EVOLUTION-MANAGER

Edit File: utils.py

#Copyright ReportLab Europe Ltd. 2000-2004 #see license.txt for license details #history http://www.reportlab.co.uk/cgi-bin/viewcvs.cgi/public/reportlab/trunk/reportlab/graphics/charts/utils.py __version__=''' $Id: utils.py 3746 2010-07-21 10:32:55Z rgbecker $ ''' __doc__="Utilities used here and there." from time import mktime, gmtime, strftime ### Dinu's stuff used in some line plots (likely to vansih). def mkTimeTuple(timeString): "Convert a 'dd/mm/yyyy' formatted string to a tuple for use in the time module." list = [0] * 9 dd, mm, yyyy = map(int, timeString.split('/')) list[:3] = [yyyy, mm, dd] return tuple(list) def str2seconds(timeString): "Convert a number of seconds since the epoch into a date string." return mktime(mkTimeTuple(timeString)) def seconds2str(seconds): "Convert a date string into the number of seconds since the epoch." return strftime('%Y-%m-%d', gmtime(seconds)) ### Aaron's rounding function for making nice values on axes. from math import log10 def nextRoundNumber(x): """Return the first 'nice round number' greater than or equal to x Used in selecting apropriate tick mark intervals; we say we want an interval which places ticks at least 10 points apart, work out what that is in chart space, and ask for the nextRoundNumber(). Tries the series 1,2,5,10,20,50,100.., going up or down as needed. """ #guess to nearest order of magnitude if x in (0, 1): return x if x < 0: return -1.0 * nextRoundNumber(-x) else: lg = int(log10(x)) if lg == 0: if x < 1: base = 0.1 else: base = 1.0 elif lg < 0: base = 10.0 ** (lg - 1) else: base = 10.0 ** lg # e.g. base(153) = 100 # base will always be lower than x if base >= x: return base * 1.0 elif (base * 2) >= x: return base * 2.0 elif (base * 5) >= x: return base * 5.0 else: return base * 10.0 ### Robin's stuff from rgb_ticks. from math import log10, floor _intervals=(.1, .2, .25, .5) _j_max=len(_intervals)-1 def find_interval(lo,hi,I=5): 'determine tick parameters for range [lo, hi] using I intervals' if lo >= hi: if lo==hi: if lo==0: lo = -.1 hi = .1 else: lo = 0.9*lo hi = 1.1*hi else: raise ValueError, "lo>hi" x=(hi - lo)/float(I) b= (x>0 and (x<1 or x>10)) and 10**floor(log10(x)) or 1 b = b while 1: a = x/b if a<=_intervals[-1]: break b = b*10 j = 0 while a>_intervals[j]: j = j + 1 while 1: ss = _intervals[j]*b n = lo/ss l = int(n)-(n<0) n = ss*l x = ss*(l+I) a = I*ss if n>0: if a>=hi: n = 0.0 x = a elif hi<0: a = -a if lo>a: n = a x = 0 if hi<=x and n<=lo: break j = j + 1 if j>_j_max: j = 0 b = b*10 return n, x, ss, lo - n + x - hi def find_good_grid(lower,upper,n=(4,5,6,7,8,9), grid=None): if grid: t = divmod(lower,grid)[0] * grid hi, z = divmod(upper,grid) if z>1e-8: hi = hi+1 hi = hi*grid else: try: n[0] except TypeError: n = xrange(max(1,n-2),max(n+3,2)) w = 1e308 for i in n: z=find_interval(lower,upper,i) if z[3]<w: t, hi, grid = z[:3] w=z[3] return t, hi, grid def ticks(lower, upper, n=(4,5,6,7,8,9), split=1, percent=0, grid=None, labelVOffset=0): ''' return tick positions and labels for range lower<=x<=upper n=number of intervals to try (can be a list or sequence) split=1 return ticks then labels else (tick,label) pairs ''' t, hi, grid = find_good_grid(lower, upper, n, grid) power = floor(log10(grid)) if power==0: power = 1 w = grid/10.**power w = int(w)!=w if power > 3 or power < -3: format = '%+'+repr(w+7)+'.0e' else: if power >= 0: digits = int(power)+w format = '%' + repr(digits)+'.0f' else: digits = w-int(power) format = '%'+repr(digits+2)+'.'+repr(digits)+'f' if percent: format=format+'%%' T = [] n = int(float(hi-t)/grid+0.1)+1 if split: labels = [] for i in xrange(n): v = t+grid*i T.append(v) labels.append(format % (v+labelVOffset)) return T, labels else: for i in xrange(n): v = t+grid*i T.append((v, format % (v+labelVOffset))) return T def findNones(data): m = len(data) if None in data: b = 0 while b<m and data[b] is None: b += 1 if b==m: return data l = m-1 while data[l] is None: l -= 1 l+=1 if b or l: data = data[b:l] I = [i for i in xrange(len(data)) if data[i] is None] for i in I: data[i] = 0.5*(data[i-1]+data[i+1]) return b, l, data return 0,m,data def pairFixNones(pairs): Y = [x[1] for x in pairs] b,l,nY = findNones(Y) m = len(Y) if b or l<m or nY!=Y: if b or l<m: pairs = pairs[b:l] pairs = [(x[0],y) for x,y in zip(pairs,nY)] return pairs def maverage(data,n=6): data = (n-1)*[data[0]]+data data = [float(sum(data[i-n:i]))/n for i in xrange(n,len(data)+1)] return data def pairMaverage(data,n=6): return [(x[0],s) for x,s in zip(data, maverage([x[1] for x in data],n))] import weakref from reportlab.graphics.shapes import transformPoint, transformPoints, inverse, Ellipse from reportlab.lib.utils import flatten class DrawTimeCollector(object): ''' generic mechanism for collecting information about nodes at the time they are about to be drawn ''' def __init__(self,formats=['gif']): self._nodes = weakref.WeakKeyDictionary() self.clear() self._pmcanv = None self.formats = formats self.disabled = False def clear(self): self._info = [] self._info_append = self._info.append def record(self,func,node,*args,**kwds): self._nodes[node] = (func,args,kwds) node.__dict__['_drawTimeCallback'] = self def __call__(self,node,canvas,renderer): func = self._nodes.get(node,None) if func: func, args, kwds = func i = func(node,canvas,renderer, *args, **kwds) if i is not None: self._info_append(i) @staticmethod def rectDrawTimeCallback(node,canvas,renderer,**kwds): A = getattr(canvas,'ctm',None) if not A: return x1 = node.x y1 = node.y x2 = x1 + node.width y2 = y1 + node.height D = kwds.copy() D['rect']=DrawTimeCollector.transformAndFlatten(A,((x1,y1),(x2,y2))) return D @staticmethod def transformAndFlatten(A,p): ''' transform an flatten a list of points A transformation matrix p points [(x0,y0),....(xk,yk).....] ''' if tuple(A)!=(1,0,0,1,0,0): iA = inverse(A) p = transformPoints(iA,p) return tuple(flatten(p)) @property def pmcanv(self): if not self._pmcanv: import renderPM self._pmcanv = renderPM.PMCanvas(1,1) return self._pmcanv def wedgeDrawTimeCallback(self,node,canvas,renderer,**kwds): A = getattr(canvas,'ctm',None) if not A: return if isinstance(node,Ellipse): c = self.pmcanv c.ellipse(node.cx, node.cy, node.rx,node.ry) p = c.vpath p = [(x[1],x[2]) for x in p] else: p = node.asPolygon().points p = [(p[i],p[i+1]) for i in xrange(0,len(p),2)] D = kwds.copy() D['poly'] = self.transformAndFlatten(A,p) return D def save(self,fnroot): ''' save the current information known to this collector fnroot is the root name of a resource to name the saved info override this to get the right semantics for your collector ''' import pprint f=open(fnroot+'.default-collector.out','w') try: pprint.pprint(self._info,f) finally: f.close()