s_supportedGraphicsModes[] = {
{"GP2X Graphics Mode", "1x", GFX_NORMAL},
{0, 0, 0}
};
// Table of relative scalers magnitudes
// [definedScale - 1][_scaleFactor - 1]
static ScalerProc *scalersMagn[3][3] = {
{ Normal1x, Normal1x, Normal1x },
{ Normal1x, Normal1x, Normal1x },
{ Normal1x, Normal1x, Normal1x }
};
static const int s_gfxModeSwitchTable[][4] = {
{ GFX_NORMAL, GFX_DOUBLESIZE, GFX_TRIPLESIZE, -1 },
{ GFX_NORMAL, GFX_ADVMAME2X, GFX_ADVMAME3X, -1 },
{ GFX_NORMAL, GFX_HQ2X, GFX_HQ3X, -1 },
{ GFX_NORMAL, GFX_2XSAI, -1, -1 },
{ GFX_NORMAL, GFX_SUPER2XSAI, -1, -1 },
{ GFX_NORMAL, GFX_SUPEREAGLE, -1, -1 },
{ GFX_NORMAL, GFX_TV2X, -1, -1 },
{ GFX_NORMAL, GFX_DOTMATRIX, -1, -1 }
};
static int cursorStretch200To240(uint8 *buf, uint32 pitch, int width, int height, int srcX, int srcY, int origSrcY);
const OSystem::GraphicsMode *OSystem_GP2X::getSupportedGraphicsModes() const {
return s_supportedGraphicsModes;
}
int OSystem_GP2X::getDefaultGraphicsMode() const {
return GFX_NORMAL;
}
void OSystem_GP2X::beginGFXTransaction(void) {
assert (_transactionMode == kTransactionNone);
_transactionMode = kTransactionActive;
_transactionDetails.modeChanged = false;
_transactionDetails.sizeChanged = false;
_transactionDetails.arChanged = false;
_transactionDetails.fsChanged = false;
_transactionDetails.needHotswap = false;
_transactionDetails.needUpdatescreen = false;
_transactionDetails.needUnload = false;
_transactionDetails.normal1xScaler = false;
}
void OSystem_GP2X::endGFXTransaction(void) {
// for each engine we run initCommonGFX() as first thing in the transaction
// and initSize() is called later. If user runs launcher at 320x200 with
// 2x overlay, setting to Nomral1x sclaler in that case will be suppressed
// and backend is forced to 2x
//
// This leads to bad results such as 1280x960 window for 640x480 engines.
// To prevent that we rerun setGraphicsMode() if there was 1x scaler request
if (_transactionDetails.normal1xScaler)
setGraphicsMode(GFX_NORMAL);
assert (_transactionMode == kTransactionActive);
_transactionMode = kTransactionCommit;
if (_transactionDetails.modeChanged)
setGraphicsMode(_transactionDetails.mode);
if (_transactionDetails.sizeChanged)
initSize(_transactionDetails.w, _transactionDetails.h);
if (_transactionDetails.arChanged)
setAspectRatioCorrection(_transactionDetails.ar);
if (_transactionDetails.needUnload) {
unloadGFXMode();
loadGFXMode();
clearOverlay();
} else {
if (!_transactionDetails.fsChanged) {
if (_transactionDetails.needHotswap)
hotswapGFXMode();
else if (_transactionDetails.needUpdatescreen)
internUpdateScreen();
}
}
if (_transactionDetails.fsChanged)
setFullscreenMode(_transactionDetails.fs);
_transactionMode = kTransactionNone;
}
bool OSystem_GP2X::setGraphicsMode(int mode) {
Common::StackLock lock(_graphicsMutex);
int newScaleFactor = 1;
ScalerProc *newScalerProc;
mode = GFX_NORMAL;
newScaleFactor = 1;
newScalerProc = Normal1x;
_transactionDetails.normal1xScaler = (mode == GFX_NORMAL);
_mode = mode;
_scalerProc = newScalerProc;
if (_transactionMode == kTransactionActive) {
_transactionDetails.mode = mode;
_transactionDetails.modeChanged = true;
if (newScaleFactor != _scaleFactor) {
_transactionDetails.needHotswap = true;
_scaleFactor = newScaleFactor;
}
_transactionDetails.needUpdatescreen = true;
return true;
}
// NOTE: This should not be executed at transaction commit
// Otherwise there is some unsolicited setGraphicsMode() call
// which should be properly removed
if (newScaleFactor != _scaleFactor) {
assert(_transactionMode != kTransactionCommit);
_scaleFactor = newScaleFactor;
hotswapGFXMode();
}
// Determine the "scaler type", i.e. essentially an index into the
// s_gfxModeSwitchTable array defined in events.cpp.
if (_mode != GFX_NORMAL) {
for (int i = 0; i < ARRAYSIZE(s_gfxModeSwitchTable); i++) {
if (s_gfxModeSwitchTable[i][1] == _mode || s_gfxModeSwitchTable[i][2] == _mode) {
_scalerType = i;
break;
}
}
}
if (!_screen)
return true;
// Blit everything to the screen
_forceFull = true;
// Even if the old and new scale factors are the same, we may have a
// different scaler for the cursor now.
blitCursor();
if (_transactionMode != kTransactionCommit)
internUpdateScreen();
// Make sure that an Common::EVENT_SCREEN_CHANGED gets sent later
_modeChanged = true;
return true;
}
int OSystem_GP2X::getGraphicsMode() const {
assert (_transactionMode == kTransactionNone);
return _mode;
}
void OSystem_GP2X::initSize(uint w, uint h){
// Avoid redundant res changes
if ((int)w == _screenWidth && (int)h == _screenHeight &&
_transactionMode != kTransactionCommit)
return;
_screenWidth = w;
_screenHeight = h;
_cksumNum = (_screenWidth * _screenHeight / (8 * 8));
if (_transactionMode == kTransactionActive) {
_transactionDetails.w = w;
_transactionDetails.h = h;
_transactionDetails.sizeChanged = true;
_transactionDetails.needUnload = true;
return;
}
free(_dirtyChecksums);
_dirtyChecksums = (uint32 *)calloc(_cksumNum * 2, sizeof(uint32));
if (_transactionMode != kTransactionCommit) {
unloadGFXMode();
loadGFXMode();
// if initSize() gets called in the middle, overlay is not transparent
clearOverlay();
}
}
void OSystem_GP2X::loadGFXMode() {
assert(_inited);
_forceFull = true;
_modeFlags |= DF_UPDATE_EXPAND_1_PIXEL;
int hwW, hwH;
_overlayWidth = _screenWidth * _scaleFactor;
_overlayHeight = _screenHeight * _scaleFactor;
if (_screenHeight != 200)
_adjustAspectRatio = false;
if (_adjustAspectRatio)
_overlayHeight = real2Aspect(_overlayHeight);
hwW = _screenWidth * _scaleFactor;
hwH = effectiveScreenHeight();
//
// Create the surface that contains the 8 bit game data
//
_screen = SDL_CreateRGBSurface(SDL_SWSURFACE, _screenWidth, _screenHeight, 8, 0, 0, 0, 0);
if (_screen == NULL)
error("allocating _screen failed");
//
// Create the surface that contains the graphics in 16 bit mode
//
// FIXME: Hack for GP2X SDL querks.
if (_screenWidth <= 320) {
_hwscreen = SDL_SetVideoMode(320, 240, 16, SDL_FULLSCREEN|SDL_SWSURFACE);
} else {
_hwscreen = SDL_SetVideoMode(_screenWidth, _screenHeight, 16, SDL_FULLSCREEN|SDL_SWSURFACE);
}
if (_hwscreen == NULL) {
warning("SDL_SetVideoMode says we can't switch to that mode");
quit();
}
// GP2X Specific, must be called after any SDL_SetVideoMode to ensure the hardware cursor is off.
// Note: On the GP2X SDL_SetVideoMode recalls SDL_Init().
SDL_ShowCursor(SDL_DISABLE);
//
// Create the surface used for the graphics in 16 bit before scaling, and also the overlay
//
// Distinguish 555 and 565 mode
if (_hwscreen->format->Rmask == 0x7C00)
InitScalers(555);
else
InitScalers(565);
// Need some extra bytes around when using 2xSaI
_tmpscreen = SDL_CreateRGBSurface(SDL_SWSURFACE, _screenWidth + 3, _screenHeight + 3,
16,
_hwscreen->format->Rmask,
_hwscreen->format->Gmask,
_hwscreen->format->Bmask,
_hwscreen->format->Amask);
if (_tmpscreen == NULL)
error("allocating _tmpscreen failed");
_overlayscreen = SDL_CreateRGBSurface(SDL_SWSURFACE, _overlayWidth, _overlayHeight,
16,
_hwscreen->format->Rmask,
_hwscreen->format->Gmask,
_hwscreen->format->Bmask,
_hwscreen->format->Amask);
if (_overlayscreen == NULL)
error("allocating _overlayscreen failed");
_tmpscreen2 = SDL_CreateRGBSurface(SDL_SWSURFACE, _overlayWidth + 3, _overlayHeight + 3,
16,
_hwscreen->format->Rmask,
_hwscreen->format->Gmask,
_hwscreen->format->Bmask,
_hwscreen->format->Amask);
if (_tmpscreen2 == NULL)
error("allocating _tmpscreen2 failed");
_osdSurface = SDL_CreateRGBSurface(SDL_SWSURFACE | SDL_RLEACCEL | SDL_SRCCOLORKEY | SDL_SRCALPHA,
_hwscreen->w,
_hwscreen->h,
16,
_hwscreen->format->Rmask,
_hwscreen->format->Gmask,
_hwscreen->format->Bmask,
_hwscreen->format->Amask);
if (_osdSurface == NULL)
error("allocating _osdSurface failed");
SDL_SetColorKey(_osdSurface, SDL_RLEACCEL | SDL_SRCCOLORKEY | SDL_SRCALPHA, kOSDColorKey);
// keyboard cursor control, some other better place for it?
_km.x_max = _screenWidth * _scaleFactor - 1;
_km.y_max = effectiveScreenHeight() - 1;
_km.delay_time = 25;
_km.last_time = 0;
}
void OSystem_GP2X::unloadGFXMode() {
if (_screen) {
SDL_FreeSurface(_screen);
_screen = NULL;
}
if (_hwscreen) {
SDL_FreeSurface(_hwscreen);
_hwscreen = NULL;
}
if (_tmpscreen) {
SDL_FreeSurface(_tmpscreen);
_tmpscreen = NULL;
}
if (_tmpscreen2) {
SDL_FreeSurface(_tmpscreen2);
_tmpscreen2 = NULL;
}
if (_overlayscreen) {
SDL_FreeSurface(_overlayscreen);
_overlayscreen = NULL;
}
if (_osdSurface) {
SDL_FreeSurface(_osdSurface);
_osdSurface = NULL;
}
}
void OSystem_GP2X::hotswapGFXMode() {
if (!_screen)
return;
// Keep around the old _screen & _overlayscreen so we can restore the screen data
// after the mode switch.
SDL_Surface *old_screen = _screen;
SDL_Surface *old_overlayscreen = _overlayscreen;
// Release the HW screen surface
SDL_FreeSurface(_hwscreen);
SDL_FreeSurface(_tmpscreen);
SDL_FreeSurface(_tmpscreen2);
// Release the OSD surface
SDL_FreeSurface(_osdSurface);
// Setup the new GFX mode
loadGFXMode();
// reset palette
SDL_SetColors(_screen, _currentPalette, 0, 256);
// Restore old screen content
SDL_BlitSurface(old_screen, NULL, _screen, NULL);
SDL_BlitSurface(old_overlayscreen, NULL, _overlayscreen, NULL);
// Free the old surfaces
SDL_FreeSurface(old_screen);
SDL_FreeSurface(old_overlayscreen);
// Update cursor to new scale
blitCursor();
// Blit everything to the screen
internUpdateScreen();
// Make sure that an Common::EVENT_SCREEN_CHANGED gets sent later
_modeChanged = true;
}
void OSystem_GP2X::updateScreen() {
assert (_transactionMode == kTransactionNone);
Common::StackLock lock(_graphicsMutex); // Lock the mutex until this function ends
internUpdateScreen();
}
void OSystem_GP2X::internUpdateScreen() {
SDL_Surface *srcSurf, *origSurf;
int height, width;
ScalerProc *scalerProc;
int scale1;
#if defined (DEBUG) && ! defined(_WIN32_WCE) // definitions not available for non-DEBUG here. (needed this to compile in SYMBIAN32 & linux?)
assert(_hwscreen != NULL);
assert(_hwscreen->map->sw_data != NULL);
#endif
// If the shake position changed, fill the dirty area with blackness
if (_currentShakePos != _newShakePos) {
SDL_Rect blackrect = {0, 0, _screenWidth * _scaleFactor, _newShakePos * _scaleFactor};
if (_adjustAspectRatio && !_overlayVisible)
blackrect.h = real2Aspect(blackrect.h - 1) + 1;
SDL_FillRect(_hwscreen, &blackrect, 0);
_currentShakePos = _newShakePos;
_forceFull = true;
}
// Check whether the palette was changed in the meantime and update the
// screen surface accordingly.
if (_screen && _paletteDirtyEnd != 0) {
SDL_SetColors(_screen, _currentPalette + _paletteDirtyStart,
_paletteDirtyStart,
_paletteDirtyEnd - _paletteDirtyStart);
_paletteDirtyEnd = 0;
_forceFull = true;
}
// OSD visible (i.e. non-transparent)?
if (_osdAlpha != SDL_ALPHA_TRANSPARENT) {
// Updated alpha value
const int diff = SDL_GetTicks() - _osdFadeStartTime;
if (diff > 0) {
if (diff >= kOSDFadeOutDuration) {
// Back to full transparency
_osdAlpha = SDL_ALPHA_TRANSPARENT;
} else {
// Do a linear fade out...
const int startAlpha = SDL_ALPHA_TRANSPARENT + kOSDInitialAlpha * (SDL_ALPHA_OPAQUE - SDL_ALPHA_TRANSPARENT) / 100;
_osdAlpha = startAlpha + diff * (SDL_ALPHA_TRANSPARENT - startAlpha) / kOSDFadeOutDuration;
}
SDL_SetAlpha(_osdSurface, SDL_RLEACCEL | SDL_SRCCOLORKEY | SDL_SRCALPHA, _osdAlpha);
_forceFull = true;
}
}
if (!_overlayVisible) {
origSurf = _screen;
srcSurf = _tmpscreen;
width = _screenWidth;
height = _screenHeight;
scalerProc = _scalerProc;
scale1 = _scaleFactor;
} else {
origSurf = _overlayscreen;
srcSurf = _tmpscreen2;
width = _overlayWidth;
height = _overlayHeight;
scalerProc = Normal1x;
scale1 = 1;
}
// Force a full redraw if requested
if (_forceFull) {
_numDirtyRects = 1;
_dirtyRectList[0].x = 0;
_dirtyRectList[0].y = 0;
_dirtyRectList[0].w = width;
_dirtyRectList[0].h = height;
} else
undrawMouse();
// Only draw anything if necessary
if (_numDirtyRects > 0) {
SDL_Rect *r;
SDL_Rect dst;
uint32 srcPitch, dstPitch;
SDL_Rect *lastRect = _dirtyRectList + _numDirtyRects;
if (scalerProc == Normal1x && !_adjustAspectRatio && 0) {
for (r = _dirtyRectList; r != lastRect; ++r) {
dst = *r;
dst.y += _currentShakePos;
if (SDL_BlitSurface(origSurf, r, _hwscreen, &dst) != 0)
error("SDL_BlitSurface failed: %s", SDL_GetError());
}
} else {
for (r = _dirtyRectList; r != lastRect; ++r) {
dst = *r;
dst.x++; // Shift rect by one since 2xSai needs to acces the data around
dst.y++; // any pixel to scale it, and we want to avoid mem access crashes.
if (SDL_BlitSurface(origSurf, r, srcSurf, &dst) != 0)
error("SDL_BlitSurface failed: %s", SDL_GetError());
}
SDL_LockSurface(srcSurf);
SDL_LockSurface(_hwscreen);
srcPitch = srcSurf->pitch;
dstPitch = _hwscreen->pitch;
for (r = _dirtyRectList; r != lastRect; ++r) {
register int dst_y = r->y + _currentShakePos;
register int dst_h = 0;
register int orig_dst_y = 0;
register int rx1 = r->x * scale1;
if (dst_y < height) {
dst_h = r->h;
if (dst_h > height - dst_y)
dst_h = height - dst_y;
orig_dst_y = dst_y;
dst_y = dst_y * scale1;
if (_adjustAspectRatio && !_overlayVisible)
dst_y = real2Aspect(dst_y);
assert(scalerProc != NULL);
scalerProc((byte *)srcSurf->pixels + (r->x * 2 + 2) + (r->y + 1) * srcPitch, srcPitch,
(byte *)_hwscreen->pixels + rx1 * 2 + dst_y * dstPitch, dstPitch, r->w, dst_h);
}
r->x = rx1;
r->y = dst_y;
r->w = r->w * scale1;
r->h = dst_h * scale1;
#ifndef DISABLE_SCALERS
if (_adjustAspectRatio && orig_dst_y < height && !_overlayVisible)
r->h = stretch200To240((uint8 *) _hwscreen->pixels, dstPitch, r->w, r->h, r->x, r->y, orig_dst_y * scale1);
#endif
}
SDL_UnlockSurface(srcSurf);
SDL_UnlockSurface(_hwscreen);
}
// Readjust the dirty rect list in case we are doing a full update.
// This is necessary if shaking is active.
if (_forceFull) {
_dirtyRectList[0].y = 0;
_dirtyRectList[0].h = effectiveScreenHeight();
}
drawMouse();
if (_osdAlpha != SDL_ALPHA_TRANSPARENT) {
SDL_BlitSurface(_osdSurface, 0, _hwscreen, 0);
}
// Finally, blit all our changes to the screen
SDL_UpdateRects(_hwscreen, _numDirtyRects, _dirtyRectList);
} else {
drawMouse();
if (_numDirtyRects)
SDL_UpdateRects(_hwscreen, _numDirtyRects, _dirtyRectList);
}
_numDirtyRects = 0;
_forceFull = false;
}
bool OSystem_GP2X::saveScreenshot(const char *filename) {
assert(_hwscreen != NULL);
Common::StackLock lock(_graphicsMutex); // Lock the mutex until this function ends
return SDL_SaveBMP(_hwscreen, filename) == 0;
}
void OSystem_GP2X::setFullscreenMode(bool enable) {
Common::StackLock lock(_graphicsMutex);
if (_fullscreen != enable || _transactionMode == kTransactionCommit) {
assert(_hwscreen != 0);
_fullscreen = enable;
if (_transactionMode == kTransactionActive) {
_transactionDetails.fs = enable;
_transactionDetails.fsChanged = true;
_transactionDetails.needHotswap = true;
return;
}
#if (defined(MACOSX) && !SDL_VERSION_ATLEAST(1, 2, 6)) || defined(__MAEMO__)
// On OS X, SDL_WM_ToggleFullScreen is currently not implemented. Worse,
// before SDL 1.2.6 it always returned -1 (which would indicate a
// successful switch). So we simply don't call it at all and use
// hotswapGFXMode() directly to switch to fullscreen mode.
hotswapGFXMode();
#else
if (!SDL_WM_ToggleFullScreen(_hwscreen)) {
// if ToggleFullScreen fails, achieve the same effect with hotswap gfx mode
hotswapGFXMode();
} else {
// Blit everything to the screen
internUpdateScreen();
// Make sure that an Common::EVENT_SCREEN_CHANGED gets sent later
_modeChanged = true;
}
#endif
}
}
void OSystem_GP2X::setAspectRatioCorrection(bool enable) {
if ((_screenHeight == 200 && _adjustAspectRatio != enable) ||
_transactionMode == kTransactionCommit) {
Common::StackLock lock(_graphicsMutex);
//assert(_hwscreen != 0);
_adjustAspectRatio = enable;
if (_transactionMode == kTransactionActive) {
_transactionDetails.ar = enable;
_transactionDetails.arChanged = true;
_transactionDetails.needHotswap = true;
return;
} else {
if (_transactionMode != kTransactionCommit)
hotswapGFXMode();
}
// Make sure that an Common::EVENT_SCREEN_CHANGED gets sent later
_modeChanged = true;
}
}
void OSystem_GP2X::setZoomOnMouse() {
if (_adjustZoomOnMouse == true) {
_adjustZoomOnMouse = false;
return;
} else {
_adjustZoomOnMouse = true;
return;
}
}
void OSystem_GP2X::copyRectToScreen(const byte *src, int pitch, int x, int y, int w, int h) {
assert (_transactionMode == kTransactionNone);
assert(src);
if (_screen == NULL) {
warning("OSystem_GP2X::copyRectToScreen: _screen == NULL");
return;
}
Common::StackLock lock(_graphicsMutex); // Lock the mutex until this function ends
// assert(x >= 0 && x < _screenWidth);
// assert(y >= 0 && y < _screenHeight);
// assert(h > 0 && y + h <= _screenHeight);
// assert(w > 0 && x + w <= _screenWidth);
if (((long)src & 3) == 0 && pitch == _screenWidth && x == 0 && y == 0 &&
w == _screenWidth && h == _screenHeight && _modeFlags & DF_WANT_RECT_OPTIM) {
/* Special, optimized case for full screen updates.
* It tries to determine what areas were actually changed,
* and just updates those, on the actual display. */
addDirtyRgnAuto(src);
} else {
/* Clip the coordinates */
if (x < 0) {
w += x;
src -= x;
x = 0;
}
if (y < 0) {
h += y;
src -= y * pitch;
y = 0;
}
if (w > _screenWidth - x) {
w = _screenWidth - x;
}
if (h > _screenHeight - y) {
h = _screenHeight - y;
}
if (w <= 0 || h <= 0)
return;
_cksumValid = false;
addDirtyRect(x, y, w, h);
}
// Try to lock the screen surface
if (SDL_LockSurface(_screen) == -1)
error("SDL_LockSurface failed: %s", SDL_GetError());
byte *dst = (byte *)_screen->pixels + y * _screenWidth + x;
if (_screenWidth == pitch && pitch == w) {
memcpy(dst, src, h*w);
} else {
do {
memcpy(dst, src, w);
src += pitch;
dst += _screenWidth;
} while (--h);
}
// Unlock the screen surface
SDL_UnlockSurface(_screen);
}
Graphics::Surface *OSystem_GP2X::lockScreen() {
assert (_transactionMode == kTransactionNone);
// Lock the graphics mutex
lockMutex(_graphicsMutex);
// paranoia check
assert(!_screenIsLocked);
_screenIsLocked = true;
// Try to lock the screen surface
if (SDL_LockSurface(_screen) == -1)
error("SDL_LockSurface failed: %s", SDL_GetError());
_framebuffer.pixels = _screen->pixels;
_framebuffer.w = _screen->w;
_framebuffer.h = _screen->h;
_framebuffer.pitch = _screen->pitch;
_framebuffer.bytesPerPixel = 1;
return &_framebuffer;
}
void OSystem_GP2X::unlockScreen() {
assert (_transactionMode == kTransactionNone);
// paranoia check
assert(_screenIsLocked);
_screenIsLocked = false;
// Unlock the screen surface
SDL_UnlockSurface(_screen);
// Trigger a full screen update
_forceFull = true;
// Finally unlock the graphics mutex
unlockMutex(_graphicsMutex);
}
void OSystem_GP2X::addDirtyRect(int x, int y, int w, int h, bool realCoordinates) {
if (_forceFull)
return;
if (_numDirtyRects == NUM_DIRTY_RECT) {
_forceFull = true;
return;
}
int height, width;
if (!_overlayVisible && !realCoordinates) {
width = _screenWidth;
height = _screenHeight;
} else {
width = _overlayWidth;
height = _overlayHeight;
}
// Extend the dirty region by 1 pixel for scalers
// that "smear" the screen, e.g. 2xSAI
if ((_modeFlags & DF_UPDATE_EXPAND_1_PIXEL) && !realCoordinates) {
x--;
y--;
w+=2;
h+=2;
}
// clip
if (x < 0) {
w += x;
x = 0;
}
if (y < 0) {
h += y;
y=0;
}
if (w > width - x) {
w = width - x;
}
if (h > height - y) {
h = height - y;
}
if (_adjustAspectRatio && !_overlayVisible && !realCoordinates) {
makeRectStretchable(x, y, w, h);
}
if (w == width && h == height) {
_forceFull = true;
return;
}
if (w > 0 && h > 0) {
SDL_Rect *r = &_dirtyRectList[_numDirtyRects++];
r->x = x;
r->y = y;
r->w = w;
r->h = h;
}
}
void OSystem_GP2X::makeChecksums(const byte *buf) {
assert(buf);
uint32 *sums = _dirtyChecksums;
uint x,y;
const uint last_x = (uint)_screenWidth / 8;
const uint last_y = (uint)_screenHeight / 8;
const uint BASE = 65521; /* largest prime smaller than 65536 */
/* the 8x8 blocks in buf are enumerated starting in the top left corner and
* reading each line at a time from left to right */
for (y = 0; y != last_y; y++, buf += _screenWidth * (8 - 1))
for (x = 0; x != last_x; x++, buf += 8) {
// Adler32 checksum algorithm (from RFC1950, used by gzip and zlib).
// This computes the Adler32 checksum of a 8x8 pixel block. Note
// that we can do the modulo operation (which is the slowest part)
// of the algorithm) at the end, instead of doing each iteration,
// since we only have 64 iterations in total - and thus s1 and
// s2 can't overflow anyway.
uint32 s1 = 1;
uint32 s2 = 0;
const byte *ptr = buf;
for (int subY = 0; subY < 8; subY++) {
for (int subX = 0; subX < 8; subX++) {
s1 += ptr[subX];
s2 += s1;
}
ptr += _screenWidth;
}
s1 %= BASE;
s2 %= BASE;
/* output the checksum for this block */
*sums++ = (s2 << 16) + s1;
}
}
void OSystem_GP2X::addDirtyRgnAuto(const byte *buf) {
assert(buf);
assert(((long)buf & 3) == 0);
/* generate a table of the checksums */
makeChecksums(buf);
if (!_cksumValid) {
_forceFull = true;
_cksumValid = true;
}
/* go through the checksum list, compare it with the previous checksums,
and add all dirty rectangles to a list. try to combine small rectangles
into bigger ones in a simple way */
if (!_forceFull) {
int x, y, w;
uint32 *ck = _dirtyChecksums;
for (y = 0; y != _screenHeight / 8; y++) {
for (x = 0; x != _screenWidth / 8; x++, ck++) {
if (ck[0] != ck[_cksumNum]) {
/* found a dirty 8x8 block, now go as far to the right as possible,
and at the same time, unmark the dirty status by setting old to new. */
w=0;
do {
ck[w + _cksumNum] = ck[w];
w++;
} while (x + w != _screenWidth / 8 && ck[w] != ck[w + _cksumNum]);
addDirtyRect(x * 8, y * 8, w * 8, 8);
if (_forceFull)
goto get_out;
}
}
}
} else {
get_out:;
/* Copy old checksums to new */
memcpy(_dirtyChecksums + _cksumNum, _dirtyChecksums, _cksumNum * sizeof(uint32));
}
}
int16 OSystem_GP2X::getHeight() {
return _screenHeight;
}
int16 OSystem_GP2X::getWidth() {
return _screenWidth;
}
void OSystem_GP2X::setPalette(const byte *colors, uint start, uint num) {
assert(colors);
// Setting the palette before _screen is created is allowed - for now -
// since we don't actually set the palette until the screen is updated.
// But it could indicate a programming error, so let's warn about it.
if (!_screen)
warning("OSystem_SDL::setPalette: _screen == NULL");
const byte *b = colors;
uint i;
SDL_Color *base = _currentPalette + start;
for (i = 0; i < num; i++) {
base[i].r = b[0];
base[i].g = b[1];
base[i].b = b[2];
b += 4;
}
if (start < _paletteDirtyStart)
_paletteDirtyStart = start;
if (start + num > _paletteDirtyEnd)
_paletteDirtyEnd = start + num;
// Some games blink cursors with palette
if (_cursorPaletteDisabled)
blitCursor();
}
void OSystem_GP2X::grabPalette(byte *colors, uint start, uint num) {
assert(colors);
const SDL_Color *base = _currentPalette + start;
for (uint i = 0; i < num; ++i) {
colors[i * 4] = base[i].r;
colors[i * 4 + 1] = base[i].g;
colors[i * 4 + 2] = base[i].b;
colors[i * 4 + 3] = 0xFF;
}
}
void OSystem_GP2X::setCursorPalette(const byte *colors, uint start, uint num) {
assert(colors);
const byte *b = colors;
uint i;
SDL_Color *base = _cursorPalette + start;
for (i = 0; i < num; i++) {
base[i].r = b[0];
base[i].g = b[1];
base[i].b = b[2];
b += 4;
}
_cursorPaletteDisabled = false;
blitCursor();
}
void OSystem_GP2X::setShakePos(int shake_pos) {
assert (_transactionMode == kTransactionNone);
_newShakePos = shake_pos;
}
#pragma mark -
#pragma mark --- Overlays ---
#pragma mark -
void OSystem_GP2X::showOverlay() {
assert (_transactionMode == kTransactionNone);
int x, y;
if (_overlayVisible)
return;
_overlayVisible = true;
// Since resolution could change, put mouse to adjusted position
// Fixes bug #1349059
x = _mouseCurState.x * _scaleFactor;
if (_adjustAspectRatio)
y = real2Aspect(_mouseCurState.y) * _scaleFactor;
else
y = _mouseCurState.y * _scaleFactor;
warpMouse(x, y);
clearOverlay();
}
void OSystem_GP2X::hideOverlay() {
assert (_transactionMode == kTransactionNone);
if (!_overlayVisible)
return;
int x, y;
_overlayVisible = false;
// Since resolution could change, put mouse to adjusted position
// Fixes bug #1349059
x = _mouseCurState.x / _scaleFactor;
y = _mouseCurState.y / _scaleFactor;
if (_adjustAspectRatio)
y = aspect2Real(y);
warpMouse(x, y);
clearOverlay();
_forceFull = true;
}
void OSystem_GP2X::clearOverlay() {
//assert (_transactionMode == kTransactionNone);
Common::StackLock lock(_graphicsMutex); // Lock the mutex until this function ends
if (!_overlayVisible)
return;
// Clear the overlay by making the game screen "look through" everywhere.
SDL_Rect src, dst;
src.x = src.y = 0;
dst.x = dst.y = 1;
src.w = dst.w = _screenWidth;
src.h = dst.h = _screenHeight;
if (SDL_BlitSurface(_screen, &src, _tmpscreen, &dst) != 0)
error("SDL_BlitSurface failed: %s", SDL_GetError());
SDL_LockSurface(_tmpscreen);
SDL_LockSurface(_overlayscreen);
_scalerProc((byte *)(_tmpscreen->pixels) + _tmpscreen->pitch + 2, _tmpscreen->pitch,
(byte *)_overlayscreen->pixels, _overlayscreen->pitch, _screenWidth, _screenHeight);
#ifndef DISABLE_SCALERS
if (_adjustAspectRatio)
stretch200To240((uint8 *)_overlayscreen->pixels, _overlayscreen->pitch,
_overlayWidth, _screenHeight * _scaleFactor, 0, 0, 0);
#endif
SDL_UnlockSurface(_tmpscreen);
SDL_UnlockSurface(_overlayscreen);
_forceFull = true;
}
void OSystem_GP2X::grabOverlay(OverlayColor *buf, int pitch) {
assert (_transactionMode == kTransactionNone);
if (_overlayscreen == NULL)
return;
if (SDL_LockSurface(_overlayscreen) == -1)
error("SDL_LockSurface failed: %s", SDL_GetError());
byte *src = (byte *)_overlayscreen->pixels;
int h = _overlayHeight;
do {
memcpy(buf, src, _overlayWidth * 2);
src += _overlayscreen->pitch;
buf += pitch;
} while (--h);
SDL_UnlockSurface(_overlayscreen);
}
void OSystem_GP2X::copyRectToOverlay(const OverlayColor *buf, int pitch, int x, int y, int w, int h) {
assert (_transactionMode == kTransactionNone);
if (_overlayscreen == NULL)
return;
// Clip the coordinates
if (x < 0) {
w += x;
buf -= x;
x = 0;
}
if (y < 0) {
h += y; buf -= y * pitch;
y = 0;
}
if (w > _overlayWidth - x) {
w = _overlayWidth - x;
}
if (h > _overlayHeight - y) {
h = _overlayHeight - y;
}
if (w <= 0 || h <= 0)
return;
// Mark the modified region as dirty
_cksumValid = false;
addDirtyRect(x, y, w, h);
if (SDL_LockSurface(_overlayscreen) == -1)
error("SDL_LockSurface failed: %s", SDL_GetError());
byte *dst = (byte *)_overlayscreen->pixels + y * _overlayscreen->pitch + x * 2;
do {
memcpy(dst, buf, w * 2);
dst += _overlayscreen->pitch;
buf += pitch;
} while (--h);
SDL_UnlockSurface(_overlayscreen);
}
OverlayColor OSystem_GP2X::RGBToColor(uint8 r, uint8 g, uint8 b) {
return SDL_MapRGB(_overlayscreen->format, r, g, b);
}
void OSystem_GP2X::colorToRGB(OverlayColor color, uint8 &r, uint8 &g, uint8 &b) {
SDL_GetRGB(color, _overlayscreen->format, &r, &g, &b);
}
#pragma mark -
#pragma mark --- Mouse ---
#pragma mark -
bool OSystem_GP2X::showMouse(bool visible) {
if (_mouseVisible == visible)
return visible;
bool last = _mouseVisible;
_mouseVisible = visible;
return last;
}
void OSystem_GP2X::setMousePos(int x, int y) {
if (x != _mouseCurState.x || y != _mouseCurState.y) {
_mouseCurState.x = x;
_mouseCurState.y = y;
}
}
void OSystem_GP2X::warpMouse(int x, int y) {
int y1 = y;
if (_adjustAspectRatio && !_overlayVisible)
y1 = real2Aspect(y);
if (_mouseCurState.x != x || _mouseCurState.y != y) {
if (!_overlayVisible)
SDL_WarpMouse(x * _scaleFactor, y1 * _scaleFactor);
else
SDL_WarpMouse(x, y1);
// SDL_WarpMouse() generates a mouse movement event, so
// setMousePos() would be called eventually. However, the
// cannon script in CoMI calls this function twice each time
// the cannon is reloaded. Unless we update the mouse position
// immediately the second call is ignored, causing the cannon
// to change its aim.
setMousePos(x, y);
}
}
void OSystem_GP2X::setMouseCursor(const byte *buf, uint w, uint h, int hotspot_x, int hotspot_y, byte keycolor, int cursorTargetScale) {
if (w == 0 || h == 0)
return;
_mouseCurState.hotX = hotspot_x;
_mouseCurState.hotY = hotspot_y;
_mouseKeyColor = keycolor;
_cursorTargetScale = cursorTargetScale;
if (_mouseCurState.w != (int)w || _mouseCurState.h != (int)h) {
_mouseCurState.w = w;
_mouseCurState.h = h;
if (_mouseOrigSurface)
SDL_FreeSurface(_mouseOrigSurface);
// Allocate bigger surface because AdvMame2x adds black pixel at [0,0]
_mouseOrigSurface = SDL_CreateRGBSurface(SDL_SWSURFACE | SDL_RLEACCEL | SDL_SRCCOLORKEY | SDL_SRCALPHA,
_mouseCurState.w + 2,
_mouseCurState.h + 2,
16,
_hwscreen->format->Rmask,
_hwscreen->format->Gmask,
_hwscreen->format->Bmask,
_hwscreen->format->Amask);
if (_mouseOrigSurface == NULL)
error("allocating _mouseOrigSurface failed");
SDL_SetColorKey(_mouseOrigSurface, SDL_RLEACCEL | SDL_SRCCOLORKEY | SDL_SRCALPHA, kMouseColorKey);
}
free(_mouseData);
_mouseData = (byte *)malloc(w * h);
memcpy(_mouseData, buf, w * h);
blitCursor();
}
void OSystem_GP2X::blitCursor() {
byte *dstPtr;
const byte *srcPtr = _mouseData;
byte color;
int w, h, i, j;
if (!_mouseOrigSurface || !_mouseData)
return;
w = _mouseCurState.w;
h = _mouseCurState.h;
SDL_LockSurface(_mouseOrigSurface);
// Make whole surface transparent
for (i = 0; i < h + 2; i++) {
dstPtr = (byte *)_mouseOrigSurface->pixels + _mouseOrigSurface->pitch * i;
for (j = 0; j < w + 2; j++) {
*(uint16 *)dstPtr = kMouseColorKey;
dstPtr += 2;
}
}
// Draw from [1,1] since AdvMame2x adds artefact at 0,0
dstPtr = (byte *)_mouseOrigSurface->pixels + _mouseOrigSurface->pitch + 2;
SDL_Color *palette;
if (_cursorPaletteDisabled)
palette = _currentPalette;
else
palette = _cursorPalette;
for (i = 0; i < h; i++) {
for (j = 0; j < w; j++) {
color = *srcPtr;
if (color != _mouseKeyColor) { // transparent, don't draw
*(uint16 *)dstPtr = SDL_MapRGB(_mouseOrigSurface->format,
palette[color].r, palette[color].g, palette[color].b);
}
dstPtr += 2;
srcPtr++;
}
dstPtr += _mouseOrigSurface->pitch - w * 2;
}
int rW, rH;
if (_cursorTargetScale >= _scaleFactor) {
// The cursor target scale is greater or equal to the scale at
// which the rest of the screen is drawn. We do not downscale
// the cursor image, we draw it at its original size. It will
// appear too large on screen.
rW = w;
rH = h;
_mouseCurState.rHotX = _mouseCurState.hotX;
_mouseCurState.rHotY = _mouseCurState.hotY;
// The virtual dimensions may be larger than the original.
_mouseCurState.vW = w * _cursorTargetScale / _scaleFactor;
_mouseCurState.vH = h * _cursorTargetScale / _scaleFactor;
_mouseCurState.vHotX = _mouseCurState.hotX * _cursorTargetScale /
_scaleFactor;
_mouseCurState.vHotY = _mouseCurState.hotY * _cursorTargetScale /
_scaleFactor;
} else {
// The cursor target scale is smaller than the scale at which
// the rest of the screen is drawn. We scale up the cursor
// image to make it appear correct.
rW = w * _scaleFactor / _cursorTargetScale;
rH = h * _scaleFactor / _cursorTargetScale;
_mouseCurState.rHotX = _mouseCurState.hotX * _scaleFactor /
_cursorTargetScale;
_mouseCurState.rHotY = _mouseCurState.hotY * _scaleFactor /
_cursorTargetScale;
// The virtual dimensions will be the same as the original.
_mouseCurState.vW = w;
_mouseCurState.vH = h;
_mouseCurState.vHotX = _mouseCurState.hotX;
_mouseCurState.vHotY = _mouseCurState.hotY;
}
int rH1 = rH; // store original to pass to aspect-correction function later
if (_adjustAspectRatio && _cursorTargetScale == 1) {
rH = real2Aspect(rH - 1) + 1;
_mouseCurState.rHotY = real2Aspect(_mouseCurState.rHotY);
}
if (_mouseCurState.rW != rW || _mouseCurState.rH != rH) {
_mouseCurState.rW = rW;
_mouseCurState.rH = rH;
if (_mouseSurface)
SDL_FreeSurface(_mouseSurface);
_mouseSurface = SDL_CreateRGBSurface(SDL_SWSURFACE | SDL_RLEACCEL | SDL_SRCCOLORKEY | SDL_SRCALPHA,
_mouseCurState.rW,
_mouseCurState.rH,
16,
_hwscreen->format->Rmask,
_hwscreen->format->Gmask,
_hwscreen->format->Bmask,
_hwscreen->format->Amask);
if (_mouseSurface == NULL)
error("allocating _mouseSurface failed");
SDL_SetColorKey(_mouseSurface, SDL_RLEACCEL | SDL_SRCCOLORKEY | SDL_SRCALPHA, kMouseColorKey);
}
SDL_LockSurface(_mouseSurface);
ScalerProc *scalerProc;
// If possible, use the same scaler for the cursor as for the rest of
// the game. This only works well with the non-blurring scalers so we
// actually only use the 1x, 1.5x, 2x and AdvMame scalers.
if (_cursorTargetScale == 1 && (_mode == GFX_DOUBLESIZE || _mode == GFX_TRIPLESIZE))
scalerProc = _scalerProc;
else
scalerProc = scalersMagn[_cursorTargetScale - 1][_scaleFactor - 1];
scalerProc((byte *)_mouseOrigSurface->pixels + _mouseOrigSurface->pitch + 2,
_mouseOrigSurface->pitch, (byte *)_mouseSurface->pixels, _mouseSurface->pitch,
_mouseCurState.w, _mouseCurState.h);
if (_adjustAspectRatio && _cursorTargetScale == 1)
cursorStretch200To240((uint8 *)_mouseSurface->pixels, _mouseSurface->pitch, rW, rH1, 0, 0, 0);
SDL_UnlockSurface(_mouseSurface);
SDL_UnlockSurface(_mouseOrigSurface);
}
// Basically it is kVeryFastAndUglyAspectMode of stretch200To240 from
// common/scale/aspect.cpp
static int cursorStretch200To240(uint8 *buf, uint32 pitch, int width, int height, int srcX, int srcY, int origSrcY) {
int maxDstY = real2Aspect(origSrcY + height - 1);
int y;
const uint8 *startSrcPtr = buf + srcX * 2 + (srcY - origSrcY) * pitch;
uint8 *dstPtr = buf + srcX * 2 + maxDstY * pitch;
for (y = maxDstY; y >= srcY; y--) {
const uint8 *srcPtr = startSrcPtr + aspect2Real(y) * pitch;
if (srcPtr == dstPtr)
break;
memcpy(dstPtr, srcPtr, width * 2);
dstPtr -= pitch;
}
return 1 + maxDstY - srcY;
}
void OSystem_GP2X::undrawMouse() {
const int x = _mouseBackup.x;
const int y = _mouseBackup.y;
// When we switch bigger overlay off mouse jumps. Argh!
// This is intended to prevent undrawing offscreen mouse
if (!_overlayVisible && (x >= _screenWidth || y >= _screenHeight)) {
return;
}
if (_mouseBackup.w != 0 && _mouseBackup.h != 0)
addDirtyRect(x, y, _mouseBackup.w, _mouseBackup.h);
}
void OSystem_GP2X::drawMouse() {
if (!_mouseVisible || !_mouseSurface) {
_mouseBackup.x = _mouseBackup.y = _mouseBackup.w = _mouseBackup.h = 0;
return;
}
SDL_Rect zoomdst;
SDL_Rect dst;
int scale;
int width, height;
int hotX, hotY;
int tmpScreenWidth, tmpScreenHeight;
// Temp vars to ensure we zoom to the LCD resolution or greater.
tmpScreenWidth = _screenWidth;
tmpScreenHeight = _screenHeight;
if (_screenHeight <= 240) {
tmpScreenHeight = 240;
}
if (_screenWidth <= 320) {
tmpScreenWidth = 320;
}
dst.x = _mouseCurState.x;
dst.y = _mouseCurState.y;
if (!_overlayVisible) {
scale = _scaleFactor;
width = _screenWidth;
height = _screenHeight;
dst.w = _mouseCurState.vW;
dst.h = _mouseCurState.vH;
hotX = _mouseCurState.vHotX;
hotY = _mouseCurState.vHotY;
} else {
scale = 1;
width = _overlayWidth;
height = _overlayHeight;
dst.w = _mouseCurState.rW;
dst.h = _mouseCurState.rH;
hotX = _mouseCurState.rHotX;
hotY = _mouseCurState.rHotY;
}
// The mouse is undrawn using virtual coordinates, i.e. they may be
// scaled and aspect-ratio corrected.
_mouseBackup.x = dst.x - hotX;
_mouseBackup.y = dst.y - hotY;
_mouseBackup.w = dst.w;
_mouseBackup.h = dst.h;
// We draw the pre-scaled cursor image, so now we need to adjust for
// scaling, shake position and aspect ratio correction manually.
if (!_overlayVisible) {
dst.y += _currentShakePos;
}
if (_adjustAspectRatio && !_overlayVisible)
dst.y = real2Aspect(dst.y);
dst.x = scale * dst.x - _mouseCurState.rHotX;
dst.y = scale * dst.y - _mouseCurState.rHotY;
dst.w = _mouseCurState.rW;
dst.h = _mouseCurState.rH;
// Hacking about with the zoom around mouse pointer stuff.
if (_adjustZoomOnMouse == true){
zoomdst.w = (tmpScreenWidth / 2);
zoomdst.h = (tmpScreenHeight / 2);
// Create a zoomed rect centered on the mouse pointer.
// Will pan 1/4 of the screen.
if (dst.x > ((tmpScreenWidth / 4) * 3)) {
zoomdst.x = (tmpScreenWidth / 2);
} else {
zoomdst.x = (dst.x - (tmpScreenWidth / 4));
if (zoomdst.x < 0) {
zoomdst.x = 0;
}
}
if (dst.y > ((tmpScreenHeight / 4) * 3)) {
zoomdst.y = (tmpScreenHeight / 2);
} else {
zoomdst.y = (dst.y - (tmpScreenHeight / 4));
if (zoomdst.y < 0) {
zoomdst.y = 0;
}
}
SDL_GP2X_Display(&zoomdst);
} else {
// Make sure we are looking at the whole screen otherwise.
zoomdst.x = 0;
zoomdst.y = 0;
zoomdst.w = (tmpScreenWidth);
zoomdst.h = (tmpScreenHeight);
SDL_GP2X_Display(&zoomdst);
};
// Note that SDL_BlitSurface() and addDirtyRect() will both perform any
// clipping necessary
if (SDL_BlitSurface(_mouseSurface, NULL, _hwscreen, &dst) != 0)
error("SDL_BlitSurface failed: %s", SDL_GetError());
// The screen will be updated using real surface coordinates, i.e.
// they will not be scaled or aspect-ratio corrected.
addDirtyRect(dst.x, dst.y, dst.w, dst.h, true);
}
#pragma mark -
#pragma mark --- On Screen Display ---
#pragma mark -
void OSystem_GP2X::displayMessageOnOSD(const char *msg) {
assert (_transactionMode == kTransactionNone);
assert(msg);
Common::StackLock lock(_graphicsMutex); // Lock the mutex until this function ends
uint i;
// Lock the OSD surface for drawing
if (SDL_LockSurface(_osdSurface))
error("displayMessageOnOSD: SDL_LockSurface failed: %s", SDL_GetError());
Graphics::Surface dst;
dst.pixels = _osdSurface->pixels;
dst.w = _osdSurface->w;
dst.h = _osdSurface->h;
dst.pitch = _osdSurface->pitch;
dst.bytesPerPixel = _osdSurface->format->BytesPerPixel;
// The font we are going to use:
const Graphics::Font *font = FontMan.getFontByUsage(Graphics::FontManager::kOSDFont);
// Clear everything with the "transparent" color, i.e. the colorkey
SDL_FillRect(_osdSurface, 0, kOSDColorKey);
// Split the message into separate lines.
Common::StringList lines;
const char *ptr;
for (ptr = msg; *ptr; ++ptr) {
if (*ptr == '\n') {
lines.push_back(Common::String(msg, ptr - msg));
msg = ptr + 1;
}
}
lines.push_back(Common::String(msg, ptr - msg));
// Determine a rect which would contain the message string (clipped to the
// screen dimensions).
const int vOffset = 6;
const int lineSpacing = 1;
const int lineHeight = font->getFontHeight() + 2 * lineSpacing;
int width = 0;
int height = lineHeight * lines.size() + 2 * vOffset;
for (i = 0; i < lines.size(); i++) {
width = MAX(width, font->getStringWidth(lines[i]) + 14);
}
// Clip the rect
if (width > dst.w)
width = dst.w;
if (height > dst.h)
height = dst.h;
// Draw a dark gray rect
// TODO: Rounded corners ? Border?
SDL_Rect osdRect;
osdRect.x = (dst.w - width) / 2;
osdRect.y = (dst.h - height) / 2;
osdRect.w = width;
osdRect.h = height;
SDL_FillRect(_osdSurface, &osdRect, SDL_MapRGB(_osdSurface->format, 64, 64, 64));
// Render the message, centered, and in white
for (i = 0; i < lines.size(); i++) {
font->drawString(&dst, lines[i],
osdRect.x, osdRect.y + i * lineHeight + vOffset + lineSpacing, osdRect.w,
SDL_MapRGB(_osdSurface->format, 255, 255, 255),
Graphics::kTextAlignCenter);
}
// Finished drawing, so unlock the OSD surface again
SDL_UnlockSurface(_osdSurface);
// Init the OSD display parameters, and the fade out
_osdAlpha = SDL_ALPHA_TRANSPARENT + kOSDInitialAlpha * (SDL_ALPHA_OPAQUE - SDL_ALPHA_TRANSPARENT) / 100;
_osdFadeStartTime = SDL_GetTicks() + kOSDFadeOutDelay;
SDL_SetAlpha(_osdSurface, SDL_RLEACCEL | SDL_SRCCOLORKEY | SDL_SRCALPHA, _osdAlpha);
// Ensure a full redraw takes place next time the screen is updated
_forceFull = true;
}
#pragma mark -
#pragma mark --- Misc ---
#pragma mark -
void OSystem_GP2X::handleScalerHotkeys(const SDL_KeyboardEvent &key) {
// Ctrl-Alt-a toggles aspect ratio correction
if (key.keysym.sym == 'a') {
setFeatureState(kFeatureAspectRatioCorrection, !_adjustAspectRatio);
char buffer[128];
if (_adjustAspectRatio)
sprintf(buffer, "Enabled aspect ratio correction\n%d x %d -> %d x %d",
_screenWidth, _screenHeight,
_hwscreen->w, _hwscreen->h
);
else
sprintf(buffer, "Disabled aspect ratio correction\n%d x %d -> %d x %d",
_screenWidth, _screenHeight,
_hwscreen->w, _hwscreen->h
);
displayMessageOnOSD(buffer);
return;
}
int newMode = -1;
int factor = _scaleFactor - 1;
// Increase/decrease the scale factor
if (key.keysym.sym == SDLK_EQUALS || key.keysym.sym == SDLK_PLUS || key.keysym.sym == SDLK_MINUS ||
key.keysym.sym == SDLK_KP_PLUS || key.keysym.sym == SDLK_KP_MINUS) {
factor += (key.keysym.sym == SDLK_MINUS || key.keysym.sym == SDLK_KP_MINUS) ? -1 : +1;
if (0 <= factor && factor <= 3) {
newMode = s_gfxModeSwitchTable[_scalerType][factor];
}
}
const bool isNormalNumber = (SDLK_1 <= key.keysym.sym && key.keysym.sym <= SDLK_9);
const bool isKeypadNumber = (SDLK_KP1 <= key.keysym.sym && key.keysym.sym <= SDLK_KP9);
if (isNormalNumber || isKeypadNumber) {
_scalerType = key.keysym.sym - (isNormalNumber ? SDLK_1 : SDLK_KP1);
if (_scalerType >= ARRAYSIZE(s_gfxModeSwitchTable))
return;
while (s_gfxModeSwitchTable[_scalerType][factor] < 0) {
assert(factor > 0);
factor--;
}
newMode = s_gfxModeSwitchTable[_scalerType][factor];
}
if (newMode >= 0) {
setGraphicsMode(newMode);
if (_osdSurface) {
const char *newScalerName = 0;
const GraphicsMode *g = getSupportedGraphicsModes();
while (g->name) {
if (g->id == _mode) {
newScalerName = g->description;
break;
}
g++;
}
if (newScalerName) {
char buffer[128];
sprintf(buffer, "Active graphics filter: %s\n%d x %d -> %d x %d",
newScalerName,
_screenWidth, _screenHeight,
_hwscreen->w, _hwscreen->h
);
displayMessageOnOSD(buffer);
}
}
}
}