All scipy imports in the library are now optional (need to test each of these changes)

Several examples still require scipy.

examples/ViewBox.py

@@ -14,7 +14,6 @@ import initExample
 
 ## This example uses a ViewBox to create a PlotWidget-like interface
 
-#from scipy import random
 import numpy as np
 from pyqtgraph.Qt import QtGui, QtCore
 import pyqtgraph as pg

pyqtgraph/SRTTransform3D.py

@@ -4,7 +4,6 @@ from .Vector import Vector
 from .Transform3D import Transform3D
 from .Vector import Vector
 import numpy as np
-import scipy.linalg
 
 class SRTTransform3D(Transform3D):
     """4x4 Transform matrix that can always be represented as a combination of 3 matrices: scale * rotate * translate
@@ -118,6 +117,7 @@ class SRTTransform3D(Transform3D):
         The input matrix must be affine AND have no shear,
         otherwise the conversion will most likely fail.
         """
+        import numpy.linalg
         for i in range(4):
             self.setRow(i, m.row(i))
         m = self.matrix().reshape(4,4)
@@ -134,7 +134,7 @@ class SRTTransform3D(Transform3D):
         ## rotation axis is the eigenvector with eigenvalue=1
         r = m[:3, :3] / scale[:, np.newaxis]
         try:
-            evals, evecs = scipy.linalg.eig(r)
+            evals, evecs = numpy.linalg.eig(r)
         except:
             print("Rotation matrix: %s" % str(r))
             print("Scale: %s" % str(scale))

pyqtgraph/colormap.py

@@ -1,5 +1,4 @@
 import numpy as np
-import scipy.interpolate
 from .Qt import QtGui, QtCore
 
 class ColorMap(object):
@@ -84,6 +83,11 @@ class ColorMap(object):
         qcolor      Values are returned as an array of QColor objects.
         =========== ===============================================================
         """
+        try:
+            import scipy.interpolate
+        except:
+            raise Exception("Colormap.map() requires the package scipy.interpolate, but it could not be imported.")
+        
         if isinstance(mode, basestring):
             mode = self.enumMap[mode.lower()]
             

pyqtgraph/flowchart/library/Filters.py

@@ -1,9 +1,6 @@
 # -*- coding: utf-8 -*-
 from ...Qt import QtCore, QtGui
 from ..Node import Node
-from scipy.signal import detrend
-from scipy.ndimage import median_filter, gaussian_filter
-#from ...SignalProxy import SignalProxy
 from . import functions
 from .common import *
 import numpy as np
@@ -119,7 +116,11 @@ class Median(CtrlNode):
     
     @metaArrayWrapper
     def processData(self, data):
-        return median_filter(data, self.ctrls['n'].value())
+        try:
+            import scipy.ndimage
+        except ImportError:
+            raise Exception("MedianFilter node requires the package scipy.ndimage.")
+        return scipy.ndimage.median_filter(data, self.ctrls['n'].value())
 
 class Mode(CtrlNode):
     """Filters data by taking the mode (histogram-based) of a sliding window"""
@@ -156,7 +157,11 @@ class Gaussian(CtrlNode):
     
     @metaArrayWrapper
     def processData(self, data):
-        return gaussian_filter(data, self.ctrls['sigma'].value())
+        try:
+            import scipy.ndimage
+        except ImportError:
+            raise Exception("GaussianFilter node requires the package scipy.ndimage.")
+        return scipy.ndimage.gaussian_filter(data, self.ctrls['sigma'].value())
 
 
 class Derivative(CtrlNode):
@@ -189,6 +194,10 @@ class Detrend(CtrlNode):
     
     @metaArrayWrapper
     def processData(self, data):
+        try:
+            from scipy.signal import detrend
+        except ImportError:
+            raise Exception("DetrendFilter node requires the package scipy.signal.")
         return detrend(data)
 
 

pyqtgraph/flowchart/library/functions.py

@@ -1,4 +1,3 @@
-import scipy
 import numpy as np
 from ...metaarray import MetaArray
 
@@ -47,6 +46,11 @@ def downsample(data, n, axis=0, xvals='subsample'):
 def applyFilter(data, b, a, padding=100, bidir=True):
     """Apply a linear filter with coefficients a, b. Optionally pad the data before filtering
     and/or run the filter in both directions."""
+    try:
+        import scipy.signal
+    except ImportError:
+        raise Exception("applyFilter() requires the package scipy.signal.")
+    
     d1 = data.view(np.ndarray)
     
     if padding > 0:
@@ -67,6 +71,11 @@ def applyFilter(data, b, a, padding=100, bidir=True):
     
 def besselFilter(data, cutoff, order=1, dt=None, btype='low', bidir=True):
     """return data passed through bessel filter"""
+    try:
+        import scipy.signal
+    except ImportError:
+        raise Exception("besselFilter() requires the package scipy.signal.")
+    
     if dt is None:
         try:
             tvals = data.xvals('Time')
@@ -85,6 +94,11 @@ def besselFilter(data, cutoff, order=1, dt=None, btype='low', bidir=True):
 
 def butterworthFilter(data, wPass, wStop=None, gPass=2.0, gStop=20.0, order=1, dt=None, btype='low', bidir=True):
     """return data passed through bessel filter"""
+    try:
+        import scipy.signal
+    except ImportError:
+        raise Exception("butterworthFilter() requires the package scipy.signal.")
+    
     if dt is None:
         try:
             tvals = data.xvals('Time')
@@ -175,6 +189,11 @@ def denoise(data, radius=2, threshold=4):
 
 def adaptiveDetrend(data, x=None, threshold=3.0):
     """Return the signal with baseline removed. Discards outliers from baseline measurement."""
+    try:
+        import scipy.signal
+    except ImportError:
+        raise Exception("adaptiveDetrend() requires the package scipy.signal.")
+    
     if x is None:
         x = data.xvals(0)
     

pyqtgraph/functions.py

@@ -34,17 +34,6 @@ import decimal, re
 import ctypes
 import sys, struct
 
-try:
-    import scipy.ndimage
-    HAVE_SCIPY = True
-    if getConfigOption('useWeave'):
-        try:
-            import scipy.weave
-        except ImportError:
-            setConfigOptions(useWeave=False)
-except ImportError:
-    HAVE_SCIPY = False
-
 from . import debug
 
 def siScale(x, minVal=1e-25, allowUnicode=True):
@@ -422,7 +411,9 @@ def affineSlice(data, shape, origin, vectors, axes, order=1, returnCoords=False,
         affineSlice(data, shape=(20,20), origin=(40,0,0), vectors=((-1, 1, 0), (-1, 0, 1)), axes=(1,2,3))
     
     """
-    if not HAVE_SCIPY:
+    try:
+        import scipy.ndimage
+    except ImportError:
         raise Exception("This function requires the scipy library, but it does not appear to be importable.")
 
     # sanity check
@@ -579,15 +570,14 @@ def solve3DTransform(points1, points2):
     Find a 3D transformation matrix that maps points1 onto points2.
     Points must be specified as a list of 4 Vectors.
     """
-    if not HAVE_SCIPY:
-        raise Exception("This function depends on the scipy library, but it does not appear to be importable.")
+    import numpy.linalg
     A = np.array([[points1[i].x(), points1[i].y(), points1[i].z(), 1] for i in range(4)])
     B = np.array([[points2[i].x(), points2[i].y(), points2[i].z(), 1] for i in range(4)])
     
     ## solve 3 sets of linear equations to determine transformation matrix elements
     matrix = np.zeros((4,4))
     for i in range(3):
-        matrix[i] = scipy.linalg.solve(A, B[:,i])  ## solve Ax = B; x is one row of the desired transformation matrix
+        matrix[i] = numpy.linalg.solve(A, B[:,i])  ## solve Ax = B; x is one row of the desired transformation matrix
     
     return matrix
     
@@ -600,8 +590,7 @@ def solveBilinearTransform(points1, points2):
     
         mapped = np.dot(matrix, [x*y, x, y, 1])
     """
-    if not HAVE_SCIPY:
-        raise Exception("This function depends on the scipy library, but it does not appear to be importable.")
+    import numpy.linalg
     ## A is 4 rows (points) x 4 columns (xy, x, y, 1)
     ## B is 4 rows (points) x 2 columns (x, y)
     A = np.array([[points1[i].x()*points1[i].y(), points1[i].x(), points1[i].y(), 1] for i in range(4)])
@@ -610,7 +599,7 @@ def solveBilinearTransform(points1, points2):
     ## solve 2 sets of linear equations to determine transformation matrix elements
     matrix = np.zeros((2,4))
     for i in range(2):
-        matrix[i] = scipy.linalg.solve(A, B[:,i])  ## solve Ax = B; x is one row of the desired transformation matrix
+        matrix[i] = numpy.linalg.solve(A, B[:,i])  ## solve Ax = B; x is one row of the desired transformation matrix
     
     return matrix
     
@@ -629,6 +618,10 @@ def rescaleData(data, scale, offset, dtype=None):
     try:
         if not getConfigOption('useWeave'):
             raise Exception('Weave is disabled; falling back to slower version.')
+        try:
+            import scipy.weave
+        except ImportError:
+            raise Exception('scipy.weave is not importable; falling back to slower version.')
         
         ## require native dtype when using weave
         if not data.dtype.isnative:
@@ -671,68 +664,13 @@ def applyLookupTable(data, lut):
     Uses values in *data* as indexes to select values from *lut*.
     The returned data has shape data.shape + lut.shape[1:]
     
-    Uses scipy.weave to improve performance if it is available.
     Note: color gradient lookup tables can be generated using GradientWidget.
     """
     if data.dtype.kind not in ('i', 'u'):
         data = data.astype(int)
     
-    ## using np.take appears to be faster than even the scipy.weave method and takes care of clipping as well.
     return np.take(lut, data, axis=0, mode='clip')  
     
-    ### old methods: 
-    #data = np.clip(data, 0, lut.shape[0]-1)
-    
-    #try:
-        #if not USE_WEAVE:
-            #raise Exception('Weave is disabled; falling back to slower version.')
-        
-        ### number of values to copy for each LUT lookup
-        #if lut.ndim == 1:
-            #ncol = 1
-        #else:
-            #ncol = sum(lut.shape[1:])
-        
-        ### output array
-        #newData = np.empty((data.size, ncol), dtype=lut.dtype)
-        
-        ### flattened input arrays
-        #flatData = data.flatten()
-        #flatLut = lut.reshape((lut.shape[0], ncol))
-        
-        #dataSize = data.size
-        
-        ### strides for accessing each item 
-        #newStride = newData.strides[0] / newData.dtype.itemsize
-        #lutStride = flatLut.strides[0] / flatLut.dtype.itemsize
-        #dataStride = flatData.strides[0] / flatData.dtype.itemsize
-        
-        ### strides for accessing individual values within a single LUT lookup
-        #newColStride = newData.strides[1] / newData.dtype.itemsize
-        #lutColStride = flatLut.strides[1] / flatLut.dtype.itemsize
-        
-        #code = """
-        
-        #for( int i=0; i<dataSize; i++ ) {
-            #for( int j=0; j<ncol; j++ ) {
-                #newData[i*newStride + j*newColStride] = flatLut[flatData[i*dataStride]*lutStride + j*lutColStride];
-            #}
-        #}
-        #"""
-        #scipy.weave.inline(code, ['flatData', 'flatLut', 'newData', 'dataSize', 'ncol', 'newStride', 'lutStride', 'dataStride', 'newColStride', 'lutColStride'])
-        #newData = newData.reshape(data.shape + lut.shape[1:])
-        ##if np.any(newData != lut[data]):
-            ##print "mismatch!"
-            
-        #data = newData
-    #except:
-        #if USE_WEAVE:
-            #debug.printExc("Error; disabling weave.")
-            #USE_WEAVE = False
-        #data = lut[data]
-        
-    #return data
-
 
 def makeRGBA(*args, **kwds):
     """Equivalent to makeARGB(..., useRGBA=True)"""
@@ -1473,7 +1411,11 @@ def traceImage(image, values, smooth=0.5):
     If image is RGB or RGBA, then the shape of values should be (nvals, 3/4)
     The parameter *smooth* is expressed in pixels.
     """
-    import scipy.ndimage as ndi
+    try:
+        import scipy.ndimage as ndi
+    except ImportError:
+        raise Exception("traceImage() requires the package scipy.ndimage, but it is not importable.")
+    
     if values.ndim == 2:
         values = values.T
     values = values[np.newaxis, np.newaxis, ...].astype(float)
@@ -1967,14 +1909,16 @@ def invertQTransform(tr):
     bugs in that method. (specifically, Qt has floating-point precision issues
     when determining whether a matrix is invertible)
     """
-    if not HAVE_SCIPY:
+    try:
+        import numpy.linalg
+        arr = np.array([[tr.m11(), tr.m12(), tr.m13()], [tr.m21(), tr.m22(), tr.m23()], [tr.m31(), tr.m32(), tr.m33()]])
+        inv = numpy.linalg.inv(arr)
+        return QtGui.QTransform(inv[0,0], inv[0,1], inv[0,2], inv[1,0], inv[1,1], inv[1,2], inv[2,0], inv[2,1])
+    except ImportError:
         inv = tr.inverted()
         if inv[1] is False:
             raise Exception("Transform is not invertible.")
         return inv[0]
-    arr = np.array([[tr.m11(), tr.m12(), tr.m13()], [tr.m21(), tr.m22(), tr.m23()], [tr.m31(), tr.m32(), tr.m33()]])
-    inv = scipy.linalg.inv(arr)
-    return QtGui.QTransform(inv[0,0], inv[0,1], inv[0,2], inv[1,0], inv[1,1], inv[1,2], inv[2,0], inv[2,1])
     
     
 def pseudoScatter(data, spacing=None, shuffle=True, bidir=False):

pyqtgraph/graphicsItems/PlotDataItem.py

@@ -655,7 +655,10 @@ class PlotDataItem(GraphicsObject):
         dx = np.diff(x)
         uniform = not np.any(np.abs(dx-dx[0]) > (abs(dx[0]) / 1000.))
         if not uniform:
-            import scipy.interpolate as interp
+            try:
+                import scipy.interpolate as interp
+            except:
+                raise Exception('Fourier transform of irregularly-sampled data requires the package scipy.interpolate.')
             x2 = np.linspace(x[0], x[-1], len(x))
             y = interp.griddata(x, y, x2, method='linear')
             x = x2

pyqtgraph/graphicsItems/ROI.py

@@ -13,11 +13,8 @@ of how to build an ROI at the bottom of the file.
 """
 
 from ..Qt import QtCore, QtGui
-#if not hasattr(QtCore, 'Signal'):
-    #QtCore.Signal = QtCore.pyqtSignal
 import numpy as np
-from numpy.linalg import norm
-import scipy.ndimage as ndimage
+#from numpy.linalg import norm
 from ..Point import *
 from ..SRTTransform import SRTTransform
 from math import cos, sin