WUT_Computer_Science/code/linear_algebra_utils.py

401 lines
13 KiB
Python

import math
import itertools
import operator
from multiprocessing import Pool
from abc import ABC, abstractmethod
from concurrent.futures import ThreadPoolExecutor
from functools import partial
from time_measurement import time_measurement, time_accumulator
import numpy as np
class LinearAlgebraUtils(ABC):
@staticmethod
@abstractmethod
def dot_product(v1, v2):
pass
@staticmethod
@abstractmethod
def matrix_vector_multiply(A, x):
pass
@staticmethod
@abstractmethod
def vector_norm(v):
pass
@staticmethod
@abstractmethod
def vector_scalar_divide(x, scalar):
pass
@staticmethod
@abstractmethod
def matrix_scalar_multiply(A, w):
pass
@staticmethod
@abstractmethod
def vector_vector_subtraction(v1, v2):
pass
@staticmethod
@abstractmethod
def vector_vector_addition(v1, v2):
pass
@staticmethod
@abstractmethod
def scalar_vector_multiply(omega, vector):
pass
@staticmethod
@abstractmethod
def matrix_norm(A):
pass
@staticmethod
@abstractmethod
def matrix_matrix_subtraction(A, B):
pass
class SequentialLinearAlgebraUtils(ABC):
@staticmethod
def dot_product(v1, v2):
return sum(x*y for x, y in zip(v1, v2))
@staticmethod
def matrix_vector_multiply(A, x):
return [SequentialLinearAlgebraUtils.dot_product(row, x) for row in A]
@staticmethod
def vector_norm(v):
return math.sqrt(sum(x*x for x in v))
@staticmethod
def vector_scalar_divide(x, scalar):
return [xi / scalar for xi in x]
@staticmethod
def matrix_scalar_multiply(A, w):
return A * w
@staticmethod
def vector_vector_subtraction(v1, v2):
return [x-y for x, y in zip(v1, v2)]
@staticmethod
def vector_vector_addition(v1, v2):
return [x+y for x, y in zip(v1, v2)]
@staticmethod
def scalar_vector_multiply(omega, vector):
return [omega * x for x in vector]
@staticmethod
def matrix_norm(A):
return math.sqrt(sum(sum(element ** 2 for element in row) for row in A))
@staticmethod
def matrix_matrix_subtraction(A, B):
return [[A[i][j] - B[i][j] for j in range(len(A[0]))] for i in range(len(A))]
class ThreadsLinearAlgebraUtils(ABC):
NUM_THREADS = 4
@staticmethod
@time_measurement(time_accumulator)
def get_chunk_size(data):
num_elements = len(data)
num_threads = min(ThreadsLinearAlgebraUtils.NUM_THREADS, num_elements)
chunk_size = num_elements // num_threads
remainder = num_elements % num_threads
return chunk_size, num_threads, remainder
@staticmethod
@time_measurement(time_accumulator)
def divide_vectors_to_chunks(v1, v2):
chunk_size, num_threads, remainder = ThreadsLinearAlgebraUtils.get_chunk_size(v1)
chunks = []
start = 0
for i in range(num_threads):
end = start + chunk_size + (1 if i < remainder else 0)
chunks.append((v1[start:end], v2[start:end]))
start = end
return chunks
@staticmethod
@time_measurement(time_accumulator)
def divide_vector_or_matrix_to_chunks(v):
chunk_size, num_threads, remainder = ThreadsLinearAlgebraUtils.get_chunk_size(v)
chunks = []
start = 0
for i in range(num_threads):
end = start + chunk_size + (1 if i < remainder else 0)
chunks.append(v[start:end])
start = end
return chunks
@staticmethod
@time_measurement(time_accumulator)
def dot_product(v1, v2):
chunks = ThreadsLinearAlgebraUtils.divide_vectors_to_chunks(v1, v2)
with ThreadPoolExecutor(max_workers=ThreadsLinearAlgebraUtils.NUM_THREADS) as executor:
results = executor.map(lambda pair: SequentialLinearAlgebraUtils.dot_product(*pair), chunks)
return sum(results)
@staticmethod
@time_measurement(time_accumulator)
def matrix_vector_multiply(A, x):
chunks = ThreadsLinearAlgebraUtils.divide_vector_or_matrix_to_chunks(A)
with ThreadPoolExecutor(max_workers=ThreadsLinearAlgebraUtils.NUM_THREADS) as executor:
func = partial(SequentialLinearAlgebraUtils.matrix_vector_multiply, x=x)
results = executor.map(func, chunks)
return [item for sublist in results for item in sublist]
@staticmethod
@time_measurement(time_accumulator)
def vector_norm(v):
chunks = ThreadsLinearAlgebraUtils.divide_vector_or_matrix_to_chunks(v)
def partial_norm(chunk):
return sum(x * x for x in chunk)
with ThreadPoolExecutor(max_workers=ThreadsLinearAlgebraUtils.NUM_THREADS) as executor:
results = executor.map(partial_norm, chunks)
total_sum = sum(results)
return total_sum**0.5
@staticmethod
@time_measurement(time_accumulator)
def vector_scalar_divide(x, scalar):
chunks = ThreadsLinearAlgebraUtils.divide_vector_or_matrix_to_chunks(x)
with ThreadPoolExecutor(max_workers=ThreadsLinearAlgebraUtils.NUM_THREADS) as executor:
results = executor.map(lambda chunk: SequentialLinearAlgebraUtils.vector_scalar_divide(chunk, scalar), chunks)
return [item for sublist in results for item in sublist]
@staticmethod
@time_measurement(time_accumulator)
def matrix_scalar_multiply(A, w):
chunks = ThreadsLinearAlgebraUtils.divide_vector_or_matrix_to_chunks(A)
with ThreadPoolExecutor(max_workers=ThreadsLinearAlgebraUtils.NUM_THREADS) as executor:
results = executor.map(lambda chunk: SequentialLinearAlgebraUtils.matrix_scalar_multiply(w, chunk), chunks)
return [item for sublist in results for item in sublist]
@staticmethod
@time_measurement(time_accumulator)
def vector_vector_subtraction(v1, v2):
chunks = ThreadsLinearAlgebraUtils.divide_vectors_to_chunks(v1, v2)
with ThreadPoolExecutor(max_workers=ThreadsLinearAlgebraUtils.NUM_THREADS) as executor:
results = executor.map(lambda pair: SequentialLinearAlgebraUtils.vector_vector_subtraction(*pair), chunks)
return [item for sublist in results for item in sublist]
@staticmethod
@time_measurement(time_accumulator)
def vector_vector_addition(v1, v2):
chunks = ThreadsLinearAlgebraUtils.divide_vectors_to_chunks(v1, v2)
with ThreadPoolExecutor(max_workers=ThreadsLinearAlgebraUtils.NUM_THREADS) as executor:
results = executor.map(lambda pair: SequentialLinearAlgebraUtils.vector_vector_addition(*pair), chunks)
return [item for sublist in results for item in sublist]
@staticmethod
@time_measurement(time_accumulator)
def scalar_vector_multiply(omega, vector):
chunks = ThreadsLinearAlgebraUtils.divide_vector_or_matrix_to_chunks(vector)
with ThreadPoolExecutor(max_workers=ThreadsLinearAlgebraUtils.NUM_THREADS) as executor:
results = executor.map(lambda chunk: SequentialLinearAlgebraUtils.scalar_vector_multiply(omega, chunk), chunks)
return [item for sublist in results for item in sublist]
@staticmethod
@time_measurement(time_accumulator)
def matrix_norm(A):
chunks = ThreadsLinearAlgebraUtils.divide_vector_or_matrix_to_chunks(A)
def partial_norm(chunk):
return sum(element ** 2 for row in chunk for element in row)
with ThreadPoolExecutor(max_workers=ThreadsLinearAlgebraUtils.NUM_THREADS) as executor:
results = executor.map(partial_norm, chunks)
total_sum = sum(results)
return math.sqrt(total_sum)
@staticmethod
@time_measurement(time_accumulator)
def divide_matrixes_to_chunks(A, B):
num_rows = len(A)
num_threads = ThreadsLinearAlgebraUtils.NUM_THREADS
if num_threads > num_rows:
num_threads = num_rows
if num_rows == 0:
return []
chunk_size = num_rows // num_threads
remainder = num_rows % num_threads
chunks = []
start = 0
for _ in range(num_threads):
end = start + chunk_size + (1 if remainder > 0 else 0)
chunks.append((A[start:end], B[start:end]))
start = end
if remainder > 0:
remainder -= 1
return chunks
@staticmethod
@time_measurement(time_accumulator)
def matrix_matrix_subtraction(A, B):
def subtract_chunk(pair):
chunk_A, chunk_B = pair
return [[chunk_A[i][j] - chunk_B[i][j] for j in range(len(chunk_A[0]))] for i in range(len(chunk_A))]
chunks = ThreadsLinearAlgebraUtils.divide_matrixes_to_chunks(A, B)
with ThreadPoolExecutor(max_workers=ThreadsLinearAlgebraUtils.NUM_THREADS) as executor:
results = executor.map(subtract_chunk, chunks)
return [row for chunk in results for row in chunk]
@time_measurement(time_accumulator)
def process_row(params):
A, k, i = params
factor = A[i][k] / A[k][k]
return [A[i][j] - factor * A[k][j] for j in range(len(A[0]))]
@time_measurement(time_accumulator)
def divide_by_scalar(pair):
xi, scalar = pair
return xi / scalar
@time_measurement(time_accumulator)
def multiply_by_scalar(pair):
element, scalar = pair
return element * scalar
class ProcessLinearAlgebraUtils:
@staticmethod
@time_measurement(time_accumulator)
def dot_product(v1, v2):
with Pool() as pool:
result = pool.starmap(ProcessLinearAlgebraUtils.multiply_elements, zip(v1, v2))
return sum(result)
@staticmethod
@time_measurement(time_accumulator)
def multiply_elements(x, y):
return x * y
@staticmethod
@time_measurement(time_accumulator)
def matrix_vector_multiply_row(params):
row, vector = params
return SequentialLinearAlgebraUtils.dot_product(row, vector)
@staticmethod
@time_measurement(time_accumulator)
def matrix_vector_multiply(A, x):
with Pool() as pool:
result = pool.map(ProcessLinearAlgebraUtils.matrix_vector_multiply_row, [(row, x) for row in A])
return list(result)
@staticmethod
@time_measurement(time_accumulator)
def vector_norm(v):
with Pool() as pool:
squared = pool.map(ProcessLinearAlgebraUtils.square, v)
return math.sqrt(sum(squared))
@staticmethod
@time_measurement(time_accumulator)
def square(x):
return x * x
@staticmethod
@time_measurement(time_accumulator)
def vector_scalar_divide(x, scalar):
with Pool() as pool:
result = pool.map(divide_by_scalar, [(xi, scalar) for xi in x])
return list(result)
@staticmethod
@time_measurement(time_accumulator)
def divide_vector_by_scalar(x, scalar):
with Pool() as pool:
result = pool.map(ProcessLinearAlgebraUtils.vector_scalar_divide, [(xi, scalar) for xi in x])
return list(result)
@staticmethod
@time_measurement(time_accumulator)
def matrix_scalar_multiply_row(params):
row, w = params
return [w * element for element in row]
@staticmethod
@time_measurement(time_accumulator)
def matrix_scalar_multiply(A, w):
with Pool() as pool:
result = pool.map(ProcessLinearAlgebraUtils.matrix_scalar_multiply_row, [(row, w) for row in A])
return result
@staticmethod
@time_measurement(time_accumulator)
def vector_vector_operation(params):
v1, v2, op = params
return op(v1, v2)
@staticmethod
@time_measurement(time_accumulator)
def vector_vector_subtraction(v1, v2):
with Pool() as pool:
result = pool.map(ProcessLinearAlgebraUtils.vector_vector_operation, zip(v1, v2, itertools.repeat(operator.sub)))
return list(result)
@staticmethod
@time_measurement(time_accumulator)
def vector_vector_addition(v1, v2):
with Pool() as pool:
result = pool.map(ProcessLinearAlgebraUtils.vector_vector_operation, zip(v1, v2, itertools.repeat(operator.add)))
return list(result)
@staticmethod
@time_measurement(time_accumulator)
def scalar_vector_multiply(omega, vector):
with Pool() as pool:
result = pool.map(multiply_by_scalar, [(element, omega) for element in vector])
return list(result)
@staticmethod
@time_measurement(time_accumulator)
def sum_of_squares(row):
return sum(x ** 2 for x in row)
@staticmethod
@time_measurement(time_accumulator)
def matrix_norm(A):
with Pool() as pool:
row_sums = pool.map(ProcessLinearAlgebraUtils.sum_of_squares, A)
return math.sqrt(sum(row_sums))
@staticmethod
@time_measurement(time_accumulator)
def subtract_rows(row_from_A, row_from_B):
return [a - b for a, b in zip(row_from_A, row_from_B)]
@staticmethod
@time_measurement(time_accumulator)
def matrix_matrix_subtraction(A, B):
with Pool() as pool:
result = pool.starmap(ProcessLinearAlgebraUtils.subtract_rows, zip(A, B))
return result