bsnes/ruby/video/xv.cpp

499 lines
16 KiB
C++
Executable File

#include <sys/ipc.h>
#include <sys/shm.h>
#include <X11/extensions/XShm.h>
#include <X11/extensions/Xv.h>
#include <X11/extensions/Xvlib.h>
extern "C" XvImage* XvShmCreateImage(Display*, XvPortID, int, char*, int, int, XShmSegmentInfo*);
namespace ruby {
class pVideoXv {
public:
uint32_t *buffer;
uint8_t *ytable, *utable, *vtable;
enum XvFormat {
XvFormatRGB32,
XvFormatRGB24,
XvFormatRGB16,
XvFormatRGB15,
XvFormatYUY2,
XvFormatUYVY,
XvFormatUnknown
};
struct {
Display *display;
GC gc;
Window window;
Colormap colormap;
XShmSegmentInfo shminfo;
int port;
int depth;
int visualid;
XvImage *image;
XvFormat format;
uint32_t fourcc;
unsigned width;
unsigned height;
} device;
struct {
Window handle;
bool synchronize;
unsigned width;
unsigned height;
} settings;
bool cap(const string& name) {
if(name == Video::Handle) return true;
if(name == Video::Synchronize) {
return XInternAtom(XOpenDisplay(0), "XV_SYNC_TO_VBLANK", true) != None;
}
return false;
}
any get(const string& name) {
if(name == Video::Handle) return settings.handle;
if(name == Video::Synchronize) return settings.synchronize;
return false;
}
bool set(const string& name, const any& value) {
if(name == Video::Handle) {
settings.handle = any_cast<uintptr_t>(value);
return true;
}
if(name == Video::Synchronize) {
Display *display = XOpenDisplay(0);
Atom atom = XInternAtom(display, "XV_SYNC_TO_VBLANK", true);
if(atom != None && device.port >= 0) {
settings.synchronize = any_cast<bool>(value);
XvSetPortAttribute(display, device.port, atom, settings.synchronize);
return true;
}
return false;
}
return false;
}
void resize(unsigned width, unsigned height) {
if(device.width >= width && device.height >= height) return;
device.width = max(width, device.width);
device.height = max(height, device.height);
XShmDetach(device.display, &device.shminfo);
shmdt(device.shminfo.shmaddr);
shmctl(device.shminfo.shmid, IPC_RMID, NULL);
XFree(device.image);
delete[] buffer;
device.image = XvShmCreateImage(device.display, device.port, device.fourcc, 0, device.width, device.height, &device.shminfo);
device.shminfo.shmid = shmget(IPC_PRIVATE, device.image->data_size, IPC_CREAT | 0777);
device.shminfo.shmaddr = device.image->data = (char*)shmat(device.shminfo.shmid, 0, 0);
device.shminfo.readOnly = false;
XShmAttach(device.display, &device.shminfo);
buffer = new uint32_t[device.width * device.height];
}
bool lock(uint32_t *&data, unsigned &pitch, unsigned width, unsigned height) {
if(width != settings.width || height != settings.height) {
resize(settings.width = width, settings.height = height);
}
pitch = device.width * 4;
return data = buffer;
}
void unlock() {
}
void clear() {
memset(buffer, 0, device.width * device.height * sizeof(uint32_t));
//clear twice in case video is double buffered ...
refresh();
refresh();
}
void refresh() {
unsigned width = settings.width;
unsigned height = settings.height;
XWindowAttributes target;
XGetWindowAttributes(device.display, device.window, &target);
//we must ensure that the child window is the same size as the parent window.
//unfortunately, we cannot hook the parent window resize event notification,
//as we did not create the parent window, nor have any knowledge of the toolkit used.
//therefore, query each window size and resize as needed.
XWindowAttributes parent;
XGetWindowAttributes(device.display, settings.handle, &parent);
if(target.width != parent.width || target.height != parent.height) {
XResizeWindow(device.display, device.window, parent.width, parent.height);
}
//update target width and height attributes
XGetWindowAttributes(device.display, device.window, &target);
switch(device.format) {
case XvFormatRGB32: render_rgb32(width, height); break;
case XvFormatRGB24: render_rgb24(width, height); break;
case XvFormatRGB16: render_rgb16(width, height); break;
case XvFormatRGB15: render_rgb15(width, height); break;
case XvFormatYUY2: render_yuy2 (width, height); break;
case XvFormatUYVY: render_uyvy (width, height); break;
}
XvShmPutImage(device.display, device.port, device.window, device.gc, device.image,
0, 0, width, height,
0, 0, target.width, target.height,
true);
}
bool init() {
device.display = XOpenDisplay(0);
if(!XShmQueryExtension(device.display)) {
fprintf(stderr, "VideoXv: XShm extension not found.\n");
return false;
}
//find an appropriate Xv port
device.port = -1;
XvAdaptorInfo *adaptor_info;
unsigned adaptor_count;
XvQueryAdaptors(device.display, DefaultRootWindow(device.display), &adaptor_count, &adaptor_info);
for(unsigned i = 0; i < adaptor_count; i++) {
//find adaptor that supports both input (memory->drawable) and image (drawable->screen) masks
if(adaptor_info[i].num_formats < 1) continue;
if(!(adaptor_info[i].type & XvInputMask)) continue;
if(!(adaptor_info[i].type & XvImageMask)) continue;
device.port = adaptor_info[i].base_id;
device.depth = adaptor_info[i].formats->depth;
device.visualid = adaptor_info[i].formats->visual_id;
break;
}
XvFreeAdaptorInfo(adaptor_info);
if(device.port < 0) {
fprintf(stderr, "VideoXv: failed to find valid XvPort.\n");
return false;
}
//create child window to attach to parent window.
//this is so that even if parent window visual depth doesn't match Xv visual
//(common with composited windows), Xv can still render to child window.
XWindowAttributes window_attributes;
XGetWindowAttributes(device.display, settings.handle, &window_attributes);
XVisualInfo visualtemplate;
visualtemplate.visualid = device.visualid;
visualtemplate.screen = DefaultScreen(device.display);
visualtemplate.depth = device.depth;
visualtemplate.visual = 0;
int visualmatches = 0;
XVisualInfo *visualinfo = XGetVisualInfo(device.display, VisualIDMask | VisualScreenMask | VisualDepthMask, &visualtemplate, &visualmatches);
if(visualmatches < 1 || !visualinfo->visual) {
if(visualinfo) XFree(visualinfo);
fprintf(stderr, "VideoXv: unable to find Xv-compatible visual.\n");
return false;
}
device.colormap = XCreateColormap(device.display, settings.handle, visualinfo->visual, AllocNone);
XSetWindowAttributes attributes;
attributes.colormap = device.colormap;
attributes.border_pixel = 0;
attributes.event_mask = StructureNotifyMask;
device.window = XCreateWindow(device.display, /* parent = */ settings.handle,
/* x = */ 0, /* y = */ 0, window_attributes.width, window_attributes.height,
/* border_width = */ 0, device.depth, InputOutput, visualinfo->visual,
CWColormap | CWBorderPixel | CWEventMask, &attributes);
XFree(visualinfo);
XSetWindowBackground(device.display, device.window, /* color = */ 0);
XMapWindow(device.display, device.window);
device.gc = XCreateGC(device.display, device.window, 0, 0);
//set colorkey to auto paint, so that Xv video output is always visible
Atom atom = XInternAtom(device.display, "XV_AUTOPAINT_COLORKEY", true);
if(atom != None) XvSetPortAttribute(device.display, device.port, atom, 1);
//find optimal rendering format
device.format = XvFormatUnknown;
signed format_count;
XvImageFormatValues *format = XvListImageFormats(device.display, device.port, &format_count);
if(device.format == XvFormatUnknown) for(signed i = 0; i < format_count; i++) {
if(format[i].type == XvRGB && format[i].bits_per_pixel == 32) {
device.format = XvFormatRGB32;
device.fourcc = format[i].id;
break;
}
}
if(device.format == XvFormatUnknown) for(signed i = 0; i < format_count; i++) {
if(format[i].type == XvRGB && format[i].bits_per_pixel == 24) {
device.format = XvFormatRGB24;
device.fourcc = format[i].id;
break;
}
}
if(device.format == XvFormatUnknown) for(signed i = 0; i < format_count; i++) {
if(format[i].type == XvRGB && format[i].bits_per_pixel <= 16 && format[i].red_mask == 0xf800) {
device.format = XvFormatRGB16;
device.fourcc = format[i].id;
break;
}
}
if(device.format == XvFormatUnknown) for(signed i = 0; i < format_count; i++) {
if(format[i].type == XvRGB && format[i].bits_per_pixel <= 16 && format[i].red_mask == 0x7c00) {
device.format = XvFormatRGB15;
device.fourcc = format[i].id;
break;
}
}
if(device.format == XvFormatUnknown) for(signed i = 0; i < format_count; i++) {
if(format[i].type == XvYUV && format[i].bits_per_pixel == 16 && format[i].format == XvPacked) {
if(format[i].component_order[0] == 'Y' && format[i].component_order[1] == 'U'
&& format[i].component_order[2] == 'Y' && format[i].component_order[3] == 'V'
) {
device.format = XvFormatYUY2;
device.fourcc = format[i].id;
break;
}
}
}
if(device.format == XvFormatUnknown) for(signed i = 0; i < format_count; i++) {
if(format[i].type == XvYUV && format[i].bits_per_pixel == 16 && format[i].format == XvPacked) {
if(format[i].component_order[0] == 'U' && format[i].component_order[1] == 'Y'
&& format[i].component_order[2] == 'V' && format[i].component_order[3] == 'Y'
) {
device.format = XvFormatUYVY;
device.fourcc = format[i].id;
break;
}
}
}
free(format);
if(device.format == XvFormatUnknown) {
fprintf(stderr, "VideoXv: unable to find a supported image format.\n");
return false;
}
device.width = 256;
device.height = 256;
device.image = XvShmCreateImage(device.display, device.port, device.fourcc, 0, device.width, device.height, &device.shminfo);
if(!device.image) {
fprintf(stderr, "VideoXv: XShmCreateImage failed.\n");
return false;
}
device.shminfo.shmid = shmget(IPC_PRIVATE, device.image->data_size, IPC_CREAT | 0777);
device.shminfo.shmaddr = device.image->data = (char*)shmat(device.shminfo.shmid, 0, 0);
device.shminfo.readOnly = false;
if(!XShmAttach(device.display, &device.shminfo)) {
fprintf(stderr, "VideoXv: XShmAttach failed.\n");
return false;
}
buffer = new uint32_t[device.width * device.height];
settings.width = 256;
settings.height = 256;
init_yuv_tables();
clear();
return true;
}
void term() {
XShmDetach(device.display, &device.shminfo);
shmdt(device.shminfo.shmaddr);
shmctl(device.shminfo.shmid, IPC_RMID, NULL);
XFree(device.image);
if(device.window) {
XUnmapWindow(device.display, device.window);
device.window = 0;
}
if(device.colormap) {
XFreeColormap(device.display, device.colormap);
device.colormap = 0;
}
if(buffer) { delete[] buffer; buffer = 0; }
if(ytable) { delete[] ytable; ytable = 0; }
if(utable) { delete[] utable; utable = 0; }
if(vtable) { delete[] vtable; vtable = 0; }
}
void render_rgb32(unsigned width, unsigned height) {
uint32_t *input = (uint32_t*)buffer;
uint32_t *output = (uint32_t*)device.image->data;
for(unsigned y = 0; y < height; y++) {
memcpy(output, input, width * 4);
input += device.width;
output += device.width;
}
}
void render_rgb24(unsigned width, unsigned height) {
uint32_t *input = (uint32_t*)buffer;
uint8_t *output = (uint8_t*)device.image->data;
for(unsigned y = 0; y < height; y++) {
for(unsigned x = 0; x < width; x++) {
uint32_t p = *input++;
*output++ = p;
*output++ = p >> 8;
*output++ = p >> 16;
}
input += (device.width - width);
output += (device.width - width) * 3;
}
}
void render_rgb16(unsigned width, unsigned height) {
uint32_t *input = (uint32_t*)buffer;
uint16_t *output = (uint16_t*)device.image->data;
for(unsigned y = 0; y < height; y++) {
for(unsigned x = 0; x < width; x++) {
uint32_t p = *input++;
*output++ = ((p >> 8) & 0xf800) | ((p >> 5) & 0x07e0) | ((p >> 3) & 0x001f); //RGB32->RGB16
}
input += device.width - width;
output += device.width - width;
}
}
void render_rgb15(unsigned width, unsigned height) {
uint32_t *input = (uint32_t*)buffer;
uint16_t *output = (uint16_t*)device.image->data;
for(unsigned y = 0; y < height; y++) {
for(unsigned x = 0; x < width; x++) {
uint32_t p = *input++;
*output++ = ((p >> 9) & 0x7c00) | ((p >> 6) & 0x03e0) | ((p >> 3) & 0x001f); //RGB32->RGB15
}
input += device.width - width;
output += device.width - width;
}
}
void render_yuy2(unsigned width, unsigned height) {
uint32_t *input = (uint32_t*)buffer;
uint16_t *output = (uint16_t*)device.image->data;
for(unsigned y = 0; y < height; y++) {
for(unsigned x = 0; x < width >> 1; x++) {
uint32_t p0 = *input++;
uint32_t p1 = *input++;
p0 = ((p0 >> 8) & 0xf800) + ((p0 >> 5) & 0x07e0) + ((p0 >> 3) & 0x001f); //RGB32->RGB16
p1 = ((p1 >> 8) & 0xf800) + ((p1 >> 5) & 0x07e0) + ((p1 >> 3) & 0x001f); //RGB32->RGB16
uint8_t u = (utable[p0] + utable[p1]) >> 1;
uint8_t v = (vtable[p0] + vtable[p1]) >> 1;
*output++ = (u << 8) | ytable[p0];
*output++ = (v << 8) | ytable[p1];
}
input += device.width - width;
output += device.width - width;
}
}
void render_uyvy(unsigned width, unsigned height) {
uint32_t *input = (uint32_t*)buffer;
uint16_t *output = (uint16_t*)device.image->data;
for(unsigned y = 0; y < height; y++) {
for(unsigned x = 0; x < width >> 1; x++) {
uint32_t p0 = *input++;
uint32_t p1 = *input++;
p0 = ((p0 >> 8) & 0xf800) + ((p0 >> 5) & 0x07e0) + ((p0 >> 3) & 0x001f);
p1 = ((p1 >> 8) & 0xf800) + ((p1 >> 5) & 0x07e0) + ((p1 >> 3) & 0x001f);
uint8_t u = (utable[p0] + utable[p1]) >> 1;
uint8_t v = (vtable[p0] + vtable[p1]) >> 1;
*output++ = (ytable[p0] << 8) | u;
*output++ = (ytable[p1] << 8) | v;
}
input += device.width - width;
output += device.width - width;
}
}
void init_yuv_tables() {
ytable = new uint8_t[65536];
utable = new uint8_t[65536];
vtable = new uint8_t[65536];
for(unsigned i = 0; i < 65536; i++) {
//extract RGB565 color data from i
uint8_t r = (i >> 11) & 31, g = (i >> 5) & 63, b = (i) & 31;
r = (r << 3) | (r >> 2); //R5->R8
g = (g << 2) | (g >> 4); //G6->G8
b = (b << 3) | (b >> 2); //B5->B8
//ITU-R Recommendation BT.601
//double lr = 0.299, lg = 0.587, lb = 0.114;
int y = int( +(double(r) * 0.257) + (double(g) * 0.504) + (double(b) * 0.098) + 16.0 );
int u = int( -(double(r) * 0.148) - (double(g) * 0.291) + (double(b) * 0.439) + 128.0 );
int v = int( +(double(r) * 0.439) - (double(g) * 0.368) - (double(b) * 0.071) + 128.0 );
//ITU-R Recommendation BT.709
//double lr = 0.2126, lg = 0.7152, lb = 0.0722;
//int y = int( double(r) * lr + double(g) * lg + double(b) * lb );
//int u = int( (double(b) - y) / (2.0 - 2.0 * lb) + 128.0 );
//int v = int( (double(r) - y) / (2.0 - 2.0 * lr) + 128.0 );
ytable[i] = y < 0 ? 0 : y > 255 ? 255 : y;
utable[i] = u < 0 ? 0 : u > 255 ? 255 : u;
vtable[i] = v < 0 ? 0 : v > 255 ? 255 : v;
}
}
pVideoXv() {
device.window = 0;
device.colormap = 0;
device.port = -1;
ytable = 0;
utable = 0;
vtable = 0;
settings.handle = 0;
settings.synchronize = false;
}
~pVideoXv() {
term();
}
};
DeclareVideo(Xv)
};