Commit 911d16a4 authored by Whitham D. Reeve II's avatar Whitham D. Reeve II

Direction cone speed improvements.

This code commits draw_direction_cone_mesh which is an adaptation of draw_direction_cone to generate a mesh of triangles for compression inside a vertex buffer object. The rest of the opengl code in Toolpath has been changed to use this. Only remaining use of old rendering path way is simulation.

Whitham D. Reeve II
parent 976a0111
...@@ -22,6 +22,8 @@ along with PyCAM. If not, see <http://www.gnu.org/licenses/>. ...@@ -22,6 +22,8 @@ along with PyCAM. If not, see <http://www.gnu.org/licenses/>.
import pycam.Plugins import pycam.Plugins
import pycam.Gui.OpenGLTools import pycam.Gui.OpenGLTools
import pycam.Utils.log
log = pycam.Utils.log.get_logger()
class OpenGLViewToolpath(pycam.Plugins.PluginBase): class OpenGLViewToolpath(pycam.Plugins.PluginBase):
...@@ -76,6 +78,8 @@ class OpenGLViewToolpath(pycam.Plugins.PluginBase): ...@@ -76,6 +78,8 @@ class OpenGLViewToolpath(pycam.Plugins.PluginBase):
for toolpath in self.core.get("toolpaths").get_visible(): for toolpath in self.core.get("toolpaths").get_visible():
moves = toolpath.get_moves_for_opengl(self.core.get("gcode_safety_height")) moves = toolpath.get_moves_for_opengl(self.core.get("gcode_safety_height"))
self._draw_toolpath_moves2(moves) self._draw_toolpath_moves2(moves)
#moves = toolpath.get_moves(self.core.get("gcode_safety_height"))
#self._draw_toolpath_moves(moves)
def _draw_toolpath_moves2(self, paths): def _draw_toolpath_moves2(self, paths):
GL = self._GL GL = self._GL
...@@ -91,19 +95,18 @@ class OpenGLViewToolpath(pycam.Plugins.PluginBase): ...@@ -91,19 +95,18 @@ class OpenGLViewToolpath(pycam.Plugins.PluginBase):
GL.glEnableClientState(GL.GL_VERTEX_ARRAY) GL.glEnableClientState(GL.GL_VERTEX_ARRAY)
GL.glVertexPointerf(coords) GL.glVertexPointerf(coords)
for path in paths[1]: for path in paths[1]:
if path[1]: if path[2]:
GL.glColor4f(color_rapid["red"], color_rapid["green"], color_rapid["blue"], color_rapid["alpha"]) GL.glColor4f(color_rapid["red"], color_rapid["green"], color_rapid["blue"], color_rapid["alpha"])
else: else:
GL.glColor4f(color_cut["red"], color_cut["green"], color_cut["blue"], color_cut["alpha"]) GL.glColor4f(color_cut["red"], color_cut["green"], color_cut["blue"], color_cut["alpha"])
if show_directions:
GL.glDisable(GL.GL_CULL_FACE)
GL.glDrawElements(GL.GL_TRIANGLES, len(path[1]), GL.GL_UNSIGNED_INT, path[1])
GL.glEnable(GL.GL_CULL_FACE)
GL.glDrawElements(GL.GL_LINE_STRIP, len(path[0]), GL.GL_UNSIGNED_INT, path[0]) GL.glDrawElements(GL.GL_LINE_STRIP, len(path[0]), GL.GL_UNSIGNED_INT, path[0])
finally: finally:
coords.unbind() coords.unbind()
if show_directions:
for index in range(len(moves)):
pycam.Gui.OpenGLTools.draw_direction_cone(paths[index][0][0], paths[index + 1][0][0])
## Dead code, remove at some time ## Dead code, remove at some time
def _draw_toolpath_moves(self, moves): def _draw_toolpath_moves(self, moves):
GL = self._GL GL = self._GL
...@@ -139,4 +142,3 @@ class OpenGLViewToolpath(pycam.Plugins.PluginBase): ...@@ -139,4 +142,3 @@ class OpenGLViewToolpath(pycam.Plugins.PluginBase):
p1 = moves[index][0] p1 = moves[index][0]
p2 = moves[index + 1][0] p2 = moves[index + 1][0]
pycam.Gui.OpenGLTools.draw_direction_cone(p1, p2) pycam.Gui.OpenGLTools.draw_direction_cone(p1, p2)
...@@ -32,7 +32,10 @@ from pycam.Geometry.Line import Line ...@@ -32,7 +32,10 @@ from pycam.Geometry.Line import Line
from pycam.Geometry.utils import number, epsilon from pycam.Geometry.utils import number, epsilon
import random import random
import os import os
import math
from itertools import groupby from itertools import groupby
import pycam.Utils.log
log = pycam.Utils.log.get_logger()
def _check_colinearity(p1, p2, p3): def _check_colinearity(p1, p2, p3):
v1 = pnormalized(psub(p2, p1)) v1 = pnormalized(psub(p2, p1))
...@@ -221,6 +224,40 @@ class Toolpath(object): ...@@ -221,6 +224,40 @@ class Toolpath(object):
result.append(p_last_safety, True) result.append(p_last_safety, True)
return result.moves return result.moves
def _rotate_point(self, rp, sp, v, angle):
x = (sp[0] * (v[1] ** 2 + v[2] ** 2) - v[0] * (sp[1] * v[1] + sp[2] * v[2] - v[0] * rp[0] - v[1] * rp[1] - v[2] * rp[2])) * (1 - math.cos(angle)) + rp[0] * math.cos(angle) + (-sp[2] * v[1] + sp[1] * v[2] - v[2] * rp[1] + v[1] * rp[2]) * math.sin(angle)
y = (sp[1] * (v[0] ** 2 + v[2] ** 2) - v[1] * (sp[0] * v[0] + sp[2] * v[2] - v[0] * rp[0] - v[1] * rp[1] - v[2] * rp[2])) * (1 - math.cos(angle)) + rp[1] * math.cos(angle) + (sp[2] * v[0] - sp[0] * v[2] + v[2] * rp[0] - v[0] * rp[2]) * math.sin(angle)
z = (sp[2] * (v[0] ** 2 + v[1] ** 2) - v[2] * (sp[0] * v[0] + sp[1] * v[1] - v[0] * rp[0] - v[1] * rp[1] - v[2] * rp[2])) * (1 - math.cos(angle)) + rp[2] * math.cos(angle) + (-sp[1] * v[0] + sp[0] * v[1] - v[1] * rp[0] + v[0] * rp[1]) * math.sin(angle)
return (x,y,z)
def draw_direction_cone_mesh(self, p1, p2, position=0.5, precision=12, size=0.1):
distance = psub(p2, p1)
length = pnorm(distance)
direction = pnormalized(distance)
if direction is None:
# zero-length line
return []
cone_length = length * size
cone_radius = cone_length / 3.0
bottom = padd(p1, pmul(psub(p2, p1), position - size/2))
top = padd(p1, pmul(psub(p2, p1), position + size/2))
#generate a a line perpendicular to this line, cross product is good at this
cross = pcross(direction, (0, 0, -1))
conepoints = []
if pnorm(cross) != 0:
# The line direction is not in line with the z axis.
conep1 = padd(bottom, pmul(cross, cone_radius))
conepoints = [ self._rotate_point(conep1, bottom, direction, x) for x in numpy.linspace(0, 2*math.pi, precision)]
else:
# Z axis
# just add cone radius to the x axis and rotate the point
conep1 = (bottom[0] + cone_radius, bottom[1], bottom[2])
conepoints = [ self._rotate_point(conep1, p1, direction, x) for x in numpy.linspace(0, 2*math.pi, precision)]
triangles = [(top, conepoints[idx], conepoints[idx + 1]) for idx in range ( len(conepoints) - 1)]
return triangles
def get_moves_for_opengl(self, safety_height): def get_moves_for_opengl(self, safety_height):
if self.opengl_safety_height != safety_height: if self.opengl_safety_height != safety_height:
self.make_moves_for_opengl(safety_height) self.make_moves_for_opengl(safety_height)
...@@ -234,6 +271,8 @@ class Toolpath(object): ...@@ -234,6 +271,8 @@ class Toolpath(object):
store_vertices = {} store_vertices = {}
vertices = [] vertices = []
for path in self.opengl_lines: for path in self.opengl_lines:
# compress the lines into a centeral array containing all the vertices
# generate a matching index for each line
indices = [] indices = []
for point in path[0]: for point in path[0]:
if not point in store_vertices: if not point in store_vertices:
...@@ -241,9 +280,26 @@ class Toolpath(object): ...@@ -241,9 +280,26 @@ class Toolpath(object):
vertices.insert(store_vertices[point], point) vertices.insert(store_vertices[point], point)
index += 1 index += 1
indices.append(store_vertices[point]) indices.append(store_vertices[point])
#this list comprehension removes consecutive duplicate points. # this list comprehension removes consecutive duplicate points.
indices = array([x[0] for x in groupby(indices)],dtype=numpy.int32) indices = array([x[0] for x in groupby(indices)],dtype=numpy.int32)
output.append((indices, path[1])) # generate mesh for each direction cone
# also put these vertices in the vertex array above
# also generate indices for each triangle
triangles = []
for idx in range(len(path[0]) - 1):
some_triangles = self.draw_direction_cone_mesh(path[0][idx], path[0][idx + 1])
for triangle in some_triangles:
triangles.append(triangle)
triangle_indices = []
for t in triangles:
for p in t:
if not p in store_vertices:
store_vertices[p] = index
vertices.insert(store_vertices[p], p)
index += 1
triangle_indices.append(store_vertices[p])
triangle_indices = array(triangle_indices, dtype=numpy.int32)
output.append((indices, triangle_indices, path[1]))
vertices = array(vertices,dtype=numpy.float32) vertices = array(vertices,dtype=numpy.float32)
coords = vbo.VBO(vertices) coords = vbo.VBO(vertices)
self.opengl_coords = coords self.opengl_coords = coords
......
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