I just came across the need of an incremental Numpy array in Python, and since I haven't found anything I implemented it. I'm just wondering if my way is the best way or you can come up with other ideas.
So, the problem is that I have a 2D array (the program handles nD arrays) for which the size is not known in advance and variable amount of data need to be concatenated to the array in one direction (let's say that I've to call np.vstak a lot of times). Every time I concatenate data, I need to take the array, sort it along axis 0 and do other stuff, so I cannot construct a long list of arrays and then np.vstak the list at once. Since memory allocation is expensive, I turned to incremental arrays, where I increment the size of the array of a quantity bigger than the size I need (I use 50% increments), so that I minimize the number of allocations.
I coded this up and you can see it in the following code:
class ExpandingArray: __DEFAULT_ALLOC_INIT_DIM = 10 # default initial dimension for all the axis is nothing is given by the user __DEFAULT_MAX_INCREMENT = 10 # default value in order to limit the increment of memory allocation __MAX_INCREMENT =  # Max increment __ALLOC_DIMS =  # Dimensions of the allocated np.array __DIMS =  # Dimensions of the view with data on the allocated np.array (__DIMS <= __ALLOC_DIMS) __ARRAY =  # Allocated array def __init__(self,initData,allocInitDim=None,dtype=np.float64,maxIncrement=None): self.__DIMS = np.array(initData.shape) self.__MAX_INCREMENT = maxIncrement if self.__MAX_INCREMENT == None: self.__MAX_INCREMENT = self.__DEFAULT_MAX_INCREMENT # Compute the allocation dimensions based on user's input if allocInitDim == None: allocInitDim = self.__DIMS.copy() while np.any( allocInitDim < self.__DIMS ) or np.any(allocInitDim == 0): for i in range(len(self.__DIMS)): if allocInitDim[i] == 0: allocInitDim[i] = self.__DEFAULT_ALLOC_INIT_DIM if allocInitDim[i] < self.__DIMS[i]: allocInitDim[i] += min(allocInitDim[i]/2, self.__MAX_INCREMENT) # Allocate memory self.__ALLOC_DIMS = allocInitDim self.__ARRAY = np.zeros(self.__ALLOC_DIMS,dtype=dtype) # Set initData sliceIdxs = [slice(self.__DIMS[i]) for i in range(len(self.__DIMS))] self.__ARRAY[sliceIdxs] = initData def shape(self): return tuple(self.__DIMS) def getAllocArray(self): return self.__ARRAY def getDataArray(self): """ Get the view of the array with data """ sliceIdxs = [slice(self.__DIMS[i]) for i in range(len(self.__DIMS))] return self.__ARRAY[sliceIdxs] def concatenate(self,X,axis=0): if axis > len(self.__DIMS): print "Error: axis number exceed the number of dimensions" return # Check dimensions for remaining axis for i in range(len(self.__DIMS)): if i != axis: if X.shape[i] != self.shape()[i]: print "Error: Dimensions of the input array are not consistent in the axis %d" % i return # Check whether allocated memory is enough needAlloc = False while self.__ALLOC_DIMS[axis] < self.__DIMS[axis] + X.shape[axis]: needAlloc = True # Increase the __ALLOC_DIMS self.__ALLOC_DIMS[axis] += min(self.__ALLOC_DIMS[axis]/2,self.__MAX_INCREMENT) # Reallocate memory and copy old data if needAlloc: # Allocate newArray = np.zeros(self.__ALLOC_DIMS) # Copy sliceIdxs = [slice(self.__DIMS[i]) for i in range(len(self.__DIMS))] newArray[sliceIdxs] = self.__ARRAY[sliceIdxs] self.__ARRAY = newArray # Concatenate new data sliceIdxs =  for i in range(len(self.__DIMS)): if i != axis: sliceIdxs.append(slice(self.__DIMS[i])) else: sliceIdxs.append(slice(self.__DIMS[i],self.__DIMS[i]+X.shape[i])) self.__ARRAY[sliceIdxs] = X self.__DIMS[axis] += X.shape[axis]
The code shows considerably better performances than vstack/hstack several random sized concatenations.
What I'm wondering about is: is it the best way? Is there anything that do this already in numpy?
Further it would be nice to be able to overload the slice assignment operator of np.array, so that as soon as the user assign anything outside the actual dimensions, an ExpandingArray.concatenate() is performed. How to do such overloading?
Testing code: I post here also some code I used to make comparison between vstack and my method. I add up random chunk of data of maximum length 100.
import time N = 10000 def performEA(N): EA = ExpandingArray(np.zeros((0,2)),maxIncrement=1000) for i in range(N): nNew = np.random.random_integers(low=1,high=100,size=1) X = np.random.rand(nNew,2) EA.concatenate(X,axis=0) # Perform operations on EA.getDataArray() return EA def performVStack(N): A = np.zeros((0,2)) for i in range(N): nNew = np.random.random_integers(low=1,high=100,size=1) X = np.random.rand(nNew,2) A = np.vstack((A,X)) # Perform operations on A return A start_EA = time.clock() EA = performEA(N) stop_EA = time.clock() start_VS = time.clock() VS = performVStack(N) stop_VS = time.clock() print "Elapsed Time EA: %.2f" % (stop_EA-start_EA) print "Elapsed Time VS: %.2f" % (stop_VS-start_VS)