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1 /*
2  * Copyright (C) 2017 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 #include "RenderTopView.h"
18 #include "VideoTex.h"
19 #include "glError.h"
20 #include "shader.h"
21 #include "shader_simpleTex.h"
22 #include "shader_projectedTex.h"
23 
24 #include <math/mat4.h>
25 #include <math/vec3.h>
26 #include <android/hardware/camera/device/3.2/ICameraDevice.h>
27 #include <android-base/logging.h>
28 
29 using ::android::hardware::camera::device::V3_2::Stream;
30 
31 
32 // Simple aliases to make geometric math using vectors more readable
33 static const unsigned X = 0;
34 static const unsigned Y = 1;
35 static const unsigned Z = 2;
36 //static const unsigned W = 3;
37 
38 
39 // Since we assume no roll in these views, we can simplify the required math
unitVectorFromPitchAndYaw(float pitch,float yaw)40 static android::vec3 unitVectorFromPitchAndYaw(float pitch, float yaw) {
41     float sinPitch, cosPitch;
42     sincosf(pitch, &sinPitch, &cosPitch);
43     float sinYaw, cosYaw;
44     sincosf(yaw, &sinYaw, &cosYaw);
45     return android::vec3(cosPitch * -sinYaw,
46                          cosPitch * cosYaw,
47                          sinPitch);
48 }
49 
50 
51 // Helper function to set up a perspective matrix with independent horizontal and vertical
52 // angles of view.
perspective(float hfov,float vfov,float near,float far)53 static android::mat4 perspective(float hfov, float vfov, float near, float far) {
54     const float tanHalfFovX = tanf(hfov * 0.5f);
55     const float tanHalfFovY = tanf(vfov * 0.5f);
56 
57     android::mat4 p(0.0f);
58     p[0][0] = 1.0f / tanHalfFovX;
59     p[1][1] = 1.0f / tanHalfFovY;
60     p[2][2] = - (far + near) / (far - near);
61     p[2][3] = -1.0f;
62     p[3][2] = - (2.0f * far * near) / (far - near);
63     return p;
64 }
65 
66 
67 // Helper function to set up a view matrix for a camera given it's yaw & pitch & location
68 // Yes, with a bit of work, we could use lookAt, but it does a lot of extra work
69 // internally that we can short cut.
cameraLookMatrix(const ConfigManager::CameraInfo & cam)70 static android::mat4 cameraLookMatrix(const ConfigManager::CameraInfo& cam) {
71     float sinYaw, cosYaw;
72     sincosf(cam.yaw, &sinYaw, &cosYaw);
73 
74     // Construct principal unit vectors
75     android::vec3 vAt = unitVectorFromPitchAndYaw(cam.pitch, cam.yaw);
76     android::vec3 vRt = android::vec3(cosYaw, sinYaw, 0.0f);
77     android::vec3 vUp = -cross(vAt, vRt);
78     android::vec3 eye = android::vec3(cam.position[X], cam.position[Y], cam.position[Z]);
79 
80     android::mat4 Result(1.0f);
81     Result[0][0] = vRt.x;
82     Result[1][0] = vRt.y;
83     Result[2][0] = vRt.z;
84     Result[0][1] = vUp.x;
85     Result[1][1] = vUp.y;
86     Result[2][1] = vUp.z;
87     Result[0][2] =-vAt.x;
88     Result[1][2] =-vAt.y;
89     Result[2][2] =-vAt.z;
90     Result[3][0] =-dot(vRt, eye);
91     Result[3][1] =-dot(vUp, eye);
92     Result[3][2] = dot(vAt, eye);
93     return Result;
94 }
95 
96 
RenderTopView(sp<IEvsEnumerator> enumerator,const std::vector<ConfigManager::CameraInfo> & camList,const ConfigManager & mConfig)97 RenderTopView::RenderTopView(sp<IEvsEnumerator> enumerator,
98                              const std::vector<ConfigManager::CameraInfo>& camList,
99                              const ConfigManager& mConfig) :
100     mEnumerator(enumerator),
101     mConfig(mConfig) {
102 
103     // Copy the list of cameras we're to employ into our local storage.  We'll create and
104     // associate a streaming video texture when we are activated.
105     mActiveCameras.reserve(camList.size());
106     for (unsigned i=0; i<camList.size(); i++) {
107         mActiveCameras.emplace_back(camList[i]);
108     }
109 }
110 
111 
activate()112 bool RenderTopView::activate() {
113     // Ensure GL is ready to go...
114     if (!prepareGL()) {
115         LOG(ERROR) << "Error initializing GL";
116         return false;
117     }
118 
119     // Load our shader programs
120     mPgmAssets.simpleTexture = buildShaderProgram(vtxShader_simpleTexture,
121                                                  pixShader_simpleTexture,
122                                                  "simpleTexture");
123     if (!mPgmAssets.simpleTexture) {
124         LOG(ERROR) << "Failed to build shader program";
125         return false;
126     }
127     mPgmAssets.projectedTexture = buildShaderProgram(vtxShader_projectedTexture,
128                                                     pixShader_projectedTexture,
129                                                     "projectedTexture");
130     if (!mPgmAssets.projectedTexture) {
131         LOG(ERROR) << "Failed to build shader program";
132         return false;
133     }
134 
135 
136     // Load the checkerboard text image
137     mTexAssets.checkerBoard.reset(createTextureFromPng(
138                                   "/system/etc/automotive/evs/LabeledChecker.png"));
139     if (!mTexAssets.checkerBoard) {
140         LOG(ERROR) << "Failed to load checkerboard texture";
141         return false;
142     }
143 
144     // Load the car image
145     mTexAssets.carTopView.reset(createTextureFromPng(
146                                 "/system/etc/automotive/evs/CarFromTop.png"));
147     if (!mTexAssets.carTopView) {
148         LOG(ERROR) << "Failed to load carTopView texture";
149         return false;
150     }
151 
152 
153     // Set up streaming video textures for our associated cameras
154     for (auto&& cam: mActiveCameras) {
155         cam.tex.reset(createVideoTexture(mEnumerator,
156                                          cam.info.cameraId.c_str(),
157                                          nullptr,
158                                          sDisplay));
159         if (!cam.tex) {
160             LOG(ERROR) << "Failed to set up video texture for " << cam.info.cameraId
161                        << " (" << cam.info.function << ")";
162 // TODO:  For production use, we may actually want to fail in this case, but not yet...
163 //            return false;
164         }
165     }
166 
167     return true;
168 }
169 
170 
deactivate()171 void RenderTopView::deactivate() {
172     // Release our video textures
173     // We can't hold onto it because some other Render object might need the same camera
174     // TODO(b/131492626):  investigate whether sharing video textures can save
175     // the time.
176     for (auto&& cam: mActiveCameras) {
177         cam.tex = nullptr;
178     }
179 }
180 
181 
drawFrame(const BufferDesc & tgtBuffer)182 bool RenderTopView::drawFrame(const BufferDesc& tgtBuffer) {
183     // Tell GL to render to the given buffer
184     if (!attachRenderTarget(tgtBuffer)) {
185         LOG(ERROR) << "Failed to attached render target";
186         return false;
187     }
188 
189     // Set up our top down projection matrix from car space (world units, Xfwd, Yright, Zup)
190     // to view space (-1 to 1)
191     const float top    = mConfig.getDisplayTopLocation();
192     const float bottom = mConfig.getDisplayBottomLocation();
193     const float right  = mConfig.getDisplayRightLocation(sAspectRatio);
194     const float left   = mConfig.getDisplayLeftLocation(sAspectRatio);
195 
196     const float near = 10.0f;   // arbitrary top of view volume
197     const float far = 0.0f;     // ground plane is at zero
198 
199     // We can use a simple, unrotated ortho view since the screen and car space axis are
200     // naturally aligned in the top down view.
201     // TODO:  Not sure if flipping top/bottom here is "correct" or a double reverse...
202 //    orthoMatrix = android::mat4::ortho(left, right, bottom, top, near, far);
203     orthoMatrix = android::mat4::ortho(left, right, top, bottom, near, far);
204 
205 
206     // Refresh our video texture contents.  We do it all at once in hopes of getting
207     // better coherence among images.  This does not guarantee synchronization, of course...
208     for (auto&& cam: mActiveCameras) {
209         if (cam.tex) {
210             cam.tex->refresh();
211         }
212     }
213 
214     // Iterate over all the cameras and project their images onto the ground plane
215     for (auto&& cam: mActiveCameras) {
216         renderCameraOntoGroundPlane(cam);
217     }
218 
219     // Draw the car image
220     renderCarTopView();
221 
222     // Now that everythign is submitted, release our hold on the texture resource
223     detachRenderTarget();
224 
225     // Wait for the rendering to finish
226     glFinish();
227     detachRenderTarget();
228     return true;
229 }
230 
231 
232 //
233 // Responsible for drawing the car's self image in the top down view.
234 // Draws in car model space (units of meters with origin at center of rear axel)
235 // NOTE:  We probably want to eventually switch to using a VertexArray based model system.
236 //
renderCarTopView()237 void RenderTopView::renderCarTopView() {
238     // Compute the corners of our image footprint in car space
239     const float carLengthInTexels = mConfig.carGraphicRearPixel() - mConfig.carGraphicFrontPixel();
240     const float carSpaceUnitsPerTexel = mConfig.getCarLength() / carLengthInTexels;
241     const float textureHeightInCarSpace = mTexAssets.carTopView->height() * carSpaceUnitsPerTexel;
242     const float textureAspectRatio = (float)mTexAssets.carTopView->width() /
243                                             mTexAssets.carTopView->height();
244     const float pixelsBehindCarInImage = mTexAssets.carTopView->height() -
245                                          mConfig.carGraphicRearPixel();
246     const float textureExtentBehindCarInCarSpace = pixelsBehindCarInImage * carSpaceUnitsPerTexel;
247 
248     const float btCS = mConfig.getRearLocation() - textureExtentBehindCarInCarSpace;
249     const float tpCS = textureHeightInCarSpace + btCS;
250     const float ltCS = 0.5f * textureHeightInCarSpace * textureAspectRatio;
251     const float rtCS = -ltCS;
252 
253     GLfloat vertsCarPos[] = { ltCS, tpCS, 0.0f,   // left top in car space
254                               rtCS, tpCS, 0.0f,   // right top
255                               ltCS, btCS, 0.0f,   // left bottom
256                               rtCS, btCS, 0.0f    // right bottom
257     };
258     // NOTE:  We didn't flip the image in the texture, so V=0 is actually the top of the image
259     GLfloat vertsCarTex[] = { 0.0f, 0.0f,   // left top
260                               1.0f, 0.0f,   // right top
261                               0.0f, 1.0f,   // left bottom
262                               1.0f, 1.0f    // right bottom
263     };
264     glVertexAttribPointer(0, 3, GL_FLOAT, GL_FALSE, 0, vertsCarPos);
265     glVertexAttribPointer(1, 2, GL_FLOAT, GL_FALSE, 0, vertsCarTex);
266     glEnableVertexAttribArray(0);
267     glEnableVertexAttribArray(1);
268 
269 
270     glEnable(GL_BLEND);
271     glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
272 
273     glUseProgram(mPgmAssets.simpleTexture);
274     GLint loc = glGetUniformLocation(mPgmAssets.simpleTexture, "cameraMat");
275     glUniformMatrix4fv(loc, 1, false, orthoMatrix.asArray());
276     glBindTexture(GL_TEXTURE_2D, mTexAssets.carTopView->glId());
277 
278     glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
279 
280 
281     glDisable(GL_BLEND);
282 
283     glDisableVertexAttribArray(0);
284     glDisableVertexAttribArray(1);
285 }
286 
287 
288 // NOTE:  Might be worth reviewing the ideas at
289 // http://math.stackexchange.com/questions/1691895/inverse-of-perspective-matrix
290 // to see if that simplifies the math, although we'll still want to compute the actual ground
291 // interception points taking into account the pitchLimit as below.
renderCameraOntoGroundPlane(const ActiveCamera & cam)292 void RenderTopView::renderCameraOntoGroundPlane(const ActiveCamera& cam) {
293     // How far is the farthest any camera should even consider projecting it's image?
294     const float visibleSizeV = mConfig.getDisplayTopLocation() - mConfig.getDisplayBottomLocation();
295     const float visibleSizeH = visibleSizeV * sAspectRatio;
296     const float maxRange = (visibleSizeH > visibleSizeV) ? visibleSizeH : visibleSizeV;
297 
298     // Construct the projection matrix (View + Projection) associated with this sensor
299     // TODO:  Consider just hard coding the far plane distance as it likely doesn't matter
300     const android::mat4 V = cameraLookMatrix(cam.info);
301     const android::mat4 P = perspective(cam.info.hfov, cam.info.vfov, cam.info.position[Z], maxRange);
302     const android::mat4 projectionMatix = P*V;
303 
304     // Just draw the whole darn ground plane for now -- we're wasting fill rate, but so what?
305     // A 2x optimization would be to draw only the 1/2 space of the window in the direction
306     // the sensor is facing.  A more complex solution would be to construct the intersection
307     // of the sensor volume with the ground plane and render only that geometry.
308     const float top = mConfig.getDisplayTopLocation();
309     const float bottom = mConfig.getDisplayBottomLocation();
310     const float wsHeight = top - bottom;
311     const float wsWidth = wsHeight * sAspectRatio;
312     const float right =  wsWidth * 0.5f;
313     const float left = -right;
314 
315     const android::vec3 topLeft(left, top, 0.0f);
316     const android::vec3 topRight(right, top, 0.0f);
317     const android::vec3 botLeft(left, bottom, 0.0f);
318     const android::vec3 botRight(right, bottom, 0.0f);
319 
320     GLfloat vertsPos[] = { topLeft[X],  topLeft[Y],  topLeft[Z],
321                            topRight[X], topRight[Y], topRight[Z],
322                            botLeft[X],  botLeft[Y],  botLeft[Z],
323                            botRight[X], botRight[Y], botRight[Z],
324     };
325     glVertexAttribPointer(0, 3, GL_FLOAT, GL_FALSE, 0, vertsPos);
326     glEnableVertexAttribArray(0);
327 
328 
329     glDisable(GL_BLEND);
330 
331     glUseProgram(mPgmAssets.projectedTexture);
332     GLint locCam = glGetUniformLocation(mPgmAssets.projectedTexture, "cameraMat");
333     glUniformMatrix4fv(locCam, 1, false, orthoMatrix.asArray());
334     GLint locProj = glGetUniformLocation(mPgmAssets.projectedTexture, "projectionMat");
335     glUniformMatrix4fv(locProj, 1, false, projectionMatix.asArray());
336 
337     GLuint texId;
338     if (cam.tex) {
339         texId = cam.tex->glId();
340     } else {
341         texId = mTexAssets.checkerBoard->glId();
342     }
343     glBindTexture(GL_TEXTURE_2D, texId);
344 
345     glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
346 
347 
348     glDisableVertexAttribArray(0);
349 }
350