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This commit is contained in:
loki
2021-05-17 21:21:57 +02:00
parent a6c1649493
commit 3d8a99f541
43 changed files with 1917 additions and 1872 deletions
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116
sunshine/platform/windows/display_ram.cpp
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@@ -1,12 +1,12 @@
#include "sunshine/main.h"
#include "display.h"
#include "sunshine/main.h"
namespace platf {
using namespace std::literals;
}
namespace platf::dxgi {
struct img_t : public ::platf::img_t {
struct img_t : public ::platf::img_t {
~img_t() override {
delete[] data;
data = nullptr;
@@ -22,29 +22,29 @@ void blend_cursor_monochrome(const cursor_t &cursor, img_t &img) {
auto cursor_skip_y = -std::min(0, cursor.y);
auto cursor_skip_x = -std::min(0, cursor.x);
// img cursor.{x,y} > img.{x,y}, truncate parts of the cursor.img_data
// img cursor.{x,y} > img.{x,y}, truncate parts of the cursor.img_data
auto cursor_truncate_y = std::max(0, cursor.y - img.height);
auto cursor_truncate_x = std::max(0, cursor.x - img.width);
auto cursor_width = width - cursor_skip_x - cursor_truncate_x;
auto cursor_width = width - cursor_skip_x - cursor_truncate_x;
auto cursor_height = height - cursor_skip_y - cursor_truncate_y;
if(cursor_height > height || cursor_width > width) {
return;
}
auto img_skip_y = std::max(0, cursor.y);
auto img_skip_x = std::max(0, cursor.x);
auto img_skip_y = std::max(0, cursor.y);
auto img_skip_x = std::max(0, cursor.x);
auto cursor_img_data = cursor.img_data.data() + cursor_skip_y * pitch;
int delta_height = std::min(cursor_height - cursor_truncate_y, std::max(0, img.height - img_skip_y));
int delta_width = std::min(cursor_width - cursor_truncate_x, std::max(0, img.width - img_skip_x));
int delta_width = std::min(cursor_width - cursor_truncate_x, std::max(0, img.width - img_skip_x));
auto pixels_per_byte = width / pitch;
auto bytes_per_row = delta_width / pixels_per_byte;
auto bytes_per_row = delta_width / pixels_per_byte;
auto img_data = (int*)img.data;
auto img_data = (int *)img.data;
for(int i = 0; i < delta_height; ++i) {
auto and_mask = &cursor_img_data[i * pitch];
auto xor_mask = &cursor_img_data[(i + height) * pitch];
@@ -76,8 +76,8 @@ void blend_cursor_monochrome(const cursor_t &cursor, img_t &img) {
}
void apply_color_alpha(int *img_pixel_p, int cursor_pixel) {
auto colors_out = (std::uint8_t*)&cursor_pixel;
auto colors_in = (std::uint8_t*)img_pixel_p;
auto colors_out = (std::uint8_t *)&cursor_pixel;
auto colors_in = (std::uint8_t *)img_pixel_p;
//TODO: When use of IDXGIOutput5 is implemented, support different color formats
auto alpha = colors_out[3];
@@ -85,15 +85,15 @@ void apply_color_alpha(int *img_pixel_p, int cursor_pixel) {
*img_pixel_p = cursor_pixel;
}
else {
colors_in[0] = colors_out[0] + (colors_in[0] * (255 - alpha) + 255/2) / 255;
colors_in[1] = colors_out[1] + (colors_in[1] * (255 - alpha) + 255/2) / 255;
colors_in[2] = colors_out[2] + (colors_in[2] * (255 - alpha) + 255/2) / 255;
colors_in[0] = colors_out[0] + (colors_in[0] * (255 - alpha) + 255 / 2) / 255;
colors_in[1] = colors_out[1] + (colors_in[1] * (255 - alpha) + 255 / 2) / 255;
colors_in[2] = colors_out[2] + (colors_in[2] * (255 - alpha) + 255 / 2) / 255;
}
}
void apply_color_masked(int *img_pixel_p, int cursor_pixel) {
//TODO: When use of IDXGIOutput5 is implemented, support different color formats
auto alpha = ((std::uint8_t*)&cursor_pixel)[3];
auto alpha = ((std::uint8_t *)&cursor_pixel)[3];
if(alpha == 0xFF) {
*img_pixel_p ^= cursor_pixel;
}
@@ -111,30 +111,30 @@ void blend_cursor_color(const cursor_t &cursor, img_t &img, const bool masked) {
auto cursor_skip_y = -std::min(0, cursor.y);
auto cursor_skip_x = -std::min(0, cursor.x);
// img cursor.{x,y} > img.{x,y}, truncate parts of the cursor.img_data
// img cursor.{x,y} > img.{x,y}, truncate parts of the cursor.img_data
auto cursor_truncate_y = std::max(0, cursor.y - img.height);
auto cursor_truncate_x = std::max(0, cursor.x - img.width);
auto img_skip_y = std::max(0, cursor.y);
auto img_skip_x = std::max(0, cursor.x);
auto img_skip_y = std::max(0, cursor.y);
auto img_skip_x = std::max(0, cursor.x);
auto cursor_width = width - cursor_skip_x - cursor_truncate_x;
auto cursor_width = width - cursor_skip_x - cursor_truncate_x;
auto cursor_height = height - cursor_skip_y - cursor_truncate_y;
if(cursor_height > height || cursor_width > width) {
return;
}
auto cursor_img_data = (int*)&cursor.img_data[cursor_skip_y * pitch];
auto cursor_img_data = (int *)&cursor.img_data[cursor_skip_y * pitch];
int delta_height = std::min(cursor_height - cursor_truncate_y, std::max(0, img.height - img_skip_y));
int delta_width = std::min(cursor_width - cursor_truncate_x, std::max(0, img.width - img_skip_x));
int delta_width = std::min(cursor_width - cursor_truncate_x, std::max(0, img.width - img_skip_x));
auto img_data = (int*)img.data;
auto img_data = (int *)img.data;
for(int i = 0; i < delta_height; ++i) {
auto cursor_begin = &cursor_img_data[i * cursor.shape_info.Width + cursor_skip_x];
auto cursor_end = &cursor_begin[delta_width];
auto cursor_end = &cursor_begin[delta_width];
auto img_pixel_p = &img_data[(i + img_skip_y) * (img.row_pitch / img.pixel_pitch) + img_skip_x];
std::for_each(cursor_begin, cursor_end, [&](int cursor_pixel) {
@@ -151,22 +151,22 @@ void blend_cursor_color(const cursor_t &cursor, img_t &img, const bool masked) {
void blend_cursor(const cursor_t &cursor, img_t &img) {
switch(cursor.shape_info.Type) {
case DXGI_OUTDUPL_POINTER_SHAPE_TYPE_COLOR:
blend_cursor_color(cursor, img, false);
break;
case DXGI_OUTDUPL_POINTER_SHAPE_TYPE_MONOCHROME:
blend_cursor_monochrome(cursor, img);
break;
case DXGI_OUTDUPL_POINTER_SHAPE_TYPE_MASKED_COLOR:
blend_cursor_color(cursor, img, true);
break;
default:
BOOST_LOG(warning) << "Unsupported cursor format ["sv << cursor.shape_info.Type << ']';
case DXGI_OUTDUPL_POINTER_SHAPE_TYPE_COLOR:
blend_cursor_color(cursor, img, false);
break;
case DXGI_OUTDUPL_POINTER_SHAPE_TYPE_MONOCHROME:
blend_cursor_monochrome(cursor, img);
break;
case DXGI_OUTDUPL_POINTER_SHAPE_TYPE_MASKED_COLOR:
blend_cursor_color(cursor, img, true);
break;
default:
BOOST_LOG(warning) << "Unsupported cursor format ["sv << cursor.shape_info.Type << ']';
}
}
capture_e display_ram_t::snapshot(::platf::img_t *img_base, std::chrono::milliseconds timeout, bool cursor_visible) {
auto img = (img_t*)img_base;
auto img = (img_t *)img_base;
HRESULT status;
@@ -174,9 +174,9 @@ capture_e display_ram_t::snapshot(::platf::img_t *img_base, std::chrono::millise
resource_t::pointer res_p {};
auto capture_status = dup.next_frame(frame_info, timeout, &res_p);
resource_t res{res_p};
resource_t res { res_p };
if (capture_status != capture_e::ok) {
if(capture_status != capture_e::ok) {
return capture_status;
}
@@ -187,7 +187,7 @@ capture_e display_ram_t::snapshot(::platf::img_t *img_base, std::chrono::millise
UINT dummy;
status = dup.dup->GetFramePointerShape(img_data.size(), img_data.data(), &dummy, &cursor.shape_info);
if (FAILED(status)) {
if(FAILED(status)) {
BOOST_LOG(error) << "Failed to get new pointer shape [0x"sv << util::hex(status).to_string_view() << ']';
return capture_e::error;
@@ -195,18 +195,18 @@ capture_e display_ram_t::snapshot(::platf::img_t *img_base, std::chrono::millise
}
if(frame_info.LastMouseUpdateTime.QuadPart) {
cursor.x = frame_info.PointerPosition.Position.x;
cursor.y = frame_info.PointerPosition.Position.y;
cursor.x = frame_info.PointerPosition.Position.x;
cursor.y = frame_info.PointerPosition.Position.y;
cursor.visible = frame_info.PointerPosition.Visible;
}
// If frame has been updated
if (frame_info.LastPresentTime.QuadPart != 0) {
if(frame_info.LastPresentTime.QuadPart != 0) {
{
texture2d_t src {};
status = res->QueryInterface(IID_ID3D11Texture2D, (void **)&src);
if (FAILED(status)) {
if(FAILED(status)) {
BOOST_LOG(error) << "Couldn't query interface [0x"sv << util::hex(status).to_string_view() << ']';
return capture_e::error;
}
@@ -221,14 +221,14 @@ capture_e display_ram_t::snapshot(::platf::img_t *img_base, std::chrono::millise
}
status = device_ctx->Map(texture.get(), 0, D3D11_MAP_READ, 0, &img_info);
if (FAILED(status)) {
if(FAILED(status)) {
BOOST_LOG(error) << "Failed to map texture [0x"sv << util::hex(status).to_string_view() << ']';
return capture_e::error;
}
}
const bool mouse_update =
const bool mouse_update =
(frame_info.LastMouseUpdateTime.QuadPart || frame_info.PointerShapeBufferSize > 0) &&
(cursor_visible && cursor.visible);
@@ -238,7 +238,7 @@ capture_e display_ram_t::snapshot(::platf::img_t *img_base, std::chrono::millise
return capture_e::timeout;
}
std::copy_n((std::uint8_t*)img_info.pData, height * img_info.RowPitch, (std::uint8_t*)img->data);
std::copy_n((std::uint8_t *)img_info.pData, height * img_info.RowPitch, (std::uint8_t *)img->data);
if(cursor_visible && cursor.visible) {
blend_cursor(cursor, *img);
@@ -250,11 +250,11 @@ capture_e display_ram_t::snapshot(::platf::img_t *img_base, std::chrono::millise
std::shared_ptr<platf::img_t> display_ram_t::alloc_img() {
auto img = std::make_shared<img_t>();
img->pixel_pitch = 4;
img->row_pitch = img_info.RowPitch;
img->width = width;
img->height = height;
img->data = new std::uint8_t[img->row_pitch * height];
img->pixel_pitch = 4;
img->row_pitch = img_info.RowPitch;
img->width = width;
img->height = height;
img->data = new std::uint8_t[img->row_pitch * height];
return img;
}
@@ -269,14 +269,14 @@ int display_ram_t::init() {
}
D3D11_TEXTURE2D_DESC t {};
t.Width = width;
t.Height = height;
t.MipLevels = 1;
t.ArraySize = 1;
t.Width = width;
t.Height = height;
t.MipLevels = 1;
t.ArraySize = 1;
t.SampleDesc.Count = 1;
t.Usage = D3D11_USAGE_STAGING;
t.Format = format;
t.CPUAccessFlags = D3D11_CPU_ACCESS_READ;
t.Usage = D3D11_USAGE_STAGING;
t.Format = format;
t.CPUAccessFlags = D3D11_CPU_ACCESS_READ;
auto status = device->CreateTexture2D(&t, nullptr, &texture);
@@ -294,4 +294,4 @@ int display_ram_t::init() {
return 0;
}
}
} // namespace platf::dxgi