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540 行
16 KiB
540 行
16 KiB
from __future__ import print_function
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from collections import defaultdict
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import numpy as np
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import json
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import struct # convert from Python values and C structs
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import re
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import argparse
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import os.path
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BARRACUDA_VERSION = 16
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# Definition of Barracuda model
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class Model:
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def __init__(self):
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self.layers = []
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self.tensors = {}
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self.inputs = {}
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self.outputs = []
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self.globals = []
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self.memories = []
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class Struct:
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"A structure that can have any fields defined."
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def __init__(self, **entries):
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self.__dict__.update(entries)
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# Parse command line argumengts
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def parse_args(description, source_extension, help):
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parser = argparse.ArgumentParser(description=description)
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parser.add_argument("source_file", help=help)
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parser.add_argument("target_file", help="output Barracuda binary file")
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parser.add_argument("-trim", "--trim-unused-by-output")
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parser.add_argument("--print-layers", action="store_true")
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parser.add_argument("--print-source-json", action="store_true")
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parser.add_argument("-json", "--print-barracuda-json", action="store_true")
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parser.add_argument("--print-layer-links", action="store_true")
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parser.add_argument("--print-patterns", action="store_true")
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parser.add_argument("--print-tensors", action="store_true")
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parser.add_argument("--verbose", action="store_true")
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args = parser.parse_args()
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args.compress_f16 = (
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False
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) # TEMP: disabled, until properly implemented parser.add_argument('-f16', '--compress-f16', action='store_true')
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output_extension = ".bc" if not args.compress_f16 else ".f16.bc"
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if not os.path.exists(args.source_file):
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args.source_file = args.source_file + source_extension
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if not os.path.exists(args.source_file):
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print("File", args.source_file, "does not exist.")
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exit(-1)
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def replaceFilenameExtension(filename, newExtenstion):
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return os.path.splitext(os.path.basename(filename))[0] + newExtenstion
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if os.path.isdir(args.target_file):
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args.target_file = os.path.join(
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args.target_file,
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replaceFilenameExtension(args.source_file, output_extension),
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)
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if args.verbose:
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print(args)
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return args
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# Fuse training time BatchNorm tensors into Scale & Bias
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def fuse_batchnorm_weights(gamma, beta, mean, var, epsilon):
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# https://github.com/Tencent/ncnn/blob/master/src/layer/batchnorm.cpp
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""" float sqrt_var = sqrt(var_data[i]);
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a_data[i] = bias_data[i] - slope_data[i] * mean_data[i] / sqrt_var;
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b_data[i] = slope_data[i] / sqrt_var;
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...
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ptr[i] = b * ptr[i] + a;
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"""
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scale = gamma / np.sqrt(var + epsilon)
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bias = beta - gamma * mean / np.sqrt(var + epsilon)
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return [scale, bias]
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# Resort layers so that all inputs are satisfied for every layer beforehand
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def sort(model, inputs, memories, verbose):
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if hasattr(model, "layers"):
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model = model.layers
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inputs_and_memories = set(list(inputs) + list(memories[1::3]))
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def find_missing_inputs(model, inputs):
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missing = set()
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ready = set(inputs)
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for l in model:
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for i in l.inputs:
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if i not in ready:
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missing.add(i)
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ready.add(l.name)
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return missing
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# Class to represent a graph
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# Taken from: https://www.geeksforgeeks.org/python-program-for-topological-sorting/
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class Graph:
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def __init__(self, vertices):
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self.graph = defaultdict(list) # dictionary containing adjacency List
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self.V = vertices # No. of vertices
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# function to add an edge to graph
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def addEdge(self, u, v):
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self.graph[u].append(v)
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# A recursive function used by topologicalSort
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def topologicalSortUtil(self, v, visited, stack):
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# Mark the current node as visited.
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visited[v] = True
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# Recur for all the vertices adjacent to this vertex
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for i in self.graph[v]:
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if visited[i] == False:
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self.topologicalSortUtil(i, visited, stack)
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# Push current vertex to stack which stores result
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stack.insert(0, v)
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# The function to do Topological Sort. It uses recursive
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# topologicalSortUtil()
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def topologicalSort(self):
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# Mark all the vertices as not visited
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visited = [False] * self.V
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stack = []
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# Call the recursive helper function to store Topological
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# Sort starting from all vertices one by one
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for i in range(self.V):
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if visited[i] == False:
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self.topologicalSortUtil(i, visited, stack)
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# print(stack)
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return stack
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if len(find_missing_inputs(model, inputs_and_memories)) == 0:
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return model
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g = Graph(len(model))
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layers = {}
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id = 0
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for l in model:
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layers[l.name] = id
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id += 1
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for layer in model:
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for i in layer.inputs:
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if i not in inputs_and_memories:
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g.addEdge(layers[i], layers[layer.name])
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sorted_layer_indices = g.topologicalSort()
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print("SORTED:", sorted_layer_indices)
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new_model = [model[idx] for idx in sorted_layer_indices]
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assert len(find_missing_inputs(new_model, inputs_and_memories)) == 0
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return new_model
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# Trim
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def trim(model, criteria_regexp_string, verbose):
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if hasattr(model, "layers"):
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model = model.layers
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def flatten(items, enter=lambda x: isinstance(x, list)):
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# http://stackoverflow.com/a/40857703
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# https://github.com/ctmakro/canton/blob/master/canton/misc.py
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"""Yield items from any nested iterable; see REF."""
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for x in items:
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if enter(x):
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yield from flatten(x)
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else:
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yield x
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def trim_model(model, outputs):
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layers = {l.name: l for l in model}
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connected = {o for o in outputs}
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while len(outputs) > 0:
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outputs = set(flatten([layers[o].inputs for o in outputs if o in layers]))
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if verbose and len(outputs) > 0:
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print(outputs)
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for o in outputs:
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connected.add(o)
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trimmed = [l.name for l in model if l.name not in connected]
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def array_without_brackets(arr):
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return str(arr)[1:-1] # array to string without brackets
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print("TRIMMED:", array_without_brackets(trimmed))
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return [l for l in model if l.name in connected]
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layer_names = {l.name for l in model}
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criteria = re.compile(criteria_regexp_string)
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preserve_outputs = list(filter(criteria.match, layer_names))
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if preserve_outputs:
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print("Trimming model given outputs to preserve:", preserve_outputs)
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model = trim_model(model, preserve_outputs)
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else:
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print(
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"WARNING: Trim couldn't find any layers to match:", criteria_regexp_string
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)
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return model
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def compress(model):
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compress_classes = {"Dense"}
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for l in model.layers:
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if l.class_name in compress_classes:
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print(
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"Compressing %s layer '%s' weights to float16" % (l.class_name, l.name)
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)
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for x in l.tensors:
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x.data = np.float16(x.data)
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return model
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# Verbose
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def to_json(model):
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class StructEncoder(json.JSONEncoder):
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def default(self, o):
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if isinstance(o, np.ndarray): # skip binary data packed inside ndarray
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return ""
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if getattr(o, "__dict__", None):
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return o.__dict__
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return str(o)
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s = json.dumps(model.layers, cls=StructEncoder, separators=(", ", ":"))
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# custom formatting
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s = s.replace("]}, {", "]},\n{")
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s = s.replace(":[{", ":[\n\t{")
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s = s.replace("}, {", "},\n\t{")
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s = s.replace('"', "'")
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return s
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def summary(model, print_layer_links, print_barracuda_json, print_tensors):
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def array_without_brackets(arr):
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return str(arr)[1:-1] # array to string without brackets
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if print_layer_links:
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for l in model.layers:
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print(l.name, " <= ", l.inputs)
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if print_barracuda_json:
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print(to_json(model))
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if model.globals:
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if isinstance(model.globals, dict):
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model.globals = {x.name: x.shape for x in model.globals}
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print("GLOBALS:", array_without_brackets(model.globals))
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for l in model.layers:
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if isinstance(model.inputs, dict):
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ins = {i: model.inputs[i] for i in l.inputs if i in model.inputs}
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else:
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ins = [i for i in l.inputs if i in model.inputs]
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if ins:
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print("IN: %s => '%s'" % (array_without_brackets(ins), l.name))
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for mem_in, mem_out in zip(model.memories[1::3], model.memories[2::3]):
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print("MEM: '%s' => '%s'" % (mem_in, mem_out))
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print("OUT:", array_without_brackets(model.outputs))
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if print_tensors:
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for l in model.layers:
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for x in l.tensors:
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print(x.name, x.shape, x.data.dtype, x.data)
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class Build:
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def __init__(self, scope=""):
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self.scope = scope
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self.layers = []
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self.names_taken = set()
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def __getattr__(self, attr):
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if attr == "_":
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return self.layers[-1].name if len(self.layer) > 0 else self.scope
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raise AttributeError(attr)
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def _patch_last_layer_name_and_return(self):
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if self.layers[-1].name:
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return self.layers[-1].name
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# generate unique name based on op and increasing id
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name = self.layers[-1].op
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i = 1
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while name in self.names_taken:
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name = self.layers[-1].op + "_" + str(i)
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i += 1
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self.names_taken.add(name)
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self.layers[-1].name = self.scope + ("/" if self.scope else "") + name
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return self.layers[-1].name
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def concat(self, a, b, out=""):
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self.layers += [Struct(name=out, op="Concat", input=[a, b])]
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return self._patch_last_layer_name_and_return()
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def mad(self, x, kernel, bias, out=""):
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self.layers += [Struct(name=out, op="Dense", input=[x, kernel, bias])]
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return self._patch_last_layer_name_and_return()
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def mul(self, a, b, out=""):
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self.layers += [Struct(name=out, op="Mul", input=[a, b])]
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return self._patch_last_layer_name_and_return()
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def add(self, a, b, out=""):
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self.layers += [Struct(name=out, op="Add", input=[a, b])]
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return self._patch_last_layer_name_and_return()
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def sub(self, a, b, out=""):
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self.layers += [Struct(name=out, op="Sub", input=[a, b])]
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return self._patch_last_layer_name_and_return()
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def sigmoid(self, x, out=""):
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self.layers += [Struct(name=out, op="Sigmoid", input=[x])]
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return self._patch_last_layer_name_and_return()
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def tanh(self, x, out=""):
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self.layers += [Struct(name=out, op="Tanh", input=[x])]
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return self._patch_last_layer_name_and_return()
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def rnn(name, input, state, kernel, bias, new_state, number_of_gates=2):
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""" - Ht = f(Xt*Wi + Ht_1*Ri + Wbi + Rbi)
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"""
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nn = Build(name)
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nn.tanh(nn.mad(kernel=kernel, bias=bias, x=nn.concat(input, state)), out=new_state)
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return nn.layers
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def gru(
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name,
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input,
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state,
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kernel_r,
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kernel_u,
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kernel_c,
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bias_r,
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bias_u,
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bias_c,
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new_state,
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number_of_gates=2,
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):
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""" - zt = f(Xt*Wz + Ht_1*Rz + Wbz + Rbz)
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- rt = f(Xt*Wr + Ht_1*Rr + Wbr + Rbr)
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- ht = g(Xt*Wh + (rt . Ht_1)*Rh + Rbh + Wbh)
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- Ht = (1-zt).ht + zt.Ht_1
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"""
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nn = Build(name)
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inputs = nn.concat(input, state)
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u = nn.sigmoid(nn.mad(inputs, kernel_u, bias_u))
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r = nn.sigmoid(nn.mad(inputs, kernel_r, bias_r))
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r_state = nn.mul(r, state)
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c = nn.tanh(nn.mad(kernel=kernel_c, bias=bias_c, x=nn.concat(input, r_state)))
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# new_h = u' * state + (1 - u') * c'
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# = u' * state + c' - u' * c'
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# u' * state + c'
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nn.add(nn.mul(u, state), c)
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# - u' * c'
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nn.sub(nn._, nn.mul(u, c), out=new_state)
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return nn.layers
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def lstm(
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name,
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input,
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state_c,
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state_h,
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kernel_i,
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kernel_j,
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kernel_f,
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kernel_o,
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bias_i,
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bias_j,
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bias_f,
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bias_o,
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new_state_c,
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new_state_h,
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):
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""" Full:
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- it = f(Xt*Wi + Ht_1*Ri + Pi . Ct_1 + Wbi + Rbi)
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- ft = f(Xt*Wf + Ht_1*Rf + Pf . Ct_1 + Wbf + Rbf)
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- ct = g(Xt*Wc + Ht_1*Rc + Wbc + Rbc)
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- Ct = ft . Ct_1 + it . ct
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- ot = f(Xt*Wo + Ht_1*Ro + Po . Ct + Wbo + Rbo)
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- Ht = ot . h(Ct)
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"""
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""" No peephole:
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- it = f(Xt*Wi + Ht_1*Ri + Wbi + Rbi)
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- ft = f(Xt*Wf + Ht_1*Rf + Wbf + Rbf)
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- ct = g(Xt*Wc + Ht_1*Rc + Wbc + Rbc)
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- Ct = ft . Ct_ + it . ct
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- ot = f(Xt*Wo + Ht_1*Ro + Wbo + Rbo)
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- Ht = ot . h(Ct)
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"""
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nn = Build(name)
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inputs = nn.concat(input, state_h)
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i = nn.sigmoid(nn.mad(x=inputs, kernel=kernel_i, bias=bias_i))
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j = nn.tanh(nn.mad(inputs, kernel_j, bias_j))
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f = nn.sigmoid(nn.mad(inputs, kernel_f, bias_f))
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o = nn.sigmoid(nn.mad(inputs, kernel_o, bias_o))
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# new_c = state_c * f' + i' * j'
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nn.add(nn.mul(state_c, f), nn.mul(i, j), out=new_state_c)
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# new_h =
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nn.mul(o, nn.tanh(new_state_c), out=new_state_h)
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return nn.layers
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# Serialize
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class BarracudaWriter:
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f = None
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def __init__(self, filename):
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self.f = open(filename, "wb+")
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def __enter__(self):
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return self
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def __exit__(self, type, value, tb):
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self.f.close()
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def write_array(self, arr):
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arr.tofile(self.f)
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def write_str_array(self, array_of_strigs):
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self.write_int32(len(array_of_strigs))
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for s in array_of_strigs:
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self.write_str(s)
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def write_str(self, s):
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self.write_int32(len(s))
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self.f.write(s.encode("ascii"))
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def write_float(self, d):
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self.f.write(struct.pack("<f", d))
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def write_int32(self, d):
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self.f.write(struct.pack("<i", d))
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def write_int64(self, d):
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self.f.write(struct.pack("<q", d))
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def write_shape(self, s):
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self.write_int32(len(s))
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for el in s:
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self.write_int32(el if el != None else -1)
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def close(self):
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self.f.close()
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def write(model, filename):
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with BarracudaWriter(filename) as w:
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# VERSION = 0xBA22AC0DA000 + BARRACUDA_VERSION
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w.write_int64(BARRACUDA_VERSION)
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# inputs
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w.write_int32(len(model.inputs))
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for name, shape in model.inputs.items():
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w.write_str(name)
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w.write_shape(shape)
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# outputs
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w.write_str_array(model.outputs)
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# memories
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w.write_int32(len(model.memories) // 3)
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for mem_shape, mem_in, mem_out in zip(
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model.memories[0::3], model.memories[1::3], model.memories[2::3]
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):
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w.write_shape(mem_shape)
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w.write_str(mem_in)
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w.write_str(mem_out)
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# layers
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offset = 0
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all_tensors = []
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w.write_int32(len(model.layers))
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for l in model.layers:
|
|
|
|
assert not l.name in l.inputs
|
|
|
|
w.write_str(l.name)
|
|
w.write_int32(l.type)
|
|
w.write_int32(l.activation)
|
|
w.write_int32(0) # dummy
|
|
w.write_int32(0) # dummy
|
|
w.write_shape(l.pads)
|
|
w.write_shape(l.strides)
|
|
w.write_shape(l.pool_size)
|
|
w.write_int32(l.axis)
|
|
w.write_float(l.alpha)
|
|
w.write_float(l.beta)
|
|
w.write_int32(0) # dummy
|
|
w.write_str_array(l.inputs)
|
|
|
|
w.write_int32(len(l.tensors))
|
|
for x in l.tensors:
|
|
assert len(x.shape) == 4
|
|
assert x.data.nbytes % 4 == 0
|
|
length = (
|
|
x.data.nbytes >> 2
|
|
) # length is measured in float32s (at least for now)
|
|
|
|
w.write_str(x.name)
|
|
w.write_shape(x.shape)
|
|
w.write_int64(offset)
|
|
w.write_int32(x.data.itemsize)
|
|
w.write_int32(length)
|
|
|
|
offset += length
|
|
all_tensors.append(x)
|
|
|
|
for x in all_tensors:
|
|
w.write_array(x.data)
|