ronghanghu/geometry.py

## geometry.py
import matplotlib.pyplot as plt
import os.path as osp
import numpy as np

angle_inc = np.pi / 6.


def print_bbox(bbox):
    x1, y1, x2, y2 = bbox
    plt.plot([x1, x2, x2, x1, x1], [y1, y1, y2, y2, y1], 'r-')
    return True


def bbox2para(bbox):
    x1, y1, x2, y2 = bbox
    return (x1, y1), (x2, y1), (x2, y2), (x1, y2)


def print_para(para, skip_outlier=False, width=None, height=None, color='r', circular=False, **kwargs):
    if skip_outlier:
        for x, y in para:
            if x < 0 or x > width or y < 0 or y > height:
                return False

    (x1, y1), (x2, y2), (x3, y3), (x4, y4) = para
    if circular:
        if x1 < 0 or x2 < 0 or x3 < 0 or x4 < 0:
            para = (x1+width, y1), (x2+width, y2), (x3+width, y3), (x4+width, y4)
            print_para(para, skip_outlier, width, height, color, False, **kwargs)
        elif x1 >= width or x2 >= width or x3 >= width or x4 >= width:
            para = (x1-width, y1), (x2-width, y2), (x3-width, y3), (x4-width, y4)
            print_para(para, skip_outlier, width, height, color, False, **kwargs)

    plt.plot([x1, x2, x3, x4, x1], [y1, y2, y3, y4, y1], color, **kwargs)
    return True


def _canonical_angle(x):
    ''' Make angle in (-pi, +pi) '''
    return x - 2 * np.pi * round(x / (2 * np.pi))


def _adjust_elevation(h, e, delta_e):
    y = -np.sin(e)
    x = np.cos(e)*np.sin(h)
    z = np.cos(e)*np.cos(h)
    ee = -np.arctan2(y, z)
    hh = np.arcsin(x)

    ee += delta_e

    x = np.sin(hh)
    y = -np.cos(hh) * np.sin(ee)
    z = np.cos(hh) * np.cos(ee)
    h_new = np.arctan2(x, z)
    e_new = -np.arcsin(y)
    return h_new, e_new


def map_para2angles(para, viewIndex, width, height, depth):
    base_heading = (viewIndex % 12) * angle_inc
    base_elevation = (viewIndex // 12 - 1) * angle_inc

    angles = [None]*4
    for n, (X, Y) in enumerate(para):
        x = X - width/2.
        y = Y - height/2.
        z = depth
        r = np.sqrt(x**2 + y**2 + z**2)

        rel_heading = np.arctan2(x, z)
        rel_elevation = - np.arcsin(y / r)

        heading, elevation = _adjust_elevation(
            rel_heading, rel_elevation, base_elevation)
        heading = _canonical_angle(base_heading + heading)
        angles[n] = heading, elevation
    return tuple(angles)


def map_angles2para(angles, viewIndex, width, height, depth):
    base_heading = (viewIndex % 12) * angle_inc
    base_elevation = (viewIndex // 12 - 1) * angle_inc

    paras = [None]*4
    for n, (heading, elevation) in enumerate(angles):
        heading = _canonical_angle(heading - base_heading)
        rel_heading, rel_elevation = _adjust_elevation(
            heading, elevation, -base_elevation)
        # Check whether the point is in the half-sphere (visible)
        if rel_heading <= -np.pi/2 or rel_heading > np.pi/2:
            return None, False

        z = depth
        x = z * np.tan(rel_heading)
        y = -np.tan(rel_elevation) * np.sqrt(x**2 + z**2)
        X = x + width/2.
        Y = y + height/2.
        paras[n] = X, Y
    return tuple(paras), True


def gen_panorama_img(scanId, viewpointId, agent_heading=0, vfov_deg=90,
                     hfov_deg=10, height=480):
    import sys; sys.path.append(osp.join(osp.dirname(__file__), '../../build'))  # NoQA
    import MatterSim

    assert 360 % hfov_deg == 0, 'hfov_deg must be a factor of 360'
    HEIGHT = height
    VFOV = np.radians(vfov_deg)
    HFOV = np.radians(hfov_deg)
    DEPTH = (HEIGHT/2.) / np.tan(VFOV/2.)
    WIDTH = int(np.round(2.*DEPTH*np.tan(HFOV/2.)))

    num_headings = int(360/hfov_deg) + 1
    pano_img = np.zeros(
        (HEIGHT, WIDTH*num_headings, 3), np.uint8)
    sim = MatterSim.Simulator()
    sim.setCameraResolution(WIDTH, HEIGHT)
    sim.setCameraVFOV(VFOV)
    sim.init()
    for n_heading in range(num_headings):
        heading = agent_heading+np.radians(n_heading*hfov_deg-180)
        sim.newEpisode(scanId, viewpointId, heading, 0)
        state = sim.getState()
        im = state.rgb
        X_begin = WIDTH*n_heading
        X_end = X_begin+WIDTH
        pano_img[:, X_begin:X_end, :] = im[..., ::-1]
    pano_img = pano_img[:, WIDTH//2:-WIDTH//2, :]
    return pano_img


def rotate_panorama_img(img, new_agent_heading, old_agent_heading=0):
    img_new = np.zeros_like(img)
    rotation = _canonical_angle(new_agent_heading - old_agent_heading)
    split_X = int(np.round(img.shape[1] * rotation / (2*np.pi)))
    if split_X == 0:
        img_new[...] = img
    else:
        img_new[:, -split_X:, :] = img[:, :split_X, :]
        img_new[:, :-split_X, :] = img[:, split_X:, :]
    return img_new


def map_angles_onto_panorama(
        angles, width, height, agent_heading=0, vfov_deg=90):
    VFOV = np.radians(vfov_deg)
    depth = (height/2.) / np.tan(VFOV/2.)

    paras = [None]*4

    base_heading = max(_canonical_angle(a[0] - agent_heading) for a in angles)
    base_X = width * (base_heading + np.pi) / (2*np.pi)
    for n, (heading, elevation) in enumerate(angles):
        X = base_X + width * _canonical_angle(
                heading - agent_heading - base_heading) / (np.pi*2)
        Y = height/2. - depth * np.tan(elevation)
        paras[n] = X, Y

    return paras

## visualize_panorama_bottom-up_detections.ipynb

      
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	import matplotlib.pyplot as plt
	import os.path as osp
	import numpy as np

	angle_inc = np.pi / 6.


	def print_bbox(bbox):
	x1, y1, x2, y2 = bbox
	plt.plot([x1, x2, x2, x1, x1], [y1, y1, y2, y2, y1], 'r-')
	return True


	def bbox2para(bbox):
	x1, y1, x2, y2 = bbox
	return (x1, y1), (x2, y1), (x2, y2), (x1, y2)


	def print_para(para, skip_outlier=False, width=None, height=None, color='r', circular=False, **kwargs):
	if skip_outlier:
	for x, y in para:
	if x < 0 or x > width or y < 0 or y > height:
	return False

	(x1, y1), (x2, y2), (x3, y3), (x4, y4) = para
	if circular:
	if x1 < 0 or x2 < 0 or x3 < 0 or x4 < 0:
	para = (x1+width, y1), (x2+width, y2), (x3+width, y3), (x4+width, y4)
	print_para(para, skip_outlier, width, height, color, False, **kwargs)
	elif x1 >= width or x2 >= width or x3 >= width or x4 >= width:
	para = (x1-width, y1), (x2-width, y2), (x3-width, y3), (x4-width, y4)
	print_para(para, skip_outlier, width, height, color, False, **kwargs)

	plt.plot([x1, x2, x3, x4, x1], [y1, y2, y3, y4, y1], color, **kwargs)
	return True


	def _canonical_angle(x):
	''' Make angle in (-pi, +pi) '''
	return x - 2 * np.pi * round(x / (2 * np.pi))


	def _adjust_elevation(h, e, delta_e):
	y = -np.sin(e)
	x = np.cos(e)*np.sin(h)
	z = np.cos(e)*np.cos(h)
	ee = -np.arctan2(y, z)
	hh = np.arcsin(x)

	ee += delta_e

	x = np.sin(hh)
	y = -np.cos(hh) * np.sin(ee)
	z = np.cos(hh) * np.cos(ee)
	h_new = np.arctan2(x, z)
	e_new = -np.arcsin(y)
	return h_new, e_new


	def map_para2angles(para, viewIndex, width, height, depth):
	base_heading = (viewIndex % 12) * angle_inc
	base_elevation = (viewIndex // 12 - 1) * angle_inc

	angles = [None]*4
	for n, (X, Y) in enumerate(para):
	x = X - width/2.
	y = Y - height/2.
	z = depth
	r = np.sqrt(x2 + y2 + z**2)

	rel_heading = np.arctan2(x, z)
	rel_elevation = - np.arcsin(y / r)

	heading, elevation = _adjust_elevation(
	rel_heading, rel_elevation, base_elevation)
	heading = _canonical_angle(base_heading + heading)
	angles[n] = heading, elevation
	return tuple(angles)


	def map_angles2para(angles, viewIndex, width, height, depth):
	base_heading = (viewIndex % 12) * angle_inc
	base_elevation = (viewIndex // 12 - 1) * angle_inc

	paras = [None]*4
	for n, (heading, elevation) in enumerate(angles):
	heading = _canonical_angle(heading - base_heading)
	rel_heading, rel_elevation = _adjust_elevation(
	heading, elevation, -base_elevation)
	# Check whether the point is in the half-sphere (visible)
	if rel_heading <= -np.pi/2 or rel_heading > np.pi/2:
	return None, False

	z = depth
	x = z * np.tan(rel_heading)
	y = -np.tan(rel_elevation) * np.sqrt(x2 + z2)
	X = x + width/2.
	Y = y + height/2.
	paras[n] = X, Y
	return tuple(paras), True


	def gen_panorama_img(scanId, viewpointId, agent_heading=0, vfov_deg=90,
	hfov_deg=10, height=480):
	import sys; sys.path.append(osp.join(osp.dirname(__file__), '../../build')) # NoQA
	import MatterSim

	assert 360 % hfov_deg == 0, 'hfov_deg must be a factor of 360'
	HEIGHT = height
	VFOV = np.radians(vfov_deg)
	HFOV = np.radians(hfov_deg)
	DEPTH = (HEIGHT/2.) / np.tan(VFOV/2.)
	WIDTH = int(np.round(2.DEPTHnp.tan(HFOV/2.)))

	num_headings = int(360/hfov_deg) + 1
	pano_img = np.zeros(
	(HEIGHT, WIDTH*num_headings, 3), np.uint8)
	sim = MatterSim.Simulator()
	sim.setCameraResolution(WIDTH, HEIGHT)
	sim.setCameraVFOV(VFOV)
	sim.init()
	for n_heading in range(num_headings):
	heading = agent_heading+np.radians(n_heading*hfov_deg-180)
	sim.newEpisode(scanId, viewpointId, heading, 0)
	state = sim.getState()
	im = state.rgb
	X_begin = WIDTH*n_heading
	X_end = X_begin+WIDTH
	pano_img[:, X_begin:X_end, :] = im[..., ::-1]
	pano_img = pano_img[:, WIDTH//2:-WIDTH//2, :]
	return pano_img


	def rotate_panorama_img(img, new_agent_heading, old_agent_heading=0):
	img_new = np.zeros_like(img)
	rotation = _canonical_angle(new_agent_heading - old_agent_heading)
	split_X = int(np.round(img.shape[1] * rotation / (2*np.pi)))
	if split_X == 0:
	img_new[...] = img
	else:
	img_new[:, -split_X:, :] = img[:, :split_X, :]
	img_new[:, :-split_X, :] = img[:, split_X:, :]
	return img_new


	def map_angles_onto_panorama(
	angles, width, height, agent_heading=0, vfov_deg=90):
	VFOV = np.radians(vfov_deg)
	depth = (height/2.) / np.tan(VFOV/2.)

	paras = [None]*4

	base_heading = max(_canonical_angle(a[0] - agent_heading) for a in angles)
	base_X = width * (base_heading + np.pi) / (2*np.pi)
	for n, (heading, elevation) in enumerate(angles):
	X = base_X + width * _canonical_angle(
	heading - agent_heading - base_heading) / (np.pi*2)
	Y = height/2. - depth * np.tan(elevation)
	paras[n] = X, Y

	return paras