add yapf style and apply yapf to format all Python files

This recreates pull request #2192
2019-04-27 07:31:15 -07:00
parent c591735042
commit ef9570c315
347 changed files with 70304 additions and 22752 deletions
--- a/examples/pybullet/examples/getCameraImageTest.py
+++ b/examples/pybullet/examples/getCameraImageTest.py
@@ -3,16 +3,14 @@ import numpy as np
 import pybullet as p
 import time

-
-direct = p.connect(p.GUI)#, options="--window_backend=2 --render_device=0")
+direct = p.connect(p.GUI)  #, options="--window_backend=2 --render_device=0")
 #egl = p.loadPlugin("eglRendererPlugin")

-
 p.loadURDF('plane.urdf')
-p.loadURDF("r2d2.urdf",[0,0,1])
+p.loadURDF("r2d2.urdf", [0, 0, 1])
 p.loadURDF('cube_small.urdf', basePosition=[0.0, 0.0, 0.025])
 cube_trans = p.loadURDF('cube_small.urdf', basePosition=[0.0, 0.1, 0.025])
-p.changeVisualShape(cube_trans,-1,rgbaColor=[1,1,1,0.1])
+p.changeVisualShape(cube_trans, -1, rgbaColor=[1, 1, 1, 0.1])
 width = 128
 height = 128

@@ -25,42 +23,71 @@ view_matrix = p.computeViewMatrix([0, 0, 0.5], [0, 0, 0], [1, 0, 0])
 projection_matrix = p.computeProjectionMatrixFOV(fov, aspect, near, far)

 # Get depth values using the OpenGL renderer
-images = p.getCameraImage(width, height, view_matrix, projection_matrix, shadow=True,renderer=p.ER_BULLET_HARDWARE_OPENGL)
-rgb_opengl= np.reshape(images[2], (height, width, 4))*1./255.
+images = p.getCameraImage(width,
+                          height,
+                          view_matrix,
+                          projection_matrix,
+                          shadow=True,
+                          renderer=p.ER_BULLET_HARDWARE_OPENGL)
+rgb_opengl = np.reshape(images[2], (height, width, 4)) * 1. / 255.
 depth_buffer_opengl = np.reshape(images[3], [width, height])
 depth_opengl = far * near / (far - (far - near) * depth_buffer_opengl)
-seg_opengl = np.reshape(images[4], [width, height])*1./255.
+seg_opengl = np.reshape(images[4], [width, height]) * 1. / 255.
 time.sleep(1)

 # Get depth values using Tiny renderer
-images = p.getCameraImage(width, height, view_matrix, projection_matrix, shadow=True, renderer=p.ER_TINY_RENDERER)
+images = p.getCameraImage(width,
+                          height,
+                          view_matrix,
+                          projection_matrix,
+                          shadow=True,
+                          renderer=p.ER_TINY_RENDERER)
 depth_buffer_tiny = np.reshape(images[3], [width, height])
 depth_tiny = far * near / (far - (far - near) * depth_buffer_tiny)
-rgb_tiny= np.reshape(images[2], (height, width, 4))*1./255.
-seg_tiny = np.reshape(images[4],[width,height])*1./255.
+rgb_tiny = np.reshape(images[2], (height, width, 4)) * 1. / 255.
+seg_tiny = np.reshape(images[4], [width, height]) * 1. / 255.

-
-
-bearStartPos1 = [-3.3,0,0]
-bearStartOrientation1 = p.getQuaternionFromEuler([0,0,0])
+bearStartPos1 = [-3.3, 0, 0]
+bearStartOrientation1 = p.getQuaternionFromEuler([0, 0, 0])
 bearId1 = p.loadURDF("plane.urdf", bearStartPos1, bearStartOrientation1)
-bearStartPos2 = [0,0,0]
-bearStartOrientation2 = p.getQuaternionFromEuler([0,0,0])
-bearId2 = p.loadURDF("teddy_large.urdf",bearStartPos2, bearStartOrientation2)
+bearStartPos2 = [0, 0, 0]
+bearStartOrientation2 = p.getQuaternionFromEuler([0, 0, 0])
+bearId2 = p.loadURDF("teddy_large.urdf", bearStartPos2, bearStartOrientation2)
 textureId = p.loadTexture("checker_grid.jpg")
-for b in range (p.getNumBodies()):
-	p.changeVisualShape(b,linkIndex=-1,textureUniqueId=textureId)
-	for j in range(p.getNumJoints(b)):
-		p.changeVisualShape(b,linkIndex=j,textureUniqueId=textureId)
+for b in range(p.getNumBodies()):
+  p.changeVisualShape(b, linkIndex=-1, textureUniqueId=textureId)
+  for j in range(p.getNumJoints(b)):
+    p.changeVisualShape(b, linkIndex=j, textureUniqueId=textureId)

-viewMat = [0.642787516117096, -0.4393851161003113, 0.6275069713592529, 0.0, 0.766044557094574, 0.36868777871131897, -0.5265407562255859, 0.0, -0.0, 0.8191521167755127, 0.5735764503479004, 0.0, 2.384185791015625e-07, 2.384185791015625e-07, -5.000000476837158, 1.0]
-projMat = [0.7499999403953552, 0.0, 0.0, 0.0, 0.0, 1.0, 0.0, 0.0, 0.0, 0.0, -1.0000200271606445, -1.0, 0.0, 0.0, -0.02000020071864128, 0.0]
-images = p.getCameraImage(width, height, viewMatrix = viewMat, projectionMatrix = projMat, renderer=p.ER_BULLET_HARDWARE_OPENGL, flags=p.ER_USE_PROJECTIVE_TEXTURE, projectiveTextureView=viewMat, projectiveTextureProj=projMat)
-proj_opengl= np.reshape(images[2], (height, width, 4))*1./255.
+viewMat = [
+    0.642787516117096, -0.4393851161003113, 0.6275069713592529, 0.0, 0.766044557094574,
+    0.36868777871131897, -0.5265407562255859, 0.0, -0.0, 0.8191521167755127, 0.5735764503479004,
+    0.0, 2.384185791015625e-07, 2.384185791015625e-07, -5.000000476837158, 1.0
+]
+projMat = [
+    0.7499999403953552, 0.0, 0.0, 0.0, 0.0, 1.0, 0.0, 0.0, 0.0, 0.0, -1.0000200271606445, -1.0,
+    0.0, 0.0, -0.02000020071864128, 0.0
+]
+images = p.getCameraImage(width,
+                          height,
+                          viewMatrix=viewMat,
+                          projectionMatrix=projMat,
+                          renderer=p.ER_BULLET_HARDWARE_OPENGL,
+                          flags=p.ER_USE_PROJECTIVE_TEXTURE,
+                          projectiveTextureView=viewMat,
+                          projectiveTextureProj=projMat)
+proj_opengl = np.reshape(images[2], (height, width, 4)) * 1. / 255.
 time.sleep(1)

-images = p.getCameraImage(width, height, viewMatrix = viewMat, projectionMatrix = projMat, renderer=p.ER_TINY_RENDERER, flags=p.ER_USE_PROJECTIVE_TEXTURE, projectiveTextureView=viewMat, projectiveTextureProj=projMat)
-proj_tiny= np.reshape(images[2], (height, width, 4))*1./255.
+images = p.getCameraImage(width,
+                          height,
+                          viewMatrix=viewMat,
+                          projectionMatrix=projMat,
+                          renderer=p.ER_TINY_RENDERER,
+                          flags=p.ER_USE_PROJECTIVE_TEXTURE,
+                          projectiveTextureView=viewMat,
+                          projectiveTextureProj=projMat)
+proj_tiny = np.reshape(images[2], (height, width, 4)) * 1. / 255.

 # Plot both images - should show depth values of 0.45 over the cube and 0.5 over the plane
 plt.subplot(4, 2, 1)
@@ -71,30 +98,29 @@ plt.subplot(4, 2, 2)
 plt.imshow(depth_tiny, cmap='gray', vmin=0, vmax=1)
 plt.title('Depth TinyRenderer')

-plt.subplot(4,2,3)
+plt.subplot(4, 2, 3)
 plt.imshow(rgb_opengl)
 plt.title('RGB OpenGL3')

-plt.subplot(4,2,4)
+plt.subplot(4, 2, 4)
 plt.imshow(rgb_tiny)
 plt.title('RGB Tiny')

-plt.subplot(4,2,5)
+plt.subplot(4, 2, 5)
 plt.imshow(seg_opengl)
 plt.title('Seg OpenGL3')

-plt.subplot(4,2,6)
+plt.subplot(4, 2, 6)
 plt.imshow(seg_tiny)
 plt.title('Seg Tiny')

-plt.subplot(4,2,7)
+plt.subplot(4, 2, 7)
 plt.imshow(proj_opengl)
 plt.title('Proj OpenGL')

-plt.subplot(4,2,8)
+plt.subplot(4, 2, 8)
 plt.imshow(proj_tiny)
 plt.title('Proj Tiny')
 plt.subplots_adjust(hspace=0.7)

-
 plt.show()