/* 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.
*
*/
#if defined(__ANDROID__)
// Allow use of stuff in <time.h>
#define FORBIDDEN_SYMBOL_EXCEPTION_time_h
// Disable printf override in common/forbidden.h to avoid
// clashes with log.h from the Android SDK.
// That header file uses
// __attribute__ ((format(printf, 3, 4)))
// which gets messed up by our override mechanism; this could
// be avoided by either changing the Android SDK to use the equally
// legal and valid
// __attribute__ ((format(printf, 3, 4)))
// or by refining our printf override to use a varadic macro
// (which then wouldn't be portable, though).
// Anyway, for now we just disable the printf override globally
// for the Android port
#define FORBIDDEN_SYMBOL_EXCEPTION_printf
#include "common/endian.h"
#include "graphics/conversion.h"
#include "backends/platform/android/android.h"
#include "backends/platform/android/jni.h"
static inline GLfixed xdiv(int numerator, int denominator) {
assert(numerator < (1 << 16));
return (numerator << 16) / denominator;
}
const OSystem::GraphicsMode *OSystem_Android::getSupportedGraphicsModes() const {
static const OSystem::GraphicsMode s_supportedGraphicsModes[] = {
{ "default", "Default", 0 },
{ "filter", "Linear filtering", 1 },
{ 0, 0, 0 },
};
return s_supportedGraphicsModes;
}
int OSystem_Android::getDefaultGraphicsMode() const {
return 0;
}
bool OSystem_Android::setGraphicsMode(int mode) {
ENTER("%d", mode);
if (_game_texture)
_game_texture->setLinearFilter(mode == 1);
if (_overlay_texture)
_overlay_texture->setLinearFilter(mode == 1);
if (_mouse_texture)
_mouse_texture->setLinearFilter(mode == 1);
_graphicsMode = mode;
return true;
}
int OSystem_Android::getGraphicsMode() const {
return _graphicsMode;
}
#ifdef USE_RGB_COLOR
Graphics::PixelFormat OSystem_Android::getScreenFormat() const {
return _game_texture->getPixelFormat();
}
Common::List<Graphics::PixelFormat> OSystem_Android::getSupportedFormats() const {
Common::List<Graphics::PixelFormat> res;
res.push_back(GLES565Texture::pixelFormat());
res.push_back(GLES5551Texture::pixelFormat());
res.push_back(GLES8888Texture::pixelFormat());
res.push_back(GLES4444Texture::pixelFormat());
res.push_back(Graphics::PixelFormat::createFormatCLUT8());
return res;
}
Common::String OSystem_Android::getPixelFormatName(const Graphics::PixelFormat &format) const {
if (format.bytesPerPixel == 1)
return "CLUT8";
if (format.aLoss == 8)
return Common::String::format("RGB%u%u%u",
8 - format.rLoss,
8 - format.gLoss,
8 - format.bLoss);
return Common::String::format("RGBA%u%u%u%u",
8 - format.rLoss,
8 - format.gLoss,
8 - format.bLoss,
8 - format.aLoss);
}
void OSystem_Android::initTexture(GLESBaseTexture **texture,
uint width, uint height,
const Graphics::PixelFormat *format) {
assert(texture);
Graphics::PixelFormat format_clut8 =
Graphics::PixelFormat::createFormatCLUT8();
Graphics::PixelFormat format_current;
Graphics::PixelFormat format_new;
if (*texture)
format_current = (*texture)->getPixelFormat();
else
format_current = Graphics::PixelFormat();
if (format)
format_new = *format;
else
format_new = format_clut8;
if (format_current != format_new) {
if (*texture)
LOGD("switching pixel format from: %s",
getPixelFormatName((*texture)->getPixelFormat()).c_str());
delete *texture;
if (format_new == GLES565Texture::pixelFormat())
*texture = new GLES565Texture();
else if (format_new == GLES5551Texture::pixelFormat())
*texture = new GLES5551Texture();
else if (format_new == GLES8888Texture::pixelFormat())
*texture = new GLES8888Texture();
else if (format_new == GLES4444Texture::pixelFormat())
*texture = new GLES4444Texture();
else {
// TODO what now?
if (format_new != format_clut8)
LOGE("unsupported pixel format: %s",
getPixelFormatName(format_new).c_str());
*texture = new GLESFakePalette565Texture;
}
LOGD("new pixel format: %s",
getPixelFormatName((*texture)->getPixelFormat()).c_str());
}
(*texture)->allocBuffer(width, height);
}
#endif
void OSystem_Android::initSurface() {
LOGD("initializing surface");
assert(!JNI::haveSurface());
_screen_changeid = JNI::surface_changeid;
_egl_surface_width = JNI::egl_surface_width;
_egl_surface_height = JNI::egl_surface_height;
assert(_egl_surface_width > 0 && _egl_surface_height > 0);
JNI::initSurface();
// Initialize OpenGLES context.
GLESTexture::initGLExtensions();
if (_game_texture)
_game_texture->reinit();
if (_overlay_texture) {
_overlay_texture->reinit();
initOverlay();
}
if (_mouse_texture)
_mouse_texture->reinit();
}
void OSystem_Android::deinitSurface() {
if (!JNI::haveSurface())
return;
LOGD("deinitializing surface");
_screen_changeid = JNI::surface_changeid;
_egl_surface_width = 0;
_egl_surface_height = 0;
// release texture resources
if (_game_texture)
_game_texture->release();
if (_overlay_texture)
_overlay_texture->release();
if (_mouse_texture)
_mouse_texture->release();
JNI::deinitSurface();
}
void OSystem_Android::initViewport() {
LOGD("initializing viewport");
assert(JNI::haveSurface());
// Turn off anything that looks like 3D ;)
GLCALL(glDisable(GL_CULL_FACE));
GLCALL(glDisable(GL_DEPTH_TEST));
GLCALL(glDisable(GL_LIGHTING));
GLCALL(glDisable(GL_FOG));
GLCALL(glDisable(GL_DITHER));
GLCALL(glShadeModel(GL_FLAT));
GLCALL(glHint(GL_PERSPECTIVE_CORRECTION_HINT, GL_FASTEST));
GLCALL(glEnable(GL_BLEND));
GLCALL(glBlendFunc(GL_ONE, GL_ONE_MINUS_SRC_ALPHA));
GLCALL(glEnableClientState(GL_VERTEX_ARRAY));
GLCALL(glEnableClientState(GL_TEXTURE_COORD_ARRAY));
GLCALL(glEnable(GL_TEXTURE_2D));
GLCALL(glViewport(0, 0, _egl_surface_width, _egl_surface_height));
GLCALL(glMatrixMode(GL_PROJECTION));
GLCALL(glLoadIdentity());
GLCALL(glOrthof(0, _egl_surface_width, _egl_surface_height, 0, -1, 1));
GLCALL(glMatrixMode(GL_MODELVIEW));
GLCALL(glLoadIdentity());
clearFocusRectangle();
}
void OSystem_Android::initOverlay() {
// minimum of 320x200
// (surface can get smaller when opening the virtual keyboard on *QVGA*)
int overlay_width = MAX(_egl_surface_width, 320);
int overlay_height = MAX(_egl_surface_height, 200);
// the 'normal' theme layout uses a max height of 400 pixels. if the
// surface is too big we use only a quarter of the size so that the widgets
// don't get too small. if the surface height has less than 800 pixels, this
// enforces the 'lowres' layout, which will be scaled back up by factor 2x,
// but this looks way better than the 'normal' layout scaled by some
// calculated factors
while (overlay_height > 480) {
overlay_width /= 2;
overlay_height /= 2;
}
LOGI("overlay size is %ux%u", overlay_width, overlay_height);
_overlay_texture->allocBuffer(overlay_width, overlay_height);
_overlay_texture->setDrawRect(0, 0,
_egl_surface_width, _egl_surface_height);
}
void OSystem_Android::initSize(uint width, uint height,
const Graphics::PixelFormat *format) {
ENTER("%d, %d, %p", width, height, format);
GLTHREADCHECK;
#ifdef USE_RGB_COLOR
initTexture(&_game_texture, width, height, format);
#else
_game_texture->allocBuffer(width, height);
#endif
updateScreenRect();
updateEventScale();
// Don't know mouse size yet - it gets reallocated in
// setMouseCursor. We need the palette allocated before
// setMouseCursor however, so just take a guess at the desired
// size (it's small).
_mouse_texture_palette->allocBuffer(20, 20);
clearScreen(kClear);
}
void OSystem_Android::clearScreen(FixupType type, byte count) {
assert(count > 0);
bool sm = _show_mouse;
_show_mouse = false;
GLCALL(glDisable(GL_SCISSOR_TEST));
for (byte i = 0; i < count; ++i) {
// clear screen
GLCALL(glClearColorx(0, 0, 0, 1 << 16));
GLCALL(glClear(GL_COLOR_BUFFER_BIT));
switch (type) {
case kClear:
break;
case kClearSwap:
JNI::swapBuffers();
break;
case kClearUpdate:
_force_redraw = true;
updateScreen();
break;
}
}
if (!_show_overlay)
GLCALL(glEnable(GL_SCISSOR_TEST));
_show_mouse = sm;
_force_redraw = true;
}
void OSystem_Android::updateScreenRect() {
Common::Rect rect(0, 0, _egl_surface_width, _egl_surface_height);
_overlay_texture->setDrawRect(rect);
uint16 w = _game_texture->width();
uint16 h = _game_texture->height();
if (w && h && !_fullscreen) {
if (_ar_correction && w == 320 && h == 200)
h = 240;
float dpi[2];
JNI::getDPI(dpi);
float screen_ar;
if (dpi[0] != 0.0 && dpi[1] != 0.0) {
// horizontal orientation
screen_ar = (dpi[1] * _egl_surface_width) /
(dpi[0] * _egl_surface_height);
} else {
screen_ar = float(_egl_surface_width) / float(_egl_surface_height);
}
float game_ar = float(w) / float(h);
if (screen_ar > game_ar) {
rect.setWidth(round(_egl_surface_height * game_ar));
rect.moveTo((_egl_surface_width - rect.width()) / 2, 0);
} else {
rect.setHeight(round(_egl_surface_width / game_ar));
rect.moveTo((_egl_surface_height - rect.height()) / 2, 0);
}
}
glScissor(rect.left, rect.top, rect.width(), rect.height());
_game_texture->setDrawRect(rect);
}
int OSystem_Android::getScreenChangeID() const {
return _screen_changeid;
}
int16 OSystem_Android::getHeight() {
return _game_texture->height();
}
int16 OSystem_Android::getWidth() {
return _game_texture->width();
}
void OSystem_Android::setPalette(const byte *colors, uint start, uint num) {
ENTER("%p, %u, %u", colors, start, num);
#ifdef USE_RGB_COLOR
assert(_game_texture->hasPalette());
#endif
GLTHREADCHECK;
if (!_use_mouse_palette)
setCursorPaletteInternal(colors, start, num);
const Graphics::PixelFormat &pf = _game_texture->getPalettePixelFormat();
byte *p = _game_texture->palette() + start * 2;
for (uint i = 0; i < num; ++i, colors += 3, p += 2)
WRITE_UINT16(p, pf.RGBToColor(colors[0], colors[1], colors[2]));
}
void OSystem_Android::grabPalette(byte *colors, uint start, uint num) {
ENTER("%p, %u, %u", colors, start, num);
#ifdef USE_RGB_COLOR
assert(_game_texture->hasPalette());
#endif
GLTHREADCHECK;
const Graphics::PixelFormat &pf = _game_texture->getPalettePixelFormat();
const byte *p = _game_texture->palette_const() + start * 2;
for (uint i = 0; i < num; ++i, colors += 3, p += 2)
pf.colorToRGB(READ_UINT16(p), colors[0], colors[1], colors[2]);
}
void OSystem_Android::copyRectToScreen(const void *buf, int pitch,
int x, int y, int w, int h) {
ENTER("%p, %d, %d, %d, %d, %d", buf, pitch, x, y, w, h);
GLTHREADCHECK;
_game_texture->updateBuffer(x, y, w, h, buf, pitch);
}
void OSystem_Android::updateScreen() {
//ENTER();
GLTHREADCHECK;
if (!JNI::haveSurface())
return;
if (!_force_redraw &&
!_game_texture->dirty() &&
!_overlay_texture->dirty() &&
!_mouse_texture->dirty())
return;
_force_redraw = false;
// clear pointer leftovers in dead areas
// also, HTC's GLES drivers are made of fail and don't preserve the buffer
// ( http://www.khronos.org/registry/egl/specs/EGLTechNote0001.html )
if ((_show_overlay || _htc_fail) && !_fullscreen)
clearScreen(kClear);
GLCALL(glPushMatrix());
if (_shake_offset != 0 ||
(!_focus_rect.isEmpty() &&
!Common::Rect(_game_texture->width(),
_game_texture->height()).contains(_focus_rect))) {
// These are the only cases where _game_texture doesn't
// cover the entire screen.
clearScreen(kClear);
// Move everything up by _shake_offset (game) pixels
GLCALL(glTranslatex(0, -_shake_offset << 16, 0));
}
// TODO this doesn't work on those sucky drivers, do it differently
// if (_show_overlay)
// GLCALL(glColor4ub(0x9f, 0x9f, 0x9f, 0x9f));
if (_focus_rect.isEmpty()) {
_game_texture->drawTextureRect();
} else {
GLCALL(glPushMatrix());
GLCALL(glScalex(xdiv(_egl_surface_width, _focus_rect.width()),
xdiv(_egl_surface_height, _focus_rect.height()),
1 << 16));
GLCALL(glTranslatex(-_focus_rect.left << 16,
-_focus_rect.top << 16, 0));
GLCALL(glScalex(xdiv(_game_texture->width(), _egl_surface_width),
xdiv(_game_texture->height(), _egl_surface_height),
1 << 16));
_game_texture->drawTextureRect();
GLCALL(glPopMatrix());
}
int cs = _mouse_targetscale;
if (_show_overlay) {
// TODO see above
// GLCALL(glColor4ub(0xff, 0xff, 0xff, 0xff));
// ugly, but the modern theme sets a wacko factor, only god knows why
cs = 1;
GLCALL(_overlay_texture->drawTextureRect());
}
if (_show_mouse && !_mouse_texture->isEmpty()) {
GLCALL(glPushMatrix());
const Common::Point &mouse = getEventManager()->getMousePos();
// Scale up ScummVM -> OpenGL (pixel) coordinates
if (_show_overlay) {
GLCALL(glScalex(xdiv(_egl_surface_width,
_overlay_texture->width()),
xdiv(_egl_surface_height,
_overlay_texture->height()),
1 << 16));
} else {
const Common::Rect &r = _game_texture->getDrawRect();
GLCALL(glTranslatex(r.left << 16,
r.top << 16,
0));
GLCALL(glScalex(xdiv(r.width(), _game_texture->width()),
xdiv(r.height(), _game_texture->height()),
1 << 16));
}
GLCALL(glTranslatex((-_mouse_hotspot.x * cs) << 16,
(-_mouse_hotspot.y * cs) << 16,
0));
// Note the extra half texel to position the mouse in
// the middle of the x,y square:
GLCALL(glTranslatex((mouse.x << 16) | 1 << 15,
(mouse.y << 16) | 1 << 15, 0));
GLCALL(glScalex(cs << 16, cs << 16, 1 << 16));
_mouse_texture->drawTextureOrigin();
GLCALL(glPopMatrix());
}
GLCALL(glPopMatrix());
if (!JNI::swapBuffers())
LOGW("swapBuffers failed: 0x%x", glGetError());
}
Graphics::Surface *OSystem_Android::lockScreen() {
ENTER();
GLTHREADCHECK;
Graphics::Surface *surface = _game_texture->surface();
assert(surface->getPixels());
return surface;
}
void OSystem_Android::unlockScreen() {
ENTER();
GLTHREADCHECK;
assert(_game_texture->dirty());
}
void OSystem_Android::setShakePos(int shake_offset) {
ENTER("%d", shake_offset);
if (_shake_offset != shake_offset) {
_shake_offset = shake_offset;
_force_redraw = true;
}
}
void OSystem_Android::fillScreen(uint32 col) {
ENTER("%u", col);
GLTHREADCHECK;
_game_texture->fillBuffer(col);
}
void OSystem_Android::setFocusRectangle(const Common::Rect& rect) {
ENTER("%d, %d, %d, %d", rect.left, rect.top, rect.right, rect.bottom);
if (_enable_zoning) {
_focus_rect = rect;
_force_redraw = true;
}
}
void OSystem_Android::clearFocusRectangle() {
ENTER();
if (_enable_zoning) {
_focus_rect = Common::Rect();
_force_redraw = true;
}
}
void OSystem_Android::showOverlay() {
ENTER();
_show_overlay = true;
_force_redraw = true;
updateEventScale();
warpMouse(_overlay_texture->width() / 2, _overlay_texture->height() / 2);
GLCALL(glDisable(GL_SCISSOR_TEST));
}
void OSystem_Android::hideOverlay() {
ENTER();
_show_overlay = false;
updateEventScale();
warpMouse(_game_texture->width() / 2, _game_texture->height() / 2);
// double buffered, flip twice
clearScreen(kClearUpdate, 2);
GLCALL(glEnable(GL_SCISSOR_TEST));
}
void OSystem_Android::clearOverlay() {
ENTER();
GLTHREADCHECK;
_overlay_texture->fillBuffer(0);
}
void OSystem_Android::grabOverlay(void *buf, int pitch) {
ENTER("%p, %d", buf, pitch);
GLTHREADCHECK;
const Graphics::Surface *surface = _overlay_texture->surface_const();
assert(surface->format.bytesPerPixel == sizeof(uint16));
byte *dst = (byte *)buf;
const byte *src = (const byte *)surface->getPixels();
uint h = surface->h;
do {
memcpy(dst, src, surface->w * surface->format.bytesPerPixel);
src += surface->pitch;
dst += pitch;
} while (--h);
}
void OSystem_Android::copyRectToOverlay(const void *buf, int pitch,
int x, int y, int w, int h) {
ENTER("%p, %d, %d, %d, %d, %d", buf, pitch, x, y, w, h);
GLTHREADCHECK;
_overlay_texture->updateBuffer(x, y, w, h, buf, pitch);
}
int16 OSystem_Android::getOverlayHeight() {
return _overlay_texture->height();
}
int16 OSystem_Android::getOverlayWidth() {
return _overlay_texture->width();
}
Graphics::PixelFormat OSystem_Android::getOverlayFormat() const {
return _overlay_texture->getPixelFormat();
}
bool OSystem_Android::showMouse(bool visible) {
ENTER("%d", visible);
_show_mouse = visible;
return true;
}
void OSystem_Android::setMouseCursor(const void *buf, uint w, uint h,
int hotspotX, int hotspotY,
uint32 keycolor, bool dontScale,
const Graphics::PixelFormat *format) {
ENTER("%p, %u, %u, %d, %d, %u, %d, %p", buf, w, h, hotspotX, hotspotY,
keycolor, dontScale, format);
GLTHREADCHECK;
#ifdef USE_RGB_COLOR
if (format && format->bytesPerPixel > 1) {
if (_mouse_texture != _mouse_texture_rgb) {
LOGD("switching to rgb mouse cursor");
assert(!_mouse_texture_rgb);
_mouse_texture_rgb = new GLES5551Texture();
_mouse_texture_rgb->setLinearFilter(_graphicsMode == 1);
}
_mouse_texture = _mouse_texture_rgb;
} else {
if (_mouse_texture != _mouse_texture_palette)
LOGD("switching to paletted mouse cursor");
_mouse_texture = _mouse_texture_palette;
delete _mouse_texture_rgb;
_mouse_texture_rgb = 0;
}
#endif
_mouse_texture->allocBuffer(w, h);
if (_mouse_texture == _mouse_texture_palette) {
assert(keycolor < 256);
byte *p = _mouse_texture_palette->palette() + _mouse_keycolor * 2;
WRITE_UINT16(p, READ_UINT16(p) | 1);
_mouse_keycolor = keycolor;
p = _mouse_texture_palette->palette() + _mouse_keycolor * 2;
WRITE_UINT16(p, 0);
}
if (w == 0 || h == 0)
return;
if (_mouse_texture == _mouse_texture_palette) {
_mouse_texture->updateBuffer(0, 0, w, h, buf, w);
} else {
uint16 pitch = _mouse_texture->pitch();
byte *tmp = new byte[pitch * h];
// meh, a 16bit cursor without alpha bits... this is so silly
if (!crossBlit(tmp, (const byte *)buf, pitch, w * 2, w, h,
_mouse_texture->getPixelFormat(),
*format)) {
LOGE("crossblit failed");
delete[] tmp;
_mouse_texture->allocBuffer(0, 0);
return;
}
const uint16 *s = (const uint16 *)buf;
uint16 *d = (uint16 *)tmp;
for (uint16 y = 0; y < h; ++y, d += pitch / 2 - w)
for (uint16 x = 0; x < w; ++x, d++)
if (*s++ == (keycolor & 0xffff))
*d = 0;
_mouse_texture->updateBuffer(0, 0, w, h, tmp, pitch);
delete[] tmp;
}
_mouse_hotspot = Common::Point(hotspotX, hotspotY);
// TODO: Adapt to the new "do not scale" cursor logic.
_mouse_targetscale = 1;
}
void OSystem_Android::setCursorPaletteInternal(const byte *colors,
uint start, uint num) {
const Graphics::PixelFormat &pf =
_mouse_texture_palette->getPalettePixelFormat();
byte *p = _mouse_texture_palette->palette() + start * 2;
for (uint i = 0; i < num; ++i, colors += 3, p += 2)
WRITE_UINT16(p, pf.RGBToColor(colors[0], colors[1], colors[2]));
p = _mouse_texture_palette->palette() + _mouse_keycolor * 2;
WRITE_UINT16(p, 0);
}
void OSystem_Android::setCursorPalette(const byte *colors,
uint start, uint num) {
ENTER("%p, %u, %u", colors, start, num);
GLTHREADCHECK;
if (!_mouse_texture->hasPalette()) {
LOGD("switching to paletted mouse cursor");
_mouse_texture = _mouse_texture_palette;
delete _mouse_texture_rgb;
_mouse_texture_rgb = 0;
}
setCursorPaletteInternal(colors, start, num);
_use_mouse_palette = true;
}
void OSystem_Android::disableCursorPalette() {
// when disabling the cursor palette, and we're running a clut8 game,
// it expects the game palette to be used for the cursor
if (_game_texture->hasPalette()) {
const byte *src = _game_texture->palette_const();
byte *dst = _mouse_texture_palette->palette();
const Graphics::PixelFormat &pf_src =
_game_texture->getPalettePixelFormat();
const Graphics::PixelFormat &pf_dst =
_mouse_texture_palette->getPalettePixelFormat();
uint8 r, g, b;
for (uint i = 0; i < 256; ++i, src += 2, dst += 2) {
pf_src.colorToRGB(READ_UINT16(src), r, g, b);
WRITE_UINT16(dst, pf_dst.RGBToColor(r, g, b));
}
byte *p = _mouse_texture_palette->palette() + _mouse_keycolor * 2;
WRITE_UINT16(p, 0);
}
}
#endif