Made the minimum changes to make the texture extraction work with the affine renderer

- Taking a 3x4 affine matrix and adding an orthogonal row to make it 4x4 - Removed all transformations from clip to screen space as our camera matrix now goes directly from world to screen space - Removed division by w (it's 1 anyway)

Made the minimum changes to make the texture extraction work with the affine renderer
- Taking a 3x4 affine matrix and adding an orthogonal row to make it 4x4 - Removed all transformations from clip to screen space as our camera matrix now goes directly from world to screen space - Removed division by w (it's 1 anyway)
00595c3d · patrikhuber · 4b5a2919 · 00595c3d
Commit 00595c3d authored Aug 01, 2015 by patrikhuber
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Showing with 7 additions and 22 deletions

include/eos/render/texture_extraction.hpp include/eos/render/texture_extraction.hpp +7 -22

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--- a/include/eos/render/texture_extraction.hpp
+++ b/include/eos/render/texture_extraction.hpp
@@ -116,6 +116,8 @@ inline cv::Mat extract_texture(Mesh mesh, cv::Mat mvp_matrix, int viewport_width
 	using std::floor;
 	using std::ceil;

+	mvp_matrix = detail::calculate_affine_z_direction(mvp_matrix);
+
 	// optional param  cv::Mat texture_map = Mat(512, 512, CV_8UC3) ?
 	// cv::Mat texture_map(512, 512, inputImage.type());
 	Mat texture_map = Mat::zeros(512, 512, CV_8UC3); // We don't want an alpha channel. We might want to handle grayscale input images though.
@@ -144,19 +146,7 @@ inline cv::Mat extract_texture(Mesh mesh, cv::Mat mvp_matrix, int viewport_width
 		// clipping against the frustums etc.
 		// But as long as our model is fully on the screen, we're fine.

-		// divide by w
-		// if ortho, we can do the divide as well, it will just be a / 1.0f.
-		v0 = v0 / v0[3];
-		v1 = v1 / v1[3];
-		v2 = v2 / v2[3];
-
 		// Todo: This is all very similar to processProspectiveTri(...), except the other function does texturing stuff as well. Remove code duplication!
-		Vec2f v0_clip = clip_to_screen_space(Vec2f(v0[0], v0[1]), viewport_width, viewport_height);
-		Vec2f v1_clip = clip_to_screen_space(Vec2f(v1[0], v1[1]), viewport_width, viewport_height);
-		Vec2f v2_clip = clip_to_screen_space(Vec2f(v2[0], v2[1]), viewport_width, viewport_height);
-		v0[0] = v0_clip[0]; v0[1] = v0_clip[1];
-		v1[0] = v1_clip[0]; v1[1] = v1_clip[1];
-		v2[0] = v2_clip[0]; v2[1] = v2_clip[1];

 		//if (doBackfaceCulling) {
 		if (!are_vertices_cc_in_screen_space(v0, v1, v2))
@@ -213,23 +203,18 @@ inline cv::Mat extract_texture(Mesh mesh, cv::Mat mvp_matrix, int viewport_width

 		cv::Point2f src_tri[3];
 		cv::Point2f dst_tri[3];
+
 		cv::Vec4f vec(mesh.vertices[triangle_indices[0]][0], mesh.vertices[triangle_indices[0]][1], mesh.vertices[triangle_indices[0]][2], 1.0f);
 		cv::Vec4f res = Mat(mvp_matrix * Mat(vec));
-		res /= res[3];
-		Vec2f screen_space = clip_to_screen_space(Vec2f(res[0], res[1]), viewport_width, viewport_height);
-		src_tri[0] = screen_space;
+		src_tri[0] = Vec2f(res[0], res[1]);

 		vec = cv::Vec4f(mesh.vertices[triangle_indices[1]][0], mesh.vertices[triangle_indices[1]][1], mesh.vertices[triangle_indices[1]][2], 1.0f);
 		res = Mat(mvp_matrix * Mat(vec));
-		res /= res[3];
-		screen_space = clip_to_screen_space(Vec2f(res[0], res[1]), viewport_width, viewport_height);
-		src_tri[1] = screen_space;
+		src_tri[1] = Vec2f(res[0], res[1]);

 		vec = cv::Vec4f(mesh.vertices[triangle_indices[2]][0], mesh.vertices[triangle_indices[2]][1], mesh.vertices[triangle_indices[2]][2], 1.0f);
 		res = Mat(mvp_matrix * Mat(vec));
-		res /= res[3];
-		screen_space = clip_to_screen_space(Vec2f(res[0], res[1]), viewport_width, viewport_height);
-		src_tri[2] = screen_space;
+		src_tri[2] = Vec2f(res[0], res[1]);

 		dst_tri[0] = cv::Point2f(texture_map.cols*mesh.texcoords[triangle_indices[0]][0], texture_map.rows*mesh.texcoords[triangle_indices[0]][1] - 1.0f);
 		dst_tri[1] = cv::Point2f(texture_map.cols*mesh.texcoords[triangle_indices[1]][0], texture_map.rows*mesh.texcoords[triangle_indices[1]][1] - 1.0f);