""" The rechunk module defines: intersect_chunks: a function for converting chunks to new dimensions rechunk: a function to convert the blocks of an existing dask array to new chunks or blockshape """ from __future__ import absolute_import, division, print_function import math import heapq from itertools import product, chain, count from operator import getitem, add, mul, itemgetter import numpy as np import toolz from toolz import accumulate, reduce from ..base import tokenize from ..highlevelgraph import HighLevelGraph from ..utils import parse_bytes from .core import concatenate3, Array, normalize_chunks from .utils import validate_axis from .wrap import empty from .. import config def cumdims_label(chunks, const): """ Internal utility for cumulative sum with label. >>> cumdims_label(((5, 3, 3), (2, 2, 1)), 'n') # doctest: +NORMALIZE_WHITESPACE [(('n', 0), ('n', 5), ('n', 8), ('n', 11)), (('n', 0), ('n', 2), ('n', 4), ('n', 5))] """ return [tuple(zip((const,) * (1 + len(bds)), accumulate(add, (0,) + bds))) for bds in chunks] def _breakpoints(cumold, cumnew): """ >>> new = cumdims_label(((2, 3), (2, 2, 1)), 'n') >>> old = cumdims_label(((2, 2, 1), (5,)), 'o') >>> _breakpoints(new[0], old[0]) (('n', 0), ('o', 0), ('n', 2), ('o', 2), ('o', 4), ('n', 5), ('o', 5)) >>> _breakpoints(new[1], old[1]) (('n', 0), ('o', 0), ('n', 2), ('n', 4), ('n', 5), ('o', 5)) """ return tuple(sorted(cumold + cumnew, key=itemgetter(1))) def _intersect_1d(breaks): """ Internal utility to intersect chunks for 1d after preprocessing. >>> new = cumdims_label(((2, 3), (2, 2, 1)), 'n') >>> old = cumdims_label(((2, 2, 1), (5,)), 'o') >>> _intersect_1d(_breakpoints(old[0], new[0])) # doctest: +NORMALIZE_WHITESPACE [[(0, slice(0, 2, None))], [(1, slice(0, 2, None)), (2, slice(0, 1, None))]] >>> _intersect_1d(_breakpoints(old[1], new[1])) # doctest: +NORMALIZE_WHITESPACE [[(0, slice(0, 2, None))], [(0, slice(2, 4, None))], [(0, slice(4, 5, None))]] Parameters ---------- breaks: list of tuples Each tuple is ('o', 8) or ('n', 8) These are pairs of 'o' old or new 'n' indicator with a corresponding cumulative sum. Uses 'o' and 'n' to make new tuples of slices for the new block crosswalk to old blocks. """ start = 0 last_end = 0 old_idx = 0 ret = [] ret_next = [] for idx in range(1, len(breaks)): label, br = breaks[idx] last_label, last_br = breaks[idx - 1] if last_label == 'n': if ret_next: ret.append(ret_next) ret_next = [] if last_label == 'o': start = 0 else: start = last_end end = br - last_br + start last_end = end if br == last_br: continue ret_next.append((old_idx, slice(start, end))) if label == 'o': old_idx += 1 start = 0 if ret_next: ret.append(ret_next) return ret def _old_to_new(old_chunks, new_chunks): """ Helper to build old_chunks to new_chunks. Handles missing values, as long as the missing dimension is unchanged. Examples -------- >>> old = ((10, 10, 10, 10, 10), ) >>> new = ((25, 5, 20), ) >>> _old_to_new(old, new) # doctest: +NORMALIZE_WHITESPACE [[[(0, slice(0, 10, None)), (1, slice(0, 10, None)), (2, slice(0, 5, None))], [(2, slice(5, 10, None))], [(3, slice(0, 10, None)), (4, slice(0, 10, None))]]] """ old_known = [x for x in old_chunks if not any(math.isnan(y) for y in x)] new_known = [x for x in new_chunks if not any(math.isnan(y) for y in x)] n_missing = [sum(math.isnan(y) for y in x) for x in old_chunks] n_missing2 = [sum(math.isnan(y) for y in x) for x in new_chunks] cmo = cumdims_label(old_known, 'o') cmn = cumdims_label(new_known, 'n') sums = [sum(o) for o in old_known] sums2 = [sum(n) for n in new_known] if not sums == sums2: raise ValueError('Cannot change dimensions from %r to %r' % (sums, sums2)) if not n_missing == n_missing2: raise ValueError('Chunks must be unchanging along unknown dimensions') old_to_new = [_intersect_1d(_breakpoints(cm[0], cm[1])) for cm in zip(cmo, cmn)] for idx, missing in enumerate(n_missing): if missing: # Missing dimensions are always unchanged, so old -> new is everything extra = [[(i, slice(0, None))] for i in range(missing)] old_to_new.insert(idx, extra) return old_to_new def intersect_chunks(old_chunks, new_chunks): """ Make dask.array slices as intersection of old and new chunks. >>> intersections = intersect_chunks(((4, 4), (2,)), ... ((8,), (1, 1))) >>> list(intersections) # doctest: +NORMALIZE_WHITESPACE [(((0, slice(0, 4, None)), (0, slice(0, 1, None))), ((1, slice(0, 4, None)), (0, slice(0, 1, None)))), (((0, slice(0, 4, None)), (0, slice(1, 2, None))), ((1, slice(0, 4, None)), (0, slice(1, 2, None))))] Parameters ---------- old_chunks : iterable of tuples block sizes along each dimension (convert from old_chunks) new_chunks: iterable of tuples block sizes along each dimension (converts to new_chunks) """ old_to_new = _old_to_new(old_chunks, new_chunks) cross1 = product(*old_to_new) cross = chain(tuple(product(*cr)) for cr in cross1) return cross def rechunk(x, chunks, threshold=None, block_size_limit=None): """ Convert blocks in dask array x for new chunks. Parameters ---------- x: dask array Array to be rechunked. chunks: int, tuple or dict The new block dimensions to create. -1 indicates the full size of the corresponding dimension. threshold: int The graph growth factor under which we don't bother introducing an intermediate step. block_size_limit: int The maximum block size (in bytes) we want to produce Defaults to the configuration value ``array.chunk-size`` Examples -------- >>> import dask.array as da >>> x = da.ones((1000, 1000), chunks=(100, 100)) Specify uniform chunk sizes with a tuple >>> y = x.rechunk((1000, 10)) Or chunk only specific dimensions with a dictionary >>> y = x.rechunk({0: 1000}) Use the value ``-1`` to specify that you want a single chunk along a dimension or the value ``"auto"`` to specify that dask can freely rechunk a dimension to attain blocks of a uniform block size >>> y = x.rechunk({0: -1, 1: 'auto'}, block_size_limit=1e8) """ if isinstance(chunks, dict): chunks = {validate_axis(c, x.ndim): v for c, v in chunks.items()} for i in range(x.ndim): if i not in chunks: chunks[i] = x.chunks[i] if isinstance(chunks, (tuple, list)): chunks = tuple(lc if lc is not None else rc for lc, rc in zip(chunks, x.chunks)) chunks = normalize_chunks(chunks, x.shape, limit=block_size_limit, dtype=x.dtype, previous_chunks=x.chunks) if chunks == x.chunks: return x ndim = x.ndim if not len(chunks) == ndim: raise ValueError("Provided chunks are not consistent with shape") new_shapes = tuple(map(sum, chunks)) for new, old in zip(new_shapes, x.shape): if new != old and not math.isnan(old) and not math.isnan(new): raise ValueError("Provided chunks are not consistent with shape") steps = plan_rechunk(x.chunks, chunks, x.dtype.itemsize, threshold, block_size_limit) for c in steps: x = _compute_rechunk(x, c) return x def _number_of_blocks(chunks): return reduce(mul, map(len, chunks)) def _largest_block_size(chunks): return reduce(mul, map(max, chunks)) def estimate_graph_size(old_chunks, new_chunks): """ Estimate the graph size during a rechunk computation. """ # Estimate the number of intermediate blocks that will be produced # (we don't use intersect_chunks() which is much more expensive) crossed_size = reduce(mul, (len(oc) + len(nc) for oc, nc in zip(old_chunks, new_chunks))) return crossed_size def divide_to_width(desired_chunks, max_width): """ Minimally divide the given chunks so as to make the largest chunk width less or equal than *max_width*. """ chunks = [] for c in desired_chunks: nb_divides = int(np.ceil(c / max_width)) for i in range(nb_divides): n = c // (nb_divides - i) chunks.append(n) c -= n assert c == 0 return tuple(chunks) def merge_to_number(desired_chunks, max_number): """ Minimally merge the given chunks so as to drop the number of chunks below *max_number*, while minimizing the largest width. """ if len(desired_chunks) <= max_number: return desired_chunks distinct = set(desired_chunks) if len(distinct) == 1: # Fast path for homogeneous target, also ensuring a regular result w = distinct.pop() n = len(desired_chunks) total = n * w desired_width = total // max_number width = w * (desired_width // w) adjust = (total - max_number * width) // w return (width + w,) * adjust + (width,) * (max_number - adjust) desired_width = sum(desired_chunks) // max_number nmerges = len(desired_chunks) - max_number heap = [(desired_chunks[i] + desired_chunks[i + 1], i, i + 1) for i in range(len(desired_chunks) - 1)] heapq.heapify(heap) chunks = list(desired_chunks) while nmerges > 0: # Find smallest interval to merge width, i, j = heapq.heappop(heap) # If interval was made invalid by another merge, recompute # it, re-insert it and retry. if chunks[j] == 0: j += 1 while chunks[j] == 0: j += 1 heapq.heappush(heap, (chunks[i] + chunks[j], i, j)) continue elif chunks[i] + chunks[j] != width: heapq.heappush(heap, (chunks[i] + chunks[j], i, j)) continue # Merge assert chunks[i] != 0 chunks[i] = 0 # mark deleted chunks[j] = width nmerges -= 1 return tuple(filter(None, chunks)) def find_merge_rechunk(old_chunks, new_chunks, block_size_limit): """ Find an intermediate rechunk that would merge some adjacent blocks together in order to get us nearer the *new_chunks* target, without violating the *block_size_limit* (in number of elements). """ ndim = len(old_chunks) old_largest_width = [max(c) for c in old_chunks] new_largest_width = [max(c) for c in new_chunks] graph_size_effect = { dim: len(nc) / len(oc) for dim, (oc, nc) in enumerate(zip(old_chunks, new_chunks)) } block_size_effect = { dim: new_largest_width[dim] / (old_largest_width[dim] or 1) for dim in range(ndim) } # Our goal is to reduce the number of nodes in the rechunk graph # by merging some adjacent chunks, so consider dimensions where we can # reduce the # of chunks merge_candidates = [dim for dim in range(ndim) if graph_size_effect[dim] <= 1.0] # Merging along each dimension reduces the graph size by a certain factor # and increases memory largest block size by a certain factor. # We want to optimize the graph size while staying below the given # block_size_limit. This is in effect a knapsack problem, except with # multiplicative values and weights. Just use a greedy algorithm # by trying dimensions in decreasing value / weight order. def key(k): gse = graph_size_effect[k] bse = block_size_effect[k] if bse == 1: bse = 1 + 1e-9 return (np.log(gse) / np.log(bse)) if bse > 0 else 0 sorted_candidates = sorted(merge_candidates, key=key) largest_block_size = reduce(mul, old_largest_width) chunks = list(old_chunks) memory_limit_hit = False for dim in sorted_candidates: # Examine this dimension for possible graph reduction new_largest_block_size = ( largest_block_size * new_largest_width[dim] // (old_largest_width[dim] or 1)) if new_largest_block_size <= block_size_limit: # Full replacement by new chunks is possible chunks[dim] = new_chunks[dim] largest_block_size = new_largest_block_size else: # Try a partial rechunk, dividing the new chunks into # smaller pieces largest_width = old_largest_width[dim] chunk_limit = int(block_size_limit * largest_width / largest_block_size) c = divide_to_width(new_chunks[dim], chunk_limit) if len(c) <= len(old_chunks[dim]): # We manage to reduce the number of blocks, so do it chunks[dim] = c largest_block_size = largest_block_size * max(c) // largest_width memory_limit_hit = True assert largest_block_size == _largest_block_size(chunks) assert largest_block_size <= block_size_limit return tuple(chunks), memory_limit_hit def find_split_rechunk(old_chunks, new_chunks, graph_size_limit): """ Find an intermediate rechunk that would split some chunks to get us nearer *new_chunks*, without violating the *graph_size_limit*. """ ndim = len(old_chunks) chunks = list(old_chunks) for dim in range(ndim): graph_size = estimate_graph_size(chunks, new_chunks) if graph_size > graph_size_limit: break if len(old_chunks[dim]) > len(new_chunks[dim]): # It's not interesting to split continue # Merge the new chunks so as to stay within the graph size budget max_number = int(len(old_chunks[dim]) * graph_size_limit / graph_size) c = merge_to_number(new_chunks[dim], max_number) assert len(c) <= max_number # Consider the merge successful if its result has a greater length # and smaller max width than the old chunks if len(c) >= len(old_chunks[dim]) and max(c) <= max(old_chunks[dim]): chunks[dim] = c return tuple(chunks) def plan_rechunk(old_chunks, new_chunks, itemsize, threshold=None, block_size_limit=None): """ Plan an iterative rechunking from *old_chunks* to *new_chunks*. The plan aims to minimize the rechunk graph size. Parameters ---------- itemsize: int The item size of the array threshold: int The graph growth factor under which we don't bother introducing an intermediate step block_size_limit: int The maximum block size (in bytes) we want to produce during an intermediate step Notes ----- No intermediate steps will be planned if any dimension of ``old_chunks`` is unknown. """ threshold = threshold or config.get('array.rechunk-threshold') block_size_limit = block_size_limit or config.get('array.chunk-size') if isinstance(block_size_limit, str): block_size_limit = parse_bytes(block_size_limit) ndim = len(new_chunks) steps = [] has_nans = [any(math.isnan(y) for y in x) for x in old_chunks] if ndim <= 1 or not all(new_chunks) or any(has_nans): # Trivial array / unknown dim => no need / ability for an intermediate return steps + [new_chunks] # Make it a number ef elements block_size_limit /= itemsize # Fix block_size_limit if too small for either old_chunks or new_chunks largest_old_block = _largest_block_size(old_chunks) largest_new_block = _largest_block_size(new_chunks) block_size_limit = max([block_size_limit, largest_old_block, largest_new_block, ]) # The graph size above which to optimize graph_size_threshold = threshold * (_number_of_blocks(old_chunks) + _number_of_blocks(new_chunks)) current_chunks = old_chunks first_pass = True while True: graph_size = estimate_graph_size(current_chunks, new_chunks) if graph_size < graph_size_threshold: break if first_pass: chunks = current_chunks else: # We hit the block_size_limit in a previous merge pass => # accept a significant increase in graph size in exchange for # 1) getting nearer the goal 2) reducing the largest block size # to make place for the following merge. # To see this pass in action, make the block_size_limit very small. chunks = find_split_rechunk(current_chunks, new_chunks, graph_size * threshold) chunks, memory_limit_hit = find_merge_rechunk(chunks, new_chunks, block_size_limit) if (chunks == current_chunks and not first_pass) or chunks == new_chunks: break steps.append(chunks) current_chunks = chunks if not memory_limit_hit: break first_pass = False return steps + [new_chunks] def _compute_rechunk(x, chunks): """ Compute the rechunk of *x* to the given *chunks*. """ if x.size == 0: # Special case for empty array, as the algorithm below does not behave correctly return empty(x.shape, chunks=chunks, dtype=x.dtype) ndim = x.ndim crossed = intersect_chunks(x.chunks, chunks) x2 = dict() intermediates = dict() token = tokenize(x, chunks) merge_name = 'rechunk-merge-' + token split_name = 'rechunk-split-' + token split_name_suffixes = count() # Pre-allocate old block references, to allow re-use and reduce the # graph's memory footprint a bit. old_blocks = np.empty([len(c) for c in x.chunks], dtype='O') for index in np.ndindex(old_blocks.shape): old_blocks[index] = (x.name,) + index # Iterate over all new blocks new_index = product(*(range(len(c)) for c in chunks)) for new_idx, cross1 in zip(new_index, crossed): key = (merge_name,) + new_idx old_block_indices = [[cr[i][0] for cr in cross1] for i in range(ndim)] subdims1 = [len(set(old_block_indices[i])) for i in range(ndim)] rec_cat_arg = np.empty(subdims1, dtype='O') rec_cat_arg_flat = rec_cat_arg.flat # Iterate over the old blocks required to build the new block for rec_cat_index, ind_slices in enumerate(cross1): old_block_index, slices = zip(*ind_slices) name = (split_name, next(split_name_suffixes)) old_index = old_blocks[old_block_index][1:] if all(slc.start == 0 and slc.stop == x.chunks[i][ind] for i, (slc, ind) in enumerate(zip(slices, old_index))): rec_cat_arg_flat[rec_cat_index] = old_blocks[old_block_index] else: intermediates[name] = (getitem, old_blocks[old_block_index], slices) rec_cat_arg_flat[rec_cat_index] = name assert rec_cat_index == rec_cat_arg.size - 1 # New block is formed by concatenation of sliced old blocks if all(d == 1 for d in rec_cat_arg.shape): x2[key] = rec_cat_arg.flat[0] else: x2[key] = (concatenate3, rec_cat_arg.tolist()) del old_blocks, new_index layer = toolz.merge(x2, intermediates) graph = HighLevelGraph.from_collections(merge_name, layer, dependencies=[x]) return Array(graph, merge_name, chunks, dtype=x.dtype) class _PrettyBlocks(object): def __init__(self, blocks): self.blocks = blocks def __str__(self): runs = [] run = [] repeats = 0 for c in self.blocks: if run and run[-1] == c: if repeats == 0 and len(run) > 1: runs.append((None, run[:-1])) run = run[-1:] repeats += 1 else: if repeats > 0: assert len(run) == 1 runs.append((repeats + 1, run[-1])) run = [] repeats = 0 run.append(c) if run: if repeats == 0: runs.append((None, run)) else: assert len(run) == 1 runs.append((repeats + 1, run[-1])) parts = [] for repeats, run in runs: if repeats is None: parts.append(str(run)) else: parts.append("%d*[%s]" % (repeats, run)) return " | ".join(parts) __repr__ = __str__ def format_blocks(blocks): """ Pretty-format *blocks*. >>> format_blocks((10, 10, 10)) 3*[10] >>> format_blocks((2, 3, 4)) [2, 3, 4] >>> format_blocks((10, 10, 5, 6, 2, 2, 2, 7)) 2*[10] | [5, 6] | 3*[2] | [7] """ assert (isinstance(blocks, tuple) and all(isinstance(x, int) or math.isnan(x) for x in blocks)) return _PrettyBlocks(blocks) def format_chunks(chunks): """ >>> format_chunks((10 * (3,), 3 * (10,))) (10*[3], 3*[10]) """ assert isinstance(chunks, tuple) return tuple(format_blocks(c) for c in chunks) def format_plan(plan): """ >>> format_plan([((10, 10, 10), (15, 15)), ((30,), (10, 10, 10))]) [(3*[10], 2*[15]), ([30], 3*[10])] """ return [format_chunks(c) for c in plan]