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mpv/video/out/vo_xv.c
wm4 89391e7c94 vo: different hack for VOs which need to mangle mouse input
Follow up on commit 760548da. Mouse handling is a bit confusing, because
there are at least 3 coordinate systems associated with it, and it
should be cleaned up. But that is hard, so just apply a hack which gets
the currently-annoying issue (VO backends needing access to the VO) out
of the way.
2014-07-27 21:33:11 +02:00

892 lines
28 KiB
C

/*
* X11 Xv interface
*
* This file is part of MPlayer.
*
* Original author: Gerd Knorr <kraxel@goldbach.in-berlin.de>
*
* MPlayer 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.
*
* MPlayer 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 MPlayer; if not, write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <stdint.h>
#include <stdbool.h>
#include <errno.h>
#include <X11/Xlib.h>
#include <X11/Xutil.h>
#include <libavutil/common.h>
#include "config.h"
#if HAVE_SHM && HAVE_XEXT
#include <sys/types.h>
#include <sys/ipc.h>
#include <sys/shm.h>
#include <X11/extensions/XShm.h>
#endif
// Note: depends on the inclusion of X11/extensions/XShm.h
#include <X11/extensions/Xv.h>
#include <X11/extensions/Xvlib.h>
#include "options/options.h"
#include "talloc.h"
#include "common/msg.h"
#include "vo.h"
#include "video/vfcap.h"
#include "video/mp_image.h"
#include "video/img_fourcc.h"
#include "x11_common.h"
#include "video/memcpy_pic.h"
#include "sub/osd.h"
#include "sub/draw_bmp.h"
#include "video/csputils.h"
#include "options/m_option.h"
#include "input/input.h"
#include "osdep/timer.h"
#define CK_METHOD_NONE 0 // no colorkey drawing
#define CK_METHOD_BACKGROUND 1 // set colorkey as window background
#define CK_METHOD_AUTOPAINT 2 // let xv draw the colorkey
#define CK_METHOD_MANUALFILL 3 // manually draw the colorkey
#define CK_SRC_USE 0 // use specified / default colorkey
#define CK_SRC_SET 1 // use and set specified / default colorkey
#define CK_SRC_CUR 2 // use current colorkey (get it from xv)
struct xvctx {
struct xv_ck_info_s {
int method; // CK_METHOD_* constants
int source; // CK_SRC_* constants
} xv_ck_info;
int colorkey;
unsigned long xv_colorkey;
int xv_port;
int cfg_xv_adaptor;
XvAdaptorInfo *ai;
XvImageFormatValues *fo;
unsigned int formats, adaptors, xv_format;
int current_buf;
int current_ip_buf;
int num_buffers;
XvImage *xvimage[2];
struct mp_image *original_image;
uint32_t image_width;
uint32_t image_height;
uint32_t image_format;
int cached_csp;
struct mp_rect src_rect;
struct mp_rect dst_rect;
uint32_t max_width, max_height; // zero means: not set
int Shmem_Flag;
#if HAVE_SHM && HAVE_XEXT
XShmSegmentInfo Shminfo[2];
int Shm_Warned_Slow;
#endif
};
struct fmt_entry {
int imgfmt;
int fourcc;
};
static const struct fmt_entry fmt_table[] = {
{IMGFMT_420P, MP_FOURCC_YV12},
{IMGFMT_420P, MP_FOURCC_I420},
{IMGFMT_YUYV, MP_FOURCC_YUY2},
{IMGFMT_UYVY, MP_FOURCC_UYVY},
{0}
};
static bool allocate_xvimage(struct vo *, int);
static void deallocate_xvimage(struct vo *vo, int foo);
static struct mp_image get_xv_buffer(struct vo *vo, int buf_index);
static int find_xv_format(int imgfmt)
{
for (int n = 0; fmt_table[n].imgfmt; n++) {
if (fmt_table[n].imgfmt == imgfmt)
return fmt_table[n].fourcc;
}
return 0;
}
static int xv_find_atom(struct vo *vo, uint32_t xv_port, const char *name,
bool get, int *min, int *max)
{
Atom atom = None;
int howmany = 0;
XvAttribute *attributes = XvQueryPortAttributes(vo->x11->display, xv_port,
&howmany);
for (int i = 0; i < howmany && attributes; i++) {
int flag = get ? XvGettable : XvSettable;
if (attributes[i].flags & flag) {
atom = XInternAtom(vo->x11->display, attributes[i].name, True);
*min = attributes[i].min_value;
*max = attributes[i].max_value;
/* since we have SET_DEFAULTS first in our list, we can check if it's available
then trigger it if it's ok so that the other values are at default upon query */
if (atom != None) {
if (!strcmp(attributes[i].name, "XV_BRIGHTNESS") &&
(!strcmp(name, "brightness")))
break;
else if (!strcmp(attributes[i].name, "XV_CONTRAST") &&
(!strcmp(name, "contrast")))
break;
else if (!strcmp(attributes[i].name, "XV_SATURATION") &&
(!strcmp(name, "saturation")))
break;
else if (!strcmp(attributes[i].name, "XV_HUE") &&
(!strcmp(name, "hue")))
break;
if (!strcmp(attributes[i].name, "XV_RED_INTENSITY") &&
(!strcmp(name, "red_intensity")))
break;
else if (!strcmp(attributes[i].name, "XV_GREEN_INTENSITY")
&& (!strcmp(name, "green_intensity")))
break;
else if (!strcmp(attributes[i].name, "XV_BLUE_INTENSITY")
&& (!strcmp(name, "blue_intensity")))
break;
else if ((!strcmp(attributes[i].name, "XV_ITURBT_709") //NVIDIA
|| !strcmp(attributes[i].name, "XV_COLORSPACE")) //ATI
&& (!strcmp(name, "bt_709")))
break;
atom = None;
continue;
}
}
}
XFree(attributes);
return atom;
}
static int xv_set_eq(struct vo *vo, uint32_t xv_port, const char *name,
int value)
{
MP_VERBOSE(vo, "xv_set_eq called! (%s, %d)\n", name, value);
int min, max;
int atom = xv_find_atom(vo, xv_port, name, false, &min, &max);
if (atom != None) {
// -100 -> min
// 0 -> (max+min)/2
// +100 -> max
int port_value = (value + 100) * (max - min) / 200 + min;
XvSetPortAttribute(vo->x11->display, xv_port, atom, port_value);
return VO_TRUE;
}
return VO_FALSE;
}
static int xv_get_eq(struct vo *vo, uint32_t xv_port, const char *name,
int *value)
{
int min, max;
int atom = xv_find_atom(vo, xv_port, name, true, &min, &max);
if (atom != None) {
int port_value = 0;
XvGetPortAttribute(vo->x11->display, xv_port, atom, &port_value);
*value = (port_value - min) * 200 / (max - min) - 100;
MP_VERBOSE(vo, "xv_get_eq called! (%s, %d)\n", name, *value);
return VO_TRUE;
}
return VO_FALSE;
}
static Atom xv_intern_atom_if_exists(struct vo *vo, char const *atom_name)
{
struct xvctx *ctx = vo->priv;
XvAttribute *attributes;
int attrib_count, i;
Atom xv_atom = None;
attributes = XvQueryPortAttributes(vo->x11->display, ctx->xv_port,
&attrib_count);
if (attributes != NULL) {
for (i = 0; i < attrib_count; ++i) {
if (strcmp(attributes[i].name, atom_name) == 0) {
xv_atom = XInternAtom(vo->x11->display, atom_name, False);
break;
}
}
XFree(attributes);
}
return xv_atom;
}
// Try to enable vsync for xv.
// Returns -1 if not available, 0 on failure and 1 on success.
static int xv_enable_vsync(struct vo *vo)
{
struct xvctx *ctx = vo->priv;
Atom xv_atom = xv_intern_atom_if_exists(vo, "XV_SYNC_TO_VBLANK");
if (xv_atom == None)
return -1;
return XvSetPortAttribute(vo->x11->display, ctx->xv_port, xv_atom, 1)
== Success;
}
// Get maximum supported source image dimensions.
// If querying the dimensions fails, don't change *width and *height.
static void xv_get_max_img_dim(struct vo *vo, uint32_t *width, uint32_t *height)
{
struct xvctx *ctx = vo->priv;
XvEncodingInfo *encodings;
unsigned int num_encodings, idx;
XvQueryEncodings(vo->x11->display, ctx->xv_port, &num_encodings, &encodings);
if (encodings) {
for (idx = 0; idx < num_encodings; ++idx) {
if (strcmp(encodings[idx].name, "XV_IMAGE") == 0) {
*width = encodings[idx].width;
*height = encodings[idx].height;
break;
}
}
}
MP_VERBOSE(vo, "Maximum source image dimensions: %ux%u\n", *width, *height);
XvFreeEncodingInfo(encodings);
}
static void xv_print_ck_info(struct vo *vo)
{
struct xvctx *xv = vo->priv;
switch (xv->xv_ck_info.method) {
case CK_METHOD_NONE:
MP_VERBOSE(vo, "Drawing no colorkey.\n");
return;
case CK_METHOD_AUTOPAINT:
MP_VERBOSE(vo, "Colorkey is drawn by Xv.\n");
break;
case CK_METHOD_MANUALFILL:
MP_VERBOSE(vo, "Drawing colorkey manually.\n");
break;
case CK_METHOD_BACKGROUND:
MP_VERBOSE(vo, "Colorkey is drawn as window background.\n");
break;
}
switch (xv->xv_ck_info.source) {
case CK_SRC_CUR:
MP_VERBOSE(vo, "Using colorkey from Xv (0x%06lx).\n", xv->xv_colorkey);
break;
case CK_SRC_USE:
if (xv->xv_ck_info.method == CK_METHOD_AUTOPAINT) {
MP_VERBOSE(vo, "Ignoring colorkey from mpv (0x%06lx).\n",
xv->xv_colorkey);
} else {
MP_VERBOSE(vo, "Using colorkey from mpv (0x%06lx). Use -colorkey to change.\n",
xv->xv_colorkey);
}
break;
case CK_SRC_SET:
MP_VERBOSE(vo, "Setting and using colorkey from mpv (0x%06lx)."
" Use -colorkey to change.\n", xv->xv_colorkey);
break;
}
}
/* NOTE: If vo.colorkey has bits set after the first 3 low order bytes
* we don't draw anything as this means it was forced to off. */
static int xv_init_colorkey(struct vo *vo)
{
struct xvctx *ctx = vo->priv;
Display *display = vo->x11->display;
Atom xv_atom;
int rez;
/* check if colorkeying is needed */
xv_atom = xv_intern_atom_if_exists(vo, "XV_COLORKEY");
if (xv_atom != None && !(ctx->colorkey & 0xFF000000)) {
if (ctx->xv_ck_info.source == CK_SRC_CUR) {
int colorkey_ret;
rez = XvGetPortAttribute(display, ctx->xv_port, xv_atom,
&colorkey_ret);
if (rez == Success)
ctx->xv_colorkey = colorkey_ret;
else {
MP_FATAL(vo, "Couldn't get colorkey! "
"Maybe the selected Xv port has no overlay.\n");
return 0; // error getting colorkey
}
} else {
ctx->xv_colorkey = ctx->colorkey;
/* check if we have to set the colorkey too */
if (ctx->xv_ck_info.source == CK_SRC_SET) {
xv_atom = XInternAtom(display, "XV_COLORKEY", False);
rez = XvSetPortAttribute(display, ctx->xv_port, xv_atom,
ctx->colorkey);
if (rez != Success) {
MP_FATAL(vo, "Couldn't set colorkey!\n");
return 0; // error setting colorkey
}
}
}
xv_atom = xv_intern_atom_if_exists(vo, "XV_AUTOPAINT_COLORKEY");
/* should we draw the colorkey ourselves or activate autopainting? */
if (ctx->xv_ck_info.method == CK_METHOD_AUTOPAINT) {
rez = !Success;
if (xv_atom != None) // autopaint is supported
rez = XvSetPortAttribute(display, ctx->xv_port, xv_atom, 1);
if (rez != Success)
ctx->xv_ck_info.method = CK_METHOD_MANUALFILL;
} else {
// disable colorkey autopainting if supported
if (xv_atom != None)
XvSetPortAttribute(display, ctx->xv_port, xv_atom, 0);
}
} else // do no colorkey drawing at all
ctx->xv_ck_info.method = CK_METHOD_NONE;
xv_print_ck_info(vo);
return 1;
}
/* Draw the colorkey on the video window.
*
* Draws the colorkey depending on the set method ( colorkey_handling ).
*
* Also draws the black bars ( when the video doesn't fit the display in
* fullscreen ) separately, so they don't overlap with the video area. */
static void xv_draw_colorkey(struct vo *vo, const struct mp_rect *rc)
{
struct xvctx *ctx = vo->priv;
struct vo_x11_state *x11 = vo->x11;
if (ctx->xv_ck_info.method == CK_METHOD_MANUALFILL ||
ctx->xv_ck_info.method == CK_METHOD_BACKGROUND)
{
//less tearing than XClearWindow()
XSetForeground(x11->display, x11->vo_gc, ctx->xv_colorkey);
XFillRectangle(x11->display, x11->window, x11->vo_gc, rc->x0, rc->y0,
rc->x1 - rc->x0, rc->y1 - rc->y0);
}
}
static void read_xv_csp(struct vo *vo)
{
struct xvctx *ctx = vo->priv;
ctx->cached_csp = 0;
int bt709_enabled;
if (xv_get_eq(vo, ctx->xv_port, "bt_709", &bt709_enabled))
ctx->cached_csp = bt709_enabled == 100 ? MP_CSP_BT_709 : MP_CSP_BT_601;
}
static void resize(struct vo *vo)
{
struct xvctx *ctx = vo->priv;
// Can't be used, because the function calculates screen-space coordinates,
// while we need video-space.
struct mp_osd_res unused;
vo_get_src_dst_rects(vo, &ctx->src_rect, &ctx->dst_rect, &unused);
vo_x11_clear_background(vo, &ctx->dst_rect);
xv_draw_colorkey(vo, &ctx->dst_rect);
read_xv_csp(vo);
mp_input_set_mouse_transform(vo->input_ctx, &ctx->dst_rect, &ctx->src_rect);
vo->want_redraw = true;
}
/*
* create and map window,
* allocate colors and (shared) memory
*/
static int reconfig(struct vo *vo, struct mp_image_params *params, int flags)
{
struct vo_x11_state *x11 = vo->x11;
struct xvctx *ctx = vo->priv;
int i;
mp_image_unrefp(&ctx->original_image);
ctx->image_height = params->h;
ctx->image_width = params->w;
ctx->image_format = params->imgfmt;
if ((ctx->max_width != 0 && ctx->max_height != 0)
&& (ctx->image_width > ctx->max_width
|| ctx->image_height > ctx->max_height)) {
MP_ERR(vo, "Source image dimensions are too high: %ux%u (maximum is %ux%u)\n",
ctx->image_width, ctx->image_height, ctx->max_width,
ctx->max_height);
return -1;
}
/* check image formats */
ctx->xv_format = 0;
for (i = 0; i < ctx->formats; i++) {
MP_VERBOSE(vo, "Xvideo image format: 0x%x (%4.4s) %s\n",
ctx->fo[i].id, (char *) &ctx->fo[i].id,
(ctx->fo[i].format == XvPacked) ? "packed" : "planar");
if (ctx->fo[i].id == find_xv_format(ctx->image_format))
ctx->xv_format = ctx->fo[i].id;
}
if (!ctx->xv_format)
return -1;
vo_x11_config_vo_window(vo, NULL, flags, "xv");
if (ctx->xv_ck_info.method == CK_METHOD_BACKGROUND)
XSetWindowBackground(x11->display, x11->window, ctx->xv_colorkey);
MP_VERBOSE(vo, "using Xvideo port %d for hw scaling\n", ctx->xv_port);
// In case config has been called before
for (i = 0; i < ctx->num_buffers; i++)
deallocate_xvimage(vo, i);
ctx->num_buffers = 2;
for (i = 0; i < ctx->num_buffers; i++) {
if (!allocate_xvimage(vo, i)) {
MP_FATAL(vo, "could not allocate Xv image data\n");
return -1;
}
}
ctx->current_buf = 0;
ctx->current_ip_buf = 0;
int is_709 = params->colorspace == MP_CSP_BT_709;
xv_set_eq(vo, ctx->xv_port, "bt_709", is_709 * 200 - 100);
read_xv_csp(vo);
resize(vo);
return 0;
}
static bool allocate_xvimage(struct vo *vo, int foo)
{
struct xvctx *ctx = vo->priv;
struct vo_x11_state *x11 = vo->x11;
// align it for faster OSD rendering (draw_bmp.c swscale usage)
int aligned_w = FFALIGN(ctx->image_width, 32);
#if HAVE_SHM && HAVE_XEXT
if (x11->display_is_local && XShmQueryExtension(x11->display)) {
ctx->Shmem_Flag = 1;
x11->ShmCompletionEvent = XShmGetEventBase(x11->display)
+ ShmCompletion;
} else {
ctx->Shmem_Flag = 0;
MP_INFO(vo, "Shared memory not supported\nReverting to normal Xv.\n");
}
if (ctx->Shmem_Flag) {
ctx->xvimage[foo] =
(XvImage *) XvShmCreateImage(x11->display, ctx->xv_port,
ctx->xv_format, NULL,
aligned_w, ctx->image_height,
&ctx->Shminfo[foo]);
if (!ctx->xvimage[foo])
return false;
ctx->Shminfo[foo].shmid = shmget(IPC_PRIVATE,
ctx->xvimage[foo]->data_size,
IPC_CREAT | 0777);
ctx->Shminfo[foo].shmaddr = (char *) shmat(ctx->Shminfo[foo].shmid, 0,
0);
if (ctx->Shminfo[foo].shmaddr == (void *)-1)
return false;
ctx->Shminfo[foo].readOnly = False;
ctx->xvimage[foo]->data = ctx->Shminfo[foo].shmaddr;
XShmAttach(x11->display, &ctx->Shminfo[foo]);
XSync(x11->display, False);
shmctl(ctx->Shminfo[foo].shmid, IPC_RMID, 0);
} else
#endif
{
ctx->xvimage[foo] =
(XvImage *) XvCreateImage(x11->display, ctx->xv_port,
ctx->xv_format, NULL, aligned_w,
ctx->image_height);
if (!ctx->xvimage[foo])
return false;
ctx->xvimage[foo]->data = av_malloc(ctx->xvimage[foo]->data_size);
if (!ctx->xvimage[foo]->data)
return false;
XSync(x11->display, False);
}
struct mp_image img = get_xv_buffer(vo, foo);
img.w = aligned_w;
mp_image_clear(&img, 0, 0, img.w, img.h);
return true;
}
static void deallocate_xvimage(struct vo *vo, int foo)
{
struct xvctx *ctx = vo->priv;
#if HAVE_SHM && HAVE_XEXT
if (ctx->Shmem_Flag) {
XShmDetach(vo->x11->display, &ctx->Shminfo[foo]);
shmdt(ctx->Shminfo[foo].shmaddr);
} else
#endif
{
av_free(ctx->xvimage[foo]->data);
}
if (ctx->xvimage[foo])
XFree(ctx->xvimage[foo]);
ctx->xvimage[foo] = NULL;
#if HAVE_SHM && HAVE_XEXT
ctx->Shminfo[foo] = (XShmSegmentInfo){0};
#endif
XSync(vo->x11->display, False);
return;
}
static inline void put_xvimage(struct vo *vo, XvImage *xvi)
{
struct xvctx *ctx = vo->priv;
struct vo_x11_state *x11 = vo->x11;
struct mp_rect *src = &ctx->src_rect;
struct mp_rect *dst = &ctx->dst_rect;
int dw = dst->x1 - dst->x0, dh = dst->y1 - dst->y0;
int sw = src->x1 - src->x0, sh = src->y1 - src->y0;
#if HAVE_SHM && HAVE_XEXT
if (ctx->Shmem_Flag) {
XvShmPutImage(x11->display, ctx->xv_port, x11->window, x11->vo_gc, xvi,
src->x0, src->y0, sw, sh,
dst->x0, dst->y0, dw, dh,
True);
x11->ShmCompletionWaitCount++;
} else
#endif
{
XvPutImage(x11->display, ctx->xv_port, x11->window, x11->vo_gc, xvi,
src->x0, src->y0, sw, sh,
dst->x0, dst->y0, dw, dh);
}
}
static struct mp_image get_xv_buffer(struct vo *vo, int buf_index)
{
struct xvctx *ctx = vo->priv;
XvImage *xv_image = ctx->xvimage[buf_index];
struct mp_image img = {0};
mp_image_set_size(&img, ctx->image_width, ctx->image_height);
mp_image_setfmt(&img, ctx->image_format);
bool swapuv = ctx->xv_format == MP_FOURCC_YV12;
for (int n = 0; n < img.num_planes; n++) {
int sn = n > 0 && swapuv ? (n == 1 ? 2 : 1) : n;
img.planes[n] = xv_image->data + xv_image->offsets[sn];
img.stride[n] = xv_image->pitches[sn];
}
if (vo->params) {
struct mp_image_params params = *vo->params;
if (ctx->cached_csp)
params.colorspace = ctx->cached_csp;
mp_image_set_attributes(&img, &params);
}
return img;
}
static void wait_for_completion(struct vo *vo, int max_outstanding)
{
#if HAVE_SHM && HAVE_XEXT
struct xvctx *ctx = vo->priv;
struct vo_x11_state *x11 = vo->x11;
if (ctx->Shmem_Flag) {
while (x11->ShmCompletionWaitCount > max_outstanding) {
if (!ctx->Shm_Warned_Slow) {
MP_WARN(vo, "X11 can't keep up! Waiting"
" for XShm completion events...\n");
ctx->Shm_Warned_Slow = 1;
}
mp_sleep_us(1000);
vo_x11_check_events(vo);
}
}
#endif
}
static void flip_page(struct vo *vo)
{
struct xvctx *ctx = vo->priv;
put_xvimage(vo, ctx->xvimage[ctx->current_buf]);
/* remember the currently visible buffer */
ctx->current_buf = (ctx->current_buf + 1) % ctx->num_buffers;
if (!ctx->Shmem_Flag)
XSync(vo->x11->display, False);
}
static mp_image_t *get_screenshot(struct vo *vo)
{
struct xvctx *ctx = vo->priv;
if (!ctx->original_image)
return NULL;
return mp_image_new_ref(ctx->original_image);
}
// Note: REDRAW_FRAME can call this with NULL.
static void draw_image(struct vo *vo, mp_image_t *mpi)
{
struct xvctx *ctx = vo->priv;
wait_for_completion(vo, ctx->num_buffers - 1);
struct mp_image xv_buffer = get_xv_buffer(vo, ctx->current_buf);
if (mpi) {
mp_image_copy(&xv_buffer, mpi);
} else {
mp_image_clear(&xv_buffer, 0, 0, xv_buffer.w, xv_buffer.h);
}
struct mp_osd_res res = osd_res_from_image_params(vo->params);
osd_draw_on_image(vo->osd, res, mpi ? mpi->pts : 0, 0, &xv_buffer);
if (mpi != ctx->original_image) {
talloc_free(ctx->original_image);
ctx->original_image = mpi;
}
}
static int query_format(struct vo *vo, uint32_t format)
{
struct xvctx *ctx = vo->priv;
uint32_t i;
int flag = VFCAP_CSP_SUPPORTED | VFCAP_CSP_SUPPORTED_BY_HW;
int fourcc = find_xv_format(format);
if (fourcc) {
for (i = 0; i < ctx->formats; i++) {
if (ctx->fo[i].id == fourcc)
return flag;
}
}
return 0;
}
static void uninit(struct vo *vo)
{
struct xvctx *ctx = vo->priv;
int i;
talloc_free(ctx->original_image);
if (ctx->ai)
XvFreeAdaptorInfo(ctx->ai);
ctx->ai = NULL;
if (ctx->fo) {
XFree(ctx->fo);
ctx->fo = NULL;
}
for (i = 0; i < ctx->num_buffers; i++)
deallocate_xvimage(vo, i);
// uninit() shouldn't get called unless initialization went past vo_init()
vo_x11_uninit(vo);
}
static int preinit(struct vo *vo)
{
XvPortID xv_p;
int busy_ports = 0;
unsigned int i;
struct xvctx *ctx = vo->priv;
int xv_adaptor = ctx->cfg_xv_adaptor;
if (!vo_x11_init(vo))
return -1;
struct vo_x11_state *x11 = vo->x11;
/* check for Xvideo extension */
unsigned int ver, rel, req, ev, err;
if (Success != XvQueryExtension(x11->display, &ver, &rel, &req, &ev, &err)) {
MP_ERR(vo, "Xv not supported by this X11 version/driver\n");
goto error;
}
/* check for Xvideo support */
if (Success !=
XvQueryAdaptors(x11->display, DefaultRootWindow(x11->display),
&ctx->adaptors, &ctx->ai)) {
MP_ERR(vo, "XvQueryAdaptors failed.\n");
goto error;
}
/* check adaptors */
if (ctx->xv_port) {
int port_found;
for (port_found = 0, i = 0; !port_found && i < ctx->adaptors; i++) {
if ((ctx->ai[i].type & XvInputMask)
&& (ctx->ai[i].type & XvImageMask)) {
for (xv_p = ctx->ai[i].base_id;
xv_p < ctx->ai[i].base_id + ctx->ai[i].num_ports;
++xv_p) {
if (xv_p == ctx->xv_port) {
port_found = 1;
break;
}
}
}
}
if (port_found) {
if (XvGrabPort(x11->display, ctx->xv_port, CurrentTime))
ctx->xv_port = 0;
} else {
MP_WARN(vo, "Invalid port parameter, overriding with port 0.\n");
ctx->xv_port = 0;
}
}
for (i = 0; i < ctx->adaptors && ctx->xv_port == 0; i++) {
/* check if adaptor number has been specified */
if (xv_adaptor != -1 && xv_adaptor != i)
continue;
if ((ctx->ai[i].type & XvInputMask) && (ctx->ai[i].type & XvImageMask)) {
for (xv_p = ctx->ai[i].base_id;
xv_p < ctx->ai[i].base_id + ctx->ai[i].num_ports; ++xv_p)
if (!XvGrabPort(x11->display, xv_p, CurrentTime)) {
ctx->xv_port = xv_p;
MP_VERBOSE(vo, "Using Xv Adapter #%d (%s)\n",
i, ctx->ai[i].name);
break;
} else {
MP_WARN(vo, "Could not grab port %i.\n", (int) xv_p);
++busy_ports;
}
}
}
if (!ctx->xv_port) {
if (busy_ports)
MP_ERR(vo, "Xvideo ports busy.\n");
else
MP_ERR(vo, "No Xvideo support found.\n");
goto error;
}
if (!xv_init_colorkey(vo)) {
goto error; // bail out, colorkey setup failed
}
xv_enable_vsync(vo);
xv_get_max_img_dim(vo, &ctx->max_width, &ctx->max_height);
ctx->fo = XvListImageFormats(x11->display, ctx->xv_port,
(int *) &ctx->formats);
return 0;
error:
uninit(vo); // free resources
return -1;
}
static int control(struct vo *vo, uint32_t request, void *data)
{
struct xvctx *ctx = vo->priv;
switch (request) {
case VOCTRL_GET_PANSCAN:
return VO_TRUE;
case VOCTRL_SET_PANSCAN:
resize(vo);
return VO_TRUE;
case VOCTRL_SET_EQUALIZER: {
vo->want_redraw = true;
struct voctrl_set_equalizer_args *args = data;
return xv_set_eq(vo, ctx->xv_port, args->name, args->value);
}
case VOCTRL_GET_EQUALIZER: {
struct voctrl_get_equalizer_args *args = data;
return xv_get_eq(vo, ctx->xv_port, args->name, args->valueptr);
}
case VOCTRL_GET_COLORSPACE: {
struct mp_image_params *params = data;
read_xv_csp(vo);
params->colorspace = ctx->cached_csp;
return true;
}
case VOCTRL_REDRAW_FRAME:
draw_image(vo, ctx->original_image);
return true;
case VOCTRL_SCREENSHOT: {
struct voctrl_screenshot_args *args = data;
args->out_image = get_screenshot(vo);
return true;
}
}
int events = 0;
int r = vo_x11_control(vo, &events, request, data);
if (events & (VO_EVENT_EXPOSE | VO_EVENT_RESIZE))
resize(vo);
return r;
}
#define OPT_BASE_STRUCT struct xvctx
const struct vo_driver video_out_xv = {
.description = "X11/Xv",
.name = "xv",
.preinit = preinit,
.query_format = query_format,
.reconfig = reconfig,
.control = control,
.draw_image = draw_image,
.flip_page = flip_page,
.uninit = uninit,
.priv_size = sizeof(struct xvctx),
.priv_defaults = &(const struct xvctx) {
.cfg_xv_adaptor = -1,
.xv_ck_info = {CK_METHOD_MANUALFILL, CK_SRC_CUR},
.colorkey = 0x0000ff00, // default colorkey is green
// (0xff000000 means that colorkey has been disabled)
},
.options = (const struct m_option[]) {
OPT_INT("port", xv_port, M_OPT_MIN, .min = 0),
OPT_INT("adaptor", cfg_xv_adaptor, M_OPT_MIN, .min = -1),
OPT_CHOICE("ck", xv_ck_info.source, 0,
({"use", CK_SRC_USE},
{"set", CK_SRC_SET},
{"cur", CK_SRC_CUR})),
OPT_CHOICE("ck-method", xv_ck_info.method, 0,
({"bg", CK_METHOD_BACKGROUND},
{"man", CK_METHOD_MANUALFILL},
{"auto", CK_METHOD_AUTOPAINT})),
OPT_INT("colorkey", colorkey, 0),
OPT_FLAG_STORE("no-colorkey", colorkey, 0, 0x1000000),
{0}
},
};