#include <stdio.h>
#include <unistd.h>
+#include "gpu_timers.h"
#include "util.h"
#include <algorithm>
using namespace std;
+SDL_Window *window;
+
// Operating point 3 (10 Hz on CPU, excluding preprocessing).
constexpr float patch_overlap_ratio = 0.75f;
constexpr unsigned coarsest_level = 5;
// Weighting constants for the different parts of the variational refinement.
// These don't correspond 1:1 to the values given in the DIS paper,
// since we have different normalizations and ranges in some cases.
-float vr_gamma = 10.0f, vr_delta = 5.0f, vr_alpha = 10.0f;
+// These are found through a simple grid search on some MPI-Sintel data,
+// although the error (EPE) seems to be fairly insensitive to the precise values.
+// Only the relative values matter, so we fix alpha (the smoothness constant)
+// at unity and tweak the others.
+float vr_alpha = 1.0f, vr_delta = 0.25f, vr_gamma = 0.25f;
bool enable_timing = true;
+bool detailed_timing = false;
+bool enable_warmup = false;
+bool in_warmup = false;
bool enable_variational_refinement = true; // Just for debugging.
+bool enable_interpolation = false;
// Some global OpenGL objects.
// TODO: These should really be part of DISComputeFlow.
-GLuint nearest_sampler, linear_sampler, smoothness_sampler;
+GLuint nearest_sampler, linear_sampler, zero_border_sampler;
GLuint vertex_vbo;
// Structures for asynchronous readback. We assume everything is the same size (and GL_RG16F).
stack<GLuint> spare_pbos;
deque<ReadInProgress> reads_in_progress;
+int find_num_levels(int width, int height)
+{
+ int levels = 1;
+ for (int w = width, h = height; w > 1 || h > 1; ) {
+ w >>= 1;
+ h >>= 1;
+ ++levels;
+ }
+ return levels;
+}
+
string read_file(const string &filename)
{
FILE *fp = fopen(filename.c_str(), "r");
return obj;
}
-GLuint load_texture(const char *filename, unsigned *width_ret, unsigned *height_ret)
+enum MipmapPolicy {
+ WITHOUT_MIPMAPS,
+ WITH_MIPMAPS
+};
+
+GLuint load_texture(const char *filename, unsigned *width_ret, unsigned *height_ret, MipmapPolicy mipmaps)
{
SDL_Surface *surf = IMG_Load(filename);
if (surf == nullptr) {
}
// For whatever reason, SDL doesn't support converting to YUV surfaces
- // nor grayscale, so we'll do it (slowly) ourselves.
- SDL_Surface *rgb_surf = SDL_ConvertSurfaceFormat(surf, SDL_PIXELFORMAT_RGBA8888, /*flags=*/0);
+ // nor grayscale, so we'll do it ourselves.
+ SDL_Surface *rgb_surf = SDL_ConvertSurfaceFormat(surf, SDL_PIXELFORMAT_RGBA32, /*flags=*/0);
if (rgb_surf == nullptr) {
fprintf(stderr, "SDL_ConvertSurfaceFormat(%s): %s\n", filename, SDL_GetError());
exit(1);
unsigned width = rgb_surf->w, height = rgb_surf->h;
const uint8_t *sptr = (uint8_t *)rgb_surf->pixels;
- unique_ptr<uint8_t[]> pix(new uint8_t[width * height]);
+ unique_ptr<uint8_t[]> pix(new uint8_t[width * height * 4]);
// Extract the Y component, and convert to bottom-left origin.
for (unsigned y = 0; y < height; ++y) {
unsigned y2 = height - 1 - y;
- for (unsigned x = 0; x < width; ++x) {
- uint8_t r = sptr[(y2 * width + x) * 4 + 3];
- uint8_t g = sptr[(y2 * width + x) * 4 + 2];
- uint8_t b = sptr[(y2 * width + x) * 4 + 1];
-
- // Rec. 709.
- pix[y * width + x] = lrintf(r * 0.2126f + g * 0.7152f + b * 0.0722f);
- }
+ memcpy(pix.get() + y * width * 4, sptr + y2 * rgb_surf->pitch, width * 4);
}
SDL_FreeSurface(rgb_surf);
- int levels = 1;
- for (int w = width, h = height; w > 1 || h > 1; ) {
- w >>= 1;
- h >>= 1;
- ++levels;
- }
+ int num_levels = (mipmaps == WITH_MIPMAPS) ? find_num_levels(width, height) : 1;
GLuint tex;
glCreateTextures(GL_TEXTURE_2D, 1, &tex);
- glTextureStorage2D(tex, levels, GL_R8, width, height);
- glTextureSubImage2D(tex, 0, 0, 0, width, height, GL_RED, GL_UNSIGNED_BYTE, pix.get());
- glGenerateTextureMipmap(tex);
+ glTextureStorage2D(tex, num_levels, GL_RGBA8, width, height);
+ glTextureSubImage2D(tex, 0, 0, 0, width, height, GL_RGBA, GL_UNSIGNED_BYTE, pix.get());
+
+ if (mipmaps == WITH_MIPMAPS) {
+ glGenerateTextureMipmap(tex);
+ }
*width_ret = width;
*height_ret = height;
return program;
}
-GLuint generate_vbo(GLint size, GLsizeiptr data_size, const GLvoid *data)
-{
- GLuint vbo;
- glCreateBuffers(1, &vbo);
- glBufferData(GL_ARRAY_BUFFER, data_size, data, GL_STATIC_DRAW);
- glNamedBufferData(vbo, data_size, data, GL_STATIC_DRAW);
- return vbo;
-}
-
-GLuint fill_vertex_attribute(GLuint vao, GLuint glsl_program_num, const string &attribute_name, GLint size, GLenum type, GLsizeiptr data_size, const GLvoid *data)
-{
- int attrib = glGetAttribLocation(glsl_program_num, attribute_name.c_str());
- if (attrib == -1) {
- return -1;
- }
-
- GLuint vbo = generate_vbo(size, data_size, data);
-
- glBindBuffer(GL_ARRAY_BUFFER, vbo);
- glEnableVertexArrayAttrib(vao, attrib);
- glVertexAttribPointer(attrib, size, type, GL_FALSE, 0, BUFFER_OFFSET(0));
- glBindBuffer(GL_ARRAY_BUFFER, 0);
-
- return vbo;
-}
-
void bind_sampler(GLuint program, GLint location, GLuint texture_unit, GLuint tex, GLuint sampler)
{
if (location == -1) {
void render_to(const array<GLuint, num_elements> &textures);
// Convenience wrappers.
- void render_to(GLuint texture0, enable_if<num_elements == 1> * = nullptr) {
+ void render_to(GLuint texture0) {
render_to({{texture0}});
}
- void render_to(GLuint texture0, GLuint texture1, enable_if<num_elements == 2> * = nullptr) {
+ void render_to(GLuint texture0, GLuint texture1) {
render_to({{texture0, texture1}});
}
- void render_to(GLuint texture0, GLuint texture1, GLuint texture2, enable_if<num_elements == 3> * = nullptr) {
+ void render_to(GLuint texture0, GLuint texture1, GLuint texture2) {
render_to({{texture0, texture1, texture2}});
}
- void render_to(GLuint texture0, GLuint texture1, GLuint texture2, GLuint texture3, enable_if<num_elements == 4> * = nullptr) {
+ void render_to(GLuint texture0, GLuint texture1, GLuint texture2, GLuint texture3) {
render_to({{texture0, texture1, texture2, texture3}});
}
glBindFramebuffer(GL_FRAMEBUFFER, fbo);
}
+// Same, but with a depth texture.
+template<size_t num_elements>
+class PersistentFBOSetWithDepth {
+public:
+ void render_to(GLuint depth_rb, const array<GLuint, num_elements> &textures);
+
+ // Convenience wrappers.
+ void render_to(GLuint depth_rb, GLuint texture0) {
+ render_to(depth_rb, {{texture0}});
+ }
+
+ void render_to(GLuint depth_rb, GLuint texture0, GLuint texture1) {
+ render_to(depth_rb, {{texture0, texture1}});
+ }
+
+ void render_to(GLuint depth_rb, GLuint texture0, GLuint texture1, GLuint texture2) {
+ render_to(depth_rb, {{texture0, texture1, texture2}});
+ }
+
+ void render_to(GLuint depth_rb, GLuint texture0, GLuint texture1, GLuint texture2, GLuint texture3) {
+ render_to(depth_rb, {{texture0, texture1, texture2, texture3}});
+ }
+
+private:
+ // TODO: Delete these on destruction.
+ map<pair<GLuint, array<GLuint, num_elements>>, GLuint> fbos;
+};
+
+template<size_t num_elements>
+void PersistentFBOSetWithDepth<num_elements>::render_to(GLuint depth_rb, const array<GLuint, num_elements> &textures)
+{
+ auto key = make_pair(depth_rb, textures);
+
+ auto it = fbos.find(key);
+ if (it != fbos.end()) {
+ glBindFramebuffer(GL_FRAMEBUFFER, it->second);
+ return;
+ }
+
+ GLuint fbo;
+ glCreateFramebuffers(1, &fbo);
+ GLenum bufs[num_elements];
+ glNamedFramebufferRenderbuffer(fbo, GL_DEPTH_ATTACHMENT, GL_RENDERBUFFER, depth_rb);
+ for (size_t i = 0; i < num_elements; ++i) {
+ glNamedFramebufferTexture(fbo, GL_COLOR_ATTACHMENT0 + i, textures[i], 0);
+ bufs[i] = GL_COLOR_ATTACHMENT0 + i;
+ }
+ glNamedFramebufferDrawBuffers(fbo, num_elements, bufs);
+
+ fbos[key] = fbo;
+ glBindFramebuffer(GL_FRAMEBUFFER, fbo);
+}
+
+// Convert RGB to grayscale, using Rec. 709 coefficients.
+class GrayscaleConversion {
+public:
+ GrayscaleConversion();
+ void exec(GLint tex, GLint gray_tex, int width, int height);
+
+private:
+ PersistentFBOSet<1> fbos;
+ GLuint gray_vs_obj;
+ GLuint gray_fs_obj;
+ GLuint gray_program;
+ GLuint gray_vao;
+
+ GLuint uniform_tex;
+};
+
+GrayscaleConversion::GrayscaleConversion()
+{
+ gray_vs_obj = compile_shader(read_file("vs.vert"), GL_VERTEX_SHADER);
+ gray_fs_obj = compile_shader(read_file("gray.frag"), GL_FRAGMENT_SHADER);
+ gray_program = link_program(gray_vs_obj, gray_fs_obj);
+
+ // Set up the VAO containing all the required position/texcoord data.
+ glCreateVertexArrays(1, &gray_vao);
+ glBindVertexArray(gray_vao);
+
+ GLint position_attrib = glGetAttribLocation(gray_program, "position");
+ glEnableVertexArrayAttrib(gray_vao, position_attrib);
+ glVertexAttribPointer(position_attrib, 2, GL_FLOAT, GL_FALSE, 0, BUFFER_OFFSET(0));
+
+ uniform_tex = glGetUniformLocation(gray_program, "tex");
+}
+
+void GrayscaleConversion::exec(GLint tex, GLint gray_tex, int width, int height)
+{
+ glUseProgram(gray_program);
+ bind_sampler(gray_program, uniform_tex, 0, tex, nearest_sampler);
+
+ glViewport(0, 0, width, height);
+ fbos.render_to(gray_tex);
+ glBindVertexArray(gray_vao);
+ glDisable(GL_BLEND);
+ glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
+}
+
// Compute gradients in every point, used for the motion search.
// The DIS paper doesn't actually mention how these are computed,
// but seemingly, a 3x3 Sobel operator is used here (at least in
GLuint sobel_vs_obj;
GLuint sobel_fs_obj;
GLuint sobel_program;
- GLuint sobel_vao;
- GLuint uniform_tex, uniform_image_size;
+ GLuint uniform_tex;
};
Sobel::Sobel()
sobel_fs_obj = compile_shader(read_file("sobel.frag"), GL_FRAGMENT_SHADER);
sobel_program = link_program(sobel_vs_obj, sobel_fs_obj);
- // Set up the VAO containing all the required position/texcoord data.
- glCreateVertexArrays(1, &sobel_vao);
- glBindVertexArray(sobel_vao);
-
- GLint position_attrib = glGetAttribLocation(sobel_program, "position");
- glEnableVertexArrayAttrib(sobel_vao, position_attrib);
- glVertexAttribPointer(position_attrib, 2, GL_FLOAT, GL_FALSE, 0, BUFFER_OFFSET(0));
-
uniform_tex = glGetUniformLocation(sobel_program, "tex");
}
void Sobel::exec(GLint tex0_view, GLint grad0_tex, int level_width, int level_height)
{
glUseProgram(sobel_program);
- glBindTextureUnit(0, tex0_view);
- glBindSampler(0, nearest_sampler);
- glProgramUniform1i(sobel_program, uniform_tex, 0);
+ bind_sampler(sobel_program, uniform_tex, 0, tex0_view, nearest_sampler);
glViewport(0, 0, level_width, level_height);
fbos.render_to(grad0_tex);
- glBindVertexArray(sobel_vao);
- glUseProgram(sobel_program);
glDisable(GL_BLEND);
glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
}
GLuint motion_vs_obj;
GLuint motion_fs_obj;
GLuint motion_search_program;
- GLuint motion_search_vao;
- GLuint uniform_image_size, uniform_inv_image_size, uniform_inv_flow_size, uniform_inv_prev_level_size;
- GLuint uniform_image0_tex, uniform_image1_tex, uniform_grad0_tex, uniform_flow_tex;
+ GLuint uniform_inv_image_size, uniform_inv_prev_level_size, uniform_out_flow_size;
+ GLuint uniform_image1_tex, uniform_grad0_tex, uniform_flow_tex;
};
MotionSearch::MotionSearch()
motion_fs_obj = compile_shader(read_file("motion_search.frag"), GL_FRAGMENT_SHADER);
motion_search_program = link_program(motion_vs_obj, motion_fs_obj);
- // Set up the VAO containing all the required position/texcoord data.
- glCreateVertexArrays(1, &motion_search_vao);
- glBindVertexArray(motion_search_vao);
- glBindBuffer(GL_ARRAY_BUFFER, vertex_vbo);
-
- GLint position_attrib = glGetAttribLocation(motion_search_program, "position");
- glEnableVertexArrayAttrib(motion_search_vao, position_attrib);
- glVertexAttribPointer(position_attrib, 2, GL_FLOAT, GL_FALSE, 0, BUFFER_OFFSET(0));
-
- uniform_image_size = glGetUniformLocation(motion_search_program, "image_size");
uniform_inv_image_size = glGetUniformLocation(motion_search_program, "inv_image_size");
- uniform_inv_flow_size = glGetUniformLocation(motion_search_program, "inv_flow_size");
uniform_inv_prev_level_size = glGetUniformLocation(motion_search_program, "inv_prev_level_size");
- uniform_image0_tex = glGetUniformLocation(motion_search_program, "image0_tex");
+ uniform_out_flow_size = glGetUniformLocation(motion_search_program, "out_flow_size");
uniform_image1_tex = glGetUniformLocation(motion_search_program, "image1_tex");
uniform_grad0_tex = glGetUniformLocation(motion_search_program, "grad0_tex");
uniform_flow_tex = glGetUniformLocation(motion_search_program, "flow_tex");
{
glUseProgram(motion_search_program);
- bind_sampler(motion_search_program, uniform_image0_tex, 0, tex0_view, nearest_sampler);
bind_sampler(motion_search_program, uniform_image1_tex, 1, tex1_view, linear_sampler);
bind_sampler(motion_search_program, uniform_grad0_tex, 2, grad0_tex, nearest_sampler);
bind_sampler(motion_search_program, uniform_flow_tex, 3, flow_tex, linear_sampler);
- glProgramUniform2f(motion_search_program, uniform_image_size, level_width, level_height);
glProgramUniform2f(motion_search_program, uniform_inv_image_size, 1.0f / level_width, 1.0f / level_height);
- glProgramUniform2f(motion_search_program, uniform_inv_flow_size, 1.0f / width_patches, 1.0f / height_patches);
glProgramUniform2f(motion_search_program, uniform_inv_prev_level_size, 1.0f / prev_level_width, 1.0f / prev_level_height);
+ glProgramUniform2f(motion_search_program, uniform_out_flow_size, width_patches, height_patches);
glViewport(0, 0, width_patches, height_patches);
fbos.render_to(flow_out_tex);
- glBindVertexArray(motion_search_vao);
- glUseProgram(motion_search_program);
glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
}
GLuint densify_vs_obj;
GLuint densify_fs_obj;
GLuint densify_program;
- GLuint densify_vao;
- GLuint uniform_width_patches, uniform_patch_size, uniform_patch_spacing;
+ GLuint uniform_patch_size;
GLuint uniform_image0_tex, uniform_image1_tex, uniform_flow_tex;
};
densify_fs_obj = compile_shader(read_file("densify.frag"), GL_FRAGMENT_SHADER);
densify_program = link_program(densify_vs_obj, densify_fs_obj);
- // Set up the VAO containing all the required position/texcoord data.
- glCreateVertexArrays(1, &densify_vao);
- glBindVertexArray(densify_vao);
- glBindBuffer(GL_ARRAY_BUFFER, vertex_vbo);
-
- GLint position_attrib = glGetAttribLocation(densify_program, "position");
- glEnableVertexArrayAttrib(densify_vao, position_attrib);
- glVertexAttribPointer(position_attrib, 2, GL_FLOAT, GL_FALSE, 0, BUFFER_OFFSET(0));
-
- uniform_width_patches = glGetUniformLocation(densify_program, "width_patches");
uniform_patch_size = glGetUniformLocation(densify_program, "patch_size");
- uniform_patch_spacing = glGetUniformLocation(densify_program, "patch_spacing");
uniform_image0_tex = glGetUniformLocation(densify_program, "image0_tex");
uniform_image1_tex = glGetUniformLocation(densify_program, "image1_tex");
uniform_flow_tex = glGetUniformLocation(densify_program, "flow_tex");
bind_sampler(densify_program, uniform_image1_tex, 1, tex1_view, linear_sampler);
bind_sampler(densify_program, uniform_flow_tex, 2, flow_tex, nearest_sampler);
- glProgramUniform1i(densify_program, uniform_width_patches, width_patches);
glProgramUniform2f(densify_program, uniform_patch_size,
float(patch_size_pixels) / level_width,
float(patch_size_pixels) / level_height);
- float patch_spacing_x = float(level_width - patch_size_pixels) / (width_patches - 1);
- float patch_spacing_y = float(level_height - patch_size_pixels) / (height_patches - 1);
- if (width_patches == 1) patch_spacing_x = 0.0f; // Avoid infinities.
- if (height_patches == 1) patch_spacing_y = 0.0f;
- glProgramUniform2f(densify_program, uniform_patch_spacing,
- patch_spacing_x / level_width,
- patch_spacing_y / level_height);
-
glViewport(0, 0, level_width, level_height);
glEnable(GL_BLEND);
glBlendFunc(GL_ONE, GL_ONE);
- glBindVertexArray(densify_vao);
fbos.render_to(dense_flow_tex);
+ glClearColor(0.0f, 0.0f, 0.0f, 0.0f);
+ glClear(GL_COLOR_BUFFER_BIT);
glDrawArraysInstanced(GL_TRIANGLE_STRIP, 0, 4, width_patches * height_patches);
}
GLuint prewarp_vs_obj;
GLuint prewarp_fs_obj;
GLuint prewarp_program;
- GLuint prewarp_vao;
GLuint uniform_image0_tex, uniform_image1_tex, uniform_flow_tex;
- GLuint uniform_image_size;
};
Prewarp::Prewarp()
prewarp_fs_obj = compile_shader(read_file("prewarp.frag"), GL_FRAGMENT_SHADER);
prewarp_program = link_program(prewarp_vs_obj, prewarp_fs_obj);
- // Set up the VAO containing all the required position/texcoord data.
- glCreateVertexArrays(1, &prewarp_vao);
- glBindVertexArray(prewarp_vao);
- glBindBuffer(GL_ARRAY_BUFFER, vertex_vbo);
-
- GLint position_attrib = glGetAttribLocation(prewarp_program, "position");
- glEnableVertexArrayAttrib(prewarp_vao, position_attrib);
- glVertexAttribPointer(position_attrib, 2, GL_FLOAT, GL_FALSE, 0, BUFFER_OFFSET(0));
-
uniform_image0_tex = glGetUniformLocation(prewarp_program, "image0_tex");
uniform_image1_tex = glGetUniformLocation(prewarp_program, "image1_tex");
uniform_flow_tex = glGetUniformLocation(prewarp_program, "flow_tex");
-
- uniform_image_size = glGetUniformLocation(prewarp_program, "image_size");
}
void Prewarp::exec(GLuint tex0_view, GLuint tex1_view, GLuint flow_tex, GLuint I_tex, GLuint I_t_tex, GLuint normalized_flow_tex, int level_width, int level_height)
bind_sampler(prewarp_program, uniform_image1_tex, 1, tex1_view, linear_sampler);
bind_sampler(prewarp_program, uniform_flow_tex, 2, flow_tex, nearest_sampler);
- glProgramUniform2f(prewarp_program, uniform_image_size, level_width, level_height);
-
glViewport(0, 0, level_width, level_height);
glDisable(GL_BLEND);
- glBindVertexArray(prewarp_vao);
fbos.render_to(I_tex, I_t_tex, normalized_flow_tex);
glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
}
GLuint derivatives_vs_obj;
GLuint derivatives_fs_obj;
GLuint derivatives_program;
- GLuint derivatives_vao;
GLuint uniform_tex;
};
derivatives_fs_obj = compile_shader(read_file("derivatives.frag"), GL_FRAGMENT_SHADER);
derivatives_program = link_program(derivatives_vs_obj, derivatives_fs_obj);
- // Set up the VAO containing all the required position/texcoord data.
- glCreateVertexArrays(1, &derivatives_vao);
- glBindVertexArray(derivatives_vao);
- glBindBuffer(GL_ARRAY_BUFFER, vertex_vbo);
-
- GLint position_attrib = glGetAttribLocation(derivatives_program, "position");
- glEnableVertexArrayAttrib(derivatives_vao, position_attrib);
- glVertexAttribPointer(position_attrib, 2, GL_FLOAT, GL_FALSE, 0, BUFFER_OFFSET(0));
-
uniform_tex = glGetUniformLocation(derivatives_program, "tex");
}
glViewport(0, 0, level_width, level_height);
glDisable(GL_BLEND);
- glBindVertexArray(derivatives_vao);
fbos.render_to(I_x_y_tex, beta_0_tex);
glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
}
-// Calculate the smoothness constraints between neighboring pixels;
-// s_x(x,y) stores smoothness between pixel (x,y) and (x+1,y),
-// and s_y(x,y) stores between (x,y) and (x,y+1). We'll sample with
-// border color (0,0) later, so that there's zero diffusion out of
-// the border.
+// Calculate the diffusivity for each pixels, g(x,y). Smoothness (s) will
+// be calculated in the shaders on-the-fly by sampling in-between two
+// neighboring g(x,y) pixels, plus a border tweak to make sure we get
+// zero smoothness at the border.
//
// See variational_refinement.txt for more information.
-class ComputeSmoothness {
+class ComputeDiffusivity {
public:
- ComputeSmoothness();
- void exec(GLuint flow_tex, GLuint diff_flow_tex, GLuint smoothness_x_tex, GLuint smoothness_y_tex, int level_width, int level_height);
+ ComputeDiffusivity();
+ void exec(GLuint flow_tex, GLuint diff_flow_tex, GLuint diffusivity_tex, int level_width, int level_height, bool zero_diff_flow);
private:
- PersistentFBOSet<2> fbos;
+ PersistentFBOSet<1> fbos;
- GLuint smoothness_vs_obj;
- GLuint smoothness_fs_obj;
- GLuint smoothness_program;
- GLuint smoothness_vao;
+ GLuint diffusivity_vs_obj;
+ GLuint diffusivity_fs_obj;
+ GLuint diffusivity_program;
GLuint uniform_flow_tex, uniform_diff_flow_tex;
- GLuint uniform_alpha;
+ GLuint uniform_alpha, uniform_zero_diff_flow;
};
-ComputeSmoothness::ComputeSmoothness()
+ComputeDiffusivity::ComputeDiffusivity()
{
- smoothness_vs_obj = compile_shader(read_file("vs.vert"), GL_VERTEX_SHADER);
- smoothness_fs_obj = compile_shader(read_file("smoothness.frag"), GL_FRAGMENT_SHADER);
- smoothness_program = link_program(smoothness_vs_obj, smoothness_fs_obj);
-
- // Set up the VAO containing all the required position/texcoord data.
- glCreateVertexArrays(1, &smoothness_vao);
- glBindVertexArray(smoothness_vao);
- glBindBuffer(GL_ARRAY_BUFFER, vertex_vbo);
-
- GLint position_attrib = glGetAttribLocation(smoothness_program, "position");
- glEnableVertexArrayAttrib(smoothness_vao, position_attrib);
- glVertexAttribPointer(position_attrib, 2, GL_FLOAT, GL_FALSE, 0, BUFFER_OFFSET(0));
-
- uniform_flow_tex = glGetUniformLocation(smoothness_program, "flow_tex");
- uniform_diff_flow_tex = glGetUniformLocation(smoothness_program, "diff_flow_tex");
- uniform_alpha = glGetUniformLocation(smoothness_program, "alpha");
+ diffusivity_vs_obj = compile_shader(read_file("vs.vert"), GL_VERTEX_SHADER);
+ diffusivity_fs_obj = compile_shader(read_file("diffusivity.frag"), GL_FRAGMENT_SHADER);
+ diffusivity_program = link_program(diffusivity_vs_obj, diffusivity_fs_obj);
+
+ uniform_flow_tex = glGetUniformLocation(diffusivity_program, "flow_tex");
+ uniform_diff_flow_tex = glGetUniformLocation(diffusivity_program, "diff_flow_tex");
+ uniform_alpha = glGetUniformLocation(diffusivity_program, "alpha");
+ uniform_zero_diff_flow = glGetUniformLocation(diffusivity_program, "zero_diff_flow");
}
-void ComputeSmoothness::exec(GLuint flow_tex, GLuint diff_flow_tex, GLuint smoothness_x_tex, GLuint smoothness_y_tex, int level_width, int level_height)
+void ComputeDiffusivity::exec(GLuint flow_tex, GLuint diff_flow_tex, GLuint diffusivity_tex, int level_width, int level_height, bool zero_diff_flow)
{
- glUseProgram(smoothness_program);
+ glUseProgram(diffusivity_program);
- bind_sampler(smoothness_program, uniform_flow_tex, 0, flow_tex, nearest_sampler);
- bind_sampler(smoothness_program, uniform_diff_flow_tex, 1, diff_flow_tex, nearest_sampler);
- glProgramUniform1f(smoothness_program, uniform_alpha, vr_alpha);
+ bind_sampler(diffusivity_program, uniform_flow_tex, 0, flow_tex, nearest_sampler);
+ bind_sampler(diffusivity_program, uniform_diff_flow_tex, 1, diff_flow_tex, nearest_sampler);
+ glProgramUniform1f(diffusivity_program, uniform_alpha, vr_alpha);
+ glProgramUniform1i(diffusivity_program, uniform_zero_diff_flow, zero_diff_flow);
glViewport(0, 0, level_width, level_height);
glDisable(GL_BLEND);
- glBindVertexArray(smoothness_vao);
- fbos.render_to(smoothness_x_tex, smoothness_y_tex);
+ fbos.render_to(diffusivity_tex);
glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
-
- // Make sure the smoothness on the right and upper borders is zero.
- // We could have done this by making (W-1)xH and Wx(H-1) textures instead
- // (we're sampling smoothness with all-zero border color), but we'd
- // have to adjust the sampling coordinates, which is annoying.
- glClearTexSubImage(smoothness_x_tex, 0, level_width - 1, 0, 0, 1, level_height, 1, GL_RED, GL_FLOAT, nullptr);
- glClearTexSubImage(smoothness_y_tex, 0, 0, level_height - 1, 0, level_width, 1, 1, GL_RED, GL_FLOAT, nullptr);
}
// Set up the equations set (two equations in two unknowns, per pixel).
// All the values of the energy term (E_I, E_G, E_S), except the smoothness
// terms that depend on other pixels, are calculated in one pass.
//
-// See variational_refinement.txt for more information.
+// The equation set is split in two; one contains only the pixels needed for
+// the red pass, and one only for the black pass (see sor.frag). This reduces
+// the amount of data the SOR shader has to pull in, at the cost of some
+// complexity when the equation texture ends up with half the size and we need
+// to adjust texture coordinates. The contraction is done along the horizontal
+// axis, so that on even rows (0, 2, 4, ...), the “red” texture will contain
+// pixels 0, 2, 4, 6, etc., and on odd rows 1, 3, 5, etc..
+//
+// See variational_refinement.txt for more information about the actual
+// equations in use.
class SetupEquations {
public:
SetupEquations();
- void exec(GLuint I_x_y_tex, GLuint I_t_tex, GLuint diff_flow_tex, GLuint flow_tex, GLuint beta_0_tex, GLuint smoothness_x_tex, GLuint smoothness_y_tex, GLuint equation_tex, int level_width, int level_height);
+ void exec(GLuint I_x_y_tex, GLuint I_t_tex, GLuint diff_flow_tex, GLuint flow_tex, GLuint beta_0_tex, GLuint diffusivity_tex, GLuint equation_red_tex, GLuint equation_black_tex, int level_width, int level_height, bool zero_diff_flow);
private:
- PersistentFBOSet<1> fbos;
+ PersistentFBOSet<2> fbos;
GLuint equations_vs_obj;
GLuint equations_fs_obj;
GLuint equations_program;
- GLuint equations_vao;
GLuint uniform_I_x_y_tex, uniform_I_t_tex;
GLuint uniform_diff_flow_tex, uniform_base_flow_tex;
GLuint uniform_beta_0_tex;
- GLuint uniform_smoothness_x_tex, uniform_smoothness_y_tex;
- GLuint uniform_gamma, uniform_delta;
+ GLuint uniform_diffusivity_tex;
+ GLuint uniform_gamma, uniform_delta, uniform_zero_diff_flow;
};
SetupEquations::SetupEquations()
{
- equations_vs_obj = compile_shader(read_file("vs.vert"), GL_VERTEX_SHADER);
+ equations_vs_obj = compile_shader(read_file("equations.vert"), GL_VERTEX_SHADER);
equations_fs_obj = compile_shader(read_file("equations.frag"), GL_FRAGMENT_SHADER);
equations_program = link_program(equations_vs_obj, equations_fs_obj);
- // Set up the VAO containing all the required position/texcoord data.
- glCreateVertexArrays(1, &equations_vao);
- glBindVertexArray(equations_vao);
- glBindBuffer(GL_ARRAY_BUFFER, vertex_vbo);
-
- GLint position_attrib = glGetAttribLocation(equations_program, "position");
- glEnableVertexArrayAttrib(equations_vao, position_attrib);
- glVertexAttribPointer(position_attrib, 2, GL_FLOAT, GL_FALSE, 0, BUFFER_OFFSET(0));
-
uniform_I_x_y_tex = glGetUniformLocation(equations_program, "I_x_y_tex");
uniform_I_t_tex = glGetUniformLocation(equations_program, "I_t_tex");
uniform_diff_flow_tex = glGetUniformLocation(equations_program, "diff_flow_tex");
uniform_base_flow_tex = glGetUniformLocation(equations_program, "base_flow_tex");
uniform_beta_0_tex = glGetUniformLocation(equations_program, "beta_0_tex");
- uniform_smoothness_x_tex = glGetUniformLocation(equations_program, "smoothness_x_tex");
- uniform_smoothness_y_tex = glGetUniformLocation(equations_program, "smoothness_y_tex");
+ uniform_diffusivity_tex = glGetUniformLocation(equations_program, "diffusivity_tex");
uniform_gamma = glGetUniformLocation(equations_program, "gamma");
uniform_delta = glGetUniformLocation(equations_program, "delta");
+ uniform_zero_diff_flow = glGetUniformLocation(equations_program, "zero_diff_flow");
}
-void SetupEquations::exec(GLuint I_x_y_tex, GLuint I_t_tex, GLuint diff_flow_tex, GLuint base_flow_tex, GLuint beta_0_tex, GLuint smoothness_x_tex, GLuint smoothness_y_tex, GLuint equation_tex, int level_width, int level_height)
+void SetupEquations::exec(GLuint I_x_y_tex, GLuint I_t_tex, GLuint diff_flow_tex, GLuint base_flow_tex, GLuint beta_0_tex, GLuint diffusivity_tex, GLuint equation_red_tex, GLuint equation_black_tex, int level_width, int level_height, bool zero_diff_flow)
{
glUseProgram(equations_program);
bind_sampler(equations_program, uniform_diff_flow_tex, 2, diff_flow_tex, nearest_sampler);
bind_sampler(equations_program, uniform_base_flow_tex, 3, base_flow_tex, nearest_sampler);
bind_sampler(equations_program, uniform_beta_0_tex, 4, beta_0_tex, nearest_sampler);
- bind_sampler(equations_program, uniform_smoothness_x_tex, 5, smoothness_x_tex, smoothness_sampler);
- bind_sampler(equations_program, uniform_smoothness_y_tex, 6, smoothness_y_tex, smoothness_sampler);
+ bind_sampler(equations_program, uniform_diffusivity_tex, 5, diffusivity_tex, zero_border_sampler);
glProgramUniform1f(equations_program, uniform_delta, vr_delta);
glProgramUniform1f(equations_program, uniform_gamma, vr_gamma);
+ glProgramUniform1i(equations_program, uniform_zero_diff_flow, zero_diff_flow);
- glViewport(0, 0, level_width, level_height);
+ glViewport(0, 0, (level_width + 1) / 2, level_height);
glDisable(GL_BLEND);
- glBindVertexArray(equations_vao);
- fbos.render_to(equation_tex);
+ fbos.render_to({equation_red_tex, equation_black_tex});
glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
}
class SOR {
public:
SOR();
- void exec(GLuint diff_flow_tex, GLuint equation_tex, GLuint smoothness_x_tex, GLuint smoothness_y_tex, int level_width, int level_height, int num_iterations);
+ void exec(GLuint diff_flow_tex, GLuint equation_red_tex, GLuint equation_black_tex, GLuint diffusivity_tex, int level_width, int level_height, int num_iterations, bool zero_diff_flow, ScopedTimer *sor_timer);
private:
PersistentFBOSet<1> fbos;
GLuint sor_vs_obj;
GLuint sor_fs_obj;
GLuint sor_program;
- GLuint sor_vao;
GLuint uniform_diff_flow_tex;
- GLuint uniform_equation_tex;
- GLuint uniform_smoothness_x_tex, uniform_smoothness_y_tex;
+ GLuint uniform_equation_red_tex, uniform_equation_black_tex;
+ GLuint uniform_diffusivity_tex;
+ GLuint uniform_phase, uniform_num_nonzero_phases;
};
SOR::SOR()
{
- sor_vs_obj = compile_shader(read_file("vs.vert"), GL_VERTEX_SHADER);
+ sor_vs_obj = compile_shader(read_file("sor.vert"), GL_VERTEX_SHADER);
sor_fs_obj = compile_shader(read_file("sor.frag"), GL_FRAGMENT_SHADER);
sor_program = link_program(sor_vs_obj, sor_fs_obj);
- // Set up the VAO containing all the required position/texcoord data.
- glCreateVertexArrays(1, &sor_vao);
- glBindVertexArray(sor_vao);
- glBindBuffer(GL_ARRAY_BUFFER, vertex_vbo);
-
- GLint position_attrib = glGetAttribLocation(sor_program, "position");
- glEnableVertexArrayAttrib(sor_vao, position_attrib);
- glVertexAttribPointer(position_attrib, 2, GL_FLOAT, GL_FALSE, 0, BUFFER_OFFSET(0));
-
uniform_diff_flow_tex = glGetUniformLocation(sor_program, "diff_flow_tex");
- uniform_equation_tex = glGetUniformLocation(sor_program, "equation_tex");
- uniform_smoothness_x_tex = glGetUniformLocation(sor_program, "smoothness_x_tex");
- uniform_smoothness_y_tex = glGetUniformLocation(sor_program, "smoothness_y_tex");
+ uniform_equation_red_tex = glGetUniformLocation(sor_program, "equation_red_tex");
+ uniform_equation_black_tex = glGetUniformLocation(sor_program, "equation_black_tex");
+ uniform_diffusivity_tex = glGetUniformLocation(sor_program, "diffusivity_tex");
+ uniform_phase = glGetUniformLocation(sor_program, "phase");
+ uniform_num_nonzero_phases = glGetUniformLocation(sor_program, "num_nonzero_phases");
}
-void SOR::exec(GLuint diff_flow_tex, GLuint equation_tex, GLuint smoothness_x_tex, GLuint smoothness_y_tex, int level_width, int level_height, int num_iterations)
+void SOR::exec(GLuint diff_flow_tex, GLuint equation_red_tex, GLuint equation_black_tex, GLuint diffusivity_tex, int level_width, int level_height, int num_iterations, bool zero_diff_flow, ScopedTimer *sor_timer)
{
glUseProgram(sor_program);
bind_sampler(sor_program, uniform_diff_flow_tex, 0, diff_flow_tex, nearest_sampler);
- bind_sampler(sor_program, uniform_smoothness_x_tex, 1, smoothness_x_tex, smoothness_sampler);
- bind_sampler(sor_program, uniform_smoothness_y_tex, 2, smoothness_y_tex, smoothness_sampler);
- bind_sampler(sor_program, uniform_equation_tex, 3, equation_tex, nearest_sampler);
+ bind_sampler(sor_program, uniform_diffusivity_tex, 1, diffusivity_tex, zero_border_sampler);
+ bind_sampler(sor_program, uniform_equation_red_tex, 2, equation_red_tex, nearest_sampler);
+ bind_sampler(sor_program, uniform_equation_black_tex, 3, equation_black_tex, nearest_sampler);
+ if (!zero_diff_flow) {
+ glProgramUniform1i(sor_program, uniform_num_nonzero_phases, 2);
+ }
+
+ // NOTE: We bind to the texture we are rendering from, but we never write any value
+ // that we read in the same shader pass (we call discard for red values when we compute
+ // black, and vice versa), and we have barriers between the passes, so we're fine
+ // as per the spec.
glViewport(0, 0, level_width, level_height);
glDisable(GL_BLEND);
- glBindVertexArray(sor_vao);
- fbos.render_to(diff_flow_tex); // NOTE: Bind to same as we render from!
+ fbos.render_to(diff_flow_tex);
for (int i = 0; i < num_iterations; ++i) {
- glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
- if (i != num_iterations - 1) {
+ {
+ ScopedTimer timer("Red pass", sor_timer);
+ if (zero_diff_flow && i == 0) {
+ glProgramUniform1i(sor_program, uniform_num_nonzero_phases, 0);
+ }
+ glProgramUniform1i(sor_program, uniform_phase, 0);
+ glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
glTextureBarrier();
}
+ {
+ ScopedTimer timer("Black pass", sor_timer);
+ if (zero_diff_flow && i == 0) {
+ glProgramUniform1i(sor_program, uniform_num_nonzero_phases, 1);
+ }
+ glProgramUniform1i(sor_program, uniform_phase, 1);
+ glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
+ if (zero_diff_flow && i == 0) {
+ glProgramUniform1i(sor_program, uniform_num_nonzero_phases, 2);
+ }
+ if (i != num_iterations - 1) {
+ glTextureBarrier();
+ }
+ }
}
}
GLuint add_flow_vs_obj;
GLuint add_flow_fs_obj;
GLuint add_flow_program;
- GLuint add_flow_vao;
GLuint uniform_diff_flow_tex;
};
add_flow_fs_obj = compile_shader(read_file("add_base_flow.frag"), GL_FRAGMENT_SHADER);
add_flow_program = link_program(add_flow_vs_obj, add_flow_fs_obj);
- // Set up the VAO containing all the required position/texcoord data.
- glCreateVertexArrays(1, &add_flow_vao);
- glBindVertexArray(add_flow_vao);
- glBindBuffer(GL_ARRAY_BUFFER, vertex_vbo);
-
- GLint position_attrib = glGetAttribLocation(add_flow_program, "position");
- glEnableVertexArrayAttrib(add_flow_vao, position_attrib);
- glVertexAttribPointer(position_attrib, 2, GL_FLOAT, GL_FALSE, 0, BUFFER_OFFSET(0));
-
uniform_diff_flow_tex = glGetUniformLocation(add_flow_program, "diff_flow_tex");
}
glViewport(0, 0, level_width, level_height);
glEnable(GL_BLEND);
glBlendFunc(GL_ONE, GL_ONE);
- glBindVertexArray(add_flow_vao);
fbos.render_to(base_flow_tex);
glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
GLuint resize_flow_vs_obj;
GLuint resize_flow_fs_obj;
GLuint resize_flow_program;
- GLuint resize_flow_vao;
GLuint uniform_flow_tex;
GLuint uniform_scale_factor;
resize_flow_fs_obj = compile_shader(read_file("resize_flow.frag"), GL_FRAGMENT_SHADER);
resize_flow_program = link_program(resize_flow_vs_obj, resize_flow_fs_obj);
- // Set up the VAO containing all the required position/texcoord data.
- glCreateVertexArrays(1, &resize_flow_vao);
- glBindVertexArray(resize_flow_vao);
- glBindBuffer(GL_ARRAY_BUFFER, vertex_vbo);
-
- GLint position_attrib = glGetAttribLocation(resize_flow_program, "position");
- glEnableVertexArrayAttrib(resize_flow_vao, position_attrib);
- glVertexAttribPointer(position_attrib, 2, GL_FLOAT, GL_FALSE, 0, BUFFER_OFFSET(0));
-
uniform_flow_tex = glGetUniformLocation(resize_flow_program, "flow_tex");
uniform_scale_factor = glGetUniformLocation(resize_flow_program, "scale_factor");
}
glViewport(0, 0, output_width, output_height);
glDisable(GL_BLEND);
- glBindVertexArray(resize_flow_vao);
fbos.render_to(out_tex);
glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
}
-class GPUTimers {
+class TexturePool {
public:
- void print();
- pair<GLuint, GLuint> begin_timer(const string &name, int level);
+ GLuint get_texture(GLenum format, GLuint width, GLuint height);
+ void release_texture(GLuint tex_num);
+ GLuint get_renderbuffer(GLenum format, GLuint width, GLuint height);
+ void release_renderbuffer(GLuint tex_num);
private:
- struct Timer {
- string name;
- int level;
- pair<GLuint, GLuint> query;
+ struct Texture {
+ GLuint tex_num;
+ GLenum format;
+ GLuint width, height;
+ bool in_use = false;
+ bool is_renderbuffer = false;
};
- vector<Timer> timers;
-};
-
-pair<GLuint, GLuint> GPUTimers::begin_timer(const string &name, int level)
-{
- if (!enable_timing) {
- return make_pair(0, 0);
- }
-
- GLuint queries[2];
- glGenQueries(2, queries);
- glQueryCounter(queries[0], GL_TIMESTAMP);
-
- Timer timer;
- timer.name = name;
- timer.level = level;
- timer.query.first = queries[0];
- timer.query.second = queries[1];
- timers.push_back(timer);
- return timer.query;
-}
-
-void GPUTimers::print()
-{
- for (const Timer &timer : timers) {
- // NOTE: This makes the CPU wait for the GPU.
- GLuint64 time_start, time_end;
- glGetQueryObjectui64v(timer.query.first, GL_QUERY_RESULT, &time_start);
- glGetQueryObjectui64v(timer.query.second, GL_QUERY_RESULT, &time_end);
- //fprintf(stderr, "GPU time used = %.1f ms\n", time_elapsed / 1e6);
- for (int i = 0; i < timer.level * 2; ++i) {
- fprintf(stderr, " ");
- }
- fprintf(stderr, "%-30s %4.1f ms\n", timer.name.c_str(), GLint64(time_end - time_start) / 1e6);
- }
-}
-
-// A simple RAII class for timing until the end of the scope.
-class ScopedTimer {
-public:
- ScopedTimer(const string &name, GPUTimers *timers)
- : timers(timers), level(0)
- {
- query = timers->begin_timer(name, level);
- }
-
- ScopedTimer(const string &name, ScopedTimer *parent_timer)
- : timers(parent_timer->timers),
- level(parent_timer->level + 1)
- {
- query = timers->begin_timer(name, level);
- }
-
- ~ScopedTimer()
- {
- end();
- }
-
- void end()
- {
- if (enable_timing && !ended) {
- glQueryCounter(query.second, GL_TIMESTAMP);
- ended = true;
- }
- }
-
-private:
- GPUTimers *timers;
- int level;
- pair<GLuint, GLuint> query;
- bool ended = false;
+ vector<Texture> textures;
};
class DISComputeFlow {
public:
DISComputeFlow(int width, int height);
+ enum ResizeStrategy {
+ DO_NOT_RESIZE_FLOW,
+ RESIZE_FLOW_TO_FULL_SIZE
+ };
+
// Returns a texture that must be released with release_texture()
// after use.
- GLuint exec(GLuint tex0, GLuint tex1);
- void release_texture(GLuint tex);
+ GLuint exec(GLuint tex0, GLuint tex1, ResizeStrategy resize_strategy);
+
+ void release_texture(GLuint tex) {
+ pool.release_texture(tex);
+ }
private:
int width, height;
GLuint initial_flow_tex;
+ GLuint vertex_vbo, vao;
+ TexturePool pool;
// The various passes.
Sobel sobel;
Densify densify;
Prewarp prewarp;
Derivatives derivatives;
- ComputeSmoothness compute_smoothness;
+ ComputeDiffusivity compute_diffusivity;
SetupEquations setup_equations;
SOR sor;
AddBaseFlow add_base_flow;
ResizeFlow resize_flow;
-
- struct Texture {
- GLuint tex_num;
- GLenum format;
- GLuint width, height;
- bool in_use = false;
- };
- vector<Texture> textures;
-
- GLuint get_texture(GLenum format, GLuint width, GLuint height);
};
DISComputeFlow::DISComputeFlow(int width, int height)
// The smoothness is sampled so that once we get to a smoothness involving
// a value outside the border, the diffusivity between the two becomes zero.
- glCreateSamplers(1, &smoothness_sampler);
- glSamplerParameteri(smoothness_sampler, GL_TEXTURE_MIN_FILTER, GL_NEAREST);
- glSamplerParameteri(smoothness_sampler, GL_TEXTURE_MAG_FILTER, GL_NEAREST);
- glSamplerParameteri(smoothness_sampler, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_BORDER);
- glSamplerParameteri(smoothness_sampler, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_BORDER);
- float zero[] = { 0.0f, 0.0f, 0.0f, 0.0f };
- glSamplerParameterfv(smoothness_sampler, GL_TEXTURE_BORDER_COLOR, zero);
+ // Similarly, gradients are zero outside the border, since the edge is taken
+ // to be constant.
+ glCreateSamplers(1, &zero_border_sampler);
+ glSamplerParameteri(zero_border_sampler, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
+ glSamplerParameteri(zero_border_sampler, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
+ glSamplerParameteri(zero_border_sampler, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_BORDER);
+ glSamplerParameteri(zero_border_sampler, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_BORDER);
+ float zero[] = { 0.0f, 0.0f, 0.0f, 0.0f }; // Note that zero alpha means we can also see whether we sampled outside the border or not.
+ glSamplerParameterfv(zero_border_sampler, GL_TEXTURE_BORDER_COLOR, zero);
// Initial flow is zero, 1x1.
glCreateTextures(GL_TEXTURE_2D, 1, &initial_flow_tex);
glTextureStorage2D(initial_flow_tex, 1, GL_RG16F, 1, 1);
glClearTexImage(initial_flow_tex, 0, GL_RG, GL_FLOAT, nullptr);
+
+ // Set up the vertex data that will be shared between all passes.
+ float vertices[] = {
+ 0.0f, 1.0f,
+ 0.0f, 0.0f,
+ 1.0f, 1.0f,
+ 1.0f, 0.0f,
+ };
+ glCreateBuffers(1, &vertex_vbo);
+ glNamedBufferData(vertex_vbo, sizeof(vertices), vertices, GL_STATIC_DRAW);
+
+ glCreateVertexArrays(1, &vao);
+ glBindVertexArray(vao);
+ glBindBuffer(GL_ARRAY_BUFFER, vertex_vbo);
+
+ GLint position_attrib = 0; // Hard-coded in every vertex shader.
+ glEnableVertexArrayAttrib(vao, position_attrib);
+ glVertexAttribPointer(position_attrib, 2, GL_FLOAT, GL_FALSE, 0, BUFFER_OFFSET(0));
}
-GLuint DISComputeFlow::exec(GLuint tex0, GLuint tex1)
+GLuint DISComputeFlow::exec(GLuint tex0, GLuint tex1, ResizeStrategy resize_strategy)
{
- for (const Texture &tex : textures) {
- assert(!tex.in_use);
- }
-
int prev_level_width = 1, prev_level_height = 1;
GLuint prev_level_flow_tex = initial_flow_tex;
GPUTimers timers;
- ScopedTimer total_timer("Total", &timers);
+ glBindVertexArray(vao);
+
+ ScopedTimer total_timer("Compute flow", &timers);
for (int level = coarsest_level; level >= int(finest_level); --level) {
char timer_name[256];
- snprintf(timer_name, sizeof(timer_name), "Level %d", level);
+ snprintf(timer_name, sizeof(timer_name), "Level %d (%d x %d)", level, width >> level, height >> level);
ScopedTimer level_timer(timer_name, &total_timer);
int level_width = width >> level;
int level_height = height >> level;
float patch_spacing_pixels = patch_size_pixels * (1.0f - patch_overlap_ratio);
- int width_patches = 1 + lrintf((level_width - patch_size_pixels) / patch_spacing_pixels);
- int height_patches = 1 + lrintf((level_height - patch_size_pixels) / patch_spacing_pixels);
+
+ // Make sure we have patches at least every Nth pixel, e.g. for width=9
+ // and patch_spacing=3 (the default), we put out patch centers in
+ // x=0, x=3, x=6, x=9, which is four patches. The fragment shader will
+ // lock all the centers to integer coordinates if needed.
+ int width_patches = 1 + ceil(level_width / patch_spacing_pixels);
+ int height_patches = 1 + ceil(level_height / patch_spacing_pixels);
// Make sure we always read from the correct level; the chosen
// mipmapping could otherwise be rather unpredictable, especially
// during motion search.
- // TODO: create these beforehand, and stop leaking them.
GLuint tex0_view, tex1_view;
glGenTextures(1, &tex0_view);
glTextureView(tex0_view, GL_TEXTURE_2D, tex0, GL_R8, level, 1, 0, 1);
// Create a new texture; we could be fancy and render use a multi-level
// texture, but meh.
- GLuint grad0_tex = get_texture(GL_RG16F, level_width, level_height);
+ GLuint grad0_tex = pool.get_texture(GL_R32UI, level_width, level_height);
// Find the derivative.
{
// level (sampled bilinearly; no fancy tricks) as a guide, then search from there.
// Create an output flow texture.
- GLuint flow_out_tex = get_texture(GL_RGB16F, width_patches, height_patches);
+ GLuint flow_out_tex = pool.get_texture(GL_RGB16F, width_patches, height_patches);
// And draw.
{
ScopedTimer timer("Motion search", &level_timer);
motion_search.exec(tex0_view, tex1_view, grad0_tex, prev_level_flow_tex, flow_out_tex, level_width, level_height, prev_level_width, prev_level_height, width_patches, height_patches);
}
- release_texture(grad0_tex);
+ pool.release_texture(grad0_tex);
// Densification.
- // Set up an output texture (initially zero).
- GLuint dense_flow_tex = get_texture(GL_RGB16F, level_width, level_height);
- glClearTexImage(dense_flow_tex, 0, GL_RGB, GL_FLOAT, nullptr);
+ // Set up an output texture (cleared in Densify).
+ GLuint dense_flow_tex = pool.get_texture(GL_RGB16F, level_width, level_height);
// And draw.
{
ScopedTimer timer("Densification", &level_timer);
densify.exec(tex0_view, tex1_view, flow_out_tex, dense_flow_tex, level_width, level_height, width_patches, height_patches);
}
- release_texture(flow_out_tex);
+ pool.release_texture(flow_out_tex);
// Everything below here in the loop belongs to variational refinement.
ScopedTimer varref_timer("Variational refinement", &level_timer);
// in pixels, not 0..1 normalized OpenGL texture coordinates.
// This is because variational refinement depends so heavily on derivatives,
// which are measured in intensity levels per pixel.
- GLuint I_tex = get_texture(GL_R16F, level_width, level_height);
- GLuint I_t_tex = get_texture(GL_R16F, level_width, level_height);
- GLuint base_flow_tex = get_texture(GL_RG16F, level_width, level_height);
+ GLuint I_tex = pool.get_texture(GL_R16F, level_width, level_height);
+ GLuint I_t_tex = pool.get_texture(GL_R16F, level_width, level_height);
+ GLuint base_flow_tex = pool.get_texture(GL_RG16F, level_width, level_height);
{
ScopedTimer timer("Prewarping", &varref_timer);
prewarp.exec(tex0_view, tex1_view, dense_flow_tex, I_tex, I_t_tex, base_flow_tex, level_width, level_height);
}
- release_texture(dense_flow_tex);
+ pool.release_texture(dense_flow_tex);
+ glDeleteTextures(1, &tex0_view);
+ glDeleteTextures(1, &tex1_view);
// Calculate I_x and I_y. We're only calculating first derivatives;
// the others will be taken on-the-fly in order to sample from fewer
// textures overall, since sampling from the L1 cache is cheap.
// (TODO: Verify that this is indeed faster than making separate
// double-derivative textures.)
- GLuint I_x_y_tex = get_texture(GL_RG16F, level_width, level_height);
- GLuint beta_0_tex = get_texture(GL_R16F, level_width, level_height);
+ GLuint I_x_y_tex = pool.get_texture(GL_RG16F, level_width, level_height);
+ GLuint beta_0_tex = pool.get_texture(GL_R16F, level_width, level_height);
{
ScopedTimer timer("First derivatives", &varref_timer);
derivatives.exec(I_tex, I_x_y_tex, beta_0_tex, level_width, level_height);
}
- release_texture(I_tex);
+ pool.release_texture(I_tex);
// We need somewhere to store du and dv (the flow increment, relative
- // to the non-refined base flow u0 and v0). It starts at zero.
- GLuint du_dv_tex = get_texture(GL_RG16F, level_width, level_height);
- glClearTexImage(du_dv_tex, 0, GL_RG, GL_FLOAT, nullptr);
+ // to the non-refined base flow u0 and v0). It's initially garbage,
+ // but not read until we've written something sane to it.
+ GLuint diff_flow_tex = pool.get_texture(GL_RG16F, level_width, level_height);
- // And for smoothness.
- GLuint smoothness_x_tex = get_texture(GL_R16F, level_width, level_height);
- GLuint smoothness_y_tex = get_texture(GL_R16F, level_width, level_height);
+ // And for diffusivity.
+ GLuint diffusivity_tex = pool.get_texture(GL_R16F, level_width, level_height);
// And finally for the equation set. See SetupEquations for
// the storage format.
- GLuint equation_tex = get_texture(GL_RGBA32UI, level_width, level_height);
+ GLuint equation_red_tex = pool.get_texture(GL_RGBA32UI, (level_width + 1) / 2, level_height);
+ GLuint equation_black_tex = pool.get_texture(GL_RGBA32UI, (level_width + 1) / 2, level_height);
for (int outer_idx = 0; outer_idx < level + 1; ++outer_idx) {
- // Calculate the smoothness terms between the neighboring pixels,
- // both in x and y direction.
+ // Calculate the diffusivity term for each pixel.
{
- ScopedTimer timer("Compute smoothness", &varref_timer);
- compute_smoothness.exec(base_flow_tex, du_dv_tex, smoothness_x_tex, smoothness_y_tex, level_width, level_height);
+ ScopedTimer timer("Compute diffusivity", &varref_timer);
+ compute_diffusivity.exec(base_flow_tex, diff_flow_tex, diffusivity_tex, level_width, level_height, outer_idx == 0);
}
// Set up the 2x2 equation system for each pixel.
{
ScopedTimer timer("Set up equations", &varref_timer);
- setup_equations.exec(I_x_y_tex, I_t_tex, du_dv_tex, base_flow_tex, beta_0_tex, smoothness_x_tex, smoothness_y_tex, equation_tex, level_width, level_height);
+ setup_equations.exec(I_x_y_tex, I_t_tex, diff_flow_tex, base_flow_tex, beta_0_tex, diffusivity_tex, equation_red_tex, equation_black_tex, level_width, level_height, outer_idx == 0);
}
- // Run a few SOR (or quasi-SOR, since we're not really Jacobi) iterations.
- // Note that these are to/from the same texture.
+ // Run a few SOR iterations. Note that these are to/from the same texture.
{
ScopedTimer timer("SOR", &varref_timer);
- sor.exec(du_dv_tex, equation_tex, smoothness_x_tex, smoothness_y_tex, level_width, level_height, 5);
+ sor.exec(diff_flow_tex, equation_red_tex, equation_black_tex, diffusivity_tex, level_width, level_height, 5, outer_idx == 0, &timer);
}
}
- release_texture(I_t_tex);
- release_texture(I_x_y_tex);
- release_texture(beta_0_tex);
- release_texture(smoothness_x_tex);
- release_texture(smoothness_y_tex);
- release_texture(equation_tex);
+ pool.release_texture(I_t_tex);
+ pool.release_texture(I_x_y_tex);
+ pool.release_texture(beta_0_tex);
+ pool.release_texture(diffusivity_tex);
+ pool.release_texture(equation_red_tex);
+ pool.release_texture(equation_black_tex);
// Add the differential flow found by the variational refinement to the base flow,
// giving the final flow estimate for this level.
// it is more efficient), but it helps debug the motion search.
if (enable_variational_refinement) {
ScopedTimer timer("Add differential flow", &varref_timer);
- add_base_flow.exec(base_flow_tex, du_dv_tex, level_width, level_height);
+ add_base_flow.exec(base_flow_tex, diff_flow_tex, level_width, level_height);
}
- release_texture(du_dv_tex);
+ pool.release_texture(diff_flow_tex);
if (prev_level_flow_tex != initial_flow_tex) {
- release_texture(prev_level_flow_tex);
+ pool.release_texture(prev_level_flow_tex);
}
prev_level_flow_tex = base_flow_tex;
prev_level_width = level_width;
}
total_timer.end();
- timers.print();
+ if (!in_warmup) {
+ timers.print();
+ }
// Scale up the flow to the final size (if needed).
- if (finest_level == 0) {
+ if (finest_level == 0 || resize_strategy == DO_NOT_RESIZE_FLOW) {
return prev_level_flow_tex;
} else {
- GLuint final_tex = get_texture(GL_RG16F, width, height);
+ GLuint final_tex = pool.get_texture(GL_RG16F, width, height);
resize_flow.exec(prev_level_flow_tex, final_tex, prev_level_width, prev_level_height, width, height);
- release_texture(prev_level_flow_tex);
+ pool.release_texture(prev_level_flow_tex);
return final_tex;
}
}
-GLuint DISComputeFlow::get_texture(GLenum format, GLuint width, GLuint height)
-{
- for (Texture &tex : textures) {
- if (!tex.in_use && tex.format == format &&
- tex.width == width && tex.height == height) {
- tex.in_use = true;
- return tex.tex_num;
- }
- }
+// Forward-warp the flow half-way (or rather, by alpha). A non-zero “splatting”
+// radius fills most of the holes.
+class Splat {
+public:
+ Splat();
- Texture tex;
- glCreateTextures(GL_TEXTURE_2D, 1, &tex.tex_num);
- glTextureStorage2D(tex.tex_num, 1, format, width, height);
- tex.format = format;
- tex.width = width;
- tex.height = height;
- tex.in_use = true;
- textures.push_back(tex);
- return tex.tex_num;
+ // alpha is the time of the interpolated frame (0..1).
+ void exec(GLuint tex0, GLuint tex1, GLuint forward_flow_tex, GLuint backward_flow_tex, GLuint flow_tex, GLuint depth_rb, int width, int height, float alpha);
+
+private:
+ PersistentFBOSetWithDepth<1> fbos;
+
+ GLuint splat_vs_obj;
+ GLuint splat_fs_obj;
+ GLuint splat_program;
+
+ GLuint uniform_invert_flow, uniform_splat_size, uniform_alpha;
+ GLuint uniform_image0_tex, uniform_image1_tex, uniform_flow_tex;
+ GLuint uniform_inv_flow_size;
+};
+
+Splat::Splat()
+{
+ splat_vs_obj = compile_shader(read_file("splat.vert"), GL_VERTEX_SHADER);
+ splat_fs_obj = compile_shader(read_file("splat.frag"), GL_FRAGMENT_SHADER);
+ splat_program = link_program(splat_vs_obj, splat_fs_obj);
+
+ uniform_invert_flow = glGetUniformLocation(splat_program, "invert_flow");
+ uniform_splat_size = glGetUniformLocation(splat_program, "splat_size");
+ uniform_alpha = glGetUniformLocation(splat_program, "alpha");
+ uniform_image0_tex = glGetUniformLocation(splat_program, "image0_tex");
+ uniform_image1_tex = glGetUniformLocation(splat_program, "image1_tex");
+ uniform_flow_tex = glGetUniformLocation(splat_program, "flow_tex");
+ uniform_inv_flow_size = glGetUniformLocation(splat_program, "inv_flow_size");
}
-void DISComputeFlow::release_texture(GLuint tex_num)
+void Splat::exec(GLuint tex0, GLuint tex1, GLuint forward_flow_tex, GLuint backward_flow_tex, GLuint flow_tex, GLuint depth_rb, int width, int height, float alpha)
+{
+ glUseProgram(splat_program);
+
+ bind_sampler(splat_program, uniform_image0_tex, 0, tex0, linear_sampler);
+ bind_sampler(splat_program, uniform_image1_tex, 1, tex1, linear_sampler);
+
+ // FIXME: This is set to 1.0 right now so not to trigger Haswell's “PMA stall”.
+ // Move to 2.0 later, or even 4.0.
+ // (Since we have hole filling, it's not critical, but larger values seem to do
+ // better than hole filling for large motion, blurs etc.)
+ float splat_size = 1.0f; // 4x4 splat means 16x overdraw, 2x2 splat means 4x overdraw.
+ glProgramUniform2f(splat_program, uniform_splat_size, splat_size / width, splat_size / height);
+ glProgramUniform1f(splat_program, uniform_alpha, alpha);
+ glProgramUniform2f(splat_program, uniform_inv_flow_size, 1.0f / width, 1.0f / height);
+
+ glViewport(0, 0, width, height);
+ glDisable(GL_BLEND);
+ glEnable(GL_DEPTH_TEST);
+ glDepthFunc(GL_LESS); // We store the difference between I_0 and I_1, where less difference is good. (Default 1.0 is effectively +inf, which always loses.)
+
+ fbos.render_to(depth_rb, flow_tex);
+
+ // Evidently NVIDIA doesn't use fast clears for glClearTexImage, so clear now that
+ // we've got it bound.
+ glClearColor(1000.0f, 1000.0f, 0.0f, 1.0f); // Invalid flow.
+ glClearDepth(1.0f); // Effectively infinity.
+ glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);
+
+ // Do forward splatting.
+ bind_sampler(splat_program, uniform_flow_tex, 2, forward_flow_tex, nearest_sampler);
+ glProgramUniform1i(splat_program, uniform_invert_flow, 0);
+ glDrawArraysInstanced(GL_TRIANGLE_STRIP, 0, 4, width * height);
+
+ // Do backward splatting.
+ bind_sampler(splat_program, uniform_flow_tex, 2, backward_flow_tex, nearest_sampler);
+ glProgramUniform1i(splat_program, uniform_invert_flow, 1);
+ glDrawArraysInstanced(GL_TRIANGLE_STRIP, 0, 4, width * height);
+
+ glDisable(GL_DEPTH_TEST);
+}
+
+// Doing good and fast hole-filling on a GPU is nontrivial. We choose an option
+// that's fairly simple (given that most holes are really small) and also hopefully
+// cheap should the holes not be so small. Conceptually, we look for the first
+// non-hole to the left of us (ie., shoot a ray until we hit something), then
+// the first non-hole to the right of us, then up and down, and then average them
+// all together. It's going to create “stars” if the holes are big, but OK, that's
+// a tradeoff.
+//
+// Our implementation here is efficient assuming that the hierarchical Z-buffer is
+// on even for shaders that do discard (this typically kills early Z, but hopefully
+// not hierarchical Z); we set up Z so that only holes are written to, which means
+// that as soon as a hole is filled, the rasterizer should just skip it. Most of the
+// fullscreen quads should just be discarded outright, really.
+class HoleFill {
+public:
+ HoleFill();
+
+ // Output will be in flow_tex, temp_tex[0, 1, 2], representing the filling
+ // from the down, left, right and up, respectively. Use HoleBlend to merge
+ // them into one.
+ void exec(GLuint flow_tex, GLuint depth_rb, GLuint temp_tex[3], int width, int height);
+
+private:
+ PersistentFBOSetWithDepth<1> fbos;
+
+ GLuint fill_vs_obj;
+ GLuint fill_fs_obj;
+ GLuint fill_program;
+
+ GLuint uniform_tex;
+ GLuint uniform_z, uniform_sample_offset;
+};
+
+HoleFill::HoleFill()
+{
+ fill_vs_obj = compile_shader(read_file("hole_fill.vert"), GL_VERTEX_SHADER);
+ fill_fs_obj = compile_shader(read_file("hole_fill.frag"), GL_FRAGMENT_SHADER);
+ fill_program = link_program(fill_vs_obj, fill_fs_obj);
+
+ uniform_tex = glGetUniformLocation(fill_program, "tex");
+ uniform_z = glGetUniformLocation(fill_program, "z");
+ uniform_sample_offset = glGetUniformLocation(fill_program, "sample_offset");
+}
+
+void HoleFill::exec(GLuint flow_tex, GLuint depth_rb, GLuint temp_tex[3], int width, int height)
+{
+ glUseProgram(fill_program);
+
+ bind_sampler(fill_program, uniform_tex, 0, flow_tex, nearest_sampler);
+
+ glProgramUniform1f(fill_program, uniform_z, 1.0f - 1.0f / 1024.0f);
+
+ glViewport(0, 0, width, height);
+ glDisable(GL_BLEND);
+ glEnable(GL_DEPTH_TEST);
+ glDepthFunc(GL_LESS); // Only update the values > 0.999f (ie., only invalid pixels).
+
+ fbos.render_to(depth_rb, flow_tex); // NOTE: Reading and writing to the same texture.
+
+ // Fill holes from the left, by shifting 1, 2, 4, 8, etc. pixels to the right.
+ for (int offs = 1; offs < width; offs *= 2) {
+ glProgramUniform2f(fill_program, uniform_sample_offset, -offs / float(width), 0.0f);
+ glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
+ glTextureBarrier();
+ }
+ glCopyImageSubData(flow_tex, GL_TEXTURE_2D, 0, 0, 0, 0, temp_tex[0], GL_TEXTURE_2D, 0, 0, 0, 0, width, height, 1);
+
+ // Similar to the right; adjust Z a bit down, so that we re-fill the pixels that
+ // were overwritten in the last algorithm.
+ glProgramUniform1f(fill_program, uniform_z, 1.0f - 2.0f / 1024.0f);
+ for (int offs = 1; offs < width; offs *= 2) {
+ glProgramUniform2f(fill_program, uniform_sample_offset, offs / float(width), 0.0f);
+ glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
+ glTextureBarrier();
+ }
+ glCopyImageSubData(flow_tex, GL_TEXTURE_2D, 0, 0, 0, 0, temp_tex[1], GL_TEXTURE_2D, 0, 0, 0, 0, width, height, 1);
+
+ // Up.
+ glProgramUniform1f(fill_program, uniform_z, 1.0f - 3.0f / 1024.0f);
+ for (int offs = 1; offs < height; offs *= 2) {
+ glProgramUniform2f(fill_program, uniform_sample_offset, 0.0f, -offs / float(height));
+ glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
+ glTextureBarrier();
+ }
+ glCopyImageSubData(flow_tex, GL_TEXTURE_2D, 0, 0, 0, 0, temp_tex[2], GL_TEXTURE_2D, 0, 0, 0, 0, width, height, 1);
+
+ // Down.
+ glProgramUniform1f(fill_program, uniform_z, 1.0f - 4.0f / 1024.0f);
+ for (int offs = 1; offs < height; offs *= 2) {
+ glProgramUniform2f(fill_program, uniform_sample_offset, 0.0f, offs / float(height));
+ glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
+ glTextureBarrier();
+ }
+
+ glDisable(GL_DEPTH_TEST);
+}
+
+// Blend the four directions from HoleFill into one pixel, so that single-pixel
+// holes become the average of their four neighbors.
+class HoleBlend {
+public:
+ HoleBlend();
+
+ void exec(GLuint flow_tex, GLuint depth_rb, GLuint temp_tex[3], int width, int height);
+
+private:
+ PersistentFBOSetWithDepth<1> fbos;
+
+ GLuint blend_vs_obj;
+ GLuint blend_fs_obj;
+ GLuint blend_program;
+
+ GLuint uniform_left_tex, uniform_right_tex, uniform_up_tex, uniform_down_tex;
+ GLuint uniform_z, uniform_sample_offset;
+};
+
+HoleBlend::HoleBlend()
+{
+ blend_vs_obj = compile_shader(read_file("hole_fill.vert"), GL_VERTEX_SHADER); // Reuse the vertex shader from the fill.
+ blend_fs_obj = compile_shader(read_file("hole_blend.frag"), GL_FRAGMENT_SHADER);
+ blend_program = link_program(blend_vs_obj, blend_fs_obj);
+
+ uniform_left_tex = glGetUniformLocation(blend_program, "left_tex");
+ uniform_right_tex = glGetUniformLocation(blend_program, "right_tex");
+ uniform_up_tex = glGetUniformLocation(blend_program, "up_tex");
+ uniform_down_tex = glGetUniformLocation(blend_program, "down_tex");
+ uniform_z = glGetUniformLocation(blend_program, "z");
+ uniform_sample_offset = glGetUniformLocation(blend_program, "sample_offset");
+}
+
+void HoleBlend::exec(GLuint flow_tex, GLuint depth_rb, GLuint temp_tex[3], int width, int height)
+{
+ glUseProgram(blend_program);
+
+ bind_sampler(blend_program, uniform_left_tex, 0, temp_tex[0], nearest_sampler);
+ bind_sampler(blend_program, uniform_right_tex, 1, temp_tex[1], nearest_sampler);
+ bind_sampler(blend_program, uniform_up_tex, 2, temp_tex[2], nearest_sampler);
+ bind_sampler(blend_program, uniform_down_tex, 3, flow_tex, nearest_sampler);
+
+ glProgramUniform1f(blend_program, uniform_z, 1.0f - 4.0f / 1024.0f);
+ glProgramUniform2f(blend_program, uniform_sample_offset, 0.0f, 0.0f);
+
+ glViewport(0, 0, width, height);
+ glDisable(GL_BLEND);
+ glEnable(GL_DEPTH_TEST);
+ glDepthFunc(GL_LEQUAL); // Skip over all of the pixels that were never holes to begin with.
+
+ fbos.render_to(depth_rb, flow_tex); // NOTE: Reading and writing to the same texture.
+
+ glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
+
+ glDisable(GL_DEPTH_TEST);
+}
+
+class Blend {
+public:
+ Blend();
+ void exec(GLuint tex0, GLuint tex1, GLuint flow_tex, GLuint output_tex, int width, int height, float alpha);
+
+private:
+ PersistentFBOSet<1> fbos;
+ GLuint blend_vs_obj;
+ GLuint blend_fs_obj;
+ GLuint blend_program;
+
+ GLuint uniform_image0_tex, uniform_image1_tex, uniform_flow_tex;
+ GLuint uniform_alpha, uniform_flow_consistency_tolerance;
+};
+
+Blend::Blend()
+{
+ blend_vs_obj = compile_shader(read_file("vs.vert"), GL_VERTEX_SHADER);
+ blend_fs_obj = compile_shader(read_file("blend.frag"), GL_FRAGMENT_SHADER);
+ blend_program = link_program(blend_vs_obj, blend_fs_obj);
+
+ uniform_image0_tex = glGetUniformLocation(blend_program, "image0_tex");
+ uniform_image1_tex = glGetUniformLocation(blend_program, "image1_tex");
+ uniform_flow_tex = glGetUniformLocation(blend_program, "flow_tex");
+ uniform_alpha = glGetUniformLocation(blend_program, "alpha");
+ uniform_flow_consistency_tolerance = glGetUniformLocation(blend_program, "flow_consistency_tolerance");
+}
+
+void Blend::exec(GLuint tex0, GLuint tex1, GLuint flow_tex, GLuint output_tex, int level_width, int level_height, float alpha)
+{
+ glUseProgram(blend_program);
+ bind_sampler(blend_program, uniform_image0_tex, 0, tex0, linear_sampler);
+ bind_sampler(blend_program, uniform_image1_tex, 1, tex1, linear_sampler);
+ bind_sampler(blend_program, uniform_flow_tex, 2, flow_tex, linear_sampler); // May be upsampled.
+ glProgramUniform1f(blend_program, uniform_alpha, alpha);
+
+ glViewport(0, 0, level_width, level_height);
+ fbos.render_to(output_tex);
+ glDisable(GL_BLEND); // A bit ironic, perhaps.
+ glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
+}
+
+class Interpolate {
+public:
+ Interpolate(int width, int height, int flow_level);
+
+ // Returns a texture that must be released with release_texture()
+ // after use. tex0 and tex1 must be RGBA8 textures with mipmaps
+ // (unless flow_level == 0).
+ GLuint exec(GLuint tex0, GLuint tex1, GLuint forward_flow_tex, GLuint backward_flow_tex, GLuint width, GLuint height, float alpha);
+
+ void release_texture(GLuint tex) {
+ pool.release_texture(tex);
+ }
+
+private:
+ int width, height, flow_level;
+ GLuint vertex_vbo, vao;
+ TexturePool pool;
+
+ Splat splat;
+ HoleFill hole_fill;
+ HoleBlend hole_blend;
+ Blend blend;
+};
+
+Interpolate::Interpolate(int width, int height, int flow_level)
+ : width(width), height(height), flow_level(flow_level) {
+ // Set up the vertex data that will be shared between all passes.
+ float vertices[] = {
+ 0.0f, 1.0f,
+ 0.0f, 0.0f,
+ 1.0f, 1.0f,
+ 1.0f, 0.0f,
+ };
+ glCreateBuffers(1, &vertex_vbo);
+ glNamedBufferData(vertex_vbo, sizeof(vertices), vertices, GL_STATIC_DRAW);
+
+ glCreateVertexArrays(1, &vao);
+ glBindVertexArray(vao);
+ glBindBuffer(GL_ARRAY_BUFFER, vertex_vbo);
+
+ GLint position_attrib = 0; // Hard-coded in every vertex shader.
+ glEnableVertexArrayAttrib(vao, position_attrib);
+ glVertexAttribPointer(position_attrib, 2, GL_FLOAT, GL_FALSE, 0, BUFFER_OFFSET(0));
+}
+
+GLuint Interpolate::exec(GLuint tex0, GLuint tex1, GLuint forward_flow_tex, GLuint backward_flow_tex, GLuint width, GLuint height, float alpha)
+{
+ GPUTimers timers;
+
+ ScopedTimer total_timer("Interpolate", &timers);
+
+ glBindVertexArray(vao);
+
+ // Pick out the right level to test splatting results on.
+ GLuint tex0_view, tex1_view;
+ glGenTextures(1, &tex0_view);
+ glTextureView(tex0_view, GL_TEXTURE_2D, tex0, GL_RGBA8, flow_level, 1, 0, 1);
+ glGenTextures(1, &tex1_view);
+ glTextureView(tex1_view, GL_TEXTURE_2D, tex1, GL_RGBA8, flow_level, 1, 0, 1);
+
+ int flow_width = width >> flow_level;
+ int flow_height = height >> flow_level;
+
+ GLuint flow_tex = pool.get_texture(GL_RG16F, flow_width, flow_height);
+ GLuint depth_rb = pool.get_renderbuffer(GL_DEPTH_COMPONENT16, flow_width, flow_height); // Used for ranking flows.
+
+ {
+ ScopedTimer timer("Splat", &total_timer);
+ splat.exec(tex0_view, tex1_view, forward_flow_tex, backward_flow_tex, flow_tex, depth_rb, flow_width, flow_height, alpha);
+ }
+ glDeleteTextures(1, &tex0_view);
+ glDeleteTextures(1, &tex1_view);
+
+ GLuint temp_tex[3];
+ temp_tex[0] = pool.get_texture(GL_RG16F, flow_width, flow_height);
+ temp_tex[1] = pool.get_texture(GL_RG16F, flow_width, flow_height);
+ temp_tex[2] = pool.get_texture(GL_RG16F, flow_width, flow_height);
+
+ {
+ ScopedTimer timer("Fill holes", &total_timer);
+ hole_fill.exec(flow_tex, depth_rb, temp_tex, flow_width, flow_height);
+ hole_blend.exec(flow_tex, depth_rb, temp_tex, flow_width, flow_height);
+ }
+
+ pool.release_texture(temp_tex[0]);
+ pool.release_texture(temp_tex[1]);
+ pool.release_texture(temp_tex[2]);
+ pool.release_renderbuffer(depth_rb);
+
+ GLuint output_tex = pool.get_texture(GL_RGBA8, width, height);
+ {
+ ScopedTimer timer("Blend", &total_timer);
+ blend.exec(tex0, tex1, flow_tex, output_tex, width, height, alpha);
+ }
+ pool.release_texture(flow_tex);
+ total_timer.end();
+ if (!in_warmup) {
+ timers.print();
+ }
+
+ return output_tex;
+}
+
+GLuint TexturePool::get_texture(GLenum format, GLuint width, GLuint height)
+{
+ for (Texture &tex : textures) {
+ if (!tex.in_use && !tex.is_renderbuffer && tex.format == format &&
+ tex.width == width && tex.height == height) {
+ tex.in_use = true;
+ return tex.tex_num;
+ }
+ }
+
+ Texture tex;
+ glCreateTextures(GL_TEXTURE_2D, 1, &tex.tex_num);
+ glTextureStorage2D(tex.tex_num, 1, format, width, height);
+ tex.format = format;
+ tex.width = width;
+ tex.height = height;
+ tex.in_use = true;
+ tex.is_renderbuffer = false;
+ textures.push_back(tex);
+ return tex.tex_num;
+}
+
+GLuint TexturePool::get_renderbuffer(GLenum format, GLuint width, GLuint height)
+{
+ for (Texture &tex : textures) {
+ if (!tex.in_use && tex.is_renderbuffer && tex.format == format &&
+ tex.width == width && tex.height == height) {
+ tex.in_use = true;
+ return tex.tex_num;
+ }
+ }
+
+ Texture tex;
+ glCreateRenderbuffers(1, &tex.tex_num);
+ glNamedRenderbufferStorage(tex.tex_num, format, width, height);
+
+ tex.format = format;
+ tex.width = width;
+ tex.height = height;
+ tex.in_use = true;
+ tex.is_renderbuffer = true;
+ textures.push_back(tex);
+ return tex.tex_num;
+}
+
+void TexturePool::release_texture(GLuint tex_num)
+{
+ for (Texture &tex : textures) {
+ if (!tex.is_renderbuffer && tex.tex_num == tex_num) {
+ assert(tex.in_use);
+ tex.in_use = false;
+ return;
+ }
+ }
+ assert(false);
+}
+
+void TexturePool::release_renderbuffer(GLuint tex_num)
{
for (Texture &tex : textures) {
- if (tex.tex_num == tex_num) {
+ if (tex.is_renderbuffer && tex.tex_num == tex_num) {
assert(tex.in_use);
tex.in_use = false;
return;
}
}
+// Not relevant for RGB.
+void flip_coordinate_system(uint8_t *dense_flow, unsigned width, unsigned height)
+{
+}
+
void write_flow(const char *filename, const float *dense_flow, unsigned width, unsigned height)
{
FILE *flowfp = fopen(filename, "wb");
fclose(flowfp);
}
+// Not relevant for RGB.
+void write_flow(const char *filename, const uint8_t *dense_flow, unsigned width, unsigned height)
+{
+ assert(false);
+}
+
void write_ppm(const char *filename, const float *dense_flow, unsigned width, unsigned height)
{
FILE *fp = fopen(filename, "wb");
fclose(fp);
}
+void write_ppm(const char *filename, const uint8_t *rgba, unsigned width, unsigned height)
+{
+ unique_ptr<uint8_t[]> rgb_line(new uint8_t[width * 3 + 1]);
+
+ FILE *fp = fopen(filename, "wb");
+ fprintf(fp, "P6\n%d %d\n255\n", width, height);
+ for (unsigned y = 0; y < height; ++y) {
+ unsigned y2 = height - 1 - y;
+ for (size_t x = 0; x < width; ++x) {
+ memcpy(&rgb_line[x * 3], &rgba[(y2 * width + x) * 4], 4);
+ }
+ fwrite(rgb_line.get(), width * 3, 1, fp);
+ }
+ fclose(fp);
+}
+
+struct FlowType {
+ using type = float;
+ static constexpr GLenum gl_format = GL_RG;
+ static constexpr GLenum gl_type = GL_FLOAT;
+ static constexpr int num_channels = 2;
+};
+
+struct RGBAType {
+ using type = uint8_t;
+ static constexpr GLenum gl_format = GL_RGBA;
+ static constexpr GLenum gl_type = GL_UNSIGNED_BYTE;
+ static constexpr int num_channels = 4;
+};
+
+template <class Type>
void finish_one_read(GLuint width, GLuint height)
{
+ using T = typename Type::type;
+ constexpr int bytes_per_pixel = Type::num_channels * sizeof(T);
+
assert(!reads_in_progress.empty());
ReadInProgress read = reads_in_progress.front();
reads_in_progress.pop_front();
- unique_ptr<float[]> flow(new float[width * height * 2]);
- void *buf = glMapNamedBufferRange(read.pbo, 0, width * height * 2 * sizeof(float), GL_MAP_READ_BIT); // Blocks if the read isn't done yet.
- memcpy(flow.get(), buf, width * height * 2 * sizeof(float));
+ unique_ptr<T[]> flow(new typename Type::type[width * height * Type::num_channels]);
+ void *buf = glMapNamedBufferRange(read.pbo, 0, width * height * bytes_per_pixel, GL_MAP_READ_BIT); // Blocks if the read isn't done yet.
+ memcpy(flow.get(), buf, width * height * bytes_per_pixel); // TODO: Unneeded for RGBType, since flip_coordinate_system() does nothing.:
glUnmapNamedBuffer(read.pbo);
spare_pbos.push(read.pbo);
}
}
+template <class Type>
void schedule_read(GLuint tex, GLuint width, GLuint height, const char *filename0, const char *filename1, const char *flow_filename, const char *ppm_filename)
{
+ using T = typename Type::type;
+ constexpr int bytes_per_pixel = Type::num_channels * sizeof(T);
+
if (spare_pbos.empty()) {
- finish_one_read(width, height);
+ finish_one_read<Type>(width, height);
}
assert(!spare_pbos.empty());
reads_in_progress.emplace_back(ReadInProgress{ spare_pbos.top(), filename0, filename1, flow_filename, ppm_filename });
glBindBuffer(GL_PIXEL_PACK_BUFFER, spare_pbos.top());
spare_pbos.pop();
- glGetTextureImage(tex, 0, GL_RG, GL_FLOAT, width * height * 2 * sizeof(float), nullptr);
+ glGetTextureImage(tex, 0, Type::gl_format, Type::gl_type, width * height * bytes_per_pixel, nullptr);
glBindBuffer(GL_PIXEL_PACK_BUFFER, 0);
}
+void compute_flow_only(int argc, char **argv, int optind)
+{
+ const char *filename0 = argc >= (optind + 1) ? argv[optind] : "test1499.png";
+ const char *filename1 = argc >= (optind + 2) ? argv[optind + 1] : "test1500.png";
+ const char *flow_filename = argc >= (optind + 3) ? argv[optind + 2] : "flow.flo";
+
+ // Load pictures.
+ unsigned width1, height1, width2, height2;
+ GLuint tex0 = load_texture(filename0, &width1, &height1, WITHOUT_MIPMAPS);
+ GLuint tex1 = load_texture(filename1, &width2, &height2, WITHOUT_MIPMAPS);
+
+ if (width1 != width2 || height1 != height2) {
+ fprintf(stderr, "Image dimensions don't match (%dx%d versus %dx%d)\n",
+ width1, height1, width2, height2);
+ exit(1);
+ }
+
+ // Set up some PBOs to do asynchronous readback.
+ GLuint pbos[5];
+ glCreateBuffers(5, pbos);
+ for (int i = 0; i < 5; ++i) {
+ glNamedBufferData(pbos[i], width1 * height1 * 2 * sizeof(float), nullptr, GL_STREAM_READ);
+ spare_pbos.push(pbos[i]);
+ }
+
+ int levels = find_num_levels(width1, height1);
+ GLuint tex0_gray, tex1_gray;
+ glCreateTextures(GL_TEXTURE_2D, 1, &tex0_gray);
+ glCreateTextures(GL_TEXTURE_2D, 1, &tex1_gray);
+ glTextureStorage2D(tex0_gray, levels, GL_R8, width1, height1);
+ glTextureStorage2D(tex1_gray, levels, GL_R8, width1, height1);
+
+ GrayscaleConversion gray;
+ gray.exec(tex0, tex0_gray, width1, height1);
+ glDeleteTextures(1, &tex0);
+ glGenerateTextureMipmap(tex0_gray);
+
+ gray.exec(tex1, tex1_gray, width1, height1);
+ glDeleteTextures(1, &tex1);
+ glGenerateTextureMipmap(tex1_gray);
+
+ DISComputeFlow compute_flow(width1, height1);
+
+ if (enable_warmup) {
+ in_warmup = true;
+ for (int i = 0; i < 10; ++i) {
+ GLuint final_tex = compute_flow.exec(tex0_gray, tex1_gray, DISComputeFlow::RESIZE_FLOW_TO_FULL_SIZE);
+ compute_flow.release_texture(final_tex);
+ }
+ in_warmup = false;
+ }
+
+ GLuint final_tex = compute_flow.exec(tex0_gray, tex1_gray, DISComputeFlow::RESIZE_FLOW_TO_FULL_SIZE);
+
+ schedule_read<FlowType>(final_tex, width1, height1, filename0, filename1, flow_filename, "flow.ppm");
+ compute_flow.release_texture(final_tex);
+
+ // See if there are more flows on the command line (ie., more than three arguments),
+ // and if so, process them.
+ int num_flows = (argc - optind) / 3;
+ for (int i = 1; i < num_flows; ++i) {
+ const char *filename0 = argv[optind + i * 3 + 0];
+ const char *filename1 = argv[optind + i * 3 + 1];
+ const char *flow_filename = argv[optind + i * 3 + 2];
+ GLuint width, height;
+ GLuint tex0 = load_texture(filename0, &width, &height, WITHOUT_MIPMAPS);
+ if (width != width1 || height != height1) {
+ fprintf(stderr, "%s: Image dimensions don't match (%dx%d versus %dx%d)\n",
+ filename0, width, height, width1, height1);
+ exit(1);
+ }
+ gray.exec(tex0, tex0_gray, width, height);
+ glGenerateTextureMipmap(tex0_gray);
+ glDeleteTextures(1, &tex0);
+
+ GLuint tex1 = load_texture(filename1, &width, &height, WITHOUT_MIPMAPS);
+ if (width != width1 || height != height1) {
+ fprintf(stderr, "%s: Image dimensions don't match (%dx%d versus %dx%d)\n",
+ filename1, width, height, width1, height1);
+ exit(1);
+ }
+ gray.exec(tex1, tex1_gray, width, height);
+ glGenerateTextureMipmap(tex1_gray);
+ glDeleteTextures(1, &tex1);
+
+ GLuint final_tex = compute_flow.exec(tex0_gray, tex1_gray, DISComputeFlow::RESIZE_FLOW_TO_FULL_SIZE);
+
+ schedule_read<FlowType>(final_tex, width1, height1, filename0, filename1, flow_filename, "");
+ compute_flow.release_texture(final_tex);
+ }
+ glDeleteTextures(1, &tex0_gray);
+ glDeleteTextures(1, &tex1_gray);
+
+ while (!reads_in_progress.empty()) {
+ finish_one_read<FlowType>(width1, height1);
+ }
+}
+
+// Interpolate images based on
+//
+// Herbst, Seitz, Baker: “Occlusion Reasoning for Temporal Interpolation
+// Using Optical Flow”
+//
+// or at least a reasonable subset thereof. Unfinished.
+void interpolate_image(int argc, char **argv, int optind)
+{
+ const char *filename0 = argc >= (optind + 1) ? argv[optind] : "test1499.png";
+ const char *filename1 = argc >= (optind + 2) ? argv[optind + 1] : "test1500.png";
+ //const char *out_filename = argc >= (optind + 3) ? argv[optind + 2] : "interpolated.png";
+
+ // Load pictures.
+ unsigned width1, height1, width2, height2;
+ GLuint tex0 = load_texture(filename0, &width1, &height1, WITH_MIPMAPS);
+ GLuint tex1 = load_texture(filename1, &width2, &height2, WITH_MIPMAPS);
+
+ if (width1 != width2 || height1 != height2) {
+ fprintf(stderr, "Image dimensions don't match (%dx%d versus %dx%d)\n",
+ width1, height1, width2, height2);
+ exit(1);
+ }
+
+ // Set up some PBOs to do asynchronous readback.
+ GLuint pbos[5];
+ glCreateBuffers(5, pbos);
+ for (int i = 0; i < 5; ++i) {
+ glNamedBufferData(pbos[i], width1 * height1 * 4 * sizeof(uint8_t), nullptr, GL_STREAM_READ);
+ spare_pbos.push(pbos[i]);
+ }
+
+ DISComputeFlow compute_flow(width1, height1);
+ GrayscaleConversion gray;
+ Interpolate interpolate(width1, height1, finest_level);
+
+ int levels = find_num_levels(width1, height1);
+ GLuint tex0_gray, tex1_gray;
+ glCreateTextures(GL_TEXTURE_2D, 1, &tex0_gray);
+ glCreateTextures(GL_TEXTURE_2D, 1, &tex1_gray);
+ glTextureStorage2D(tex0_gray, levels, GL_R8, width1, height1);
+ glTextureStorage2D(tex1_gray, levels, GL_R8, width1, height1);
+
+ gray.exec(tex0, tex0_gray, width1, height1);
+ glGenerateTextureMipmap(tex0_gray);
+
+ gray.exec(tex1, tex1_gray, width1, height1);
+ glGenerateTextureMipmap(tex1_gray);
+
+ if (enable_warmup) {
+ in_warmup = true;
+ for (int i = 0; i < 10; ++i) {
+ GLuint forward_flow_tex = compute_flow.exec(tex0_gray, tex1_gray, DISComputeFlow::DO_NOT_RESIZE_FLOW);
+ GLuint backward_flow_tex = compute_flow.exec(tex1_gray, tex0_gray, DISComputeFlow::DO_NOT_RESIZE_FLOW);
+ GLuint interpolated_tex = interpolate.exec(tex0, tex1, forward_flow_tex, backward_flow_tex, width1, height1, 0.5f);
+ compute_flow.release_texture(forward_flow_tex);
+ compute_flow.release_texture(backward_flow_tex);
+ interpolate.release_texture(interpolated_tex);
+ }
+ in_warmup = false;
+ }
+
+ GLuint forward_flow_tex = compute_flow.exec(tex0_gray, tex1_gray, DISComputeFlow::DO_NOT_RESIZE_FLOW);
+ GLuint backward_flow_tex = compute_flow.exec(tex1_gray, tex0_gray, DISComputeFlow::DO_NOT_RESIZE_FLOW);
+
+ for (int frameno = 1; frameno < 60; ++frameno) {
+ char ppm_filename[256];
+ snprintf(ppm_filename, sizeof(ppm_filename), "interp%04d.ppm", frameno);
+
+ float alpha = frameno / 60.0f;
+ GLuint interpolated_tex = interpolate.exec(tex0, tex1, forward_flow_tex, backward_flow_tex, width1, height1, alpha);
+
+ schedule_read<RGBAType>(interpolated_tex, width1, height1, filename0, filename1, "", ppm_filename);
+ interpolate.release_texture(interpolated_tex);
+ }
+
+ while (!reads_in_progress.empty()) {
+ finish_one_read<RGBAType>(width1, height1);
+ }
+}
+
int main(int argc, char **argv)
{
static const option long_options[] = {
- { "alpha", required_argument, 0, 'a' },
- { "delta", required_argument, 0, 'd' },
- { "gamma", required_argument, 0, 'g' },
+ { "smoothness-relative-weight", required_argument, 0, 's' }, // alpha.
+ { "intensity-relative-weight", required_argument, 0, 'i' }, // delta.
+ { "gradient-relative-weight", required_argument, 0, 'g' }, // gamma.
{ "disable-timing", no_argument, 0, 1000 },
- { "ignore-variational-refinement", no_argument, 0, 1001 } // Still calculates it, just doesn't apply it.
+ { "detailed-timing", no_argument, 0, 1003 },
+ { "ignore-variational-refinement", no_argument, 0, 1001 }, // Still calculates it, just doesn't apply it.
+ { "interpolate", no_argument, 0, 1002 },
+ { "warmup", no_argument, 0, 1004 }
};
for ( ;; ) {
int option_index = 0;
- int c = getopt_long(argc, argv, "a:d:g:", long_options, &option_index);
+ int c = getopt_long(argc, argv, "s:i:g:", long_options, &option_index);
if (c == -1) {
break;
}
switch (c) {
- case 'a':
+ case 's':
vr_alpha = atof(optarg);
break;
- case 'd':
+ case 'i':
vr_delta = atof(optarg);
break;
case 'g':
case 1001:
enable_variational_refinement = false;
break;
+ case 1002:
+ enable_interpolation = true;
+ break;
+ case 1003:
+ detailed_timing = true;
+ break;
+ case 1004:
+ enable_warmup = true;
+ break;
default:
fprintf(stderr, "Unknown option '%s'\n", argv[option_index]);
exit(1);
SDL_GL_SetAttribute(SDL_GL_CONTEXT_MAJOR_VERSION, 4);
SDL_GL_SetAttribute(SDL_GL_CONTEXT_MINOR_VERSION, 5);
// SDL_GL_SetAttribute(SDL_GL_CONTEXT_FLAGS, SDL_GL_CONTEXT_DEBUG_FLAG);
- SDL_Window *window = SDL_CreateWindow("OpenGL window",
- SDL_WINDOWPOS_UNDEFINED,
- SDL_WINDOWPOS_UNDEFINED,
- 64, 64,
- SDL_WINDOW_OPENGL);
+ window = SDL_CreateWindow("OpenGL window",
+ SDL_WINDOWPOS_UNDEFINED,
+ SDL_WINDOWPOS_UNDEFINED,
+ 64, 64,
+ SDL_WINDOW_OPENGL | SDL_WINDOW_HIDDEN);
SDL_GLContext context = SDL_GL_CreateContext(window);
assert(context != nullptr);
- const char *filename0 = argc >= (optind + 1) ? argv[optind] : "test1499.png";
- const char *filename1 = argc >= (optind + 2) ? argv[optind + 1] : "test1500.png";
- const char *flow_filename = argc >= (optind + 3) ? argv[optind + 2] : "flow.flo";
-
- // Load pictures.
- unsigned width1, height1, width2, height2;
- GLuint tex0 = load_texture(filename0, &width1, &height1);
- GLuint tex1 = load_texture(filename1, &width2, &height2);
-
- if (width1 != width2 || height1 != height2) {
- fprintf(stderr, "Image dimensions don't match (%dx%d versus %dx%d)\n",
- width1, height1, width2, height2);
- exit(1);
- }
-
- // Set up some PBOs to do asynchronous readback.
- GLuint pbos[5];
- glCreateBuffers(5, pbos);
- for (int i = 0; i < 5; ++i) {
- glNamedBufferData(pbos[i], width1 * height1 * 2 * sizeof(float), nullptr, GL_STREAM_READ);
- spare_pbos.push(pbos[i]);
- }
+ glDisable(GL_DITHER);
// FIXME: Should be part of DISComputeFlow (but needs to be initialized
// before all the render passes).
glNamedBufferData(vertex_vbo, sizeof(vertices), vertices, GL_STATIC_DRAW);
glBindBuffer(GL_ARRAY_BUFFER, vertex_vbo);
- DISComputeFlow compute_flow(width1, height1);
- GLuint final_tex = compute_flow.exec(tex0, tex1);
-
- schedule_read(final_tex, width1, height1, filename0, filename1, flow_filename, "flow.ppm");
- compute_flow.release_texture(final_tex);
-
- // See if there are more flows on the command line (ie., more than three arguments),
- // and if so, process them.
- int num_flows = (argc - optind) / 3;
- for (int i = 1; i < num_flows; ++i) {
- const char *filename0 = argv[optind + i * 3 + 0];
- const char *filename1 = argv[optind + i * 3 + 1];
- const char *flow_filename = argv[optind + i * 3 + 2];
- GLuint width, height;
- GLuint tex0 = load_texture(filename0, &width, &height);
- if (width != width1 || height != height1) {
- fprintf(stderr, "%s: Image dimensions don't match (%dx%d versus %dx%d)\n",
- filename0, width, height, width1, height1);
- exit(1);
- }
-
- GLuint tex1 = load_texture(filename1, &width, &height);
- if (width != width1 || height != height1) {
- fprintf(stderr, "%s: Image dimensions don't match (%dx%d versus %dx%d)\n",
- filename1, width, height, width1, height1);
- exit(1);
- }
-
- GLuint final_tex = compute_flow.exec(tex0, tex1);
- schedule_read(final_tex, width1, height1, filename0, filename1, flow_filename, "");
- compute_flow.release_texture(final_tex);
- }
-
- while (!reads_in_progress.empty()) {
- finish_one_read(width1, height1);
+ if (enable_interpolation) {
+ interpolate_image(argc, argv, optind);
+ } else {
+ compute_flow_only(argc, argv, optind);
}
}