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18
README.md
18
README.md
@ -9,18 +9,11 @@ particles overlap.
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Run with
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```bash
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./src/jam [configuration_file] [-L lattice]
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./src/jam [configuration_file]
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```
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* `[configuration_file]` is an optional argument that specifies a file with
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where `[configuration_file]` is an optional argument that specifies a file with
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a list of particle positions that will be loaded on initial execution.
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* `[-L lattice]` is an optional argument that specifies a background grid that
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constrains the position of the particles. So far, the `lattice` argument must
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be `square` for the square lattice, or, to specify the unit length of the
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lattice: `square:<unit_length>`.
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# Dependencies
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@ -66,8 +59,11 @@ Commands can be executed by typing `:` (similarly to vim).
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# Current developments
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So far, Jam supports particles made of combinations of rectangles, but there is
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no infrastructure to set the shape of the particle at runtime.
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So far, Jam only supports cross-shaped particles, but work is in progress to
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support arbitrary shapes consisting of rectangles, circle arcs and triangles
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(check out the `dev` branch to follow the progress).
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Support for lattice configurations is also ongoing.
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# License
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18
TeX/jam.sty
18
TeX/jam.sty
@ -28,21 +28,3 @@
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\fill[color=#1]#2++(0.5,0.5)--++(0,1)--++(-1,0)--++(0,-1)--++(-1,0)--++(0,-1)--++(1,0)--++(0,-1)--++(1,0)--++(0,1)--++(1,0)--++(0,1)--++(-1,0);
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\draw[color=black]#2++(0.5,0.5)--++(0,1)--++(-1,0)--++(0,-1)--++(-1,0)--++(0,-1)--++(1,0)--++(0,-1)--++(1,0)--++(0,1)--++(1,0)--++(0,1)--++(-1,0);
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}
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% 3-staircase (color #1, position #2)
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\def\staircase#1#2{
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\fill[color=#1]#2++(-0.5,-0.5)--++(3,0)--++(0,1)--++(-1,0)--++(0,1)--++(-1,0)--++(0,1)--++(-1,0)--++(0,-3);
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\draw[color=black]#2++(-0.5,-0.5)--++(3,0)--++(0,1)--++(-1,0)--++(0,1)--++(-1,0)--++(0,1)--++(-1,0)--++(0,-3);
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}
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% disk (color #1, position #2)
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\def\disk#1#2{
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\fill[color=#1]#2circle(2.5);
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\draw[color=black]#2circle(2.5);
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}
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% square (color #1, position #2)
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\def\square#1#2{
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\fill[color=#1]#2++(-1,-1)--++(0,2)--++(2,0)--++(0,-2)--cycle;
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\draw[color=black]#2++(-1,-1)--++(0,2)--++(2,0)--++(0,-2)--cycle;
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}
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@ -20,7 +20,6 @@ import os.path
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import filecheck
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import colors
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from polyomino import Cross,Disk,Staircase,Square2
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class Command_prompt(Label):
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@ -339,15 +338,9 @@ class Command_prompt(Label):
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if argv[1]=="color":
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self.run_set_color(argv)
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return
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elif argv[1]=="shape":
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self.run_set_shape(argv)
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return
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elif argv[1]=="grid":
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self.run_set_grid(argv)
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return
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elif argv[1]=="voronoi":
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self.run_set_voronoi(argv)
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return
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elif argv[1]=="zoom":
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self.run_set_zoom(argv)
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else:
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@ -379,23 +372,6 @@ class Command_prompt(Label):
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return
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self.app.painter.set_color(color)
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# set particle shape
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def run_set_shape(self,argv):
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if len(argv)<3:
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self.message="error: 'set shape' command was run with without an argument -- usage: 'set shape <shape_descriptor>'"
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return
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elif argv[2]=="cross":
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self.app.painter.shape=Cross
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elif argv[2]=="disk":
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self.app.painter.shape=Disk
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elif argv[2]=="staircase":
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self.app.painter.shape=Staircase
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elif argv[2]=="2square":
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self.app.painter.shape=Square2
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else:
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self.message="error: unrecognized shape '"+argv[2]+"'; supported shapes are cross|disk"
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return
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# toggle grid
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def run_set_grid(self,argv):
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if len(argv)==2:
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@ -416,19 +392,6 @@ class Command_prompt(Label):
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return
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self.app.painter.set_grid(mesh)
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# toggle Voronoi cells
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def run_set_voronoi(self,argv):
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if len(argv)==2:
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# no argument: set to toggle
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self.app.painter.set_voronoi(-1)
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elif argv[2]=="on":
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self.app.painter.set_voronoi(1)
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elif argv[2]=="off":
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self.app.painter.set_voronoi(0)
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else:
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self.message="error: unrecognized argument '"+argv[2]+"' -- usage 'set voronoi [on|off]'"
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return
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# set zoom level (changes size of elements)
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def run_set_zoom(self,argv):
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if len(argv)==2:
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297
src/element.py
297
src/element.py
@ -1,297 +0,0 @@
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# Copyright 2021-2023 Ian Jauslin
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#
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# Licensed under the Apache License, Version 2.0 (the "License");
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# you may not use this file except in compliance with the License.
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# You may obtain a copy of the License at
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#
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# http://www.apache.org/licenses/LICENSE-2.0
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#
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# Unless required by applicable law or agreed to in writing, software
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# distributed under the License is distributed on an "AS IS" BASIS,
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# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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# See the License for the specific language governing permissions and
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# limitations under the License.
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## elements that polyominoes are made of
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import math
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import sys
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from point import Point,l_infinity,l_2
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from tools import isint_nonzero,sgn,in_interval,ceil_grid,floor_grid
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from kivy.graphics import Rectangle,Ellipse,Line
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# parent class of all elements
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class Element():
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def __init__(self,x,y,size,**kwargs):
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self.pos=Point(x,y)
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self.size=size
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# set position
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def setpos(self,x,y):
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self.pos.x=x
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self.pos.y=y
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# override in each subclass
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# draw element
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def draw(self,painter):
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return
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# override in each subclass
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# draw boundary
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def stroke(self,painter):
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return
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# override in each subclass
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# check whether an element interacts with square
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def check_interaction(self,element):
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return False
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# override in each subclass
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# whether x is in the support of the element
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def in_support(self,x):
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return False
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# override in each subclass
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# check whether an element is touching self
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def check_touch(self,element):
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return False
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# override in each subclass
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# find position along a line that comes in contact with the line going through element.pos in direction v
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def move_on_line_to_stick(self,element,v):
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return Point(0,0)
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# override in each subclass
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# move along edge of element
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# delta is the impossible move that was asked for
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def move_along(self,delta,element):
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return element
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# rectangular element
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# the size of the y component is specified by an aspect ratio: size_x=size, size_y=size*aspect
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class Element_square(Element):
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def __init__(self,x,y,size,**kwargs):
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self.pos=Point(x,y)
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self.size=size
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self.aspect=kwargs.get("aspect",1.0)
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# draw element
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def draw(self,painter):
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Rectangle(pos=(painter.pos_tocoord_x(self.pos.x-0.5*self.size),painter.pos_tocoord_y(self.pos.y-0.5*self.size*self.aspect)),size=(self.size*painter.base_size,self.size*self.aspect*painter.base_size))
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# draw boundary
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def stroke(self,painter):
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# convert to graphical coordinates
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coordx=painter.pos_tocoord_x(square.pos.x)
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coordy=painter.pos_tocoord_y(square.pos.y)
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Line(points=(
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*(coordx-0.5*self.size*painter.base_size,coordy-0.5*self.size*self.aspect*painter.base_size),
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*(coordx-0.5*self.size*painter.base_size,coordy+0.5*self.size*self.aspect*painter.base_size),
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*(coordx+0.5*self.size*painter.base_size,coordy+0.5*self.size*self.aspect*painter.base_size),
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*(coordx+0.5*self.size*painter.base_size,coordy-0.5*self.size*self.aspect*painter.base_size),
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*(coordx-0.5*self.size*painter.base_size,coordy-0.5*self.size*self.aspect*painter.base_size)
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))
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# for use with lattices
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# list of lattice points covered by square
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def lattice_points(self,lattice):
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out=[]
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dx=math.floor(0.5*self.size/lattice.spacing)
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dy=math.floor(0.5*self.size*self.aspect/lattice.spacing)
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for i in range(-dx,dx+1):
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for j in range(-dy,dy+1):
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out.append(Point(self.pos.x+i*lattice.spacing,self.pos.y+j*lattice.spacing))
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return out
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# check whether an element interacts with square
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# TODO: this only works if element is a rectangle!
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def check_interaction(self,element):
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# allow for error
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return max(abs(element.pos.x-self.pos.x)/(self.size+element.size),abs(element.pos.y-self.pos.y)/(self.size*self.aspect+element.size*element.aspect))<1/2-1e-11
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# whether x is in the support of the element
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def in_support(self,x):
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return max(abs(self.pos.x-x.x),abs(self.pos.y-x.y)/self.aspect)<=1/2
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# check whether an element is touching self
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# TODO: this only works if element is a rectangle!
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def check_touch(self,element):
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# allow for error
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if in_interval(max(abs(element.pos.x-self.pos.x)/(self.size+element.size),abs(element.pos.y-self.pos.y)/(self.size*self.aspect+element.size*element.aspect)),1/2-1e-11,1/2+1e-11):
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return True
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return False
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# find position along a line that comes in contact with the line going through element.pos in direction v
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# TODO: this only works if element is a rectangle!
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def move_on_line_to_stick(self,element,v):
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size_x=(self.size+element.size)/2
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size_y=(self.size*self.aspect+element.size*element.aspect)/2
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# compute intersections with four lines making up square
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if v.x!=0:
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if v.y!=0:
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intersections=[\
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Point(self.pos.x+size_x,element.pos.y+v.y/v.x*(self.pos.x+size_x-element.pos.x)),\
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Point(self.pos.x-size_x,element.pos.y+v.y/v.x*(self.pos.x-size_x-element.pos.x)),\
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Point(element.pos.x+v.x/v.y*(self.pos.y+size_y-element.pos.y),self.pos.y+size_y),\
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Point(element.pos.x+v.x/v.y*(self.pos.y-size_y-element.pos.y),self.pos.y-size_y)\
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]
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else:
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intersections=[\
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Point(self.pos.x+size_x,element.pos.y),\
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Point(self.pos.x-size_x,element.pos.y)
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]
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else:
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if v.y!=0:
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intersections=[\
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Point(element.pos.x,self.pos.y+size_y),\
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Point(element.pos.x,self.pos.y-size_y)\
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]
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else:
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print("error: move_on_line_to_stick called with v=0, please file a bug report with the developer",file=sys.stderr)
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exit(-1)
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# compute closest one, on square
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closest=None
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dist=math.inf
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for i in range(0,len(intersections)):
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# check that it is on square
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if abs(intersections[i].x-self.pos.x)<=size_x+1e-11 and abs(intersections[i].y-self.pos.y)<=size_y+1e-11:
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if (intersections[i]-element.pos)**2<dist:
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closest=intersections[i]
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dist=(intersections[i]-element.pos)**2
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if closest==None:
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print("error: cannot move particle at (",element.pos.x,",",element.pos.y,") to the boundary of (",self.pos.x,",",self.pos.y,") in direction (",v.x,",",v.y,")",file=sys.stderr)
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exit(-1)
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# return difference to pos
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return closest-element.pos
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# move along edge of square
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# TODO: this only works if element is a rectangle!
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def move_along(self,delta,element):
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size_x=(self.size+element.size)/2
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size_y=(self.size*self.aspect+element.size*element.aspect)/2
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rel=element.pos-self.pos
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# check if the particle is stuck in the x direction
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if isint_nonzero(rel.x/size_x):
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# check y direction
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if isint_nonzero(rel.y/size_y):
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# in corner
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if sgn(delta.y)==-sgn(rel.y):
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# stuck in x direction
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return self.move_stuck_x(delta,element)
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elif sgn(delta.x)==-sgn(rel.x):
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# stuck in y direction
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return self.move_stuck_y(delta,element)
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# stuck in both directions
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return element.pos
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else:
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# stuck in x direction
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return self.move_stuck_x(delta,element)
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elif isint_nonzero(rel.y/size_y):
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# stuck in y direction
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return self.move_stuck_y(delta,element)
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# this should never happen
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else:
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print("error: stuck particle has non-integer relative position: (",rel.x,",",rel.y,")",file=sys.stderr)
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exit(-1)
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# move when stuck in the x direction
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def move_stuck_x(self,delta,element):
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size_y=(self.size*self.aspect+element.size*element.aspect)/2
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# only move in y direction
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candidate=Point(0,delta.y)
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# do not move past corners
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rel=element.pos.y-self.pos.y
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if delta.y>0:
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if rel<ceil_grid(rel,size_y)-1e-11 and delta.y+rel>ceil_grid(rel,size_y)+1e-11 and ceil_grid(rel,size_y)!=0:
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# stick to corner
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candidate.y=ceil_grid(rel,size_y)+self.pos.y-element.pos.y
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else:
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if rel>floor_grid(rel,size_y)+1e-11 and delta.y+rel<floor_grid(rel,size_y)-1e-11 and floor_grid(rel,size_y)!=0:
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# stick to corner
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candidate.y=floor_grid(rel,size_y)+self.pos.y-element.pos.y
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return candidate
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# move when stuck in the y direction
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def move_stuck_y(self,delta,element):
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size_x=(self.size+element.size)/2
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# onlx move in x direction
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candidate=Point(delta.x,0)
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# do not move past corners
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rel=element.pos.x-self.pos.x
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if delta.x>0:
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if rel<ceil_grid(rel,size_x)-1e-11 and delta.x+rel>ceil_grid(rel,size_x)+1e-11 and ceil_grid(rel,size_x)!=0:
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# stick to corner
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candidate.x=ceil_grid(rel,size_x)+self.pos.x-element.pos.x
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else:
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if rel>floor_grid(rel,size_x)+1e-11 and delta.x+rel<floor_grid(rel,size_x)-1e-11 and floor_grid(rel,size_x)!=0:
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# stick to corner
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candidate.x=floor_grid(rel,size_x)+self.pos.x-element.pos.x
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return candidate
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# circular elements
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# (size is the diameter)
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class Element_circle(Element):
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# draw element
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def draw(self,painter):
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Ellipse(pos=(painter.pos_tocoord_x(self.pos.x-0.5*self.size),painter.pos_tocoord_y(self.pos.y-0.5*self.size)),size=(self.size*painter.base_size,self.size*painter.base_size))
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# draw boundary
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def stroke(self,painter):
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Line(circle=(painter.pos_tocoord_x(self.pos.x),painter.pos_tocoord_y(self.pos.y),self.size*0.5*painter.base_size))
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# check whether an element interacts with square
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# TODO: this only works if element is a circle!
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def check_interaction(self,element):
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# allow for error
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return l_2(element.pos-self.pos)<(self.size+element.size)/2-1e-11
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# whether x is in the support of the element
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def in_support(self,x):
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return l_2(self.pos-x)<=1/2
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# check whether an element is touching self
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# TODO: this only works if element is a circle!
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def check_touch(self,element):
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# allow for error
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if in_interval(l_2(element.pos-self.pos),(self.size+element.size)/2-1e-11,(self.size+element.size)/2+1e-11):
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return True
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return False
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# find position along a line that comes in contact with the line going through element.pos in direction v
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# TODO: this only works if element is a circle!
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def move_on_line_to_stick(self,element,v):
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# relative position
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x=element.pos-self.pos
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# radius of collision circle
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R=(element.size+self.size)/2
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# smallest root of t^2 v^2+2x.v t+x^2-R^2
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t=(-v.dot(x)-math.sqrt(v.dot(x)*v.dot(x)-v.dot(v)*(x.dot(x)-R*R)))/v.dot(v)
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# return difference to pos
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return v*t
|
||||
|
||||
# move along edge of circle
|
||||
# TODO: this only works if element is a circle!
|
||||
def move_along(self,delta,element):
|
||||
x=element.pos-self.pos+delta
|
||||
return x/l_2(x)*(element.size+self.size)/2+self.pos-element.pos
|
||||
|
||||
# for use with lattices
|
||||
# list of lattice points covered by square
|
||||
def lattice_points(self,lattice):
|
||||
out=[]
|
||||
dx=math.floor(0.5*self.size/lattice.spacing)
|
||||
for i in range(-dx,dx+1):
|
||||
for j in range(-dx,dx+1):
|
||||
if lattice.spacing*lattice.spacing*(i*i+j*j)<=self.size*self.size/4:
|
||||
out.append(Point(self.pos.x+i*lattice.spacing,self.pos.y+j*lattice.spacing))
|
||||
return out
|
||||
|
||||
|
@ -12,8 +12,6 @@
|
||||
# See the License for the specific language governing permissions and
|
||||
# limitations under the License.
|
||||
|
||||
# check that a file is creatable/writable/editable
|
||||
|
||||
import os.path
|
||||
|
||||
# check that a file can be edited
|
||||
|
128
src/jam
128
src/jam
@ -14,119 +14,18 @@
|
||||
# See the License for the specific language governing permissions and
|
||||
# limitations under the License.
|
||||
|
||||
import sys
|
||||
import os.path,os
|
||||
import filecheck
|
||||
from lattice import Lattice
|
||||
|
||||
## read cli before loading kivy, in case there are errors
|
||||
|
||||
# read cli
|
||||
openfile=""
|
||||
lattice=""
|
||||
def read_cli():
|
||||
global openfile
|
||||
global lattice
|
||||
|
||||
# init flag
|
||||
flag=""
|
||||
|
||||
# loop over arguments
|
||||
for arg in sys.argv[1:]:
|
||||
# option flag
|
||||
if arg[0]=='-':
|
||||
# loop over options
|
||||
for c in arg[1:]:
|
||||
# lattice
|
||||
if c=='L':
|
||||
flag="lattice"
|
||||
else:
|
||||
print("error: unrecognized option '"+c+"'\n", file=sys.stderr)
|
||||
exit(-1)
|
||||
|
||||
|
||||
else:
|
||||
# read lattice argument
|
||||
if flag=="lattice":
|
||||
# test the specification
|
||||
(obj,message)=Lattice.new(arg)
|
||||
if obj==None:
|
||||
print(message,file=sys.stderr)
|
||||
exit(-1)
|
||||
lattice=arg
|
||||
# reset flag
|
||||
flag=""
|
||||
|
||||
# no flags
|
||||
else:
|
||||
openfile=arg
|
||||
(ret,message)=filecheck.check_edit(openfile)
|
||||
if ret<0:
|
||||
print(message,file=sys.stderr)
|
||||
exit(-1)
|
||||
preread_conf(openfile)
|
||||
|
||||
# read command line arguments from configuration file
|
||||
def preread_conf(file):
|
||||
global lattice
|
||||
try:
|
||||
ff=open(file,"r")
|
||||
except:
|
||||
return
|
||||
|
||||
# counter
|
||||
i=0
|
||||
try:
|
||||
lines=ff.readlines()
|
||||
except:
|
||||
print("error: could not read the contents of file '"+file+"'", file=sys.stderr)
|
||||
exit(-1)
|
||||
|
||||
for line in lines:
|
||||
i+=1
|
||||
# remove newline
|
||||
line=line[:len(line)-1]
|
||||
# ignore comments
|
||||
if '#' in line:
|
||||
line=line[:line.find('#')]
|
||||
# ignore empty lines
|
||||
if len(line)==0:
|
||||
continue
|
||||
|
||||
# read options
|
||||
if line[0]=='%':
|
||||
# ignore empty line
|
||||
if len(line)==1:
|
||||
continue
|
||||
[key,val]=line[1:].split('=',1)
|
||||
if key=="lattice":
|
||||
# test the specification
|
||||
(obj,message)=Lattice.new(val)
|
||||
if obj==None:
|
||||
print("error: line "+str(i)+" in file '"+file+"': "+message,file=sys.stderr)
|
||||
exit(-1)
|
||||
lattice=val
|
||||
|
||||
ff.close()
|
||||
|
||||
|
||||
# read cli
|
||||
read_cli()
|
||||
|
||||
|
||||
## import kivy
|
||||
|
||||
# disable kivy argument parser
|
||||
os.environ["KIVY_NO_ARGS"] = "1"
|
||||
|
||||
from kivy.app import App
|
||||
from kivy.uix.widget import Widget
|
||||
from kivy.uix.boxlayout import BoxLayout
|
||||
from kivy.config import Config
|
||||
import sys
|
||||
import os.path
|
||||
|
||||
from painter import Painter
|
||||
from status_bar import Status_bar
|
||||
from command_prompt import Command_prompt
|
||||
import filecheck
|
||||
|
||||
# App class
|
||||
class Jam_app(App):
|
||||
@ -137,9 +36,6 @@ class Jam_app(App):
|
||||
# the file open for editing
|
||||
self.openfile=kwargs.get("openfile","")
|
||||
|
||||
# the lattice open for editing
|
||||
self.lattice=kwargs.get("lattice","")
|
||||
|
||||
# readonly mode
|
||||
self.readonly=False
|
||||
|
||||
@ -167,20 +63,24 @@ class Jam_app(App):
|
||||
# set readonly mode
|
||||
self.readonly=not os.access(self.openfile,os.W_OK)
|
||||
|
||||
# load lattice
|
||||
if self.lattice!="":
|
||||
(obj,message)=Lattice.new(self.lattice)
|
||||
self.painter.set_lattice(obj)
|
||||
|
||||
return layout
|
||||
|
||||
|
||||
|
||||
# disable red circles on right click
|
||||
Config.set('input', 'mouse', 'mouse,disable_multitouch')
|
||||
# do not exit on escape
|
||||
Config.set('kivy', 'exit_on_escape', 0)
|
||||
|
||||
# read cli
|
||||
openfile=""
|
||||
if len(sys.argv)==2:
|
||||
openfile=sys.argv[1]
|
||||
# check file
|
||||
(ret,message)=filecheck.check_edit(openfile)
|
||||
if ret<0:
|
||||
print(message,file=sys.stderr)
|
||||
exit(-1)
|
||||
|
||||
# run
|
||||
if __name__ == '__main__':
|
||||
Jam_app(openfile=openfile,lattice=lattice).run()
|
||||
Jam_app(openfile=openfile).run()
|
||||
|
@ -1,94 +0,0 @@
|
||||
# Copyright 2021-2023 Ian Jauslin
|
||||
#
|
||||
# Licensed under the Apache License, Version 2.0 (the "License");
|
||||
# you may not use this file except in compliance with the License.
|
||||
# You may obtain a copy of the License at
|
||||
#
|
||||
# http://www.apache.org/licenses/LICENSE-2.0
|
||||
#
|
||||
# Unless required by applicable law or agreed to in writing, software
|
||||
# distributed under the License is distributed on an "AS IS" BASIS,
|
||||
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
|
||||
# See the License for the specific language governing permissions and
|
||||
# limitations under the License.
|
||||
|
||||
# define background lattices
|
||||
|
||||
from point import Point
|
||||
|
||||
# parent class of all lattices
|
||||
class Lattice():
|
||||
def __init__(self,**kwargs):
|
||||
self.type=kwargs.get("type","")
|
||||
|
||||
# lattice point nearest to point
|
||||
# overwrite in subclasses
|
||||
def nearest(self,point):
|
||||
return point
|
||||
|
||||
# delta to nearest point
|
||||
def nearest_delta(self,point):
|
||||
return self.nearest(point)-point
|
||||
|
||||
# draw lattice
|
||||
# overwrite in subclasses
|
||||
def draw(self,painter):
|
||||
return
|
||||
|
||||
# return the lattice according to a specification
|
||||
def new(spec):
|
||||
specs=spec.split(":")
|
||||
# check type of lattice
|
||||
if specs[0]=="square":
|
||||
return Lattice_square.new_square(specs[1:],spec)
|
||||
else:
|
||||
return(None,"error: unrecognized lattice type: '"+specs[0]+"'")
|
||||
|
||||
|
||||
# square lattice
|
||||
class Lattice_square(Lattice):
|
||||
def __init__(self,**kwargs):
|
||||
|
||||
self.spacing=kwargs.get("spacing",1.)
|
||||
|
||||
super(Lattice_square,self).__init__(**kwargs,type="square")
|
||||
|
||||
# lattice point nearest to point
|
||||
def nearest(self,point):
|
||||
return Point(round(point.x/self.spacing)*self.spacing,round(point.y/self.spacing)*self.spacing)
|
||||
|
||||
# draw
|
||||
def draw(self,painter):
|
||||
painter.draw_grid(Point(self.spacing/2,self.spacing/2),self.spacing)
|
||||
|
||||
# return the lattice according to a specification
|
||||
def new_square(specs,spec):
|
||||
# no optional args
|
||||
if len(specs)==0:
|
||||
return (Lattice_square(),"")
|
||||
if len(specs)>1:
|
||||
return (None,"error: '"+spec+"' is not a valid specification for the square lattice: should be 'square[:spacing]'")
|
||||
try:
|
||||
spacing=float(specs[0])
|
||||
return (Lattice_square(spacing=spacing),"")
|
||||
except:
|
||||
return (None,"error: '"+spec+"' is not a valid specification for the square lattice: should be 'square[:spacing]'")
|
||||
|
||||
# distance on the lattice between (x1,x2) and (y1,y2)
|
||||
def distance(self, x1, x2, y1, y2):
|
||||
return round((abs(x1-y1)+abs(x2-y2))/self.spacing)
|
||||
|
||||
# distance between a lattice site and a particle
|
||||
def distance_to_particle(self, x1, x2, particle):
|
||||
mindist=self.distance_to_element(x1, x2, particle.elements[0])
|
||||
for i in range(1,len(particle.elements)):
|
||||
mindist=min(self.distance_to_element(x1, x2, particle.elements[i]),mindist)
|
||||
return mindist
|
||||
# distance between a lattice site and an element
|
||||
def distance_to_element(self, x1, x2, element):
|
||||
pts=element.lattice_points(self)
|
||||
mindist=self.distance(x1, x2, pts[0].x, pts[0].y)
|
||||
for i in range(1,len(pts)):
|
||||
mindist=min(self.distance(x1, x2, pts[i].x, pts[i].y),mindist)
|
||||
return mindist
|
||||
|
287
src/painter.py
287
src/painter.py
@ -12,16 +12,15 @@
|
||||
# See the License for the specific language governing permissions and
|
||||
# limitations under the License.
|
||||
|
||||
# main drawing class
|
||||
|
||||
import sys
|
||||
import math
|
||||
from kivy.uix.widget import Widget
|
||||
from kivy.core.window import Window
|
||||
from kivy.graphics import Color,Line,Rectangle
|
||||
from kivy.graphics import Color,Line
|
||||
|
||||
from point import Point
|
||||
from polyomino import Cross,Disk,Staircase,Square2
|
||||
from polyomino import Cross
|
||||
from polyomino import Square_element
|
||||
|
||||
from tools import remove_fromlist
|
||||
|
||||
@ -35,15 +34,6 @@ class Painter(Widget):
|
||||
# list of particles
|
||||
self.particles=[]
|
||||
|
||||
# shape of particle to add next
|
||||
self.shape=Cross
|
||||
|
||||
# color of particle to add next
|
||||
self.color=(0,0,1)
|
||||
|
||||
# underlying lattice
|
||||
self.lattice=None
|
||||
|
||||
# particle under mouse
|
||||
self.undermouse=None
|
||||
|
||||
@ -64,9 +54,6 @@ class Painter(Widget):
|
||||
# modifiers
|
||||
self.modifiers=[]
|
||||
|
||||
# base size for all particles
|
||||
self.base_size=50
|
||||
|
||||
# init Widget
|
||||
super(Painter,self).__init__(**kwargs)
|
||||
|
||||
@ -74,38 +61,21 @@ class Painter(Widget):
|
||||
self.keyboard = Window.request_keyboard(None,self,"text")
|
||||
self.keyboard.bind(on_key_down=self.on_key_down,on_key_up=self.on_key_up,on_textinput=self.on_textinput)
|
||||
|
||||
# redraw on resize
|
||||
self.bind(size=lambda obj,value: self.draw())
|
||||
|
||||
|
||||
def reset(self):
|
||||
self.particles=[]
|
||||
self.undermouse=None
|
||||
self.draw()
|
||||
|
||||
# set lattice
|
||||
def set_lattice(self,lattice):
|
||||
self.lattice=lattice
|
||||
|
||||
# draw
|
||||
self.draw()
|
||||
|
||||
# snap all existing particles to grid
|
||||
for particle in self.particles:
|
||||
delta=self.lattice.nearest_delta(particle.elements[0].pos)
|
||||
if not self.check_interaction_any(particle,delta):
|
||||
particle.move(delta)
|
||||
|
||||
|
||||
# convert logical coordinates (normalized and centered) to the ones that are plotted
|
||||
def pos_tocoord_x(self,x):
|
||||
return self.width/2+x*self.base_size
|
||||
return self.width/2+x*Square_element.size
|
||||
def pos_tocoord_y(self,y):
|
||||
return self.height/2+y*self.base_size
|
||||
return self.height/2+y*Square_element.size
|
||||
def coord_topos_x(self,x):
|
||||
return (x-self.width/2)/self.base_size
|
||||
return (x-self.width/2)/Square_element.size
|
||||
def coord_topos_y(self,y):
|
||||
return (y-self.height/2)/self.base_size
|
||||
return (y-self.height/2)/Square_element.size
|
||||
|
||||
|
||||
|
||||
@ -118,20 +88,10 @@ class Painter(Widget):
|
||||
for particle in self.particles:
|
||||
particle.draw(self)
|
||||
|
||||
# draw lattice
|
||||
if self.lattice!=None:
|
||||
self.lattice.draw(self)
|
||||
|
||||
# draw grids
|
||||
for particle in self.particles:
|
||||
if particle.grid>0:
|
||||
self.draw_grid(particle.elements[0].pos,particle.grid)
|
||||
|
||||
# draw Voronoi cells
|
||||
if self.lattice!=None:
|
||||
for particle in self.particles:
|
||||
if particle.voronoi>0:
|
||||
self.draw_voronoi(particle)
|
||||
self.draw_grid(particle.squares[0].pos,particle.grid)
|
||||
|
||||
for particle in self.particles:
|
||||
particle.draw(self,alpha=0.5)
|
||||
@ -141,79 +101,17 @@ class Painter(Widget):
|
||||
# height offset due to status bar and command prompt
|
||||
height_offset=self.app.status_bar.height+self.app.command_prompt.height
|
||||
# vertical lines
|
||||
# lines right of pos
|
||||
xx=pos.x+mesh/2
|
||||
while self.pos_tocoord_x(xx)<self.width:
|
||||
# offest wrt 0
|
||||
offset=(pos.x-0.5)%mesh
|
||||
for i in range(math.floor((self.width/Square_element.size-offset)/mesh)+1):
|
||||
Color(1,1,1)
|
||||
Line(points=(self.pos_tocoord_x(xx),height_offset,self.pos_tocoord_x(xx),self.height+height_offset))
|
||||
xx+=mesh
|
||||
# lines left of pos
|
||||
xx=pos.x-mesh/2
|
||||
while self.pos_tocoord_x(xx)>0:
|
||||
Line(points=((i*mesh+offset)*Square_element.size,height_offset,(i*mesh+offset)*Square_element.size,self.height+height_offset))
|
||||
# horizontal lines
|
||||
# offset wrt 0
|
||||
offset=(pos.y-0.5)%1-height_offset/Square_element.size
|
||||
for i in range(math.floor((self.height/Square_element.size-offset)/mesh)+1):
|
||||
Color(1,1,1)
|
||||
Line(points=(self.pos_tocoord_x(xx),height_offset,self.pos_tocoord_x(xx),self.height+height_offset))
|
||||
xx-=mesh
|
||||
# lines above pos
|
||||
yy=pos.y+mesh/2
|
||||
while self.pos_tocoord_y(yy)<self.height:
|
||||
Color(1,1,1)
|
||||
Line(points=(0,self.pos_tocoord_y(yy),self.width,self.pos_tocoord_y(yy)))
|
||||
yy+=mesh
|
||||
# lines below pos
|
||||
yy=pos.y-mesh/2
|
||||
while self.pos_tocoord_y(yy)>0:
|
||||
Color(1,1,1)
|
||||
Line(points=(0,self.pos_tocoord_y(yy),self.width,self.pos_tocoord_y(yy)))
|
||||
yy-=mesh
|
||||
|
||||
# draw the discrete Voronoi cell of a particle
|
||||
def draw_voronoi(self,particle):
|
||||
# only works for lattices
|
||||
if self.lattice!=None:
|
||||
pos=particle.elements[0].pos
|
||||
# loop over all points
|
||||
xx=pos.x
|
||||
while self.pos_tocoord_x(xx)<self.width:
|
||||
yy=pos.y
|
||||
while self.pos_tocoord_y(yy)<self.height:
|
||||
self.draw_voronoi_site(xx,yy,particle.color,self.is_in_voronoi(xx,yy,particle))
|
||||
yy+=self.lattice.spacing
|
||||
yy=pos.y-self.lattice.spacing
|
||||
while self.pos_tocoord_y(yy)>0:
|
||||
self.draw_voronoi_site(xx,yy,particle.color,self.is_in_voronoi(xx,yy,particle))
|
||||
yy-=self.lattice.spacing
|
||||
xx+=self.lattice.spacing
|
||||
xx=pos.x-self.lattice.spacing
|
||||
while self.pos_tocoord_x(xx)>0:
|
||||
yy=pos.y
|
||||
while self.pos_tocoord_y(yy)<self.height:
|
||||
self.draw_voronoi_site(xx,yy,particle.color,self.is_in_voronoi(xx,yy,particle))
|
||||
yy+=self.lattice.spacing
|
||||
yy=pos.y-self.lattice.spacing
|
||||
while self.pos_tocoord_y(yy)>0:
|
||||
self.draw_voronoi_site(xx,yy,particle.color,self.is_in_voronoi(xx,yy,particle))
|
||||
yy-=self.lattice.spacing
|
||||
xx-=self.lattice.spacing
|
||||
# check whether a site is in the Voronoi cell of a particle
|
||||
def is_in_voronoi(self,x,y,particle):
|
||||
d_to_particle=self.lattice.distance_to_particle(x,y,particle)
|
||||
# count how many are in voronoi cell
|
||||
count=1
|
||||
# TODO: start with a particle that is close to x,y
|
||||
for q in self.particles:
|
||||
dd=self.lattice.distance_to_particle(x,y,q)
|
||||
if q!=particle and dd<d_to_particle:
|
||||
return 0
|
||||
if dd==d_to_particle:
|
||||
count+=1
|
||||
return count
|
||||
# draw a site in a Voronoi cell
|
||||
def draw_voronoi_site(self,x,y,color,count):
|
||||
if count==0:
|
||||
return
|
||||
Color(color[0],color[1],color[2],1-count*0.1)
|
||||
Rectangle(pos=(self.pos_tocoord_x(x-0.5*self.lattice.spacing),self.pos_tocoord_y(y-0.5*self.lattice.spacing)),size=(self.base_size*self.lattice.spacing,self.base_size*self.lattice.spacing))
|
||||
|
||||
Line(points=(0,(i*mesh+offset)*Square_element.size+height_offset,self.width,(i*mesh+offset)*Square_element.size+height_offset))
|
||||
|
||||
|
||||
# respond to keyboard
|
||||
@ -255,10 +153,10 @@ class Painter(Widget):
|
||||
# zoom
|
||||
elif text=="+":
|
||||
# increment by 10%
|
||||
self.set_zoom(self.base_size/50*1.1)
|
||||
self.set_zoom(Square_element.size/50*1.1)
|
||||
elif text=="-":
|
||||
# decrease by 10%
|
||||
self.set_zoom(self.base_size/50*0.9)
|
||||
self.set_zoom(Square_element.size/50*0.9)
|
||||
elif text=="=":
|
||||
# reset
|
||||
self.set_zoom(1)
|
||||
@ -288,13 +186,9 @@ class Painter(Widget):
|
||||
touchx=self.coord_topos_x(touch.x)
|
||||
touchy=self.coord_topos_y(touch.y)
|
||||
|
||||
# create new particle
|
||||
# create new cross
|
||||
if touch.button=="right":
|
||||
new=self.shape(touchx,touchy,color=self.color)
|
||||
# snap to lattice
|
||||
if self.lattice!=None:
|
||||
new.move(self.lattice.nearest_delta(new.elements[0].pos))
|
||||
|
||||
new=Cross(touchx,touchy)
|
||||
if not self.check_interaction_any(new,Point(0,0)):
|
||||
# add to list
|
||||
self.particles.append(new)
|
||||
@ -314,10 +208,7 @@ class Painter(Widget):
|
||||
|
||||
# record relative position of click with respect to reference
|
||||
if self.undermouse!=None:
|
||||
self.offset=Point(touchx,touchy)-self.undermouse.elements[0].pos
|
||||
# snap to lattice
|
||||
if self.lattice!=None:
|
||||
self.offset=self.lattice.nearest(self.offset)
|
||||
self.offset=Point(touchx,touchy)-self.undermouse.squares[0].pos
|
||||
|
||||
# no modifiers
|
||||
if self.modifiers==[]:
|
||||
@ -360,32 +251,16 @@ class Painter(Widget):
|
||||
|
||||
# respond to drag
|
||||
def on_touch_move(self,touch):
|
||||
# convert to logical
|
||||
touchx=self.coord_topos_x(touch.x)
|
||||
touchy=self.coord_topos_y(touch.y)
|
||||
|
||||
# only respond to touch in drawing area
|
||||
if self.collide_point(*touch.pos):
|
||||
# convert to logical
|
||||
touchc=Point(self.coord_topos_x(touch.x),self.coord_topos_y(touch.y))
|
||||
|
||||
# snap to lattice
|
||||
if self.lattice!=None:
|
||||
touchc=self.lattice.nearest(touchc)
|
||||
|
||||
# only move on left click
|
||||
if touch.button=="left" and self.modifiers==[] and self.undermouse!=None:
|
||||
# attempted move determined by the relative position to the relative position of click within self.undermouse
|
||||
delta=self.adjust_move(touchc-(self.offset+self.undermouse.elements[0].pos),0)
|
||||
|
||||
|
||||
# snap to lattice
|
||||
if self.lattice!=None:
|
||||
delta=self.lattice.nearest(delta)
|
||||
# check that the move is possible (which is not guaranteed after snapping to lattice)
|
||||
if not self.check_interaction_unselected_list(self.selected,delta):
|
||||
for particle in self.selected:
|
||||
particle.move(delta)
|
||||
|
||||
# no lattice, move is guaranteed to be acceptable
|
||||
else:
|
||||
delta=self.adjust_move(Point(touchx,touchy)-(self.offset+self.undermouse.squares[0].pos),0)
|
||||
for particle in self.selected:
|
||||
particle.move(delta)
|
||||
|
||||
@ -430,15 +305,9 @@ class Painter(Widget):
|
||||
# check whether a candidate particle element with any of the unselected particles
|
||||
def check_interaction_unselected_element(self,element,offset):
|
||||
for particle in self.unselected:
|
||||
for elt in particle.elements:
|
||||
# add offset
|
||||
element.pos+=offset
|
||||
if elt.check_interaction(element):
|
||||
# reset offset
|
||||
element.pos-=offset
|
||||
for square in particle.squares:
|
||||
if square.check_interaction(element.pos+offset):
|
||||
return True
|
||||
# reset offset
|
||||
element.pos-=offset
|
||||
return False
|
||||
|
||||
|
||||
@ -448,7 +317,7 @@ class Painter(Widget):
|
||||
# actual_delta is the smallest (componentwise) of all the computed delta's
|
||||
actual_delta=Point(math.inf,math.inf)
|
||||
for particle in self.selected:
|
||||
for element in particle.elements:
|
||||
for element in particle.squares:
|
||||
# compute adjustment move due to unselected obstacles
|
||||
adjusted_delta=self.adjust_move_element(delta,element,0)
|
||||
# only keep the smallest delta's (in absolute value)
|
||||
@ -474,23 +343,18 @@ class Painter(Widget):
|
||||
# whether newpos is acceptable
|
||||
accept_newpos=True
|
||||
for other in self.unselected:
|
||||
for obstacle in other.elements:
|
||||
for obstacle in other.squares:
|
||||
# move would make element overlap with obstacle
|
||||
element.pos+=delta
|
||||
if obstacle.check_interaction(element):
|
||||
element.pos-=delta
|
||||
if obstacle.check_interaction(element.pos+delta):
|
||||
accept_newpos=False
|
||||
# check if particle already touches obstacle
|
||||
if obstacle.check_touch(element):
|
||||
if obstacle.check_touch(element.pos):
|
||||
# move along obstacle while remaining stuck
|
||||
newdelta=obstacle.move_along(delta,element)
|
||||
newdelta=obstacle.move_along(delta,element.pos)
|
||||
else:
|
||||
newdelta=obstacle.move_on_line_to_stick(element,delta)
|
||||
newdelta=obstacle.move_on_line_to_stick(element.pos,delta)
|
||||
if not self.check_interaction_unselected_element(element,newdelta):
|
||||
return newdelta
|
||||
else:
|
||||
# reset offset
|
||||
element.pos-=delta
|
||||
if accept_newpos:
|
||||
return delta
|
||||
else:
|
||||
@ -505,9 +369,6 @@ class Painter(Widget):
|
||||
|
||||
# set color of selected particles
|
||||
def set_color(self,color):
|
||||
# set color for next particles
|
||||
self.color=color
|
||||
# set color of selected particles
|
||||
for particle in self.selected:
|
||||
particle.color=color
|
||||
# redraw
|
||||
@ -527,46 +388,14 @@ class Painter(Widget):
|
||||
# redraw
|
||||
self.draw()
|
||||
|
||||
# set voronoi for selected particles
|
||||
def set_voronoi(self, onoff):
|
||||
for particle in self.selected:
|
||||
if onoff==0:
|
||||
particle.voronoi=False
|
||||
elif onoff==1:
|
||||
particle.voronoi=True
|
||||
elif onoff==-1:
|
||||
particle.voronoi=not particle.voronoi
|
||||
# redraw
|
||||
self.draw()
|
||||
|
||||
# write configuration to file
|
||||
def write(self,file):
|
||||
ff=open(file,"w")
|
||||
# save state (particle shape, zoom, lattice)
|
||||
if self.shape==Cross:
|
||||
ff.write("%shape=cross\n")
|
||||
elif self.shape==Disk:
|
||||
ff.write("%shape=disk\n")
|
||||
elif self.shape==Staircase:
|
||||
ff.write("%shape=staircase\n")
|
||||
elif self.shape==Square2:
|
||||
ff.write("%shape=2square\n")
|
||||
else:
|
||||
print("bug: unrecognized shape in write: '"+str(self.shape)+"'")
|
||||
ff.write("%zoom={:1.1f}\n".format(self.base_size/50))
|
||||
ff.write("%color={:1.1f},{:1.1f},{:1.1f}\n".format(self.color[0],self.color[1],self.color[2]))
|
||||
if self.lattice != None:
|
||||
ff.write("%lattice="+self.lattice.type+':'+str(self.lattice.spacing)+"\n")
|
||||
for particle in self.particles:
|
||||
if type(particle)==Cross:
|
||||
ff.write("{:d};".format(CROSS_INDEX))
|
||||
elif type(particle)==Disk:
|
||||
ff.write("{:d};".format(DISK_INDEX))
|
||||
elif type(particle)==Staircase:
|
||||
ff.write("{:d};".format(STAIRCASE_INDEX))
|
||||
elif type(particle)==Square2:
|
||||
ff.write("{:d};".format(SQUARE2_INDEX))
|
||||
ff.write("{:05.2f},{:05.2f};{:3.1f},{:3.1f},{:3.1f}\n".format(particle.elements[0].pos.x,particle.elements[0].pos.y,particle.color[0],particle.color[1],particle.color[2]))
|
||||
ff.write("{:05.2f},{:05.2f};{:3.1f},{:3.1f},{:3.1f}\n".format(particle.squares[0].pos.x,particle.squares[0].pos.y,particle.color[0],particle.color[1],particle.color[2]))
|
||||
ff.close()
|
||||
|
||||
# read configuration from file
|
||||
@ -600,35 +429,12 @@ class Painter(Widget):
|
||||
if len(line)==0:
|
||||
continue
|
||||
|
||||
# read options
|
||||
if line[0]=='%':
|
||||
# ignore empty line
|
||||
if len(line)==1:
|
||||
continue
|
||||
[key,val]=line[1:].split('=',1)
|
||||
if key=="shape":
|
||||
self.app.command_prompt.run_set_shape(["set","shape",val])
|
||||
elif key=="zoom":
|
||||
self.app.command_prompt.run_set_zoom(["set","zoom",val])
|
||||
elif key=="color":
|
||||
color_str=val.split(',')
|
||||
try:
|
||||
self.set_color((float(color_str[0]),float(color_str[1]),float(color_str[2])))
|
||||
except:
|
||||
print("warning: ignoring line "+str(i)+" in file '"+file+"': color '"+color_str+"' cannot be read",file=sys.stderr)
|
||||
# lattice is handled by main function
|
||||
elif key=="lattice":
|
||||
continue
|
||||
else:
|
||||
print("warning: ignoring line "+str(i)+" in file '"+file+"': unrecognized option '"+key+"'",file=sys.stderr)
|
||||
continue
|
||||
|
||||
entries=line.split(";")
|
||||
# skip line if improperly formatted
|
||||
if len(entries)>3:
|
||||
print("warning: ignoring line "+str(i)+" in file '"+file+"': more than three ';' separated entries in '"+line+"'",file=sys.stderr)
|
||||
print("warning: ignoring line "+str(i)+" in file '"+file+"': more than three ';' spearated entries in '"+line+"'",file=sys.stderr)
|
||||
if len(entries)<2:
|
||||
print("warning: ignoring line "+str(i)+" in file '"+file+"': fewer than two ';' separated entries in '"+line+"'",file=sys.stderr)
|
||||
print("warning: ignoring line "+str(i)+" in file '"+file+"': fewer than two ';' spearated entries in '"+line+"'",file=sys.stderr)
|
||||
continue
|
||||
|
||||
# position
|
||||
@ -666,12 +472,6 @@ class Painter(Widget):
|
||||
continue
|
||||
if particle_type==CROSS_INDEX:
|
||||
candidate=Cross(pos.x,pos.y,color=color)
|
||||
elif particle_type==DISK_INDEX:
|
||||
candidate=Disk(pos.x,pos.y,color=color)
|
||||
elif particle_type==STAIRCASE_INDEX:
|
||||
candidate=Staircase(pos.x,pos.y,color=color)
|
||||
elif particle_type==SQUARE2_INDEX:
|
||||
candidate=Square2(pos.x,pos.y,color=color)
|
||||
else:
|
||||
print("warning: ignoring line "+str(i)+" in file '"+file+"': unrecognized particle type: '"+entries[0]+"'",file=sys.stderr)
|
||||
continue
|
||||
@ -708,13 +508,7 @@ class Painter(Widget):
|
||||
for particle in self.particles:
|
||||
if type(particle)==Cross:
|
||||
ff.write("\cross{"+colors.closest_color(particle.color,colors.xcolor_names)+"}")
|
||||
elif type(particle)==Disk:
|
||||
ff.write("\disk{"+colors.closest_color(particle.color,colors.xcolor_names)+"}")
|
||||
elif type(particle)==Staircase:
|
||||
ff.write("\staircase{"+colors.closest_color(particle.color,colors.xcolor_names)+"}")
|
||||
elif type(particle)==Square2:
|
||||
ff.write("\square{"+colors.closest_color(particle.color,colors.xcolor_names)+"}")
|
||||
ff.write("{{({:05.2f},{:05.2f})}};\n".format(particle.elements[0].pos.x-self.particles[0].elements[0].pos.x,particle.elements[0].pos.y-self.particles[0].elements[0].pos.y))
|
||||
ff.write("{{({:05.2f},{:05.2f})}};\n".format(particle.squares[0].pos.x-self.particles[0].squares[0].pos.x,particle.squares[0].pos.y-self.particles[0].squares[0].pos.y))
|
||||
|
||||
ff.write("\\end{tikzpicture}\n")
|
||||
ff.write("\\end{document}\n")
|
||||
@ -724,14 +518,11 @@ class Painter(Widget):
|
||||
|
||||
# set zoom level
|
||||
def set_zoom(self,level):
|
||||
self.base_size=level*50
|
||||
Square_element.size=level*50
|
||||
self.draw()
|
||||
|
||||
|
||||
# global variables (used like precompiler variables)
|
||||
CROSS_INDEX=1
|
||||
DISK_INDEX=2
|
||||
STAIRCASE_INDEX=3
|
||||
SQUARE2_INDEX=4
|
||||
|
||||
|
||||
|
@ -12,8 +12,6 @@
|
||||
# See the License for the specific language governing permissions and
|
||||
# limitations under the License.
|
||||
|
||||
# two-dimensional point structure
|
||||
|
||||
import math
|
||||
|
||||
# point in two dimensions
|
||||
@ -63,7 +61,3 @@ class Point:
|
||||
# L infinity norm
|
||||
def l_infinity(x):
|
||||
return max(abs(x.x),abs(x.y))
|
||||
|
||||
# L 2 norm
|
||||
def l_2(x):
|
||||
return math.sqrt(x.x*x.x+x.y*x.y)
|
||||
|
270
src/polyomino.py
270
src/polyomino.py
@ -12,16 +12,18 @@
|
||||
# See the License for the specific language governing permissions and
|
||||
# limitations under the License.
|
||||
|
||||
# a polyomino is a collection of elements, defined in elements.py
|
||||
from kivy.graphics import Color,Line
|
||||
from point import l_infinity
|
||||
from element import Element_square,Element_circle
|
||||
import math
|
||||
import sys
|
||||
from kivy.graphics import Color,Line,Rectangle
|
||||
|
||||
from point import Point,l_infinity
|
||||
from tools import isint_nonzero,sgn,in_interval
|
||||
|
||||
# parent class of all polyominos
|
||||
class Polyomino():
|
||||
def __init__(self,**kwargs):
|
||||
# elements that make up the polyomino
|
||||
self.elements=kwargs.get("elements",[])
|
||||
# square elements that maje up the polyomino
|
||||
self.squares=kwargs.get("squares",[])
|
||||
|
||||
self.color=kwargs.get("color",(0,0,1))
|
||||
self.selected=False
|
||||
@ -29,9 +31,6 @@ class Polyomino():
|
||||
# mesh of background grid (no grid for mesh size 0)
|
||||
self.grid=kwargs.get("grid",0)
|
||||
|
||||
# draw Voronoi cell
|
||||
self.voronoi=kwargs.get("voronoi",False)
|
||||
|
||||
# draw function
|
||||
def draw(self,painter,**kwargs):
|
||||
alpha=kwargs.get("alpha",1)
|
||||
@ -43,137 +42,212 @@ class Polyomino():
|
||||
# darken selected
|
||||
Color(r/2,g/2,b/2,alpha)
|
||||
|
||||
for element in self.elements:
|
||||
element.draw(painter)
|
||||
for square in self.squares:
|
||||
Rectangle(pos=(painter.pos_tocoord_x(square.pos.x-0.5),painter.pos_tocoord_y(square.pos.y-0.5)),size=(square.size,square.size))
|
||||
|
||||
# draw boundary
|
||||
self.stroke(painter)
|
||||
|
||||
# draw boundary (override for connected polyominos)
|
||||
def stroke(self,painter):
|
||||
# convert to graphical coordinates
|
||||
coordx=painter.pos_tocoord_x(square.pos.x)
|
||||
coordy=painter.pos_tocoord_y(square.pos.y)
|
||||
|
||||
# white
|
||||
Color(1,1,1)
|
||||
for element in self.elements:
|
||||
element.stroke(painter)
|
||||
for square in self.squares:
|
||||
Line(points=(
|
||||
*(coordx-0.5*square.size,coordy-0.5*square.size),
|
||||
*(coordx-0.5*square.size,coordy+0.5*square.size),
|
||||
*(coordx+0.5*square.size,coordy+0.5*square.size),
|
||||
*(coordx+0.5*square.size,coordy-0.5*square.size),
|
||||
*(coordx-0.5*square.size,coordy-0.5*square.size)
|
||||
))
|
||||
|
||||
# move by delta
|
||||
def move(self,delta):
|
||||
for element in self.elements:
|
||||
element.pos+=delta
|
||||
for square in self.squares:
|
||||
square.pos+=delta
|
||||
|
||||
# whether x is in the support of the polyomino
|
||||
def in_support(self,x):
|
||||
for element in self.elements:
|
||||
if element.in_support(x):
|
||||
for square in self.squares:
|
||||
if l_infinity(square.pos-x)<=1/2:
|
||||
return True
|
||||
return False
|
||||
|
||||
# check whether self interacts with candidate if candidate were moved by offset
|
||||
def check_interaction(self,candidate,offset):
|
||||
for element1 in self.elements:
|
||||
for element2 in candidate.elements:
|
||||
# add offset
|
||||
element2.pos+=offset
|
||||
if element1.check_interaction(element2):
|
||||
# reset offset
|
||||
element2.pos-=offset
|
||||
for square1 in self.squares:
|
||||
for square2 in candidate.squares:
|
||||
if square1.check_interaction(square2.pos+offset):
|
||||
return True
|
||||
# reset offset
|
||||
element2.pos-=offset
|
||||
return False
|
||||
|
||||
# square
|
||||
class Square(Polyomino):
|
||||
def __init__(self,x,y,**kwargs):
|
||||
super(Square,self).__init__(**kwargs,elements=[Element_square(x,y,size=kwargs.get("size",1.0))])
|
||||
super(Square,self).__init__(**kwargs,squares=[Square_element(x,y)])
|
||||
|
||||
# cross
|
||||
class Cross(Polyomino):
|
||||
def __init__(self,x,y,**kwargs):
|
||||
super(Cross,self).__init__(**kwargs,elements=[\
|
||||
Element_square(x,y,1,aspect=3),\
|
||||
Element_square(x+1,y,1),\
|
||||
Element_square(x-1,y,1)\
|
||||
super(Cross,self).__init__(**kwargs,squares=[\
|
||||
Square_element(x,y),\
|
||||
Square_element(x+1,y),\
|
||||
Square_element(x-1,y),\
|
||||
Square_element(x,y+1),\
|
||||
Square_element(x,y-1)\
|
||||
])
|
||||
|
||||
# redefine stroke to avoid lines between touching elements
|
||||
# redefine stroke to avoid lines between touching squares
|
||||
def stroke(self,painter):
|
||||
# convert to graphical coordinates
|
||||
coordx=painter.pos_tocoord_x(self.elements[0].pos.x)
|
||||
coordy=painter.pos_tocoord_y(self.elements[0].pos.y)
|
||||
coordx=painter.pos_tocoord_x(self.squares[0].pos.x)
|
||||
coordy=painter.pos_tocoord_y(self.squares[0].pos.y)
|
||||
|
||||
Color(1,1,1)
|
||||
Line(points=(
|
||||
*(coordx-0.5*painter.base_size,coordy-0.5*painter.base_size),
|
||||
*(coordx-0.5*painter.base_size,coordy-1.5*painter.base_size),
|
||||
*(coordx+0.5*painter.base_size,coordy-1.5*painter.base_size),
|
||||
*(coordx+0.5*painter.base_size,coordy-0.5*painter.base_size),
|
||||
*(coordx+1.5*painter.base_size,coordy-0.5*painter.base_size),
|
||||
*(coordx+1.5*painter.base_size,coordy+0.5*painter.base_size),
|
||||
*(coordx+0.5*painter.base_size,coordy+0.5*painter.base_size),
|
||||
*(coordx+0.5*painter.base_size,coordy+1.5*painter.base_size),
|
||||
*(coordx-0.5*painter.base_size,coordy+1.5*painter.base_size),
|
||||
*(coordx-0.5*painter.base_size,coordy+0.5*painter.base_size),
|
||||
*(coordx-1.5*painter.base_size,coordy+0.5*painter.base_size),
|
||||
*(coordx-1.5*painter.base_size,coordy-0.5*painter.base_size),
|
||||
*(coordx-0.5*painter.base_size,coordy-0.5*painter.base_size),
|
||||
*(coordx-0.5*Square_element.size,coordy-0.5*Square_element.size),
|
||||
*(coordx-0.5*Square_element.size,coordy-1.5*Square_element.size),
|
||||
*(coordx+0.5*Square_element.size,coordy-1.5*Square_element.size),
|
||||
*(coordx+0.5*Square_element.size,coordy-0.5*Square_element.size),
|
||||
*(coordx+1.5*Square_element.size,coordy-0.5*Square_element.size),
|
||||
*(coordx+1.5*Square_element.size,coordy+0.5*Square_element.size),
|
||||
*(coordx+0.5*Square_element.size,coordy+0.5*Square_element.size),
|
||||
*(coordx+0.5*Square_element.size,coordy+1.5*Square_element.size),
|
||||
*(coordx-0.5*Square_element.size,coordy+1.5*Square_element.size),
|
||||
*(coordx-0.5*Square_element.size,coordy+0.5*Square_element.size),
|
||||
*(coordx-1.5*Square_element.size,coordy+0.5*Square_element.size),
|
||||
*(coordx-1.5*Square_element.size,coordy-0.5*Square_element.size),
|
||||
*(coordx-0.5*Square_element.size,coordy-0.5*Square_element.size),
|
||||
))
|
||||
|
||||
# disk
|
||||
class Disk(Polyomino):
|
||||
|
||||
|
||||
# square building block of polyominos
|
||||
class Square_element():
|
||||
# size
|
||||
size=50
|
||||
|
||||
def __init__(self,x,y,**kwargs):
|
||||
super(Disk,self).__init__(**kwargs,elements=[Element_circle(x,y,size=kwargs.get("size",1.0))])
|
||||
self.pos=Point(x,y)
|
||||
|
||||
# 3-staircase
|
||||
class Staircase(Polyomino):
|
||||
def __init__(self,x,y,**kwargs):
|
||||
super(Staircase,self).__init__(**kwargs,elements=[\
|
||||
Element_square(x,y+1,1,aspect=3),\
|
||||
Element_square(x+1,y,1),\
|
||||
Element_square(x+1,y+1,1),\
|
||||
Element_square(x+2,y,1)\
|
||||
])
|
||||
# set position
|
||||
def setpos(self,x,y):
|
||||
self.pos.x=x
|
||||
self.pos.y=y
|
||||
|
||||
# redefine stroke to avoid lines between touching elements
|
||||
def stroke(self,painter):
|
||||
# convert to graphical coordinates
|
||||
coordx=painter.pos_tocoord_x(self.elements[0].pos.x)
|
||||
coordy=painter.pos_tocoord_y(self.elements[0].pos.y)
|
||||
|
||||
Color(1,1,1)
|
||||
Line(points=(
|
||||
*(coordx-0.5*painter.base_size,coordy-1.5*painter.base_size),
|
||||
*(coordx+2.5*painter.base_size,coordy-1.5*painter.base_size),
|
||||
*(coordx+2.5*painter.base_size,coordy-0.5*painter.base_size),
|
||||
*(coordx+1.5*painter.base_size,coordy-0.5*painter.base_size),
|
||||
*(coordx+1.5*painter.base_size,coordy+0.5*painter.base_size),
|
||||
*(coordx+0.5*painter.base_size,coordy+0.5*painter.base_size),
|
||||
*(coordx+0.5*painter.base_size,coordy+1.5*painter.base_size),
|
||||
*(coordx-0.5*painter.base_size,coordy+1.5*painter.base_size),
|
||||
*(coordx-0.5*painter.base_size,coordy-1.5*painter.base_size),
|
||||
))
|
||||
# check whether a square at pos interacts with square
|
||||
def check_interaction(self,pos):
|
||||
return l_infinity(pos-self.pos)<1
|
||||
|
||||
# 2-square
|
||||
class Square2(Polyomino):
|
||||
def __init__(self,x,y,**kwargs):
|
||||
super(Square2,self).__init__(**kwargs,elements=[\
|
||||
Element_square(x,y,1),\
|
||||
Element_square(x+1,y,1),\
|
||||
Element_square(x,y+1,1),\
|
||||
Element_square(x+1,y+1,1)\
|
||||
])
|
||||
# check whether a square at position pos is touching self
|
||||
def check_touch(self,pos):
|
||||
# allow for error
|
||||
if in_interval(l_infinity(pos-self.pos),1-1e-11,1+1e-11):
|
||||
return True
|
||||
return False
|
||||
|
||||
# redefine stroke to avoid lines between touching elements
|
||||
def stroke(self,painter):
|
||||
# convert to graphical coordinates
|
||||
coordx=painter.pos_tocoord_x(self.elements[0].pos.x)
|
||||
coordy=painter.pos_tocoord_y(self.elements[0].pos.y)
|
||||
# find position along a line that comes in contact with the line going through pos in direction v
|
||||
def move_on_line_to_stick(self,pos,v):
|
||||
# compute intersections with four lines making up square
|
||||
if v.x!=0:
|
||||
if v.y!=0:
|
||||
intersections=[\
|
||||
Point(self.pos.x+1,pos.y+v.y/v.x*(self.pos.x+1-pos.x)),\
|
||||
Point(self.pos.x-1,pos.y+v.y/v.x*(self.pos.x-1-pos.x)),\
|
||||
Point(pos.x+v.x/v.y*(self.pos.y+1-pos.y),self.pos.y+1),\
|
||||
Point(pos.x+v.x/v.y*(self.pos.y-1-pos.y),self.pos.y-1)\
|
||||
]
|
||||
else:
|
||||
intersections=[\
|
||||
Point(self.pos.x+1,pos.y+v.y/v.x*(self.pos.x+1-pos.x)),\
|
||||
Point(self.pos.x-1,pos.y+v.y/v.x*(self.pos.x-1-pos.x))
|
||||
]
|
||||
else:
|
||||
if v.y!=0:
|
||||
intersections=[\
|
||||
Point(pos.x+v.x/v.y*(self.pos.y+1-pos.y),self.pos.y+1),\
|
||||
Point(pos.x+v.x/v.y*(self.pos.y-1-pos.y),self.pos.y-1)\
|
||||
]
|
||||
else:
|
||||
print("error: move_on_line_to_stick called with v=0, please file a bug report with the developer",file=sys.stderr)
|
||||
exit(-1)
|
||||
|
||||
# compute closest one, on square
|
||||
closest=None
|
||||
dist=math.inf
|
||||
for i in range(0,len(intersections)):
|
||||
# check that it is on square
|
||||
if abs(intersections[i].x-self.pos.x)<=1+1e-11 and abs(intersections[i].y-self.pos.y)<=1+1e-11:
|
||||
if (intersections[i]-pos)**2<dist:
|
||||
closest=intersections[i]
|
||||
dist=(intersections[i]-pos)**2
|
||||
|
||||
if closest==None:
|
||||
print("error: cannot move particle at (",pos.x,",",pos.y,") to the boundary of (",self.pos.x,",",self.pos.y,") in direction (",v.x,",",v.y,")",file=sys.stderr)
|
||||
exit(-1)
|
||||
|
||||
# return difference to pos
|
||||
return closest-pos
|
||||
|
||||
# move along edge of square
|
||||
def move_along(self,delta,pos):
|
||||
rel=pos-self.pos
|
||||
# check if the particle is stuck in the x direction
|
||||
if isint_nonzero(rel.x):
|
||||
# check y direction
|
||||
if isint_nonzero(rel.y):
|
||||
# in corner
|
||||
if sgn(delta.y)==-sgn(rel.y):
|
||||
# stuck in x direction
|
||||
return self.move_stuck_x(delta,pos)
|
||||
elif sgn(delta.x)==-sgn(rel.x):
|
||||
# stuck in y direction
|
||||
return self.move_stuck_y(delta,pos)
|
||||
# stuck in both directions
|
||||
return pos
|
||||
else:
|
||||
# stuck in x direction
|
||||
return self.move_stuck_x(delta,pos)
|
||||
elif isint_nonzero(rel.y):
|
||||
# stuck in y direction
|
||||
return self.move_stuck_y(delta,pos)
|
||||
# this should never happen
|
||||
else:
|
||||
print("error: stuck particle has non-integer relative position: (",rel.x,",",rel.y,")",file=sys.stderr)
|
||||
exit(-1)
|
||||
# move when stuck in the x direction
|
||||
def move_stuck_x(self,delta,pos):
|
||||
# only move in y direction
|
||||
candidate=Point(0,delta.y)
|
||||
# do not move past corners
|
||||
rel=pos.y-self.pos.y
|
||||
if delta.y>0:
|
||||
if rel<math.ceil(rel)-1e-11 and delta.y+rel>math.ceil(rel)+1e-11 and math.ceil(rel)!=0:
|
||||
# stick to corner
|
||||
candidate.y=math.ceil(rel)+self.pos.y-pos.y
|
||||
else:
|
||||
if rel>math.floor(rel)+1e-11 and delta.y+rel<math.floor(rel)-1e-11 and math.floor(rel)!=0:
|
||||
# stick to corner
|
||||
candidate.y=math.floor(rel)+self.pos.y-pos.y
|
||||
return candidate
|
||||
# move when stuck in the y direction
|
||||
def move_stuck_y(self,delta,pos):
|
||||
# onlx move in x direction
|
||||
candidate=Point(delta.x,0)
|
||||
# do not move past corners
|
||||
rel=pos.x-self.pos.x
|
||||
if delta.x>0:
|
||||
if rel<math.ceil(rel)-1e-11 and delta.x+rel>math.ceil(rel)+1e-11 and math.ceil(rel)!=0:
|
||||
# stick to corner
|
||||
candidate.x=math.ceil(rel)+self.pos.x-pos.x
|
||||
else:
|
||||
if rel>math.floor(rel)+1e-11 and delta.x+rel<math.floor(rel)-1e-11 and math.floor(rel)!=0:
|
||||
# stick to corner
|
||||
candidate.x=math.floor(rel)+self.pos.x-pos.x
|
||||
return candidate
|
||||
|
||||
Color(1,1,1)
|
||||
Line(points=(
|
||||
*(coordx-0.5*painter.base_size,coordy-0.5*painter.base_size),
|
||||
*(coordx+1.5*painter.base_size,coordy-0.5*painter.base_size),
|
||||
*(coordx+1.5*painter.base_size,coordy+1.5*painter.base_size),
|
||||
*(coordx-0.5*painter.base_size,coordy+1.5*painter.base_size),
|
||||
*(coordx-0.5*painter.base_size,coordy-0.5*painter.base_size),
|
||||
))
|
||||
|
@ -1,17 +1,3 @@
|
||||
# Copyright 2021-2023 Ian Jauslin
|
||||
#
|
||||
# Licensed under the Apache License, Version 2.0 (the "License");
|
||||
# you may not use this file except in compliance with the License.
|
||||
# You may obtain a copy of the License at
|
||||
#
|
||||
# http://www.apache.org/licenses/LICENSE-2.0
|
||||
#
|
||||
# Unless required by applicable law or agreed to in writing, software
|
||||
# distributed under the License is distributed on an "AS IS" BASIS,
|
||||
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
|
||||
# See the License for the specific language governing permissions and
|
||||
# limitations under the License.
|
||||
|
||||
from kivy.uix.label import Label
|
||||
from kivy.graphics import Color,Rectangle
|
||||
from kivy.utils import escape_markup
|
||||
@ -59,9 +45,9 @@ class Status_bar(Label):
|
||||
spaces=int(self.width/self.char_width)-len(self.raw_text)-13
|
||||
if spaces>0:
|
||||
if self.app.painter.reference==None:
|
||||
self.raw_text+=" "*spaces+"({:05.2f},{:05.2f})\n".format(self.app.painter.selected[0].elements[0].pos.x,self.app.painter.selected[0].elements[0].pos.y)
|
||||
self.raw_text+=" "*spaces+"({:05.2f},{:05.2f})\n".format(self.app.painter.selected[0].squares[0].pos.x,self.app.painter.selected[0].squares[0].pos.y)
|
||||
else:
|
||||
self.raw_text+=" "*spaces+"({:05.2f},{:05.2f})\n".format(self.app.painter.selected[0].elements[0].pos.x-self.app.painter.reference.elements[0].pos.x,self.app.painter.selected[0].elements[0].pos.y-self.app.painter.reference.elements[0].pos.y)
|
||||
self.raw_text+=" "*spaces+"({:05.2f},{:05.2f})\n".format(self.app.painter.selected[0].squares[0].pos.x-self.app.painter.reference.squares[0].pos.x,self.app.painter.selected[0].squares[0].pos.y-self.app.painter.reference.squares[0].pos.y)
|
||||
|
||||
# do not wrap
|
||||
self.text=self.raw_text[:min(len(self.raw_text),int(self.width/self.char_width))]
|
||||
|
23
src/tools.py
23
src/tools.py
@ -1,19 +1,3 @@
|
||||
# Copyright 2021-2023 Ian Jauslin
|
||||
#
|
||||
# Licensed under the Apache License, Version 2.0 (the "License");
|
||||
# you may not use this file except in compliance with the License.
|
||||
# You may obtain a copy of the License at
|
||||
#
|
||||
# http://www.apache.org/licenses/LICENSE-2.0
|
||||
#
|
||||
# Unless required by applicable law or agreed to in writing, software
|
||||
# distributed under the License is distributed on an "AS IS" BASIS,
|
||||
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
|
||||
# See the License for the specific language governing permissions and
|
||||
# limitations under the License.
|
||||
|
||||
import math
|
||||
|
||||
# sign function
|
||||
def sgn(x):
|
||||
if x>=0:
|
||||
@ -36,10 +20,3 @@ def remove_fromlist(a,x):
|
||||
a[a.index(x)]=a[len(a)-1]
|
||||
a=a[:len(a)-1]
|
||||
return a
|
||||
|
||||
# snap to a grid: ceiling
|
||||
def ceil_grid(x,size):
|
||||
return math.ceil(x/size)*size
|
||||
# snap to a grid: floor
|
||||
def floor_grid(x,size):
|
||||
return math.floor(x/size)*size
|
||||
|
Loading…
Reference in New Issue
Block a user