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gmm_tmat.py
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gmm_tmat.py
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# -*- coding: utf-8 -*-
""""
This module contains tools for Gaussian mixture modeling (GMM)
__author__ = 'Omid Sadjadi, Timothee Kheyrkhah'
__email__ = 'omid.sadjadi@nist.gov'
Modification and GPU-implementation by TrungNT
"""
import os
import pickle
import random
import threading
import time
from collections import Mapping, OrderedDict, defaultdict
import numpy as np
import tensorflow as tf
from scipy import linalg
from six import string_types
from odin import backend as K
from bigarray import MmapArray
from odin.ml.base import BaseEstimator, DensityMixin, TransformerMixin
from odin.utils import (MPI, Progbar, array_size, as_tuple, minibatch, cpu_count,
ctext, defaultdictkey, eprint, is_number, segment_list,
uuid, wprint)
EPS = 1e-6
# minimum batch size that will be optimal to transfer
# the data to GPU for calculation (tested on Titan X)
# NOTE: tensorflow has a lagging effect, it will be
# slower than numpy if you evaluate the
# expression for first time.
MINIMUM_GPU_BLOCK = 8000 * 120 * 4 # bytes
# ===========================================================================
# Helper
# ===========================================================================
def zeroStat(post):
""" Shape: (1, nmix)
# sum over all samples
# Zero-order statistics over all samples and dimension for
each components
"""
# ====== tensorflow tensor or variable ====== #
if K.is_tensor(post, inc_distribution=True, inc_variable=True):
y = tf.reduce_sum(post, axis=0, keepdims=True,
name="zero_stat")
# ====== numpy array ====== #
else:
y = np.sum(post, axis=0, keepdims=True) # (1, M)
return y
def firstStat(X, post):
""" Shape: (feat_dim, nmix)
First-order statistics over all samples for each components
"""
# ====== tensorflow tensor or variable ====== #
if K.is_tensor(X, inc_distribution=True, inc_variable=True):
y = tf.matmul(tf.transpose(X), post, name='first_stat')
# ====== numpy array ====== #
else:
y = np.dot(X.T, post)
return y
def secondStat(X, post):
""" Shape: (feat_dim, nmix)
Second-order statistics over all samples for each components
"""
# ====== tensorflow tensor or variable ====== #
if K.is_tensor(X, inc_distribution=True, inc_variable=True):
y = tf.matmul(tf.transpose(tf.pow(X, 2)), post, name="second_stat")
# ====== numpy array ====== #
else:
y = np.dot((X ** 2).T, post)
return y
def logsumexp(X, axis):
"""
Compute log(sum(exp(x),dim)) while avoiding numerical underflow
"""
# ====== tensorflow tensor or variable ====== #
if K.is_tensor(X, inc_distribution=True, inc_variable=True):
xmax = tf.reduce_max(X, axis=axis, keepdims=True)
y = tf.add_n(inputs=[
xmax,
tf.log(tf.reduce_sum(input_tensor=tf.exp(X - xmax),
axis=axis,
keepdims=True))],
name='llk')
# ====== numpy array ====== #
else:
xmax = np.max(X, axis=axis, keepdims=True)
y = xmax + np.log(np.sum(a=np.exp(X - xmax),
axis=axis,
keepdims=True))
return y
def _split_jobs(n_samples, ncpu, device, gpu_factor):
""" Return: jobs_cpu, jobs_gpu"""
# number of GPU
# TODO: fix `get_ngpu` here
ngpu = get_ngpu()
if ngpu == 0:
device = 'cpu'
# jobs split based on both number of CPU and GPU
if device == 'mix':
njob = ncpu + 1 + ngpu * gpu_factor
elif device == 'cpu':
njob = ncpu + 1
elif device == 'gpu':
njob = ngpu + 1
else:
raise ValueError("Unknown device: '%s'" % device)
jobs = np.linspace(start=0, stop=n_samples,
num=njob, dtype='int32')
jobs = list(zip(jobs, jobs[1:]))
# use both GPU and CPU
if device == 'mix':
jobs_gpu = [(jobs[i * gpu_factor][0],
jobs[i * gpu_factor + gpu_factor - 1][1])
for i in range(ngpu)]
jobs_cpu = [jobs[i] for i in range(ngpu * gpu_factor, len(jobs))]
elif device == 'gpu': # only GPU
jobs_gpu = jobs
jobs_cpu = []
elif device == 'cpu': # only CPU
jobs_gpu = []
jobs_cpu = jobs
return jobs_cpu, jobs_gpu
def _create_batch(X, sad, start, end, batch_size,
downsample, stochastic,
seed, curr_nmix, curr_niter):
"""
Return
------
(X, n_selected_frame, n_original_frame)
i.e. the number of select frames might be different from number
of original frames after applying SAD
"""
# stochastic downsample, seed change every iter and mixup
if stochastic:
random.seed(seed + curr_nmix + curr_niter)
else: # deterministic
random.seed(seed)
all_batches = list(minibatch(n=end - start, batch_size=batch_size))
random.shuffle(all_batches)
# iterate over batches
for batch_id, (batch_start, batch_end) in enumerate(all_batches):
batch_start += start
batch_end += start
n_original_sample = batch_end - batch_start
# first batch always selected,
# downsample by randomly ignore a batch
if batch_id == 0 or \
downsample == 1 or \
(downsample > 1 and random.random() <= 1. / downsample):
X_sad = (X[batch_start:batch_end]
if sad is None else
X[batch_start:batch_end][sad[batch_start:batch_end].astype('bool')])
yield X_sad, X_sad.shape[0], n_original_sample
# ====== batch ignored ====== #
else:
yield None, n_original_sample, n_original_sample
def _create_batch_indices(X, sad, indices, batch_size,
downsample, stochastic,
seed, curr_nmix, curr_niter):
"""
Return
------
(X, n_selected_frame, n_original_frame)
i.e. the number of select frames might be different from number
of original frames after applying SAD
"""
# stochastic downsample, seed change every iter and mixup
if stochastic:
random.seed(seed + curr_nmix + curr_niter)
else: # deterministic
random.seed(seed)
random.shuffle(indices)
# ====== prepare the buffer ====== #
X_buffer = []
n_original_buffer = 0
n_selected_buffer = 0
# ====== iterate over each file ====== #
for batch_id, (name, (file_start, file_end)) in enumerate(indices):
n_original_sample = file_end - file_start
# first batch always selected,
# downsample by randomly ignore a batch
if batch_id == 0 or \
downsample == 1 or \
(downsample > 1 and random.random() <= 1. / downsample):
# not enough sample for batching
if n_original_sample <= batch_size:
X_sad = (X[file_start:file_end]
if sad is None else
X[file_start:file_end][sad[file_start:file_end].astype('bool')])
# store in buffer
X_buffer.append(X_sad)
n_selected_buffer += X_sad.shape[0]
n_original_buffer += n_original_sample
# split into smaller mini-batch
else:
for batch_start, batch_end in minibatch(n=n_original_sample, batch_size=batch_size):
batch_start = batch_start + file_start
batch_end = batch_end + file_start
X_sad = (X[batch_start: batch_end]
if sad is None else
X[batch_start: batch_end][sad[batch_start: batch_end].astype('bool')])
if X_sad.shape[0] >= batch_size: # full batch
yield X_sad, X_sad.shape[0], n_original_sample
else: # store in buffer
X_buffer.append(X_sad)
n_selected_buffer += X_sad.shape[0]
n_original_buffer += n_original_sample
# ====== batch ignored ====== #
else:
yield None, n_original_sample, n_original_sample
# ====== check buffer to return ====== #
if n_selected_buffer >= batch_size:
yield np.concatenate(X_buffer, axis=0), n_selected_buffer, n_original_buffer
X_buffer = []
n_selected_buffer = 0
n_original_buffer = 0
# ====== check final buffer to return ====== #
if len(X_buffer) > 0:
yield np.concatenate(X_buffer, axis=0), n_selected_buffer, n_original_buffer
class _ExpectationResults(object):
""" ExpectationResult """
def __init__(self, n_samples, nb_results, name, print_progress):
super(_ExpectationResults, self).__init__()
# thread lock
self.lock = threading.Lock()
# progress bar
self.prog = Progbar(target=n_samples, print_report=True,
print_summary=False, name=name)
# GMM: Z, F, S, L, nframes
# I-vector: LU, RU, llk, nframes
self.stats = [0. for i in range(int(nb_results))]
self.print_progress = bool(print_progress)
def update(self, res):
"""
integer (or a number): number of processed samples (update the progress bar)
otherwise: list of results (update the statistics)
"""
# thread-safe udpate
self.lock.acquire()
try:
# returned number of processed samples
if is_number(res) and self.print_progress:
self.prog.add(res)
# return the statistics, end of process
else:
for i, r in enumerate(res):
self.stats[i] += r
finally:
self.lock.release()
# ===========================================================================
# Main GMM
# ===========================================================================
class GMM(DensityMixin, BaseEstimator, TransformerMixin):
r""" Gaussian Mixture Model with diagonal covariance.
Parameters
----------
nmix : int
number of mixtures
nmix_start : int
the algorithm start from given number of mixture, then perform
E-M and split to increase the mixtures to desire number
niter : int (default: 16)
number of iteration for E-M algorithm
dtype : {str, numpy.dtype} (default: float32)
desire dtype for mean, std, weights and input matrices
It is recommended to keep 'float32', since this speed up
a lot on GPU
allow_rollback : bool (default: True)
If True, reset the `mean`, `sigma` and `w` to the last
stable iteration, when `sigma` values smaller than 0
exit_on_error : bool (default: True)
Stop fitting when EM reach singular value and `sigma` become
numerical instabable (i.e. its values are smaller than 0)
batch_size : {int, 'auto'}
if 'auto', used `12 Megabytes` block for CPU batch and
`25 Megabytes` block for GPU batch
device : {'cpu', 'gpu', 'mix'}
'gpu' - run the computaiton on GPU
'cpu' - use multiprocessing for multiple cores
'mix' - use both GPU and multi-processing
* It is suggested to use mix of GPU and CPU if you have
more than 24 cores CPU, otherwise, 'gpu' gives the best
performance
ncpu : int
number of processes for parallel calculating Expectation
gpu_factor : int
how much jobs GPU will handle more than CPU
(i.e. `njob_gpu = gpu_factor * njob_cpu`)
stochastic_downsample : bool
if True, a subset of data is selected differently after
each iteration => the training is stochastic.
if False, a deterministic selection of data is performed
each iteration => the training is deterministic.
seed : int
random seed for reproducible
path : {str, None}
If given a path, save the model after everytime its
parameters changed (i.e. `maximization` or `gmm_mixup`
are called)
name : {str, None}
special name for this `Tmatrix` instance
Attributes
----------
mu : (feat_dim, nmix)
mean vector for each component
sigma : (feat_dim, nmix)
standard deviation for each component
w : (1, nmix)
weights of each component
Note
----
Memory throughput is the bottleneck in most of the case,
try to move the data to faster storage before fitting.
"""
STANDARD_CPU_BATCH_SIZE = 12 * 1024 * 1024 # 12 Megabytes
STANDARD_GPU_BATCH_SIZE = 25 * 1024 * 1024 # 25 Megabytes
def __init__(self, nmix, nmix_start=1, niter=16, dtype='float32',
allow_rollback=True, exit_on_error=False,
batch_size_cpu='auto', batch_size_gpu='auto',
downsample=1, stochastic_downsample=True,
device='cpu', ncpu=1, gpu_factor=80,
seed=1234, path=None, name=None):
super(GMM, self).__init__()
self._path = path if isinstance(path, string_types) else None
# ====== set number of mixtures ====== #
# start from 1 mixture, then split and up
nmix = int(nmix)
if nmix < 1:
raise ValueError("Number of Mixture must be greater than 1.")
self._nmix = nmix
self._curr_nmix = np.clip(int(nmix_start), 1, self._nmix)
# others dimension
self._feat_dim = None
self._niter = int(niter)
self.batch_size_cpu = batch_size_cpu
self.batch_size_gpu = batch_size_gpu
# ====== downsample ====== #
self.downsample = int(downsample)
self.stochastic_downsample = bool(stochastic_downsample)
self._seed = int(seed)
# ====== multi-processing ====== #
self.gpu_factor = int(gpu_factor)
# cpu
if ncpu is None:
ncpu = cpu_count() - 1
self.ncpu = int(ncpu)
# device
self.set_device(device)
# ====== state variable ====== #
# store history of {nmix -> [llk_1, llk_2] ...}
self._llk_hist = defaultdict(list)
# ====== error handling ====== #
self.allow_rollback = bool(allow_rollback)
self.exit_on_error = bool(exit_on_error)
self._stop_fitting = False
# ====== name ====== #
self._dtype = np.dtype(dtype)
if name is None:
name = uuid(length=8)
self._name = 'GMM_%s' % name
else:
self._name = str(name)
def __getstate__(self):
# 'means', 'variances', 'weights'
# self.mean, self.sigma, self.w
if not self.is_initialized:
raise RuntimeError("GMM hasn't been initialized, nothing to save")
return (self.mean, self.sigma, self.w,
self.allow_rollback, self.exit_on_error,
self._nmix, self._curr_nmix, self._feat_dim,
self._niter, self.batch_size_cpu, self.batch_size_gpu,
self.downsample, self.stochastic_downsample,
self._seed, self._llk_hist,
self.ncpu, self._device, self.gpu_factor,
self._dtype, self._path, self._name)
def __setstate__(self, states):
(self.mean, self.sigma, self.w,
self.allow_rollback, self.exit_on_error,
self._nmix, self._curr_nmix, self._feat_dim,
self._niter, self.batch_size_cpu, self.batch_size_gpu,
self.downsample, self.stochastic_downsample,
self._seed, self._llk_hist,
self.ncpu, self._device, self.gpu_factor,
self._dtype, self._path, self._name) = states
# basic constants
self._stop_fitting = False
self._feat_const = self.feat_dim * np.log(2 * np.pi)
self.X_ = tf.placeholder(shape=(None, self.feat_dim),
dtype=self.dtype,
name='GMM_input')
# init posterior
self._resfresh_cpu_posterior()
self._refresh_gpu_posterior()
# ====== warning no GPU ====== #
if self._device in ('gpu', 'mix') and get_ngpu() == 0:
wprint("Enabled GPU device, but no GPU found!")
def __str__(self):
if not self.is_initialized:
return '<"%s" nmix:%d initialized:False>' % (self.name, self._nmix)
s = '<"%s" nmix:%s ndim:%s mean:%s std:%s w:%s CPU:%s GPU:%s>' %\
(ctext(self.name, 'yellow'),
ctext(self._nmix, 'cyan'),
ctext(self._feat_dim, 'cyan'),
ctext(self.mean.shape, 'cyan'),
ctext(self.sigma.shape, 'cyan'),
ctext(self.w.shape, 'cyan'),
ctext(self.batch_size_cpu, 'cyan'),
ctext(self.batch_size_gpu, 'cyan'),
)
return s
# ==================== properties ==================== #
def set_device(self, device):
device = str(device).lower()
if device not in ('cpu', 'gpu', 'mix'):
raise ValueError("`device` must be one of the following: 'cpu', 'gpu', or 'mix'")
# ====== warning no GPU ====== #
if device in ('gpu', 'mix') and get_ngpu() == 0:
wprint("Using GPU device but NO GPU detected, "
"tensorflow will switch to slower CPU computation!")
self._device = device
return self
@property
def device(self):
return self._device
@property
def path(self):
return self._path
@property
def name(self):
return self._name
@property
def is_initialized(self):
return self._feat_dim is not None
@property
def is_fitted(self):
return self._curr_nmix == self._nmix
@property
def nmix(self):
return self._nmix
@property
def feat_dim(self):
if not self.is_initialized:
raise RuntimeError("GMM has not been initialized on data.")
return self._feat_dim
@property
def history(self):
""" Return the history of fitting this GMM in following format:
`[(current_nmix, current_niter, llk), ...]`
"""
return tuple(self._llk_hist)
@property
def dtype(self):
return self._dtype
# ==================== initialization ==================== #
def _resfresh_cpu_posterior(self):
""" Refresh cached value for CPu computations. """
expressions = {}
precision = 1 / (self.sigma + EPS)
C = np.sum((self.mean ** 2) * precision, axis=0, keepdims=True) + \
np.sum(np.log(self.sigma + EPS), axis=0, keepdims=True) - \
2 * np.log(self.w + EPS) # TODO: check here if add EPS to self.w
mu_precision = self.mean * precision
expressions['precision'] = precision
expressions['mu_precision'] = mu_precision
expressions['C'] = C
self.__expressions_cpu = expressions
def _refresh_gpu_posterior(self):
""" Call this function when you update the mixture
components.
Unlike CPU computation, tensorflow graph on need to
renew it placeholder which represent: mu, sigma, weight
when GMM mixup.
"""
expressions = {}
# ====== proper scope ====== #
if self._curr_nmix < self.nmix:
scope = self.name + str(self._curr_nmix)
else:
scope = self.name
# ====== build the graph ====== #
with tf.variable_scope(scope):
mu = tf.placeholder(shape=(self.feat_dim, self._curr_nmix),
dtype=self.dtype,
name='GMM_mu')
sigma = tf.placeholder(shape=(self.feat_dim, self._curr_nmix),
dtype=self.dtype,
name='GMM_sigma')
w = tf.placeholder(shape=(1, self._curr_nmix),
dtype=self.dtype,
name='GMM_weight')
expressions['mu'] = mu
expressions['sigma'] = sigma
expressions['w'] = w
# ====== log probability ====== #
# (feat_dim, nmix)
precision = 1 / (sigma + EPS)
C = tf.reduce_sum((mu ** 2) * precision,
axis=0, keepdims=True) + \
tf.reduce_sum(tf.log(sigma + EPS),
axis=0, keepdims=True) - \
2 * tf.log(w)
D = tf.matmul(self.X_ ** 2, precision) - \
2 * tf.matmul(self.X_, mu * precision) + \
self.feat_dim * np.log(2 * np.pi)
# (batch_size, nmix)
logprob = tf.multiply(x=tf.constant(-0.5, dtype=self.dtype),
y=C + D,
name='logprob')
expressions['logprob'] = logprob # (batch_size, nmix)
# ====== posterior and likelihood ====== #
llk = logsumexp(logprob, axis=1) # (batch_size, 1)
post = tf.exp(logprob - llk, name='postprob') # (batch_size, nmix)
expressions['llk'] = llk
expressions['post'] = post
# ====== expectation ====== #
expressions['zero'] = zeroStat(post)
expressions['first'] = firstStat(self.X_, post)
expressions['second'] = secondStat(self.X_, post)
expressions['L'] = tf.reduce_sum(llk, axis=None, name='sum_llk')
self.__expressions_gpu = expressions
def initialize(self, X):
indices = None
if isinstance(X, (tuple, list)):
tmp = [i for i in X if hasattr(i, 'shape')][0]
indices = [i for i in X if i != tmp][0]
X = tmp
# ====== check X ====== #
if not isinstance(X, np.ndarray):
raise ValueError("`X` must be numpy.ndarray")
# ====== check indices ====== #
if isinstance(indices, Mapping):
indices = list(indices.items())
elif not isinstance(indices, (tuple, list, np.ndarray, type(None))):
raise ValueError("`indices` must be None, Mapping, tuple, list or numpy.ndarray")
# ====== get input info ====== #
if hasattr(X, 'ndim'):
ndim = X.ndim
elif hasattr(X, 'get_shape'):
ndim = len(X.shape.as_list())
else:
raise ValueError("Cannot number of dimension from input.")
if hasattr(X, 'shape'):
feat_dim = X.shape[1]
elif hasattr(X, 'get_shape'):
feat_dim = X.shape.as_list()[1]
else:
raise ValueError("Cannot get feature dimension from input.")
# ====== already init ====== #
if self.is_initialized:
# validate the inputs
if ndim != 2 or feat_dim != self._feat_dim:
raise RuntimeError("Input must be 2-D matrix with the 1st "
"dimension equal to: %d" % feat_dim)
return X, indices
# ====== create input placeholder ====== #
self._feat_dim = int(feat_dim)
# const for specific dimension
self._feat_const = self.feat_dim * np.log(2 * np.pi)
# infer batch_size
if isinstance(self.batch_size_cpu, string_types):
self.batch_size_cpu = int(GMM.STANDARD_CPU_BATCH_SIZE /
(self.feat_dim * self.dtype.itemsize))
if isinstance(self.batch_size_gpu, string_types):
self.batch_size_gpu = int(GMM.STANDARD_GPU_BATCH_SIZE /
(self.feat_dim * self.dtype.itemsize))
# [batch_size, feat_dim]
self.X_ = tf.placeholder(shape=(None, self.feat_dim),
dtype=self.dtype,
name='GMM_input')
# ====== init ====== #
# (D, M)
self.mean = np.zeros((feat_dim, self._curr_nmix), dtype=self._dtype)
# (D, M)
self.sigma = np.ones((feat_dim, self._curr_nmix), dtype=self._dtype)
# (1, M)
self.w = np.ones((1, self._curr_nmix), dtype=self._dtype)
# init posterior
self._resfresh_cpu_posterior()
self._refresh_gpu_posterior()
return X, indices
# ==================== sklearn ==================== #
def fit(self, X, y=None):
"""
Parameters
----------
X : {numpy.ndarray, tuple, list}
in case a tuple is given, two options are considered:
- length of the list is 1: only training feature is given
- length of the list is 2: training data (numpy.ndarray),
indices or sad indices (numpy.ndarray)
- length of the list is 3: training data (numpy.ndarray),
sad indices (numpy.ndarray), indices
where the `indices` is a dictionary of the mapping
'file_name' -> (start_index, end_index) in the training
data array
NOTE
----
from 1, 2, 4 components, python multi-threading is fastest
from 8, 16 components, python multi-processing is fastest
from > 32 components, GPU scales much much better.
"""
# if indices is given it should be sorted for optimal
# memory access
if not isinstance(X, (tuple, list)):
X = (X,)
sad = None
indices = None
if len(X) == 1:
data = X[0]
elif len(X) == 2:
if hasattr(X[1], 'shape') and X[0].shape[0] == X[1].shape[0]:
data, sad = X
else:
data, indices = X
elif len(X) == 3:
data, sad, indices = X
else:
raise ValueError("No support for `X` in type of list with length: %d" % len(X))
# validate data
assert hasattr(data, 'shape') and data.ndim == 2, \
'Input data must be instance of 2-D ndarray but give: %s' % str(type(data))
# check if indices exist
if indices is not None:
if isinstance(indices, Mapping):
indices = list(indices.items())
indices = sorted(indices, key=lambda x: x[1][0])
X = (data, indices)
# otherwise, only data and sad are given
else:
X = data
# ====== start GMM ====== #
# supports 16384 components, modify for more components
niter = [1, 2, 4, 4, 4, 4, 6, 6, 10, 10, 10, 10, 10, 16, 16]
niter[int(np.log2(self._nmix))] = self._niter
self._stop_fitting = False
# run the algorithm
while True:
# fitting the mixtures
curr_nmix = self._curr_nmix
last_niter = len(self._llk_hist[curr_nmix])
idx = int(np.log2(curr_nmix))
curr_niter = niter[idx] - last_niter
if curr_niter > 0:
for i in range(curr_niter):
self.expectation_maximization(X, sad=sad, print_progress=True)
# check if stop now
if self._stop_fitting:
return self
print('---')
# update the mixtures
if curr_nmix < self._nmix:
self.gmm_mixup()
else:
break
return self
def score(self, X, y=None):
""" Compute the log-likelihood of each example to
the Mixture of Components.
"""
post = self.logprob(X) # (batch_size, nmix)
return logsumexp(post, axis=1) # (batch_size, 1)
def transform(self, X, zero=True, first=True, device=None):
""" Compute centered statistics given X and fitted mixtures
Parameters
----------
X : ndarray
input feature [n_samples, feat_dim] (e.g. all frames
of an utterance for audio data)
zero : bool (default: True)
if True, return the zero-th order statistics
first : bool (default: True)
if True, return the first order statistics
device : {None, 'cpu', 'gpu'}
select device for execute the expectation calculation
Return
------
zero-th statistics: [1, nmix]
e.g. the assignment score each samples to each components, hence,
`#frames = Z.sum()`
first statistics: [1, feat_dim * nmix]
dot-product of each sample and the posteriors.
NOTE
----
For more option check `GMM.expectation`
"""
if device is None:
device = self._device
zero = bool(zero)
first = bool(first)
if not zero and not first:
raise ValueError("One of `zero` or `first` must be True")
assert X.ndim == 2 and X.shape[1] == self.feat_dim, \
"`X` must be 2-D matrix, with `X.shape[1]=%d`; but given: %s" % \
(self.feat_dim, str(X.shape))
# ====== expectation ====== #
Z = None
F = None; F_hat = None
results = self._fast_expectation(X, zero=zero, first=first,
second=False, llk=False,
on_gpu=device != 'cpu')
# ====== return the results ====== #
if zero and first:
Z, F = results
# this equal to: .ravel()[np.newaxis, :]
F_hat = np.reshape(F - self.mean * Z,
newshape=(1, self.feat_dim * self._curr_nmix),
order='F')
return Z, F_hat
elif zero and not first:
Z = results
return Z
elif not zero and first:
F = results
# this equal to: .ravel()[np.newaxis, :]
F_hat = np.reshape(F - self.mean * Z,
newshape=(1, self.feat_dim * self._curr_nmix),
order='F')
return F_hat
def transform_to_disk(self, X, indices, sad=None,
pathZ=None, pathF=None, name_path=None,
dtype='float32', device='cpu', ncpu=None,
override=True):
""" Same as `transform`, however, save the transformed statistics
to file using `odin.fuel.MmapArray`
Return
------
zero-th statistics: [1, nmix]
e.g. the assignment score each samples to each components, hence,
`#frames = Z.sum()`
first statistics: [1, feat_dim * nmix]
dot-product of each sample and the posteriors.
Note
----
If your data contain many very long utterances, it is suggested to use
`device='gpu'`, otherwise, 'cpu' is mostly significant faster.
"""
# ====== prepare inputs ====== #
if isinstance(indices, Mapping):
indices = sorted(indices.items(), key=lambda x: x[1][0])
if sad is not None:
assert sad.shape[0] == X.shape[0], \
"Number of samples in `X` (%d) and `sad` (%d) are mismatched" % (len(X), len(sad))
assert sad.ndim == 1 or (sad.ndim == 2 and sad.shape[1] == 1), \
"Invalid shape for `sad.shape=%s`" % str(sad.shape)
# ====== check device ====== #
if device is None:
device = self._device
on_gpu = True if device != 'cpu' and get_ngpu() > 0 else False
name_list = []
prog = Progbar(target=len(indices),
print_report=True, print_summary=True,
name="Saving zero-th and first order statistics")
# ====== init data files ====== #
if pathZ is not None:
if os.path.exists(pathZ):
if override:
os.remove(pathZ)
z_dat = MmapArray(path=pathZ, dtype=dtype,
shape=(None, self.nmix))
else:
z_dat = None
if pathF is not None:
if os.path.exists(pathF):
if override:
os.remove(pathF)
f_dat = MmapArray(path=pathF, dtype=dtype,
shape=(None, self.nmix * self.feat_dim))
else:
f_dat = None
# ====== helper ====== #
def _update_zf(Z, F):
# save zero-th stats
if z_dat is not None:
z_dat.append(Z)
# save first stats
if f_dat is not None:
f_dat.append(F)
def _batched_transform(s, e, on_gpu):
reduction = np.floor(np.power(2, self._curr_nmix / 1024))
batch_size = self.batch_size_gpu if on_gpu else self.batch_size_cpu
batch_size = int(batch_size / reduction)
x = X[s:e]
if sad is not None:
x = x[sad[s:e].astype('bool')]
if x.shape[0] <= batch_size:
res = [self._fast_expectation(x,
zero=z_dat is not None or f_dat is not None,
first=f_dat is not None,
second=False, llk=False,
on_gpu=on_gpu)]
else:
res = [self._fast_expectation(x[start:end],
zero=z_dat is not None or f_dat is not None,
first=f_dat is not None,
second=False, llk=False,
on_gpu=on_gpu)
for start, end in minibatch(n=x.shape[0], batch_size=batch_size)]
Z = sum(r[0] for r in res)
if len(res[0]) == 2:
F = sum(r[1] for r in res)
F = np.reshape(a=F - self.mean * Z,
newshape=(Z.shape[0], self._feat_dim * self._curr_nmix),
order='F')
else:
F = None
return Z, F
# ====== running on GPU ====== #
if on_gpu:
for n, (start, end) in indices:
Z, F = _batched_transform(start, end, on_gpu=True)
_update_zf(Z, F)
name_list.append(n)
prog.add(1)
# ====== run on CPU ====== #
else:
def map_func(j):
Z_list, F_list = [], []
name = []
for n, (start, end) in j:
name.append(n)
Z, F = _batched_transform(start, end, on_gpu=False)
if z_dat is not None:
Z_list.append(Z)
if f_dat is not None:
F_list.append(F)
yield 1
# concatenate into single large matrix
if len(Z_list) > 0:
Z_list = np.concatenate(Z_list, axis=0)
if len(F_list) > 0:
F_list = np.concatenate(F_list, axis=0)
yield name, Z_list, F_list
# run the MPI task
mpi = MPI(jobs=list(indices.items()) if isinstance(indices, Mapping)
else indices,
func=map_func,
ncpu=self.ncpu if ncpu is None else int(ncpu),
batch=max(2, self.batch_size_cpu // (self.ncpu * 2)),
hwm=2**25)
for results in mpi:
if is_number(results):
prog['Z_path'] = str(pathZ)
prog['F_path'] = str(pathF)
prog.add(results)
else:
name, Z, F = results
_update_zf(Z, F)
name_list += name
# ====== flush and return ====== #
if z_dat is not None:
z_dat.flush()
z_dat.close()
if f_dat is not None:
f_dat.flush()
f_dat.close()
# ====== save name_list ====== #
if isinstance(name_path, string_types):
np.savetxt(fname=name_path, X=name_list, fmt='%s')
return name_list
# ==================== math helper ==================== #
def logprob(self, X):
""" Shape: [batch_size, nmix]
the log probability of each observations to each components
given the GMM.
"""
self.initialize(X)
if self._device != 'cpu':
feed_dict = {self.X_: X}
feed_dict[self.__expressions_gpu['mu']] = self.mean
feed_dict[self.__expressions_gpu['sigma']] = self.sigma
feed_dict[self.__expressions_gpu['w']] = self.w
return K.eval(x=self.__expressions_gpu['logprob'],
feed_dict=feed_dict)
# ====== run on numpy ====== #
# (feat_dim, nmix)
precision = self.__expressions_cpu['precision']
mu_precision = self.__expressions_cpu['mu_precision']
C = self.__expressions_cpu['C']
X_2 = X ** 2
D = np.dot(X_2, precision) - \
2 * np.dot(X, mu_precision) + \
self._feat_const
# (batch_size, nmix)
logprob = -0.5 * (C + D)
return logprob
def postprob(self, X, gpu='auto'):
""" Shape: (batch_size, nmix)
The posterior probability of mixtures for each frame
"""
self.initialize(X)
if self._device != 'cpu':
feed_dict = {self.X_: X}
feed_dict[self.__expressions_gpu['mu']] = self.mean
feed_dict[self.__expressions_gpu['sigma']] = self.sigma
feed_dict[self.__expressions_gpu['w']] = self.w
return K.eval(x=self.__expressions_gpu['post'],
feed_dict=feed_dict)
# ====== run on numpy ====== #
# (feat_dim, nmix)
precision = self.__expressions_cpu['precision']
mu_precision = self.__expressions_cpu['mu_precision']
C = self.__expressions_cpu['C']
X_2 = X ** 2
D = np.dot(X_2, precision) - \
2 * np.dot(X, mu_precision) + \
self._feat_const
# (batch_size, nmix)
logprob = -0.5 * (C + D)
# ====== posterior and likelihood ====== #
llk = logsumexp(logprob, axis=1) # (batch_size, 1)
post = np.exp(logprob - llk) # (batch_size, nmix)
return post
def llk(self, X, gpu='auto'):
""" Shape: (batch_size, 1)
The log-likelihood value of each frame to all components
"""
self.initialize(X)
if self._device != 'cpu':
feed_dict = {self.X_: X}
feed_dict[self.__expressions_gpu['mu']] = self.mean
feed_dict[self.__expressions_gpu['sigma']] = self.sigma
feed_dict[self.__expressions_gpu['w']] = self.w
return K.eval(x=self.__expressions_gpu['llk'],
feed_dict=feed_dict)
# ====== run on numpy ====== #
# (feat_dim, nmix)
precision = self.__expressions_cpu['precision']
mu_precision = self.__expressions_cpu['mu_precision']
C = self.__expressions_cpu['C']
X_2 = X ** 2
D = np.dot(X_2, precision) - \
2 * np.dot(X, mu_precision) + \
self._feat_const
# (batch_size, nmix)
logprob = -0.5 * (C + D)
# ====== posterior and likelihood ====== #
llk = logsumexp(logprob, axis=1) # (batch_size, 1)
return llk
def _fast_expectation(self, X, zero=True, first=True, second=True,
llk=True, on_gpu=False):
# ====== run on GPU ====== #
if on_gpu: