def _drawAxes(self, canvas, xaxis, yaxis, bb1, bb2, scale, shift, xticks, yticks): dict = {'anchor': N, 'fill': 'black'} if self.font is not None: dict['font'] = self.font if xaxis is not None: #draw x - axis lower, upper = xaxis text = 1 once = 1 for y, d in [(bb1[1], -3), (bb2[1], 3)]: #d=.5 of tick - length p1 = (scale[0] * lower) + shift[0], (scale[1] * y) + shift[1] if once: pp1 = p1 p2 = (scale[0] * upper) + shift[0], (scale[1] * y) + shift[1] if once: pp2 = p2 once = 0 Line(self.canvas, p1[0], p1[1], p2[0], p2[1], fill = 'black', width = 1) if xticks: for x, label in xticks: p = (scale[0] * x) + shift[0], \ (scale[1] * y) + shift[1] Line(self.canvas, p[0], p[1], p[0], p[1] + d, fill = 'black', width = 1) if text: dict['text'] = label CanvasText(self.canvas, p[0], p[1] + 2, **dict) ##KGM 14 Aug 03 text = 0 #write x - axis title CanvasText(self.canvas,(pp2[0] - pp1[0]) / 2.+pp1[0],pp1[1] + 22, text = self.xtitle) #write graph title CanvasText(self.canvas,(pp2[0] - pp1[0]) / 2.+pp1[0],7, text = self.title) dict['anchor'] = E if yaxis is not None: #draw y - axis lower, upper = yaxis text = 1 once = 1 for x, d in [(bb1[0], -3), (bb2[0], 3)]: p1 = (scale[0] * x) + shift[0], (scale[1] * lower) + shift[1] p2 = (scale[0] * x) + shift[0], (scale[1] * upper) + shift[1] if once: pp1 = p1 ;pp2 = p2 once = 0 Line(self.canvas, p1[0], p1[1], p2[0], p2[1], fill = 'black', width = 1) if yticks: for y, label in yticks: p = (scale[0] * x) + shift[0], \ (scale[1] * y) + shift[1] Line(self.canvas, p[0], p[1], p[0] - d, p[1], fill = 'black', width = 1) if text: dict['text'] = label CanvasText(self.canvas, p[0] - 4, p[1] + 2, **dict) text = 0 #write y - axis title CanvasText(self.canvas, pp2[0],pp2[1] - 10, text = self.ytitle)
def _drawAxes(self, canvas, xaxis, yaxis, bb1, bb2, scale, shift, xticks, yticks): dict = {'anchor': Tkinter.N, 'fill': 'black'} if self.font is not None: dict['font'] = self.font if xaxis is not None: lower, upper = xaxis text = 1 for y, d in [(bb1[1], -3), (bb2[1], 3)]: p1 = scale * Numeric.array([lower, y]) + shift p2 = scale * Numeric.array([upper, y]) + shift Line(self.canvas, p1[0], p1[1], p2[0], p2[1], fill='black', width=1) for x, label in xticks: p = scale * Numeric.array([x, y]) + shift Line(self.canvas, p[0], p[1], p[0], p[1] + d, fill='black', width=1) if text: dict['text'] = label apply(CanvasText, (self.canvas, p[0], p[1]), dict) text = 0 dict['anchor'] = Tkinter.E if yaxis is not None: lower, upper = yaxis text = 1 for x, d in [(bb1[0], -3), (bb2[0], 3)]: p1 = scale * Numeric.array([x, lower]) + shift p2 = scale * Numeric.array([x, upper]) + shift Line(self.canvas, p1[0], p1[1], p2[0], p2[1], fill='black', width=1) for y, label in yticks: p = scale * Numeric.array([x, y]) + shift Line(self.canvas, p[0], p[1], p[0] - d, p[1], fill='black', width=1) if text: dict['text'] = label apply(CanvasText, (self.canvas, p[0], p[1]), dict) text = 0
def draw(self, graphics): """Draws the graphics object |graphics|, which can be a PolyLine3D or a VisualizationGraphics object.""" self.last_draw = (graphics, ) self.configure(cursor='watch') self.update_idletasks() graphics.project(self.axis, self.plane) p1, p2 = graphics.boundingBoxPlane() center = 0.5*(p1+p2) scale = self.plotbox_size / (p2-p1) sign = scale/Numeric.fabs(scale) if self.scale is None: minscale = Numeric.minimum.reduce(Numeric.fabs(scale)) self.scale = 0.9*minscale scale = sign*self.scale box_center = self.plotbox_origin + 0.5*self.plotbox_size shift = -center*scale + box_center + self.translate graphics.scaleAndShift(scale, shift) items, depths = graphics.lines() sort = Numeric.argsort(depths) for index in sort: x1, y1, x2, y2, color, width = items[index] Line(self.canvas, x1, y1, x2, y2, fill=color, width=width) self.configure(cursor='top_left_arrow') self.update_idletasks()
def plot_cut_cor(self, Canvas=None, length=20): start, start_ang = self.get_st_en_points(0) #BaseEntitie erstellen um auf oberster Ebene zu Fräsen BaseEntitie = EntitieContentClass(Nr=-1, Name='BaseEntitie', parent=None, children=[], p0=PointClass(x=0.0, y=0.0), pb=PointClass(x=0.0, y=0.0), sca=[1, 1, 1], rot=0.0) x_ca, y_ca = Canvas.get_can_coordinates(start.x, start.y) if self.cut_cor == 41: start_ang = start_ang + 90 else: start_ang = start_ang - 90 dx = cos(radians(start_ang)) * length dy = sin(radians(start_ang)) * length hdl = Line(Canvas.canvas, x_ca, -y_ca, x_ca + dx, -y_ca - dy, fill='SteelBlue3', arrow='last') return hdl
def plot2can(self, canvas=None, parent=None, tag=None, col='black'): anf = self.Pa.rot_sca_abs(parent=parent) ende = self.Pe.rot_sca_abs(parent=parent) hdl = Line(canvas, anf.x, -anf.y, ende.x, -ende.y, tag=tag, fill=col) return [hdl]
def plot2can(self, canvas=None, parent=None, tag=None, col='black'): x = [] y = [] hdl = [] #Alle 10 Grad ein Segment => 120 Segmente für einen Kreis !! segments = int((abs(degrees(self.ext)) // 10) + 1) for i in range(segments + 1): ang = self.s_ang + i * self.ext / segments p_cur=PointClass(x=(self.O.x+cos(ang)*abs(self.r)),\ y=(self.O.y+sin(ang)*abs(self.r))) p_cur_rot = p_cur.rot_sca_abs(parent=parent) x.append(p_cur_rot.x) y.append(p_cur_rot.y) if i >= 1: hdl.append( Line(canvas, x[i - 1], -y[i - 1], x[i], -y[i], tag=tag, fill=col)) return hdl
def __init__(self, master, data=None): self.master = master self.frame = Frame(self.master) self.frame.pack(fill=X) self.label = Label(self.frame) self.label.pack() self.canvas = Canvas(self.frame) self.canvas.pack() self.report = Label(self.frame) self.report.pack() self.left = Line(self.canvas, 0, 0, 0, 0) self.right = Line(self.canvas, 0, 0, 0, 0) self.pivot = Line(self.canvas, 0, 0, 0, 0) self.items = [] self.size = self.maxvalue = 0 if data: self.setdata(data)
def _drawAxes(self, canvas, xaxis, yaxis, bb1, bb2, scale, shift, xticks, yticks): dict = {'anchor': N, 'fill': 'black'} if self.font is not None: dict['font'] = self.font if xaxis is not None: lower, upper = xaxis text = 1 for y, d in [(bb1[1], -3), (bb2[1], 3)]: p1 = (scale[0]*lower)+shift[0], (scale[1]*y)+shift[1] p2 = (scale[0]*upper)+shift[0], (scale[1]*y)+shift[1] Line(self.canvas, p1[0], p1[1], p2[0], p2[1], fill = 'black', width = 1) if xticks: for x, label in xticks: p = (scale[0]*x)+shift[0], \ (scale[1]*y)+shift[1] Line(self.canvas, p[0], p[1], p[0], p[1]+d, fill = 'black', width = 1) if text: dict['text'] = label apply(CanvasText, (self.canvas, p[0], p[1]), dict) text = 0 dict['anchor'] = E if yaxis is not None: lower, upper = yaxis text = 1 for x, d in [(bb1[0], -3), (bb2[0], 3)]: p1 = (scale[0]*x)+shift[0], (scale[1]*lower)+shift[1] p2 = (scale[0]*x)+shift[0], (scale[1]*upper)+shift[1] Line(self.canvas, p1[0], p1[1], p2[0], p2[1], fill = 'black', width = 1) if yticks: for y, label in yticks: p = (scale[0]*x)+shift[0], \ (scale[1]*y)+shift[1] Line(self.canvas, p[0], p[1], p[0]-d, p[1], fill = 'black', width = 1) if text: dict['text'] = label apply(CanvasText, (self.canvas, p[0]-2, p[1]), dict) text = 0
def xTicks(xMin,xMax,Ax,Bx): # Plot ticks and labels for x-axis dx = tickSpace(xMin,xMax,px) yp = topMargin + height if xMin < 0.0: x = 0.0 while x >= xMin: if x <= xMax: xp = Ax + Bx*x Line(cv,xp,yp,xp,yp - 8) label = str(round(x,4)) CanvasText(cv,xp,yp+20,text=label) x = x - dx if xMax > 0.0: x = 0.0 while x <= xMax: if x >= xMin: xp = Ax + Bx*x Line(cv,xp,yp,xp,yp - 8) label = str(round(x,4)) CanvasText(cv,xp,yp+20,text=label) x = x + dx
def yTicks(yMin,yMax,Ay,By): # Plot ticks and labels for y-axis dy = tickSpace(yMin,yMax,py) xp = leftMargin if yMin < 0.0: y = 0.0 while y >= yMin: if y <= yMax: yp = Ay + By*y Line(cv,xp,yp,xp+8,yp) label = str(round(y,4)) xxp = xp-10-len(label)*3 CanvasText(cv,xxp,yp,text=label) y = y - dy if yMax > 0.0: y = 0.0 while y <= yMax: if y >= yMin: yp = Ay + By*y Line(cv,xp,yp,xp+8,yp) label = str(round(y,4)) xxp = xp-10-len(label)*3 CanvasText(cv,xxp,yp,text=label) y = y + dy
def plot_end(self, Canvas=None, length=20): ende, en_angle = self.get_st_en_points(1) dx = cos(radians(en_angle)) * length dy = sin(radians(en_angle)) * length x_ca, y_ca = Canvas.get_can_coordinates(ende.x, ende.y) hdl = Line(Canvas.canvas, x_ca, -y_ca, x_ca + dx, -y_ca - dy, fill='PaleGreen2', arrow='first') return hdl
def plot_end(self, CanvasClass): en_point, en_angle = self.geos[-1].get_start_end_points(1) ende = (en_point * self.sca) + self.p0 x_ca, y_ca = CanvasClass.get_can_coordinates(ende.x, ende.y) length = 20 dx = cos(radians(en_angle)) * length dy = sin(radians(en_angle)) * length hdl = Line(CanvasClass.canvas, x_ca, -y_ca, x_ca + dx, -y_ca - dy, fill='PaleGreen2', arrow='first') return hdl
def draw(self, canvas): color = self.attributes['color'] width = self.attributes['width'] smooth = self.attributes['smooth'] steps = self.attributes['splinesteps'] arguments = (canvas,) if smooth: for i in range(len(self.points)): x1, y1 = self.scaled[i] arguments = arguments + (x1, y1) else: for i in range(len(self.points) - 1): x1, y1 = self.scaled[i] x2, y2 = self.scaled[i + 1] arguments = arguments + (x1, y1, x2, y2) Line(*arguments, **{'fill': color, 'width': width, 'smooth': smooth, 'splinesteps':steps})
def plotting(xData,yData,symb,Ax,Bx,Ay,By): # Plots the data global cv for i in range(len(xData)-1): x1 = round(Ax + Bx*xData[i]) y1 = round(Ay + By*yData[i]) x2 = round(Ax + Bx*xData[i+1]) y2 = round(Ay + By*yData[i+1]) if symb[0] == 'l': Line(cv,x1,y1,x2,y2) if symb[1] == 'o': Oval(cv,x1-3,y1-3,x1+3,y1+3,fill="white") if symb[1] == 'b': Rectangle(cv,x1-3,y1-3,x1+3,y1+3,fill="white") if symb[1] == 'o': Oval(cv,x2-3,y2-3,x2+3,y2+3,fill="white") if symb[1] == 'b': Rectangle(cv,x2-3,y2-3,x2+3,y2+3,fill="white")
def plot_start(self, Canvas=None, length=20): #st_point, st_angle=self.geos[0].get_start_end_points(0,parent) start, start_ang = self.get_st_en_points(0) x_ca, y_ca = Canvas.get_can_coordinates(start.x, start.y) dx = cos(radians(start_ang)) * length dy = sin(radians(start_ang)) * length hdl = Line(Canvas.canvas, x_ca, -y_ca, x_ca + dx, -y_ca - dy, fill='SteelBlue3', arrow='last') return hdl
def plot_start(self, CanvasClass): st_point, st_angle = self.geos[0].get_start_end_points(0) start = (st_point * self.sca) + self.p0 x_ca, y_ca = CanvasClass.get_can_coordinates(start.x, start.y) length = 120 dx = cos(radians(st_angle)) * length dy = sin(radians(st_angle)) * length hdl = Line(CanvasClass.canvas, x_ca, -y_ca, x_ca + dx, -y_ca - dy, fill='SteelBlue3', arrow='last') return hdl
#! /usr/bin/env python
def _drawAxes(self, canvas, xaxis, yaxis, bb1, bb2, scale, shift, xticks, yticks): dict = {'anchor': N, 'fill': 'black'} width = 2 s_ticks = 5 if self.font is not None: dict['font'] = self.font if xaxis is not None: lower, upper = xaxis text = 1 for y, d in [(bb1[1], -6), (bb2[1], 6)]: p1 = (scale[0] * lower) + shift[0], (scale[1] * y) + shift[1] p2 = (scale[0] * upper) + shift[0], (scale[1] * y) + shift[1] Line(self.canvas, p1[0], p1[1], p2[0], p2[1], fill='black', width=width) if xticks: for x, label in xticks: p = (scale[0]*x)+shift[0], \ (scale[1]*y)+shift[1] Line(self.canvas, p[0], p[1], p[0], p[1] + d, fill='black', width=width) if text: dict['text'] = label apply(CanvasText, (self.canvas, p[0], p[1]), dict) text = 0 if xticks: x1, lb1 = xticks[0] x2, lb2 = xticks[1] dx = (x2 - x1) / s_ticks for i in range(len(xticks) - 1): x1, lb1 = xticks[i] for j in range(1, s_ticks): x = x1 + dx * j p = (scale[0] * x) + shift[0], (scale[1] * y) + shift[1] Line(self.canvas, p[0], p[1], p[0], p[1] + d, fill='black', width=1) dict['anchor'] = E if yaxis is not None: lower, upper = yaxis text = 1 for x, d in [(bb1[0], -6), (bb2[0], 6)]: p1 = (scale[0] * x) + shift[0], (scale[1] * lower) + shift[1] p2 = (scale[0] * x) + shift[0], (scale[1] * upper) + shift[1] Line(self.canvas, p1[0], p1[1], p2[0], p2[1], fill='black', width=width) if yticks: for y, label in yticks: p = (scale[0]*x)+shift[0], \ (scale[1]*y)+shift[1] Line(self.canvas, p[0], p[1], p[0] - d, p[1], fill='black', width=width) if text: dict['text'] = label apply(CanvasText, (self.canvas, p[0] - 2, p[1]), dict) text = 0 if yticks: y1, lb1 = yticks[0] y2, lb2 = yticks[1] dy = (y2 - y1) / s_ticks for i in range(len(yticks) - 1): y1, lb1 = yticks[i] for j in range(1, s_ticks): y = y1 + dy * j p = (scale[0] * x) + shift[0], (scale[1] * y) + shift[1] Line(self.canvas, p[0], p[1], p[0] - d, p[1], fill='black', width=1)
def axes(xMin,xMax,yMin,yMax,Ax,Ay): # Draws the x = 0 and y = 0 lines if xMin*xMax < 0: Line(cv,Ax,topMargin,Ax,topMargin+height) if yMin*yMax < 0: Line(cv,leftMargin,Ay,leftMargin+width,Ay)