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NeMo / nemo /collections /audio /data /data_simulation.py
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# Copyright (c) 2022, NVIDIA CORPORATION. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import itertools
import multiprocessing
import os
import random
from typing import Dict, Iterable, List, Optional, Tuple, Union
import librosa
import matplotlib.pyplot as plt
import numpy as np
import soundfile as sf
from numpy.random import default_rng
from omegaconf import DictConfig, OmegaConf
from scipy.signal import convolve
from scipy.spatial.transform import Rotation
from tqdm import tqdm
from nemo.collections.asr.parts.preprocessing.segment import AudioSegment
from nemo.collections.asr.parts.utils.manifest_utils import read_manifest, write_manifest
from nemo.collections.audio.parts.utils.audio import db2mag, generate_approximate_noise_field, mag2db, pow2db, rms
from nemo.utils import logging
try:
 import pyroomacoustics as pra
PRA = True
except ImportError:
 PRA = False
try:
 import h5py
HAS_H5PY = True
except ImportError:
 HAS_H5PY = False
def check_angle(key: str, val: Union[float, Iterable[float]]) -> bool:
 """Check if the angle value is within the expected range. Input
 values are in degrees.
 Note:
 azimuth: angle between a projection on the horizontal (xy) plane and
 positive x axis. Increases counter-clockwise. Range: [-180, 180].
 elevation: angle between a vector an its projection on the horizontal (xy) plane.
 Positive above, negative below, i.e., north=+90, south=-90. Range: [-90, 90]
 yaw: rotation around the z axis. Defined accoding to right-hand rule.
 Range: [-180, 180]
 pitch: rotation around the yʹ axis. Defined accoding to right-hand rule.
 Range: [-90, 90]
 roll: rotation around the xʺ axis. Defined accoding to right-hand rule.
 Range: [-180, 180]
 Args:
 key: angle type
 val: values in degrees
 Returns:
 True if all values are within the expected range.
 """
 if np.isscalar(val):
 min_val = max_val = val
 else:
 min_val = min(val)
 max_val = max(val)
if key == 'azimuth' and -180 <= min_val <= max_val <= 180:
 return True
 if key == 'elevation' and -90 <= min_val <= max_val <= 90:
 return True
 if key == 'yaw' and -180 <= min_val <= max_val <= 180:
 return True
 if key == 'pitch' and -90 <= min_val <= max_val <= 90:
 return True
 if key == 'roll' and -180 <= min_val <= max_val <= 180:
 return True
raise ValueError(f'Invalid value for angle {key} = {val}')
def wrap_to_180(angle: float) -> float:
 """Wrap an angle to range ±180 degrees.
 Args:
 angle: angle in degrees
 Returns:
 Angle in degrees wrapped to ±180 degrees.
 """
 return angle - np.floor(angle / 360 + 1 / 2) * 360
class ArrayGeometry(object):
 """A class to simplify handling of array geometry.
 Supports translation and rotation of the array and calculation of
 spherical coordinates of a given point relative to the internal
 coordinate system of the array.
 Args:
 mic_positions: 3D coordinates, with shape (num_mics, 3)
 center: optional position of the center of the array. Defaults to the average of the coordinates.
 internal_cs: internal coordinate system for the array relative to the global coordinate system.
 Defaults to (x, y, z), and is rotated with the array.
 """
def __init__(
 self,
 mic_positions: Union[np.ndarray, List],
 center: Optional[np.ndarray] = None,
 internal_cs: Optional[np.ndarray] = None,
 ):
 if isinstance(mic_positions, Iterable):
 mic_positions = np.array(mic_positions)
if not mic_positions.ndim == 2:
 raise ValueError(
 f'Expecting a 2D array specifying mic positions, but received {mic_positions.ndim}-dim array'
 )
if not mic_positions.shape[1] == 3:
 raise ValueError(f'Expecting 3D positions, but received {mic_positions.shape[1]}-dim positions')
mic_positions_center = np.mean(mic_positions, axis=0)
 self.centered_positions = mic_positions - mic_positions_center
 self.center = mic_positions_center if center is None else center
# Internal coordinate system
 if internal_cs is None:
 # Initially aligned with the global
 self.internal_cs = np.eye(3)
 else:
 self.internal_cs = internal_cs
@property
 def num_mics(self):
 """Return the number of microphones for the current array."""
 return self.centered_positions.shape[0]
@property
 def positions(self):
 """Absolute positions of the microphones."""
 return self.centered_positions + self.center
@property
 def internal_positions(self):
 """Positions in the internal coordinate system."""
 return np.matmul(self.centered_positions, self.internal_cs.T)
@property
 def radius(self):
 """Radius of the array, relative to the center."""
 return max(np.linalg.norm(self.centered_positions, axis=1))
@staticmethod
 def get_rotation(yaw: float = 0, pitch: float = 0, roll: float = 0) -> Rotation:
 """Get a Rotation object for given angles.
 All angles are defined according to the right-hand rule.
 Args:
 yaw: rotation around the z axis
 pitch: rotation around the yʹ axis
 roll: rotation around the xʺ axis
 Returns:
 A rotation object constructed using the provided angles.
 """
 check_angle('yaw', yaw)
 check_angle('pitch', pitch)
 check_angle('roll', roll)
return Rotation.from_euler('ZYX', [yaw, pitch, roll], degrees=True)
def translate(self, to: np.ndarray):
 """Translate the array center to a new point.
 Translation does not change the centered positions or the internal coordinate system.
 Args:
 to: 3D point, shape (3,)
 """
 self.center = to
def rotate(self, yaw: float = 0, pitch: float = 0, roll: float = 0):
 """Apply rotation on the mic array.
 This rotates the centered microphone positions and the internal
 coordinate system, it doesn't change the center of the array.
 All angles are defined according to the right-hand rule.
 For example, this means that a positive pitch will result in a rotation from z
 to x axis, which will result in a reduced elevation with respect to the global
 horizontal plane.
 Args:
 yaw: rotation around the z axis
 pitch: rotation around the yʹ axis
 roll: rotation around the xʺ axis
 """
 # construct rotation using TB angles
 rotation = self.get_rotation(yaw=yaw, pitch=pitch, roll=roll)
# rotate centered positions
 self.centered_positions = rotation.apply(self.centered_positions)
# apply the same transformation on the internal coordinate system
 self.internal_cs = rotation.apply(self.internal_cs)
def new_rotated_array(self, yaw: float = 0, pitch: float = 0, roll: float = 0):
 """Create a new array by rotating this array.
 Args:
 yaw: rotation around the z axis
 pitch: rotation around the yʹ axis
 roll: rotation around the xʺ axis
 Returns:
 A new ArrayGeometry object constructed using the provided angles.
 """
 new_array = ArrayGeometry(mic_positions=self.positions, center=self.center, internal_cs=self.internal_cs)
 new_array.rotate(yaw=yaw, pitch=pitch, roll=roll)
 return new_array
def spherical_relative_to_array(
 self, point: np.ndarray, use_internal_cs: bool = True
 ) -> Tuple[float, float, float]:
 """Return spherical coordinates of a point relative to the internal coordinate system.
 Args:
 point: 3D coordinate, shape (3,)
 use_internal_cs: Calculate position relative to the internal coordinate system.
 If `False`, the positions will be calculated relative to the
 external coordinate system centered at `self.center`.
 Returns:
 A tuple (distance, azimuth, elevation) relative to the mic array.
 """
 rel_position = point - self.center
 distance = np.linalg.norm(rel_position)
if use_internal_cs:
 # transform from the absolute coordinate system to the internal coordinate system
 rel_position = np.matmul(self.internal_cs, rel_position)
# get azimuth
 azimuth = np.arctan2(rel_position[1], rel_position[0]) / np.pi * 180
 # get elevation
 elevation = np.arcsin(rel_position[2] / distance) / np.pi * 180
return distance, azimuth, elevation
def __str__(self):
 with np.printoptions(precision=3, suppress=True):
 desc = f"{type(self)}:\ncenter =\n{self.center}\ncentered positions =\n{self.centered_positions}\nradius = \n{self.radius:.3}\nabsolute positions =\n{self.positions}\ninternal coordinate system =\n{self.internal_cs}\n\n"
 return desc
def plot(self, elev=30, azim=-55, mic_size=25):
 """Plot microphone positions.
 Args:
 elev: elevation for the view of the plot
 azim: azimuth for the view of the plot
 mic_size: size of the microphone marker in the plot
 """
 fig = plt.figure()
 ax = fig.add_subplot(projection='3d')
# show mic positions
 for m in range(self.num_mics):
 # show mic
 ax.scatter(
 self.positions[m, 0],
 self.positions[m, 1],
 self.positions[m, 2],
 marker='o',
 c='black',
 s=mic_size,
 depthshade=False,
 )
 # add label
 ax.text(self.positions[m, 0], self.positions[m, 1], self.positions[m, 2], str(m), c='red', zorder=10)
# show the internal coordinate system
 ax.quiver(
 self.center[0],
 self.center[1],
 self.center[2],
 self.internal_cs[:, 0],
 self.internal_cs[:, 1],
 self.internal_cs[:, 2],
 length=self.radius,
 label='internal cs',
 normalize=False,
 linestyle=':',
 linewidth=1.0,
 )
 for dim, label in enumerate(['x′', 'y′', 'z′']):
 label_pos = self.center + self.radius * self.internal_cs[dim]
 ax.text(label_pos[0], label_pos[1], label_pos[2], label, tuple(self.internal_cs[dim]), c='blue')
 try:
 # Unfortunately, equal aspect ratio has been added very recently to Axes3D
 ax.set_aspect('equal')
 except NotImplementedError:
 logging.warning('Equal aspect ratio not supported by Axes3D')
 # Set view
 ax.view_init(elev=elev, azim=azim)
 # Set reasonable limits for all axes, even for the case of an unequal aspect ratio
 ax.set_xlim([self.center[0] - self.radius, self.center[0] + self.radius])
 ax.set_ylim([self.center[1] - self.radius, self.center[1] + self.radius])
 ax.set_zlim([self.center[2] - self.radius, self.center[2] + self.radius])
ax.set_xlabel('x/m')
 ax.set_ylabel('y/m')
 ax.set_zlabel('z/m')
 ax.set_title('Microphone positions')
 ax.legend()
 plt.show()
def convert_placement_to_range(
 placement: dict, room_dim: Iterable[float], object_radius: float = 0
) -> List[List[float]]:
 """Given a placement dictionary, return ranges for each dimension.
 Args:
 placement: dictionary containing x, y, height, and min_to_wall
 room_dim: dimensions of the room, shape (3,)
 object_radius: radius of the object to be placed
 Returns
 List with a range of values for each dimensions.
 """
 if not np.all(np.array(room_dim) > 0):
 raise ValueError(f'Room dimensions must be positive: {room_dim}')
if object_radius < 0:
 raise ValueError(f'Object radius must be non-negative: {object_radius}')
placement_range = [None] * 3
 min_to_wall = placement.get('min_to_wall', 0)
if min_to_wall < 0:
 raise ValueError(f'Min distance to wall must be positive: {min_to_wall}')
for idx, key in enumerate(['x', 'y', 'height']):
 # Room dimension
 dim = room_dim[idx]
 # Construct the range
 val = placement.get(key)
 if val is None:
 # No constrained specified on the coordinate of the mic center
 min_val, max_val = 0, dim
 elif np.isscalar(val):
 min_val = max_val = val
 else:
 if len(val) != 2:
 raise ValueError(f'Invalid value for placement for dim {idx}/{key}: {str(placement)}')
 min_val, max_val = val
# Make sure the array is not too close to a wall
 min_val = max(min_val, min_to_wall + object_radius)
 max_val = min(max_val, dim - min_to_wall - object_radius)
if min_val > max_val or min(min_val, max_val) < 0:
 raise ValueError(f'Invalid range dim {idx}/{key}: min={min_val}, max={max_val}')
placement_range[idx] = [min_val, max_val]
return placement_range
class RIRCorpusGenerator(object):
 """Creates a corpus of RIRs based on a defined configuration of rooms and microphone array.
 RIRs are generated using `generate` method.
 """
def __init__(self, cfg: DictConfig):
 """
 Args:
 cfg: dictionary with parameters of the simulation
 """
 logging.info("Initialize RIRCorpusGenerator")
 self._cfg = cfg
 self.check_cfg()
@property
 def cfg(self):
 """Property holding the internal config of the object.
 Note:
 Changes to this config are not reflected in the state of the object.
 Please create a new model with the updated config.
 """
 return self._cfg
@property
 def sample_rate(self):
 return self._cfg.sample_rate
@cfg.setter
 def cfg(self, cfg):
 """Property holding the internal config of the object.
 Note:
 Changes to this config are not reflected in the state of the object.
 Please create a new model with the updated config.
 """
 self._cfg = cfg
def check_cfg(self):
 """
 Checks provided configuration to ensure it has the minimal required
 configuration the values are in a reasonable range.
 """
 # sample rate
 sample_rate = self.cfg.get('sample_rate')
 if sample_rate is None:
 raise ValueError('Sample rate not provided.')
 elif sample_rate < 0:
 raise ValueError(f'Sample rate must to be positive: {sample_rate}')
# room configuration
 room_cfg = self.cfg.get('room')
 if room_cfg is None:
 raise ValueError('Room configuration not provided')
if room_cfg.get('num') is None:
 raise ValueError('Number of rooms per subset not provided')
if room_cfg.get('dim') is None:
 raise ValueError('Room dimensions not provided')
for idx, key in enumerate(['width', 'length', 'height']):
 dim = room_cfg.dim.get(key)
if dim is None:
 # not provided
 raise ValueError(f'Room {key} needs to be a scalar or a range, currently it is None')
 elif np.isscalar(dim) and dim <= 0:
 # fixed dimension
 raise ValueError(f'A fixed dimension must be positive for {key}: {dim}')
 elif len(dim) != 2 or not 0 < dim[0] < dim[1]:
 # not a valid range
 raise ValueError(f'Range must be specified with two positive increasing elements for {key}: {dim}')
rt60 = room_cfg.get('rt60')
 if rt60 is None:
 # not provided
 raise ValueError('RT60 needs to be a scalar or a range, currently it is None')
 elif np.isscalar(rt60) and rt60 <= 0:
 # fixed dimension
 raise ValueError(f'RT60 must be positive: {rt60}')
 elif len(rt60) != 2 or not 0 < rt60[0] < rt60[1]:
 # not a valid range
 raise ValueError(f'RT60 range must be specified with two positive increasing elements: {rt60}')
# mic array
 mic_cfg = self.cfg.get('mic_array')
 if mic_cfg is None:
 raise ValueError('Mic configuration not provided')
if mic_cfg.get('positions') == 'random':
 # Only num_mics and placement are required
 mic_cfg_keys = ['num_mics', 'placement']
 else:
 mic_cfg_keys = ['positions', 'placement', 'orientation']
for key in mic_cfg_keys:
 if key not in mic_cfg:
 raise ValueError(f'Mic array {key} not provided')
# source
 source_cfg = self.cfg.get('source')
 if source_cfg is None:
 raise ValueError('Source configuration not provided')
if source_cfg.get('num') is None:
 raise ValueError('Number of sources per room not provided')
 elif source_cfg.num <= 0:
 raise ValueError(f'Number of sources must be positive: {source_cfg.num}')
if 'placement' not in source_cfg:
 raise ValueError('Source placement dictionary not provided')
# anechoic
 if self.cfg.get('anechoic') is None:
 raise ValueError('Anechoic configuratio not provided.')
def generate_room_params(self) -> dict:
 """Generate randomized room parameters based on the provided
 configuration.
 """
 # Prepare room sim parameters
 if not PRA:
 raise ImportError('pyroomacoustics is required for room simulation')
room_cfg = self.cfg.room
# Prepare rt60
 if room_cfg.rt60 is None:
 raise ValueError('Room RT60 needs to be a scalar or a range, currently it is None')
if np.isscalar(room_cfg.rt60):
 assert room_cfg.rt60 > 0, f'RT60 should be positive: {room_cfg.rt60}'
 rt60 = room_cfg.rt60
 elif len(room_cfg.rt60) == 2:
 assert (
 0 < room_cfg.rt60[0] <= room_cfg.rt60[1]
 ), f'Expecting two non-decreasing values for RT60, received {room_cfg.rt60}'
 rt60 = self.random.uniform(low=room_cfg.rt60[0], high=room_cfg.rt60[1])
 else:
 raise ValueError(f'Unexpected value for RT60: {room_cfg.rt60}')
# Generate a room with random dimensions
 num_retries = self.cfg.get('num_retries', 20)
for n in range(num_retries):
# width, length, height
 room_dim = np.zeros(3)
# prepare dimensions
 for idx, key in enumerate(['width', 'length', 'height']):
 # get configured dimension
 dim = room_cfg.dim[key]
# set a value
 if dim is None:
 raise ValueError(f'Room {key} needs to be a scalar or a range, currently it is None')
 elif np.isscalar(dim):
 assert dim > 0, f'Dimension should be positive for {key}: {dim}'
 room_dim[idx] = dim
 elif len(dim) == 2:
 assert 0 < dim[0] <= dim[1], f'Expecting two non-decreasing values for {key}, received {dim}'
 # Reduce dimension if the previous attempt failed
 room_dim[idx] = self.random.uniform(low=dim[0], high=dim[1] - n * (dim[1] - dim[0]) / num_retries)
 else:
 raise ValueError(f'Unexpected value for {key}: {dim}')
try:
 # Get parameters from size and RT60
 room_absorption, room_max_order = pra.inverse_sabine(rt60, room_dim)
 break
 except Exception as e:
 logging.debug('Inverse sabine failed: %s', str(e))
 # Inverse sabine may fail if the room is too large for the selected RT60.
 # Try again by generate a smaller room.
 room_absorption = room_max_order = None
 continue
if room_absorption is None or room_max_order is None:
 raise RuntimeError(f'Evaluation of parameters failed for RT60 {rt60}s and room size {room_dim}.')
# Return the required values
 room_params = {
 'dim': room_dim,
 'absorption': room_absorption,
 'max_order': room_max_order,
 'rt60_theoretical': rt60,
 'anechoic_absorption': self.cfg.anechoic.absorption,
 'anechoic_max_order': self.cfg.anechoic.max_order,
 'sample_rate': self.cfg.sample_rate,
 }
 return room_params
def generate_array(self, room_dim: Iterable[float]) -> ArrayGeometry:
 """Generate array placement for the current room and config.
 Args:
 room_dim: dimensions of the room, [width, length, height]
 Returns:
 Randomly placed microphone array.
 """
 mic_cfg = self.cfg.mic_array
if mic_cfg.positions == 'random':
 # Create a radom set of microphones
 num_mics = mic_cfg.num_mics
 mic_positions = []
# Each microphone is placed individually
 placement_range = convert_placement_to_range(
 placement=mic_cfg.placement, room_dim=room_dim, object_radius=0
 )
# Randomize mic placement
 for m in range(num_mics):
 position_m = [None] * 3
 for idx in range(3):
 position_m[idx] = self.random.uniform(low=placement_range[idx][0], high=placement_range[idx][1])
 mic_positions.append(position_m)
mic_array = ArrayGeometry(mic_positions)
else:
 mic_array = ArrayGeometry(mic_cfg.positions)
# Randomize center placement
 center = np.zeros(3)
 placement_range = convert_placement_to_range(
 placement=mic_cfg.placement, room_dim=room_dim, object_radius=mic_array.radius
 )
for idx in range(len(center)):
 center[idx] = self.random.uniform(low=placement_range[idx][0], high=placement_range[idx][1])
# Place the array at the configured center point
 mic_array.translate(to=center)
# Randomize orientation
 orientation = dict()
 for key in ['yaw', 'roll', 'pitch']:
 # angle for current orientation
 angle = mic_cfg.orientation[key]
if angle is None:
 raise ValueError(f'Mic array {key} should be a scalar or a range, currently it is set to None.')
# check it's within the expected range
 check_angle(key, angle)
if np.isscalar(angle):
 orientation[key] = angle
 elif len(angle) == 2:
 assert angle[0] <= angle[1], f"Expecting two non-decreasing values for {key}, received {angle}"
 # generate integer values, for easier bucketing, if necessary
 orientation[key] = self.random.uniform(low=angle[0], high=angle[1])
 else:
 raise ValueError(f'Unexpected value for orientation {key}: {angle}')
# Rotate the array to match the selected orientation
 mic_array.rotate(**orientation)
return mic_array
def generate_source_position(self, room_dim: Iterable[float]) -> List[List[float]]:
 """Generate position for all sources in a room.
 Args:
 room_dim: dimensions of a 3D shoebox room
 Returns:
 List of source positions, with each position characterized with a 3D coordinate
 """
 source_cfg = self.cfg.source
 placement_range = convert_placement_to_range(placement=source_cfg.placement, room_dim=room_dim)
 source_position = []
for n in range(source_cfg.num):
 # generate a random point withing the range
 s_pos = [None] * 3
 for idx in range(len(s_pos)):
 s_pos[idx] = self.random.uniform(low=placement_range[idx][0], high=placement_range[idx][1])
 source_position.append(s_pos)
return source_position
def generate(self):
 """Generate RIR corpus.
 This method will prepare randomized examples based on the current configuration,
 run room simulations and save results to output_dir.
 """
 logging.info("Generate RIR corpus")
# Initialize
 self.random = default_rng(seed=self.cfg.random_seed)
# Prepare output dir
 output_dir = self.cfg.output_dir
 if output_dir.endswith('.yaml'):
 output_dir = output_dir[:-5]
# Create absolute path
 logging.info('Output dir set to: %s', output_dir)
# Generate all cases
 for subset, num_rooms in self.cfg.room.num.items():
output_dir_subset = os.path.join(output_dir, subset)
 examples = []
if not os.path.exists(output_dir_subset):
 logging.info('Creating output directory: %s', output_dir_subset)
 os.makedirs(output_dir_subset)
 elif os.path.isdir(output_dir_subset) and len(os.listdir(output_dir_subset)) > 0:
 raise RuntimeError(f'Output directory {output_dir_subset} is not empty.')
# Generate examples
 for n_room in range(num_rooms):
# room info
 room_params = self.generate_room_params()
# array placement
 mic_array = self.generate_array(room_params['dim'])
# source placement
 source_position = self.generate_source_position(room_params['dim'])
# file name for the file
 room_filepath = os.path.join(output_dir_subset, f'{subset}_room_{n_room:06d}.h5')
# prepare example
 example = {
 'room_params': room_params,
 'mic_array': mic_array,
 'source_position': source_position,
 'room_filepath': room_filepath,
 }
 examples.append(example)
# Simulation
 if (num_workers := self.cfg.get('num_workers')) is None:
 num_workers = os.cpu_count() - 1
if num_workers > 1:
 logging.info(f'Simulate using {num_workers} workers')
 with multiprocessing.Pool(processes=num_workers) as pool:
 metadata = list(tqdm(pool.imap(simulate_room_kwargs, examples), total=len(examples)))
else:
 logging.info('Simulate using a single worker')
 metadata = []
 for example in tqdm(examples, total=len(examples)):
 metadata.append(simulate_room(**example))
# Save manifest
 manifest_filepath = os.path.join(output_dir, f'{subset}_manifest.json')
if os.path.exists(manifest_filepath) and os.path.isfile(manifest_filepath):
 raise RuntimeError(f'Manifest config file exists: {manifest_filepath}')
# Make all paths in the manifest relative to the output dir
 for data in metadata:
 data['room_filepath'] = os.path.relpath(data['room_filepath'], start=output_dir)
write_manifest(manifest_filepath, metadata)
# Generate plots with information about generated data
 plot_filepath = os.path.join(output_dir, f'{subset}_info.png')
if os.path.exists(plot_filepath) and os.path.isfile(plot_filepath):
 raise RuntimeError(f'Plot file exists: {plot_filepath}')
plot_rir_manifest_info(manifest_filepath, plot_filepath=plot_filepath)
# Save used configuration for reference
 config_filepath = os.path.join(output_dir, 'config.yaml')
 if os.path.exists(config_filepath) and os.path.isfile(config_filepath):
 raise RuntimeError(f'Output config file exists: {config_filepath}')
OmegaConf.save(self.cfg, config_filepath, resolve=True)
def simulate_room_kwargs(kwargs: dict) -> dict:
 """Wrapper around `simulate_room` to handle kwargs.
 `pool.map(simulate_room_kwargs, examples)` would be
 equivalent to `pool.starstarmap(simulate_room, examples)`
 if `starstarmap` would exist.
 Args:
 kwargs: kwargs that are forwarded to `simulate_room`
 Returns:
 Dictionary with metadata, see `simulate_room`
 """
 return simulate_room(**kwargs)
def simulate_room(
 room_params: dict,
 mic_array: ArrayGeometry,
 source_position: Iterable[Iterable[float]],
 room_filepath: str,
) -> dict:
 """Simulate room
 Args:
 room_params: parameters of the room to be simulated
 mic_array: defines positions of the microphones
 source_positions: positions for all sources to be simulated
 room_filepath: results are saved to this path
 Returns:
 Dictionary with metadata based on simulation setup
 and simulation results. Used to create the corresponding
 manifest file.
 """
 # room with the selected parameters
 room_sim = pra.ShoeBox(
 room_params['dim'],
 fs=room_params['sample_rate'],
 materials=pra.Material(room_params['absorption']),
 max_order=room_params['max_order'],
 )
# same geometry for generating anechoic responses
 room_anechoic = pra.ShoeBox(
 room_params['dim'],
 fs=room_params['sample_rate'],
 materials=pra.Material(room_params['anechoic_absorption']),
 max_order=room_params['anechoic_max_order'],
 )
# Compute RIRs
 for room in [room_sim, room_anechoic]:
 # place the array
 room.add_microphone_array(mic_array.positions.T)
# place the sources
 for s_pos in source_position:
 room.add_source(s_pos)
# generate RIRs
 room.compute_rir()
# Get metadata for sources
 source_distance = []
 source_azimuth = []
 source_elevation = []
 for s_pos in source_position:
 distance, azimuth, elevation = mic_array.spherical_relative_to_array(s_pos)
 source_distance.append(distance)
 source_azimuth.append(azimuth)
 source_elevation.append(elevation)
# RIRs
 rir_dataset = {
 'rir': convert_rir_to_multichannel(room_sim.rir),
 'anechoic': convert_rir_to_multichannel(room_anechoic.rir),
 }
# Prepare metadata dict and return
 metadata = {
 'room_filepath': room_filepath,
 'sample_rate': room_params['sample_rate'],
 'dim': room_params['dim'],
 'rir_absorption': room_params['absorption'],
 'rir_max_order': room_params['max_order'],
 'rir_rt60_theory': room_sim.rt60_theory(),
 'rir_rt60_measured': room_sim.measure_rt60().mean(axis=0), # average across mics for each source
 'anechoic_rt60_theory': room_anechoic.rt60_theory(),
 'anechoic_rt60_measured': room_anechoic.measure_rt60().mean(axis=0), # average across mics for each source
 'anechoic_absorption': room_params['anechoic_absorption'],
 'anechoic_max_order': room_params['anechoic_max_order'],
 'mic_positions': mic_array.positions,
 'mic_center': mic_array.center,
 'source_position': source_position,
 'source_distance': source_distance,
 'source_azimuth': source_azimuth,
 'source_elevation': source_elevation,
 'num_sources': len(source_position),
 }
# Save simulated RIR
 save_rir_simulation(room_filepath, rir_dataset, metadata)
return convert_numpy_to_serializable(metadata)
def save_rir_simulation(filepath: str, rir_dataset: Dict[str, List[np.array]], metadata: dict):
 """Save simulated RIRs and metadata.
 Args:
 filepath: Path to the file where the data will be saved.
 rir_dataset: Dictionary with RIR data. Each item is a set of multi-channel RIRs.
 metadata: Dictionary with related metadata.
 """
 if not HAS_H5PY:
 raise ImportError("Install h5py to use save_rir_simulation")
 if os.path.exists(filepath):
 raise RuntimeError(f'Output file exists: {filepath}')
num_sources = metadata['num_sources']
with h5py.File(filepath, 'w') as h5f:
 # Save RIRs, each RIR set in a separate group
 for rir_key, rir_value in rir_dataset.items():
 if len(rir_value) != num_sources:
 raise ValueError(
 f'Each RIR dataset should have exactly {num_sources} elements. Current RIR {rir_key} has {len(rir_value)} elements'
 )
rir_group = h5f.create_group(rir_key)
# RIRs for different sources are saved under [group]['idx']
 for idx, rir in enumerate(rir_value):
 rir_group.create_dataset(f'{idx}', data=rir_value[idx])
# Save metadata
 metadata_group = h5f.create_group('metadata')
 for key, value in metadata.items():
 metadata_group.create_dataset(key, data=value)
def load_rir_simulation(filepath: str, source: int = 0, rir_key: str = 'rir') -> Tuple[np.ndarray, float]:
 """Load simulated RIRs and metadata.
 Args:
 filepath: Path to simulated RIR data
 source: Index of a source.
 rir_key: String to denote which RIR to load, if there are multiple available.
 Returns:
 Multichannel RIR as ndarray with shape (num_samples, num_channels) and scalar sample rate.
 """
 if not HAS_H5PY:
 raise ImportError("Install h5py to use load_rir_simulation")
 with h5py.File(filepath, 'r') as h5f:
 # Load RIR
 rir = h5f[rir_key][f'{source}'][:]
# Load metadata
 sample_rate = h5f['metadata']['sample_rate'][()]
return rir, sample_rate
def convert_numpy_to_serializable(data: Union[dict, float, np.ndarray]) -> Union[dict, float, np.ndarray]:
 """Convert all numpy estries to list.
 Can be used to preprocess data before writing to a JSON file.
 Args:
 data: Dictionary, array or scalar.
 Returns:
 The same structure, but converted to list if
 the input is np.ndarray, so `data` can be seralized.
 """
 if isinstance(data, dict):
 for key, val in data.items():
 data[key] = convert_numpy_to_serializable(val)
 elif isinstance(data, list):
 data = [convert_numpy_to_serializable(d) for d in data]
 elif isinstance(data, np.ndarray):
 data = data.tolist()
 elif isinstance(data, np.integer):
 data = int(data)
 elif isinstance(data, np.floating):
 data = float(data)
 elif isinstance(data, np.generic):
 data = data.item()
return data
def convert_rir_to_multichannel(rir: List[List[np.ndarray]]) -> List[np.ndarray]:
 """Convert RIR to a list of arrays.
 Args:
 rir: list of lists, each element is a single-channel RIR
 Returns:
 List of multichannel RIRs
 """
 num_mics = len(rir)
 num_sources = len(rir[0])
mc_rir = [None] * num_sources
for n_source in range(num_sources):
 rir_len = [len(rir[m][n_source]) for m in range(num_mics)]
 max_len = max(rir_len)
 mc_rir[n_source] = np.zeros((max_len, num_mics))
 for n_mic, len_mic in enumerate(rir_len):
 mc_rir[n_source][:len_mic, n_mic] = rir[n_mic][n_source]
return mc_rir
def plot_rir_manifest_info(filepath: str, plot_filepath: str = None):
 """Plot distribution of parameters from manifest file.
 Args:
 filepath: path to a RIR corpus manifest file
 plot_filepath: path to save the plot at
 """
 metadata = read_manifest(filepath)
# source placement
 source_distance = []
 source_azimuth = []
 source_elevation = []
 source_height = []
# room config
 rir_rt60_theory = []
 rir_rt60_measured = []
 anechoic_rt60_theory = []
 anechoic_rt60_measured = []
# get the required data
 for data in metadata:
 # source config
 source_distance += data['source_distance']
 source_azimuth += data['source_azimuth']
 source_elevation += data['source_elevation']
 source_height += [s_pos[2] for s_pos in data['source_position']]
# room config
 rir_rt60_theory.append(data['rir_rt60_theory'])
 rir_rt60_measured += data['rir_rt60_measured']
 anechoic_rt60_theory.append(data['anechoic_rt60_theory'])
 anechoic_rt60_measured += data['anechoic_rt60_measured']
# plot
 plt.figure(figsize=(12, 6))
plt.subplot(2, 4, 1)
 plt.hist(source_distance, label='distance')
 plt.xlabel('distance / m')
 plt.ylabel('# examples')
 plt.title('Source-to-array center distance')
plt.subplot(2, 4, 2)
 plt.hist(source_azimuth, label='azimuth')
 plt.xlabel('azimuth / deg')
 plt.ylabel('# examples')
 plt.title('Source-to-array center azimuth')
plt.subplot(2, 4, 3)
 plt.hist(source_elevation, label='elevation')
 plt.xlabel('elevation / deg')
 plt.ylabel('# examples')
 plt.title('Source-to-array center elevation')
plt.subplot(2, 4, 4)
 plt.hist(source_height, label='source height')
 plt.xlabel('height / m')
 plt.ylabel('# examples')
 plt.title('Source height')
plt.subplot(2, 4, 5)
 plt.hist(rir_rt60_theory, label='theory')
 plt.xlabel('RT60 / s')
 plt.ylabel('# examples')
 plt.title('RT60 theory')
plt.subplot(2, 4, 6)
 plt.hist(rir_rt60_measured, label='measured')
 plt.xlabel('RT60 / s')
 plt.ylabel('# examples')
 plt.title('RT60 measured')
plt.subplot(2, 4, 7)
 plt.hist(anechoic_rt60_theory, label='theory')
 plt.xlabel('RT60 / s')
 plt.ylabel('# examples')
 plt.title('RT60 theory (anechoic)')
plt.subplot(2, 4, 8)
 plt.hist(anechoic_rt60_measured, label='measured')
 plt.xlabel('RT60 / s')
 plt.ylabel('# examples')
 plt.title('RT60 measured (anechoic)')
for n in range(8):
 plt.subplot(2, 4, n + 1)
 plt.grid()
 plt.legend(loc='lower left')
plt.tight_layout()
if plot_filepath is not None:
 plt.savefig(plot_filepath)
 plt.close()
 logging.info('Plot saved at %s', plot_filepath)
class RIRMixGenerator(object):
 """Creates a dataset of mixed signals at the microphone
 by combining target speech, background noise and interference.
 Correspnding signals are are generated and saved
 using the `generate` method.
 Input configuration is expexted to have the following structure
 ```
 sample_rate: sample rate used for simulation
 room:
 subset: manifest for RIR data
 target:
 subset: manifest for target source data
 noise:
 subset: manifest for noise data
 interference:
 subset: manifest for interference data
 interference_probability: probability that interference is present
 max_num_interferers: max number of interferers, randomly selected between 0 and max
 mix:
 subset:
 num: number of examples to generate
 rsnr: range of RSNR
 rsir: range of RSIR
 ref_mic: reference microphone
 ref_mic_rms: desired RMS at ref_mic
 ```
 """
def __init__(self, cfg: DictConfig):
 """
 Instantiate a RIRMixGenerator object.
 Args:
 cfg: generator configuration defining data for room,
 target signal, noise, interference and mixture
 """
 logging.info("Initialize RIRMixGenerator")
 self._cfg = cfg
 self.check_cfg()
self.subsets = self.cfg.room.keys()
 logging.info('Initialized with %d subsets: %s', len(self.subsets), str(self.subsets))
# load manifests
 self.metadata = dict()
 for subset in self.subsets:
 subset_data = dict()
logging.info('Loading data for %s', subset)
 for key in ['room', 'target', 'noise', 'interference']:
 try:
 subset_data[key] = read_manifest(self.cfg[key][subset])
 logging.info('\t%-*s: \t%d files', 15, key, len(subset_data[key]))
 except Exception as e:
 subset_data[key] = None
 logging.info('\t%-*s: \t0 files', 15, key)
 logging.warning('\t\tManifest data not loaded. Exception: %s', str(e))
self.metadata[subset] = subset_data
logging.info('Loaded all manifests')
self.num_retries = self.cfg.get('num_retries', 5)
@property
 def cfg(self):
 """Property holding the internal config of the object.
 Note:
 Changes to this config are not reflected in the state of the object.
 Please create a new model with the updated config.
 """
 return self._cfg
@property
 def sample_rate(self):
 return self._cfg.sample_rate
@cfg.setter
 def cfg(self, cfg):
 """Property holding the internal config of the object.
 Note:
 Changes to this config are not reflected in the state of the object.
 Please create a new model with the updated config.
 """
 self._cfg = cfg
def check_cfg(self):
 """
 Checks provided configuration to ensure it has the minimal required
 configuration the values are in a reasonable range.
 """
 # sample rate
 sample_rate = self.cfg.get('sample_rate')
 if sample_rate is None:
 raise ValueError('Sample rate not provided.')
 elif sample_rate < 0:
 raise ValueError(f'Sample rate must be positive: {sample_rate}')
# room configuration
 room_cfg = self.cfg.get('room')
 if not room_cfg:
 raise ValueError(
 'Room configuration not provided. Expecting RIR manifests in format {subset: path_to_manifest}'
 )
# target configuration
 target_cfg = self.cfg.get('target')
 if not target_cfg:
 raise ValueError(
 'Target configuration not provided. Expecting audio manifests in format {subset: path_to_manifest}'
 )
for key in ['azimuth', 'elevation', 'distance']:
 value = target_cfg.get(key)
if value is None or np.isscalar(value):
 # no constraint or a fixed dimension is ok
 pass
 elif len(value) != 2 or not value[0] < value[1]:
 # not a valid range
 raise ValueError(f'Range must be specified with two positive increasing elements for {key}: {value}')
# noise configuration
 noise_cfg = self.cfg.get('noise')
 if not noise_cfg:
 raise ValueError(
 'Noise configuration not provided. Expecting audio manifests in format {subset: path_to_manifest}'
 )
# interference configuration
 interference_cfg = self.cfg.get('interference')
 if not interference_cfg:
 logging.info('Interference configuration not provided.')
 else:
 interference_probability = interference_cfg.get('interference_probability', 0)
 max_num_interferers = interference_cfg.get('max_num_interferers', 0)
 min_azimuth_to_target = interference_cfg.get('min_azimuth_to_target', 0)
 if interference_probability is not None:
 if interference_probability < 0:
 raise ValueError(
 f'Interference probability must be non-negative. Current value: {interference_probability}'
 )
 elif interference_probability > 0:
 assert (
 max_num_interferers is not None and max_num_interferers > 0
 ), f'Max number of interferers must be positive. Current value: {max_num_interferers}'
 assert (
 min_azimuth_to_target is not None and min_azimuth_to_target >= 0
 ), 'Min azimuth to target must be non-negative'
# mix configuration
 mix_cfg = self.cfg.get('mix')
 if not mix_cfg:
 raise ValueError('Mix configuration not provided. Expecting configuration for each subset.')
 if 'ref_mic' not in mix_cfg:
 raise ValueError('Reference microphone not defined.')
 if 'ref_mic_rms' not in mix_cfg:
 raise ValueError('Reference microphone RMS not defined.')
def generate_target(self, subset: str) -> dict:
 """
 Prepare a dictionary with target configuration.
 The output dictionary contains the following information
 ```
 room_index: index of the selected room from the RIR corpus
 room_filepath: path to the room simulation file
 source: index of the selected source for the target
 rt60: reverberation time of the selected room
 num_mics: number of microphones
 azimuth: azimuth of the target source, relative to the microphone array
 elevation: elevation of the target source, relative to the microphone array
 distance: distance of the target source, relative to the microphone array
 audio_filepath: path to the audio file for the target source
 text: text for the target source audio signal, if available
 duration: duration of the target source audio signal
 ```
 Args:
 subset: string denoting a subset which will be used to selected target
 audio and room parameters.
 Returns:
 Dictionary with target configuration, including room, source index, and audio information.
 """
# Utility function
 def select_target_source(room_metadata, room_indices):
 """Find a room and a source that satisfies the constraints."""
 for room_index in room_indices:
 # Select room
 room_data = room_metadata[room_index]
# Candidate sources
 sources = self.random.choice(room_data['num_sources'], size=self.num_retries, replace=False)
# Select target source in this room
 for source in sources:
 # Check constraints
 constraints_met = []
 for constraint in ['azimuth', 'elevation', 'distance']:
 if self.cfg.target.get(constraint) is not None:
 # Check that the selected source is in the range
 source_value = room_data[f'source_{constraint}'][source]
 if self.cfg.target[constraint][0] <= source_value <= self.cfg.target[constraint][1]:
 constraints_met.append(True)
 else:
 constraints_met.append(False)
 # No need to check the remaining constraints
 break
# Check if a feasible source is found
 if all(constraints_met):
 # A feasible source has been found
 return source, room_index
return None, None
# Prepare room & source position
 room_metadata = self.metadata[subset]['room']
 room_indices = self.random.choice(len(room_metadata), size=self.num_retries, replace=False)
 source, room_index = select_target_source(room_metadata, room_indices)
if source is None:
 raise RuntimeError(f'Could not find a feasible source given target constraints {self.cfg.target}')
room_data = room_metadata[room_index]
# Optional: select subset of channels
 num_available_mics = len(room_data['mic_positions'])
 if 'mic_array' in self.cfg:
 num_mics = self.cfg.mic_array['num_mics']
 mic_selection = self.cfg.mic_array['selection']
if mic_selection == 'random':
 logging.debug('Randomly selecting %d mics', num_mics)
 selected_mics = self.random.choice(num_available_mics, size=num_mics, replace=False)
 elif isinstance(mic_selection, Iterable):
 logging.debug('Using explicitly selected mics: %s', str(mic_selection))
 assert (
 0 <= min(mic_selection) < num_available_mics
 ), f'Expecting mic_selection in range [0,{num_available_mics}), current value: {mic_selection}'
 selected_mics = np.array(mic_selection)
 else:
 raise ValueError(f'Unexpected value for mic_selection: {mic_selection}')
 else:
 logging.debug('Using all %d available mics', num_available_mics)
 num_mics = num_available_mics
 selected_mics = np.arange(num_mics)
# Double-check the number of mics is as expected
 assert (
 len(selected_mics) == num_mics
 ), f'Expecting {num_mics} mics, but received {len(selected_mics)} mics: {selected_mics}'
 logging.debug('Selected mics: %s', str(selected_mics))
# Calculate distance from the source to each microphone
 mic_positions = np.array(room_data['mic_positions'])[selected_mics]
 source_position = np.array(room_data['source_position'][source])
 distance_source_to_mic = np.linalg.norm(mic_positions - source_position, axis=1)
# Handle relative paths
 room_filepath = room_data['room_filepath']
 if not os.path.isabs(room_filepath):
 manifest_dir = os.path.dirname(self.cfg.room[subset])
 room_filepath = os.path.join(manifest_dir, room_filepath)
target_cfg = {
 'room_index': int(room_index),
 'room_filepath': room_filepath,
 'source': source,
 'rt60': room_data['rir_rt60_measured'][source],
 'selected_mics': selected_mics.tolist(),
 # Positions
 'source_position': source_position.tolist(),
 'mic_positions': mic_positions.tolist(),
 # Relative to center of the array
 'azimuth': room_data['source_azimuth'][source],
 'elevation': room_data['source_elevation'][source],
 'distance': room_data['source_distance'][source],
 # Relative to mics
 'distance_source_to_mic': distance_source_to_mic,
 }
return target_cfg
def generate_interference(self, subset: str, target_cfg: dict) -> List[dict]:
 """
 Prepare a list of dictionaries with interference configuration.
 Args:
 subset: string denoting a subset which will be used to select interference audio.
 target_cfg: dictionary with target configuration. This is used to determine
 the minimal required duration for the noise signal.
 Returns:
 List of dictionary with interference configuration, including source index and audio information
 for one or more interference sources.
 """
 if self.metadata[subset]['interference'] is None:
 # No interference to be configured
 return None
# Configure interfering sources
 max_num_sources = self.cfg.interference.get('max_num_interferers', 0)
 interference_probability = self.cfg.interference.get('interference_probability', 0)
if (
 max_num_sources >= 1
 and interference_probability > 0
 and self.random.uniform(low=0.0, high=1.0) < interference_probability
 ):
 # interference present
 num_interferers = self.random.integers(low=1, high=max_num_sources + 1)
 else:
 # interference not present
 return None
# Room setup: same room as target
 room_index = target_cfg['room_index']
 room_data = self.metadata[subset]['room'][room_index]
 feasible_sources = list(range(room_data['num_sources']))
 # target source is not eligible
 feasible_sources.remove(target_cfg['source'])
# Constraints for interfering sources
 min_azimuth_to_target = self.cfg.interference.get('min_azimuth_to_target', 0)
# Prepare interference configuration
 interference_cfg = []
 for n in range(num_interferers):
# Select a source
 source = None
 while len(feasible_sources) > 0 and source is None:
# Select a potential source for the target
 source = self.random.choice(feasible_sources)
 feasible_sources.remove(source)
# Check azimuth separation
 if min_azimuth_to_target > 0:
 source_azimuth = room_data['source_azimuth'][source]
 azimuth_diff = wrap_to_180(source_azimuth - target_cfg['azimuth'])
 if abs(azimuth_diff) < min_azimuth_to_target:
 # Try again
 source = None
 continue
if source is None:
 logging.warning('Could not select a feasible interference source %d of %s', n, num_interferers)
# Return what we have for now or None
 return interference_cfg if interference_cfg else None
# Current source setup
 interfering_source = {
 'source': source,
 'selected_mics': target_cfg['selected_mics'],
 'position': room_data['source_position'][source],
 'azimuth': room_data['source_azimuth'][source],
 'elevation': room_data['source_elevation'][source],
 'distance': room_data['source_distance'][source],
 }
# Done with interference for this source
 interference_cfg.append(interfering_source)
return interference_cfg
def generate_mix(self, subset: str, target_cfg: dict) -> dict:
 """Generate scaling parameters for mixing
 the target speech at the microphone, background noise
 and interference signal at the microphone.
 The output dictionary contains the following information
 ```
 rsnr: reverberant signal-to-noise ratio
 rsir: reverberant signal-to-interference ratio
 ref_mic: reference microphone for calculating the metrics
 ref_mic_rms: RMS of the signal at the reference microphone
 ```
 Args:
 subset: string denoting the subset of configuration
 target_cfg: dictionary with target configuration
 Returns:
 Dictionary containing configured RSNR, RSIR, ref_mic
 and RMS on ref_mic.
 """
 mix_cfg = dict()
for key in ['rsnr', 'rsir', 'ref_mic', 'ref_mic_rms', 'min_duration']:
 if key in self.cfg.mix[subset]:
 # Take the value from subset config
 value = self.cfg.mix[subset].get(key)
 else:
 # Take the global value
 value = self.cfg.mix.get(key)
if value is None:
 mix_cfg[key] = None
 elif np.isscalar(value):
 mix_cfg[key] = value
 elif len(value) == 2:
 # Select from the given range, including the upper bound
 mix_cfg[key] = self.random.integers(low=value[0], high=value[1] + 1)
 else:
 # Select one of the multiple values
 mix_cfg[key] = self.random.choice(value)
if mix_cfg['ref_mic'] == 'closest':
 # Select the closest mic as the reference
 mix_cfg['ref_mic'] = np.argmin(target_cfg['distance_source_to_mic'])
# Configuration for saving individual components
 mix_cfg['save'] = OmegaConf.to_object(self.cfg.mix['save']) if 'save' in self.cfg.mix else {}
return mix_cfg
def generate(self):
 """Generate a corpus of microphone signals by mixing target, background noise
 and interference signals.
 This method will prepare randomized examples based on the current configuration,
 run simulations and save results to output_dir.
 """
 logging.info('Generate mixed signals')
# Initialize
 self.random = default_rng(seed=self.cfg.random_seed)
# Prepare output dir
 output_dir = self.cfg.output_dir
 if output_dir.endswith('.yaml'):
 output_dir = output_dir[:-5]
# Create absolute path
 logging.info('Output dir set to: %s', output_dir)
# Generate all cases
 for subset in self.subsets:
output_dir_subset = os.path.join(output_dir, subset)
 examples = []
if not os.path.exists(output_dir_subset):
 logging.info('Creating output directory: %s', output_dir_subset)
 os.makedirs(output_dir_subset)
 elif os.path.isdir(output_dir_subset) and len(os.listdir(output_dir_subset)) > 0:
 raise RuntimeError(f'Output directory {output_dir_subset} is not empty.')
num_examples = self.cfg.mix[subset].num
 logging.info('Preparing %d examples for subset %s', num_examples, subset)
# Generate examples
 for n_example in tqdm(range(num_examples), total=num_examples, desc=f'Preparing {subset}'):
 # prepare configuration
 target_cfg = self.generate_target(subset)
 interference_cfg = self.generate_interference(subset, target_cfg)
 mix_cfg = self.generate_mix(subset, target_cfg)
# base file name
 base_output_filepath = os.path.join(output_dir_subset, f'{subset}_example_{n_example:09d}')
# prepare example
 example = {
 'sample_rate': self.sample_rate,
 'target_cfg': target_cfg,
 'interference_cfg': interference_cfg,
 'mix_cfg': mix_cfg,
 'base_output_filepath': base_output_filepath,
 }
examples.append(example)
# Audio data
 audio_metadata = {
 'target': self.metadata[subset]['target'],
 'target_dir': os.path.dirname(self.cfg.target[subset]), # manifest_dir
 'noise': self.metadata[subset]['noise'],
 'noise_dir': os.path.dirname(self.cfg.noise[subset]), # manifest_dir
 }
if interference_cfg is not None:
 audio_metadata.update(
 {
 'interference': self.metadata[subset]['interference'],
 'interference_dir': os.path.dirname(self.cfg.interference[subset]), # manifest_dir
 }
 )
# Simulation
 if (num_workers := self.cfg.get('num_workers')) is None:
 num_workers = os.cpu_count() - 1
if num_workers is not None and num_workers > 1:
 logging.info(f'Simulate using {num_workers} workers')
 examples_and_audio_metadata = zip(examples, itertools.repeat(audio_metadata, len(examples)))
 with multiprocessing.Pool(processes=num_workers) as pool:
 metadata = list(
 tqdm(
 pool.imap(simulate_room_mix_helper, examples_and_audio_metadata),
 total=len(examples),
 desc=f'Simulating {subset}',
 )
 )
 else:
 logging.info('Simulate using a single worker')
 metadata = []
 for example in tqdm(examples, total=len(examples), desc=f'Simulating {subset}'):
 metadata.append(simulate_room_mix(**example, audio_metadata=audio_metadata))
# Save manifest
 manifest_filepath = os.path.join(output_dir, f'{os.path.basename(output_dir)}_{subset}.json')
if os.path.exists(manifest_filepath) and os.path.isfile(manifest_filepath):
 raise RuntimeError(f'Manifest config file exists: {manifest_filepath}')
# Make all paths in the manifest relative to the output dir
 for data in tqdm(metadata, total=len(metadata), desc=f'Making filepaths relative {subset}'):
 for key, val in data.items():
 if key.endswith('_filepath') and val is not None:
 data[key] = os.path.relpath(val, start=output_dir)
write_manifest(manifest_filepath, metadata)
# Generate plots with information about generated data
 plot_filepath = os.path.join(output_dir, f'{os.path.basename(output_dir)}_{subset}_info.png')
if os.path.exists(plot_filepath) and os.path.isfile(plot_filepath):
 raise RuntimeError(f'Plot file exists: {plot_filepath}')
plot_mix_manifest_info(manifest_filepath, plot_filepath=plot_filepath)
# Save used configuration for reference
 config_filepath = os.path.join(output_dir, 'config.yaml')
 if os.path.exists(config_filepath) and os.path.isfile(config_filepath):
 raise RuntimeError(f'Output config file exists: {config_filepath}')
OmegaConf.save(self.cfg, config_filepath, resolve=True)
def convolve_rir(signal: np.ndarray, rir: np.ndarray) -> np.ndarray:
 """Convolve signal with a possibly multichannel IR in rir, i.e.,
 calculate the following for each channel m:
 signal_m = rir_m \ast signal
 Args:
 signal: single-channel signal (samples,)
 rir: single- or multi-channel IR, (samples,) or (samples, channels)
 Returns:
 out: same length as signal, same number of channels as rir, shape (samples, channels)
 """
 num_samples = len(signal)
 if rir.ndim == 1:
 # convolve and trim to length
 out = convolve(signal, rir)[:num_samples]
 elif rir.ndim == 2:
 num_channels = rir.shape[1]
 out = np.zeros((num_samples, num_channels))
 for m in range(num_channels):
 out[:, m] = convolve(signal, rir[:, m])[:num_samples]
else:
 raise RuntimeError(f'RIR with {rir.ndim} not supported')
return out
def calculate_drr(rir: np.ndarray, sample_rate: float, n_direct: List[int], n_0_ms=2.5) -> List[float]:
 """Calculate direct-to-reverberant ratio (DRR) from the measured RIR.
 Calculation is done as in eq. (3) from [1].
 Args:
 rir: room impulse response, shape (num_samples, num_channels)
 sample_rate: sample rate for the impulse response
 n_direct: direct path delay
 n_0_ms: window around n_direct for calculating the direct path energy
 Returns:
 Calculated DRR for each channel of the input RIR.
 References:
 [1] Eaton et al, The ACE challenge: Corpus description and performance evaluation, WASPAA 2015
 """
 # Define a window around the direct path delay
 n_0 = int(n_0_ms * sample_rate / 1000)
len_rir, num_channels = rir.shape
 drr = [None] * num_channels
 for m in range(num_channels):
# Window around the direct path
 dir_start = max(n_direct[m] - n_0, 0)
 dir_end = n_direct[m] + n_0
# Power of the direct component
 pow_dir = np.sum(np.abs(rir[dir_start:dir_end, m]) ** 2) / len_rir
# Power of the reverberant component
 pow_reverberant = (np.sum(np.abs(rir[0:dir_start, m]) ** 2) + np.sum(np.abs(rir[dir_end:, m]) ** 2)) / len_rir
# DRR in dB
 drr[m] = pow2db(pow_dir / pow_reverberant)
return drr
def normalize_max(x: np.ndarray, max_db: float = 0, eps: float = 1e-16) -> np.ndarray:
 """Normalize max input value to max_db full scale (±1).
 Args:
 x: input signal
 max_db: desired max magnitude compared to full scale
 eps: small regularization constant
 Returns:
 Normalized signal with max absolute value max_db.
 """
 max_val = db2mag(max_db)
 return max_val * x / (np.max(np.abs(x)) + eps)
def simultaneously_active_rms(
 x: np.ndarray,
 y: np.ndarray,
 sample_rate: float,
 rms_threshold_db: float = -60,
 window_len_ms: float = 200,
 min_active_duration: float = 0.5,
) -> Tuple[float, float]:
 """Calculate RMS over segments where both input signals are active.
 Args:
 x: first input signal
 y: second input signal
 sample_rate: sample rate for input signals in Hz
 rms_threshold_db: threshold for determining activity of the signal, relative
 to max absolute value
 window_len_ms: window length in milliseconds, used for calculating segmental RMS
 min_active_duration: minimal duration of the active segments
 Returns:
 RMS value over active segments for x and y.
 """
 if len(x) != len(y):
 raise RuntimeError(f'Expecting signals of same length: len(x)={len(x)}, len(y)={len(y)}')
 window_len = int(window_len_ms * sample_rate / 1000)
 rms_threshold = db2mag(rms_threshold_db) # linear scale
x_normalized = normalize_max(x)
 y_normalized = normalize_max(y)
x_active_power = y_active_power = active_len = 0
 for start in range(0, len(x) - window_len, window_len):
 window = slice(start, start + window_len)
# check activity on the scaled signal
 x_window_rms = rms(x_normalized[window])
 y_window_rms = rms(y_normalized[window])
if x_window_rms > rms_threshold and y_window_rms > rms_threshold:
 # sum the power of the original non-scaled signal
 x_active_power += np.sum(np.abs(x[window]) ** 2)
 y_active_power += np.sum(np.abs(y[window]) ** 2)
 active_len += window_len
if active_len < int(min_active_duration * sample_rate):
 raise RuntimeError(
 f'Signals are simultaneously active less than {min_active_duration} s: only {active_len/sample_rate} s'
 )
# normalize
 x_active_power /= active_len
 y_active_power /= active_len
return np.sqrt(x_active_power), np.sqrt(y_active_power)
def scaled_disturbance(
 signal: np.ndarray,
 disturbance: np.ndarray,
 sdr: float,
 sample_rate: float = None,
 ref_channel: int = 0,
 eps: float = 1e-16,
) -> np.ndarray:
 """
 Args:
 signal: numpy array, shape (num_samples, num_channels)
 disturbance: numpy array, same shape as signal
 sdr: desired signal-to-disturbance ration
 sample_rate: sample rate of the input signals
 ref_channel: ref mic used to calculate RMS
 eps: regularization constant
 Returns:
 Scaled disturbance, so that signal-to-disturbance ratio at ref_channel
 is approximately equal to input SDR during simultaneously active
 segment of signal and disturbance.
 """
 if signal.shape != disturbance.shape:
 raise ValueError(f'Signal and disturbance shapes do not match: {signal.shape} != {disturbance.shape}')
# set scaling based on RMS at ref_mic
 signal_rms, disturbance_rms = simultaneously_active_rms(
 signal[:, ref_channel], disturbance[:, ref_channel], sample_rate=sample_rate
 )
 disturbance_gain = db2mag(-sdr) * signal_rms / (disturbance_rms + eps)
 # scale disturbance
 scaled_disturbance = disturbance_gain * disturbance
 return scaled_disturbance
def prepare_source_signal(
 signal_type: str,
 sample_rate: int,
 audio_data: List[dict],
 audio_dir: Optional[str] = None,
 min_duration: Optional[int] = None,
 ref_signal: Optional[np.ndarray] = None,
 mic_positions: Optional[np.ndarray] = None,
 num_retries: int = 10,
) -> tuple:
 """Prepare an audio signal for a source.
 Args:
 signal_type: 'point' or 'diffuse'
 sample_rate: Sampling rate for the signal
 audio_data: List of audio items, each is a dictionary with audio_filepath, duration, offset and optionally text
 audio_dir: Base directory for resolving paths, e.g., manifest basedir
 min_duration: Minimal duration to be loaded if ref_signal is not provided, in seconds
 ref_signal: Optional, used to determine the length of the signal
 mic_positions: Optional, used to prepare approximately diffuse signal
 num_retries: Number of retries when selecting the source files
 Returns:
 (audio_signal, metadata), where audio_signal is an ndarray and metadata is a dictionary
 with audio filepaths, durations and offsets
 """
 if signal_type not in ['point', 'diffuse']:
 raise ValueError(f'Unexpected signal type {signal_type}.')
if audio_data is None:
 # No data to load
 return None
metadata = {}
if ref_signal is None:
 audio_signal = None
 # load at least one sample if min_duration is not provided
 samples_to_load = int(min_duration * sample_rate) if min_duration is not None else 1
 source_signals_metadata = {'audio_filepath': [], 'duration': [], 'offset': [], 'text': []}
while samples_to_load > 0:
 # Select a random item and load the audio
 item = random.choice(audio_data)
audio_filepath = item['audio_filepath']
 if not os.path.isabs(audio_filepath) and audio_dir is not None:
 audio_filepath = os.path.join(audio_dir, audio_filepath)
# Load audio
 check_min_sample_rate(audio_filepath, sample_rate)
 audio_segment = AudioSegment.from_file(
 audio_file=audio_filepath,
 target_sr=sample_rate,
 duration=item['duration'],
 offset=item.get('offset', 0),
 )
if signal_type == 'point':
 if audio_segment.num_channels > 1:
 raise RuntimeError(
 f'Expecting single-channel source signal, but received {audio_segment.num_channels}. File: {audio_filepath}'
 )
 else:
 raise ValueError(f'Unexpected signal type {signal_type}.')
source_signals_metadata['audio_filepath'].append(audio_filepath)
 source_signals_metadata['duration'].append(item['duration'])
 source_signals_metadata['duration'].append(item.get('offset', 0))
 source_signals_metadata['text'].append(item.get('text'))
# not perfect, since different files may have different distributions
 segment_samples = normalize_max(audio_segment.samples)
 # concatenate
 audio_signal = (
 np.concatenate((audio_signal, segment_samples)) if audio_signal is not None else segment_samples
 )
 # remaining samples
 samples_to_load -= len(segment_samples)
# Finally, we need only the metadata for the complete signal
 metadata = {
 'duration': sum(source_signals_metadata['duration']),
 'offset': 0,
 }
# Add text only if all source signals have text
 if all([isinstance(tt, str) for tt in source_signals_metadata['text']]):
 metadata['text'] = ' '.join(source_signals_metadata['text'])
 else:
 # Load a signal with total_len samples and ensure it has enough simultaneous activity/overlap with ref_signal
 # Concatenate multiple files if necessary
 total_len = len(ref_signal)
for n in range(num_retries):
audio_signal = None
 source_signals_metadata = {'audio_filepath': [], 'duration': [], 'offset': []}
if signal_type == 'point':
 samples_to_load = total_len
 elif signal_type == 'diffuse':
 # Load longer signal so it can be reshaped into (samples, mics) and
 # used to generate approximately diffuse noise field
 num_mics = len(mic_positions)
 samples_to_load = num_mics * total_len
while samples_to_load > 0:
 # Select an audio file
 item = random.choice(audio_data)
audio_filepath = item['audio_filepath']
 if not os.path.isabs(audio_filepath) and audio_dir is not None:
 audio_filepath = os.path.join(audio_dir, audio_filepath)
# Load audio signal
 check_min_sample_rate(audio_filepath, sample_rate)
if (max_offset := item['duration'] - np.ceil(samples_to_load / sample_rate)) > 0:
 # Load with a random offset if the example is longer than samples_to_load
 offset = random.uniform(0, max_offset)
 duration = -1
 else:
 # Load the whole file
 offset, duration = 0, item['duration']
 audio_segment = AudioSegment.from_file(
 audio_file=audio_filepath, target_sr=sample_rate, duration=duration, offset=offset
 )
# Prepare a single-channel signal
 if audio_segment.num_channels == 1:
 # Take all samples
 segment_samples = audio_segment.samples
 else:
 # Take a random channel
 selected_channel = random.choice(range(audio_segment.num_channels))
 segment_samples = audio_segment.samples[:, selected_channel]
source_signals_metadata['audio_filepath'].append(audio_filepath)
 source_signals_metadata['duration'].append(len(segment_samples) / sample_rate)
 source_signals_metadata['offset'].append(offset)
# not perfect, since different files may have different distributions
 segment_samples = normalize_max(segment_samples)
 # concatenate
 audio_signal = (
 np.concatenate((audio_signal, segment_samples)) if audio_signal is not None else segment_samples
 )
 # remaining samples
 samples_to_load -= len(segment_samples)
if signal_type == 'diffuse' and num_mics > 1:
 try:
 # Trim and reshape to num_mics to prepare num_mics source signals
 audio_signal = audio_signal[: num_mics * total_len].reshape(num_mics, -1).T
# Make spherically diffuse noise
 audio_signal = generate_approximate_noise_field(
 mic_positions=np.array(mic_positions), noise_signal=audio_signal, sample_rate=sample_rate
 )
 except Exception as e:
 logging.info('Failed to generate approximate noise field: %s', str(e))
 logging.info('Try again.')
 # Try again
 audio_signal, source_signals_metadata = None, {}
 continue
# Trim to length
 audio_signal = audio_signal[:total_len, ...]
# Include the channel dimension if the reference includes it
 if ref_signal.ndim == 2 and audio_signal.ndim == 1:
 audio_signal = audio_signal[:, None]
try:
 # Signal and ref_signal should be simultaneously active
 simultaneously_active_rms(ref_signal, audio_signal, sample_rate=sample_rate)
 # We have enough overlap
 break
 except Exception as e:
 # Signal and ref_signal are not overlapping, try again
 logging.info('Exception: %s', str(e))
 logging.info('Signals are not overlapping, try again.')
 audio_signal, source_signals_metadata = None, {}
 continue
if audio_signal is None:
 logging.warning('Audio signal not set: %s.', signal_type)
metadata['source_signals'] = source_signals_metadata
return audio_signal, metadata
def check_min_sample_rate(filepath: str, sample_rate: float):
 """Make sure the file's sample rate is at least sample_rate.
 This will make sure that we have only downsampling if loading
 this file, while upsampling is not permitted.
 Args:
 filepath: path to a file
 sample_rate: desired sample rate
 """
 file_sample_rate = librosa.get_samplerate(path=filepath)
 if file_sample_rate < sample_rate:
 raise RuntimeError(
 f'Sample rate ({file_sample_rate}) is lower than the desired sample rate ({sample_rate}). File: {filepath}.'
 )
def simulate_room_mix(
 sample_rate: int,
 target_cfg: dict,
 interference_cfg: dict,
 mix_cfg: dict,
 audio_metadata: dict,
 base_output_filepath: str,
 max_amplitude: float = 0.999,
 eps: float = 1e-16,
) -> dict:
 """Simulate mixture signal at the microphone, including target, noise and
 interference signals and mixed at specific RSNR and RSIR.
 Args:
 sample_rate: Sample rate for all signals
 target_cfg: Dictionary with configuration of the target. Includes
 room_filepath, source index, audio_filepath, duration
 noise_cfg: List of dictionaries, where each item includes audio_filepath,
 offset and duration.
 interference_cfg: List of dictionaries, where each item contains source
 index
 mix_cfg: Dictionary with the mixture configuration. Includes RSNR, RSIR,
 ref_mic and ref_mic_rms.
 audio_metadata: Dictionary with a list of files for target, noise and interference
 base_output_filepath: All output audio files will be saved with this prefix by
 adding a diffierent suffix for each component, e.g., _mic.wav.
 max_amplitude: Maximum amplitude of the mic signal, used to prevent clipping.
 eps: Small regularization constant.
 Returns:
 Dictionary with metadata based on the mixture setup and
 simulation results. This corresponds to a line of the
 output manifest file.
 """
# Local utilities
 def load_rir(
 room_filepath: str, source: int, selected_mics: list, sample_rate: float, rir_key: str = 'rir'
 ) -> np.ndarray:
 """Load a RIR and check that the sample rate is matching the desired sample rate
 Args:
 room_filepath: Path to a room simulation in an h5 file
 source: Index of the desired source
 sample_rate: Sample rate of the simulation
 rir_key: Key of the RIR to load from the simulation.
 Returns:
 Numpy array with shape (num_samples, num_channels)
 """
 rir, rir_sample_rate = load_rir_simulation(room_filepath, source=source, rir_key=rir_key)
 if rir_sample_rate != sample_rate:
 raise RuntimeError(
 f'RIR sample rate ({sample_rate}) is not matching the expected sample rate ({sample_rate}). File: {room_filepath}'
 )
 return rir[:, selected_mics]
def get_early_rir(
 rir: np.ndarray, rir_anechoic: np.ndarray, sample_rate: int, early_duration: float = 0.050
 ) -> np.ndarray:
 """Return only the early part of the RIR."""
 early_len = int(early_duration * sample_rate)
 direct_path_delay = np.min(np.argmax(rir_anechoic, axis=0))
 rir_early = rir.copy()
 rir_early[direct_path_delay + early_len :, :] = 0
 return rir_early
def save_audio(
 base_path: str,
 tag: str,
 audio_signal: Optional[np.ndarray],
 sample_rate: int,
 save: str = 'all',
 ref_mic: Optional[int] = None,
 format: str = 'wav',
 subtype: str = 'float',
 ):
 """Save audio signal and return filepath."""
 if (audio_signal is None) or (not save):
 return None
if save == 'ref_mic':
 # save only ref_mic
 audio_signal = audio_signal[:, ref_mic]
audio_filepath = base_path + f'_{tag}.{format}'
 sf.write(audio_filepath, audio_signal, sample_rate, subtype)
return audio_filepath
# Target RIRs
 target_rir = load_rir(
 target_cfg['room_filepath'],
 source=target_cfg['source'],
 selected_mics=target_cfg['selected_mics'],
 sample_rate=sample_rate,
 )
 target_rir_anechoic = load_rir(
 target_cfg['room_filepath'],
 source=target_cfg['source'],
 sample_rate=sample_rate,
 selected_mics=target_cfg['selected_mics'],
 rir_key='anechoic',
 )
 target_rir_early = get_early_rir(rir=target_rir, rir_anechoic=target_rir_anechoic, sample_rate=sample_rate)
# Target signals
 target_signal, target_metadata = prepare_source_signal(
 signal_type='point',
 sample_rate=sample_rate,
 audio_data=audio_metadata['target'],
 audio_dir=audio_metadata['target_dir'],
 min_duration=mix_cfg['min_duration'],
 )
 source_signals_metadata = {'target': target_metadata['source_signals']}
# Convolve target
 target_reverberant = convolve_rir(target_signal, target_rir)
 target_anechoic = convolve_rir(target_signal, target_rir_anechoic)
 target_early = convolve_rir(target_signal, target_rir_early)
# Prepare noise signal
 noise, noise_metadata = prepare_source_signal(
 signal_type='diffuse',
 sample_rate=sample_rate,
 mic_positions=target_cfg['mic_positions'],
 audio_data=audio_metadata['noise'],
 audio_dir=audio_metadata['noise_dir'],
 ref_signal=target_reverberant,
 )
 source_signals_metadata['noise'] = noise_metadata['source_signals']
# Prepare interference signal
 if interference_cfg is None:
 interference = None
 else:
 # Load interference signals
 interference = 0
 source_signals_metadata['interference'] = []
 for i_cfg in interference_cfg:
 # Load single-channel signal for directional interference
 i_signal, i_metadata = prepare_source_signal(
 signal_type='point',
 sample_rate=sample_rate,
 audio_data=audio_metadata['interference'],
 audio_dir=audio_metadata['interference_dir'],
 ref_signal=target_signal,
 )
 source_signals_metadata['interference'].append(i_metadata['source_signals'])
 # Load RIR from the same room as the target, but a difference source
 i_rir = load_rir(
 target_cfg['room_filepath'],
 source=i_cfg['source'],
 selected_mics=i_cfg['selected_mics'],
 sample_rate=sample_rate,
 )
 # Convolve interference
 i_reverberant = convolve_rir(i_signal, i_rir)
 # Sum
 interference += i_reverberant
# Scale and add components of the signal
 mic = target_reverberant.copy()
if noise is not None:
 noise = scaled_disturbance(
 signal=target_reverberant,
 disturbance=noise,
 sdr=mix_cfg['rsnr'],
 sample_rate=sample_rate,
 ref_channel=mix_cfg['ref_mic'],
 )
 # Update mic signal
 mic += noise
if interference is not None:
 interference = scaled_disturbance(
 signal=target_reverberant,
 disturbance=interference,
 sdr=mix_cfg['rsir'],
 sample_rate=sample_rate,
 ref_channel=mix_cfg['ref_mic'],
 )
 # Update mic signal
 mic += interference
# Set the final mic signal level
 mic_rms = rms(mic[:, mix_cfg['ref_mic']])
 global_gain = db2mag(mix_cfg['ref_mic_rms']) / (mic_rms + eps)
 mic_max = np.max(np.abs(mic))
 if (clipped_max := mic_max * global_gain) > max_amplitude:
 # Downscale the global gain to prevent clipping + adjust ref_mic_rms accordingly
 clipping_prevention_gain = max_amplitude / clipped_max
 global_gain *= clipping_prevention_gain
 mix_cfg['ref_mic_rms'] += mag2db(clipping_prevention_gain)
logging.debug(
 'Clipping prevented for example %s (protection gain: %.2f dB)',
 base_output_filepath,
 mag2db(clipping_prevention_gain),
 )
# save signals
 signals = {
 'mic': mic,
 'target_reverberant': target_reverberant,
 'target_anechoic': target_anechoic,
 'target_early': target_early,
 'noise': noise,
 'interference': interference,
 }
metadata = {}
for tag, signal in signals.items():
if signal is not None:
 # scale all signal components with the global gain
 signal = global_gain * signal
audio_filepath = save_audio(
 base_path=base_output_filepath,
 tag=tag,
 audio_signal=signal,
 sample_rate=sample_rate,
 save=mix_cfg['save'].get(tag, 'all'),
 ref_mic=mix_cfg['ref_mic'],
 format=mix_cfg['save'].get('format', 'wav'),
 subtype=mix_cfg['save'].get('subtype', 'float'),
 )
if tag == 'mic':
 metadata['audio_filepath'] = audio_filepath
 else:
 metadata[tag + '_filepath'] = audio_filepath
# Add metadata
 metadata.update(
 {
 'text': target_metadata.get('text'),
 'duration': target_metadata['duration'],
 'target_cfg': target_cfg,
 'interference_cfg': interference_cfg,
 'mix_cfg': mix_cfg,
 'ref_channel': mix_cfg.get('ref_mic'),
 'rt60': target_cfg.get('rt60'),
 'drr': calculate_drr(target_rir, sample_rate, n_direct=np.argmax(target_rir_anechoic, axis=0)),
 'rsnr': None if noise is None else mix_cfg['rsnr'],
 'rsir': None if interference is None else mix_cfg['rsir'],
 'source_signals': source_signals_metadata,
 }
 )
return convert_numpy_to_serializable(metadata)
def simulate_room_mix_helper(example_and_audio_metadata: tuple) -> dict:
 """Wrapper around `simulate_room_mix` for pool.imap.
 Args:
 args: example and audio_metadata that are forwarded to `simulate_room_mix`
 Returns:
 Dictionary with metadata, see `simulate_room_mix`
 """
 example, audio_metadata = example_and_audio_metadata
 return simulate_room_mix(**example, audio_metadata=audio_metadata)
def plot_mix_manifest_info(filepath: str, plot_filepath: str = None):
 """Plot distribution of parameters from the manifest file.
 Args:
 filepath: path to a RIR corpus manifest file
 plot_filepath: path to save the plot at
 """
 metadata = read_manifest(filepath)
# target info
 target_distance = []
 target_azimuth = []
 target_elevation = []
 target_duration = []
# room config
 rt60 = []
 drr = []
# noise
 rsnr = []
 rsir = []
# get the required data
 for data in metadata:
 # target info
 target_distance.append(data['target_cfg']['distance'])
 target_azimuth.append(data['target_cfg']['azimuth'])
 target_elevation.append(data['target_cfg']['elevation'])
 target_duration.append(data['duration'])
# room config
 rt60.append(data['rt60'])
 drr += data['drr'] # average DRR across all mics
# noise
 if data['rsnr'] is not None:
 rsnr.append(data['rsnr'])
if data['rsir'] is not None:
 rsir.append(data['rsir'])
# plot
 plt.figure(figsize=(12, 6))
plt.subplot(2, 4, 1)
 plt.hist(target_distance, label='distance')
 plt.xlabel('distance / m')
 plt.ylabel('# examples')
 plt.title('Target-to-array distance')
plt.subplot(2, 4, 2)
 plt.hist(target_azimuth, label='azimuth')
 plt.xlabel('azimuth / deg')
 plt.ylabel('# examples')
 plt.title('Target-to-array azimuth')
plt.subplot(2, 4, 3)
 plt.hist(target_elevation, label='elevation')
 plt.xlabel('elevation / deg')
 plt.ylabel('# examples')
 plt.title('Target-to-array elevation')
plt.subplot(2, 4, 4)
 plt.hist(target_duration, label='duration')
 plt.xlabel('time / s')
 plt.ylabel('# examples')
 plt.title('Target duration')
plt.subplot(2, 4, 5)
 plt.hist(rt60, label='RT60')
 plt.xlabel('RT60 / s')
 plt.ylabel('# examples')
 plt.title('RT60')
plt.subplot(2, 4, 6)
 plt.hist(drr, label='DRR')
 plt.xlabel('DRR / dB')
 plt.ylabel('# examples')
 plt.title('DRR [avg over mics]')
if len(rsnr) > 0:
 plt.subplot(2, 4, 7)
 plt.hist(rsnr, label='RSNR')
 plt.xlabel('RSNR / dB')
 plt.ylabel('# examples')
 plt.title(f'RSNR [{100 * len(rsnr) / len(rt60):.0f}% ex]')
if len(rsir):
 plt.subplot(2, 4, 8)
 plt.hist(rsir, label='RSIR')
 plt.xlabel('RSIR / dB')
 plt.ylabel('# examples')
 plt.title(f'RSIR [{100 * len(rsir) / len(rt60):.0f}% ex]')
for n in range(8):
 plt.subplot(2, 4, n + 1)
 plt.grid()
 plt.legend(loc='lower left')
plt.tight_layout()
if plot_filepath is not None:
 plt.savefig(plot_filepath)
 plt.close()
 logging.info('Plot saved at %s', plot_filepath)