scrcpy/app/src/screen.c

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#include "screen.h"
#include <assert.h>
#include <string.h>
#include <SDL2/SDL.h>
#include "config.h"
#include "common.h"
#include "compat.h"
#include "icon.xpm"
#include "tiny_xpm.h"
#include "video_buffer.h"
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#include "util/lock.h"
#include "util/log.h"
#define DISPLAY_MARGINS 96
static inline struct size
get_rotated_size(struct size size, int rotation) {
struct size rotated_size;
if (rotation & 1) {
rotated_size.width = size.height;
rotated_size.height = size.width;
} else {
rotated_size.width = size.width;
rotated_size.height = size.height;
}
return rotated_size;
}
// get the window size in a struct size
static struct size
get_window_size(const struct screen *screen) {
int width;
int height;
SDL_GetWindowSize(screen->window, &width, &height);
struct size size;
size.width = width;
size.height = height;
return size;
}
// set the window size to be applied when fullscreen is disabled
static void
set_window_size(struct screen *screen, struct size new_size) {
assert(!screen->fullscreen);
assert(!screen->maximized);
SDL_SetWindowSize(screen->window, new_size.width, new_size.height);
}
// get the preferred display bounds (i.e. the screen bounds with some margins)
static bool
get_preferred_display_bounds(struct size *bounds) {
SDL_Rect rect;
#ifdef SCRCPY_SDL_HAS_GET_DISPLAY_USABLE_BOUNDS
# define GET_DISPLAY_BOUNDS(i, r) SDL_GetDisplayUsableBounds((i), (r))
#else
# define GET_DISPLAY_BOUNDS(i, r) SDL_GetDisplayBounds((i), (r))
#endif
if (GET_DISPLAY_BOUNDS(0, &rect)) {
LOGW("Could not get display usable bounds: %s", SDL_GetError());
return false;
}
bounds->width = MAX(0, rect.w - DISPLAY_MARGINS);
bounds->height = MAX(0, rect.h - DISPLAY_MARGINS);
return true;
}
static bool
is_optimal_size(struct size current_size, struct size content_size) {
// The size is optimal if we can recompute one dimension of the current
// size from the other
return current_size.height == current_size.width * content_size.height
/ content_size.width
|| current_size.width == current_size.height * content_size.width
/ content_size.height;
}
// return the optimal size of the window, with the following constraints:
// - it attempts to keep at least one dimension of the current_size (i.e. it
// crops the black borders)
// - it keeps the aspect ratio
// - it scales down to make it fit in the display_size
static struct size
get_optimal_size(struct size current_size, struct size content_size) {
if (content_size.width == 0 || content_size.height == 0) {
// avoid division by 0
return current_size;
}
struct size window_size;
struct size display_size;
if (!get_preferred_display_bounds(&display_size)) {
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// could not get display bounds, do not constraint the size
window_size.width = current_size.width;
window_size.height = current_size.height;
} else {
window_size.width = MIN(current_size.width, display_size.width);
window_size.height = MIN(current_size.height, display_size.height);
}
if (is_optimal_size(window_size, content_size)) {
return window_size;
}
bool keep_width = content_size.width * window_size.height
> content_size.height * window_size.width;
if (keep_width) {
// remove black borders on top and bottom
window_size.height = content_size.height * window_size.width
/ content_size.width;
} else {
// remove black borders on left and right (or none at all if it already
// fits)
window_size.width = content_size.width * window_size.height
/ content_size.height;
}
return window_size;
}
// same as get_optimal_size(), but read the current size from the window
static inline struct size
get_optimal_window_size(const struct screen *screen, struct size content_size) {
struct size window_size = get_window_size(screen);
return get_optimal_size(window_size, content_size);
}
// initially, there is no current size, so use the frame size as current size
// req_width and req_height, if not 0, are the sizes requested by the user
static inline struct size
get_initial_optimal_size(struct size content_size, uint16_t req_width,
uint16_t req_height) {
struct size window_size;
if (!req_width && !req_height) {
window_size = get_optimal_size(content_size, content_size);
} else {
if (req_width) {
window_size.width = req_width;
} else {
// compute from the requested height
window_size.width = (uint32_t) req_height * content_size.width
/ content_size.height;
}
if (req_height) {
window_size.height = req_height;
} else {
// compute from the requested width
window_size.height = (uint32_t) req_width * content_size.height
/ content_size.width;
}
}
return window_size;
}
static void
screen_update_content_rect(struct screen *screen) {
int dw;
int dh;
SDL_GL_GetDrawableSize(screen->window, &dw, &dh);
struct size content_size = screen->content_size;
// The drawable size is the window size * the HiDPI scale
struct size drawable_size = {dw, dh};
SDL_Rect *rect = &screen->rect;
if (is_optimal_size(drawable_size, content_size)) {
rect->x = 0;
rect->y = 0;
rect->w = drawable_size.width;
rect->h = drawable_size.height;
return;
}
bool keep_width = content_size.width * drawable_size.height
> content_size.height * drawable_size.width;
if (keep_width) {
rect->x = 0;
rect->w = drawable_size.width;
rect->h = drawable_size.width * content_size.height
/ content_size.width;
rect->y = (drawable_size.height - rect->h) / 2;
} else {
rect->y = 0;
rect->h = drawable_size.height;
rect->w = drawable_size.height * content_size.width
/ content_size.height;
rect->x = (drawable_size.width - rect->w) / 2;
}
}
void
screen_init(struct screen *screen) {
*screen = (struct screen) SCREEN_INITIALIZER;
}
static inline SDL_Texture *
create_texture(struct screen *screen) {
SDL_Renderer *renderer = screen->renderer;
struct size size = screen->frame_size;
SDL_Texture *texture = SDL_CreateTexture(renderer, SDL_PIXELFORMAT_YV12,
SDL_TEXTUREACCESS_STREAMING,
size.width, size.height);
if (!texture) {
return NULL;
}
if (screen->mipmaps) {
struct sc_opengl *gl = &screen->gl;
SDL_GL_BindTexture(texture, NULL, NULL);
// Enable trilinear filtering for downscaling
gl->TexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER,
GL_LINEAR_MIPMAP_LINEAR);
gl->TexParameterf(GL_TEXTURE_2D, GL_TEXTURE_LOD_BIAS, -.5f);
SDL_GL_UnbindTexture(texture);
}
return texture;
}
bool
screen_init_rendering(struct screen *screen, const char *window_title,
struct size frame_size, bool always_on_top,
int16_t window_x, int16_t window_y, uint16_t window_width,
uint16_t window_height, bool window_borderless,
uint8_t rotation, bool mipmaps) {
screen->frame_size = frame_size;
screen->rotation = rotation;
if (rotation) {
LOGI("Initial display rotation set to %u", rotation);
}
struct size content_size = get_rotated_size(frame_size, screen->rotation);
screen->content_size = content_size;
struct size window_size =
get_initial_optimal_size(content_size, window_width, window_height);
uint32_t window_flags = SDL_WINDOW_HIDDEN | SDL_WINDOW_RESIZABLE;
#ifdef HIDPI_SUPPORT
window_flags |= SDL_WINDOW_ALLOW_HIGHDPI;
#endif
if (always_on_top) {
#ifdef SCRCPY_SDL_HAS_WINDOW_ALWAYS_ON_TOP
window_flags |= SDL_WINDOW_ALWAYS_ON_TOP;
#else
LOGW("The 'always on top' flag is not available "
"(compile with SDL >= 2.0.5 to enable it)");
#endif
}
if (window_borderless) {
window_flags |= SDL_WINDOW_BORDERLESS;
}
int x = window_x != WINDOW_POSITION_UNDEFINED
? window_x : (int) SDL_WINDOWPOS_UNDEFINED;
int y = window_y != WINDOW_POSITION_UNDEFINED
? window_y : (int) SDL_WINDOWPOS_UNDEFINED;
screen->window = SDL_CreateWindow(window_title, x, y,
window_size.width, window_size.height,
window_flags);
if (!screen->window) {
LOGC("Could not create window: %s", SDL_GetError());
return false;
}
screen->renderer = SDL_CreateRenderer(screen->window, -1,
SDL_RENDERER_ACCELERATED);
if (!screen->renderer) {
LOGC("Could not create renderer: %s", SDL_GetError());
screen_destroy(screen);
return false;
}
SDL_RendererInfo renderer_info;
int r = SDL_GetRendererInfo(screen->renderer, &renderer_info);
const char *renderer_name = r ? NULL : renderer_info.name;
LOGI("Renderer: %s", renderer_name ? renderer_name : "(unknown)");
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// starts with "opengl"
screen->use_opengl = renderer_name && !strncmp(renderer_name, "opengl", 6);
if (screen->use_opengl) {
struct sc_opengl *gl = &screen->gl;
sc_opengl_init(gl);
LOGI("OpenGL version: %s", gl->version);
if (mipmaps) {
bool supports_mipmaps =
sc_opengl_version_at_least(gl, 3, 0, /* OpenGL 3.0+ */
2, 0 /* OpenGL ES 2.0+ */);
if (supports_mipmaps) {
LOGI("Trilinear filtering enabled");
screen->mipmaps = true;
} else {
LOGW("Trilinear filtering disabled "
"(OpenGL 3.0+ or ES 2.0+ required)");
}
} else {
LOGI("Trilinear filtering disabled");
}
} else {
LOGW("Trilinear filtering disabled (not an OpenGL renderer)");
}
SDL_Surface *icon = read_xpm(icon_xpm);
if (icon) {
SDL_SetWindowIcon(screen->window, icon);
SDL_FreeSurface(icon);
} else {
LOGW("Could not load icon");
}
LOGI("Initial texture: %" PRIu16 "x%" PRIu16, frame_size.width,
frame_size.height);
screen->texture = create_texture(screen);
if (!screen->texture) {
LOGC("Could not create texture: %s", SDL_GetError());
screen_destroy(screen);
return false;
}
// Reset the window size to trigger a SIZE_CHANGED event, to workaround
// HiDPI issues with some SDL renderers when several displays having
// different HiDPI scaling are connected
SDL_SetWindowSize(screen->window, window_size.width, window_size.height);
screen_update_content_rect(screen);
return true;
}
void
screen_show_window(struct screen *screen) {
Improve startup time On startup, the client has to: 1. listen on a port 2. push and start the server to the device 3. wait for the server to connect (accept) 4. read device name and size 5. initialize SDL 6. initialize the window and renderer 7. show the window From the execution of the app_process command to start the server on the device, to the execution of the java main method, it takes ~800ms. As a consequence, step 3 also takes ~800ms on the client. Once complete, the client initializes SDL, which takes ~500ms. These two expensive actions are executed sequentially: HOST DEVICE listen on port | | push/start the server |----------------->|| app_process loads the jar accept the connection . ^ || . | || . | WASTE || . | OF || . | TIME || . | || . | || . v X execution of our java main connection accepted |<-----------------| connect to the host init SDL || | || ,----------------| send frames || |,---------------| || ||,--------------| || |||,-------------| || ||||,------------| init window/renderer | |||||,-----------| display frames |<++++++-----------| (many frames skipped) The rationale for step 3 occuring before step 5 is that initializing SDL replaces the SIGTERM handler to receive the event in the event loop, so pressing Ctrl+C during step 5 would not work (since it blocks the event loop). But this is not so important; let's parallelize the SDL initialization with the app_process execution (we'll just add a timeout to the connection): HOST DEVICE listen on port | | push/start the server |----------------->||app_process loads the jar init SDL || || || || || || || || || || || || accept the connection . || . X execution of our java main connection accepted |<-----------------| connect to the host init window/renderer | | display frames |<-----------------| send frames |<-----------------| In addition, show the window only once the first frame is available to avoid flickering (opening a black window for 100~200ms). Note: the window and renderer are initialized after the connection is accepted because they use the device information received from the device.
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SDL_ShowWindow(screen->window);
}
void
screen_destroy(struct screen *screen) {
if (screen->texture) {
SDL_DestroyTexture(screen->texture);
}
if (screen->renderer) {
SDL_DestroyRenderer(screen->renderer);
}
if (screen->window) {
SDL_DestroyWindow(screen->window);
}
}
static void
resize_for_content(struct screen *screen, struct size old_content_size,
struct size new_content_size) {
struct size window_size = get_window_size(screen);
struct size target_size = {
.width = (uint32_t) window_size.width * new_content_size.width
/ old_content_size.width,
.height = (uint32_t) window_size.height * new_content_size.height
/ old_content_size.height,
};
target_size = get_optimal_size(target_size, new_content_size);
set_window_size(screen, target_size);
}
static void
set_content_size(struct screen *screen, struct size new_content_size) {
if (!screen->fullscreen && !screen->maximized) {
resize_for_content(screen, screen->content_size, new_content_size);
} else if (!screen->resize_pending) {
// Store the windowed size to be able to compute the optimal size once
// fullscreen and maximized are disabled
screen->windowed_content_size = screen->content_size;
screen->resize_pending = true;
}
screen->content_size = new_content_size;
}
static void
apply_pending_resize(struct screen *screen) {
assert(!screen->fullscreen);
assert(!screen->maximized);
if (screen->resize_pending) {
resize_for_content(screen, screen->windowed_content_size,
screen->content_size);
screen->resize_pending = false;
}
}
void
screen_set_rotation(struct screen *screen, unsigned rotation) {
assert(rotation < 4);
if (rotation == screen->rotation) {
return;
}
struct size new_content_size =
get_rotated_size(screen->frame_size, rotation);
set_content_size(screen, new_content_size);
screen->rotation = rotation;
LOGI("Display rotation set to %u", rotation);
screen_render(screen, true);
}
// recreate the texture and resize the window if the frame size has changed
static bool
prepare_for_frame(struct screen *screen, struct size new_frame_size) {
if (screen->frame_size.width != new_frame_size.width
|| screen->frame_size.height != new_frame_size.height) {
// frame dimension changed, destroy texture
SDL_DestroyTexture(screen->texture);
screen->frame_size = new_frame_size;
struct size new_content_size =
get_rotated_size(new_frame_size, screen->rotation);
set_content_size(screen, new_content_size);
screen_update_content_rect(screen);
LOGI("New texture: %" PRIu16 "x%" PRIu16,
screen->frame_size.width, screen->frame_size.height);
screen->texture = create_texture(screen);
if (!screen->texture) {
LOGC("Could not create texture: %s", SDL_GetError());
return false;
}
}
return true;
}
// write the frame into the texture
static void
update_texture(struct screen *screen, const AVFrame *frame) {
SDL_UpdateYUVTexture(screen->texture, NULL,
frame->data[0], frame->linesize[0],
frame->data[1], frame->linesize[1],
frame->data[2], frame->linesize[2]);
if (screen->mipmaps) {
assert(screen->use_opengl);
SDL_GL_BindTexture(screen->texture, NULL, NULL);
screen->gl.GenerateMipmap(GL_TEXTURE_2D);
SDL_GL_UnbindTexture(screen->texture);
}
}
bool
screen_update_frame(struct screen *screen, struct video_buffer *vb) {
mutex_lock(vb->mutex);
const AVFrame *frame = video_buffer_consume_rendered_frame(vb);
struct size new_frame_size = {frame->width, frame->height};
if (!prepare_for_frame(screen, new_frame_size)) {
mutex_unlock(vb->mutex);
return false;
}
update_texture(screen, frame);
mutex_unlock(vb->mutex);
screen_render(screen, false);
return true;
}
void
screen_render(struct screen *screen, bool update_content_rect) {
if (update_content_rect) {
screen_update_content_rect(screen);
}
SDL_RenderClear(screen->renderer);
if (screen->rotation == 0) {
SDL_RenderCopy(screen->renderer, screen->texture, NULL, &screen->rect);
} else {
// rotation in RenderCopyEx() is clockwise, while screen->rotation is
// counterclockwise (to be consistent with --lock-video-orientation)
int cw_rotation = (4 - screen->rotation) % 4;
double angle = 90 * cw_rotation;
SDL_Rect *dstrect = NULL;
SDL_Rect rect;
if (screen->rotation & 1) {
rect.x = screen->rect.x + (screen->rect.w - screen->rect.h) / 2;
rect.y = screen->rect.y + (screen->rect.h - screen->rect.w) / 2;
rect.w = screen->rect.h;
rect.h = screen->rect.w;
dstrect = &rect;
} else {
assert(screen->rotation == 2);
dstrect = &screen->rect;
}
SDL_RenderCopyEx(screen->renderer, screen->texture, NULL, dstrect,
angle, NULL, 0);
}
SDL_RenderPresent(screen->renderer);
}
void
screen_switch_fullscreen(struct screen *screen) {
uint32_t new_mode = screen->fullscreen ? 0 : SDL_WINDOW_FULLSCREEN_DESKTOP;
if (SDL_SetWindowFullscreen(screen->window, new_mode)) {
LOGW("Could not switch fullscreen mode: %s", SDL_GetError());
return;
}
screen->fullscreen = !screen->fullscreen;
if (!screen->fullscreen && !screen->maximized) {
apply_pending_resize(screen);
}
LOGD("Switched to %s mode", screen->fullscreen ? "fullscreen" : "windowed");
screen_render(screen, true);
}
void
screen_resize_to_fit(struct screen *screen) {
if (screen->fullscreen || screen->maximized) {
return;
}
struct size optimal_size =
get_optimal_window_size(screen, screen->content_size);
SDL_SetWindowSize(screen->window, optimal_size.width, optimal_size.height);
LOGD("Resized to optimal size: %ux%u", optimal_size.width,
optimal_size.height);
}
void
screen_resize_to_pixel_perfect(struct screen *screen) {
if (screen->fullscreen) {
return;
}
if (screen->maximized) {
SDL_RestoreWindow(screen->window);
screen->maximized = false;
}
struct size content_size = screen->content_size;
SDL_SetWindowSize(screen->window, content_size.width, content_size.height);
LOGD("Resized to pixel-perfect: %ux%u", content_size.width,
content_size.height);
}
void
screen_handle_window_event(struct screen *screen,
const SDL_WindowEvent *event) {
switch (event->event) {
case SDL_WINDOWEVENT_EXPOSED:
screen_render(screen, true);
break;
case SDL_WINDOWEVENT_SIZE_CHANGED:
screen_render(screen, true);
break;
case SDL_WINDOWEVENT_MAXIMIZED:
screen->maximized = true;
break;
case SDL_WINDOWEVENT_RESTORED:
if (screen->fullscreen) {
// On Windows, in maximized+fullscreen, disabling fullscreen
// mode unexpectedly triggers the "restored" then "maximized"
// events, leaving the window in a weird state (maximized
// according to the events, but not maximized visually).
break;
}
screen->maximized = false;
apply_pending_resize(screen);
break;
}
}
struct point
screen_convert_to_frame_coords(struct screen *screen, int32_t x, int32_t y) {
unsigned rotation = screen->rotation;
assert(rotation < 4);
int32_t w = screen->content_size.width;
int32_t h = screen->content_size.height;
screen_hidpi_scale_coords(screen, &x, &y);
x = (int64_t) (x - screen->rect.x) * w / screen->rect.w;
y = (int64_t) (y - screen->rect.y) * h / screen->rect.h;
// rotate
struct point result;
switch (rotation) {
case 0:
result.x = x;
result.y = y;
break;
case 1:
result.x = h - y;
result.y = x;
break;
case 2:
result.x = w - x;
result.y = h - y;
break;
default:
assert(rotation == 3);
result.x = y;
result.y = w - x;
break;
}
return result;
}
void
screen_hidpi_scale_coords(struct screen *screen, int32_t *x, int32_t *y) {
// take the HiDPI scaling (dw/ww and dh/wh) into account
int ww, wh, dw, dh;
SDL_GetWindowSize(screen->window, &ww, &wh);
SDL_GL_GetDrawableSize(screen->window, &dw, &dh);
// scale for HiDPI (64 bits for intermediate multiplications)
*x = (int64_t) *x * dw / ww;
*y = (int64_t) *y * dh / wh;
}