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#!/usr/local/bin/ruby
#
# matrix.rb -
# $Release Version: 1.0$
# $Revision: 1.11 $
# $Date: 1999/10/06 11:01:53 $
# Original Version from Smalltalk-80 version
# on July 23, 1985 at 8:37:17 am
# by Keiju ISHITSUKA
#
# --
#
# Matrix[[1,2,3],
# :
# [3,4,5]]
# Matrix[row0,
# row1,
# :
# rown]
#
#
# module ExceptionForMatrix::
# Exceptions:
# ErrDimensionMismatch
# number of column/row do not match
# ErrNotRegular
# not a regular matrix
# ErrOperationNotDefined
# specified operator is not defined (yet)
#
# class Matrix
# include ExceptionForMatrix
#
# Methods:
# class methods:
# Matrix.[](*rows)
# creates a matrix where `rows' indicates rows.
# `rows' is an array of arrays,
# e.g, Matrix[[11, 12], [21, 22]]
# Matrix.rows(rows, copy = true)
# creates a matrix where `rows' indicates rows.
# if optional argument `copy' is false, use the array as
# internal structure of the metrix without copying.
# Matrix.columns(columns)
# creates a new matrix using `columns` as set of colums vectors.
# Matrix.diagonal(*values)
# creates a matrix where `columns' indicates columns.
# Matrix.scalar(n, value)
# creates a diagonal matrix such that the diagal compornents is
# given by `values'.
# Matrix.scalar(n, value)
# creates an n-by-n scalar matrix such that the diagal compornent is
# given by `value'.
# Matrix.identity(n)
# Matrix.unit(n)
# Matrix.I(n)
# creates an n-by-n unit matrix.
# Matrix.zero(n)
# creates an n-by-n zero matrix.
# Matrix.row_vector(row)
# creates a 1-by-n matrix such the row vector is `row'.
# `row' is specifed as a Vector or an Array.
# Matrix.column_vector(column)
# creates a 1-by-n matrix such that column vector is `column'.
# `column' is specifed as a Vector or an Array.
# accessing:
# [](i, j)
# returns (i,j) compornent
# row_size
# returns the number of rows
# column_size
# returns the number of columns
# row(i)
# returns the i-th row vector.
# when the block is supplied for the method, the block is iterated
# over all row vectors.
# column(j)
# returns the jth column vector.
# when the block is supplied for the method, the block is iterated
# over all column vectors.
# collect
# map
# creates a matrix which is the result of iteration of given
# block over all compornents.
# minor(*param)
# returns sub matrix. parameter is specified as the following:
# 1. from_row, row_size, from_col, size_col
# 2. from_row..to_row, from_col..to_col
# TESTING:
# regular?
# Is regular?
# singular?
# Is singular? i.e. Is non-regular?
# square?
# Is square?
# ARITHMETIC:
# *(m)
# times
# +(m)
# plus
# -(m)
# minus
# /(m)
# self * m.inv
# inverse
# inv
# inverse
# **
# power
# Matrix functions:
# determinant
# det
# returns the determinant
# rank
# returns the rank
# trace
# tr
# returns the trace
# transpose
# t
# returns the transposed
# CONVERTING:
# coerce(other)
# row_vectors
# array of row vectors
# column_vectors
# array of column vectors
# to_a
# converts each element to Array
# to_f
# converts each element to Float
# to_i
# converts each element to Integer
# to_r
# converts each element to Rational
# PRINTING:
# to_s
# returns string representation
# inspect
#
# class Vector
# include ExceptionForMatrix
#
# INSTANCE CREATION:
# Vector.[](*array)
# Vector.elements(array, copy = true)
# ACCSESSING:
# [](i)
# size
# ENUMRATIONS:
# each2(v)
# collect2(v)
# ARITHMETIC:
# *(x) "is matrix or number"
# +(v)
# -(v)
# VECTOR FUNCTIONS:
# inner_product(v)
# collect
# map
# map2(v)
# r
# CONVERTING:
# covector
# to_a
# to_f
# to_i
# to_r
# coerce(other)
# PRINTING:
# to_s
# inspect
require "e2mmap.rb"
module ExceptionForMatrix
extend Exception2MessageMapper
def_e2message(TypeError, "wrong argument type %s (expected %s)")
def_e2message(ArgumentError, "Wrong # of arguments(%d for %d)")
def_exception("ErrDimensionMismatch", "\#{self.name} dimension mismatch")
def_exception("ErrNotRegular", "Not Regular Matrix")
def_exception("ErrOperationNotDefined", "This operation(%s) can\\'t defined")
end
class Matrix
@RCS_ID='-$Id: matrix.rb,v 1.11 1999/10/06 11:01:53 keiju Exp keiju $-'
# extend Exception2MessageMapper
include ExceptionForMatrix
# instance creations
private_class_method :new
def Matrix.[](*rows)
new(:init_rows, rows, false)
end
def Matrix.rows(rows, copy = true)
new(:init_rows, rows, copy)
end
def Matrix.columns(columns)
rows = (0 .. columns[0].size - 1).collect {
|i|
(0 .. columns.size - 1).collect {
|j|
columns[j][i]
}
}
Matrix.rows(rows, false)
end
def Matrix.diagonal(*values)
size = values.size
rows = (0 .. size - 1).collect {
|j|
row = Array.new(size).fill(0, 0, size)
row[j] = values[j]
row
}
rows(rows, false)
end
def Matrix.scalar(n, value)
Matrix.diagonal(*Array.new(n).fill(value, 0, n))
end
def Matrix.identity(n)
Matrix.scalar(n, 1)
end
class << Matrix
alias unit identity
alias I identity
end
def Matrix.zero(n)
Matrix.scalar(n, 0)
end
def Matrix.row_vector(row)
case row
when Vector
Matrix.rows([row.to_a], false)
when Array
Matrix.rows([row.dup], false)
else
Matrix.row([[row]], false)
end
end
def Matrix.column_vector(column)
case column
when Vector
Matrix.columns([column.to_a])
when Array
Matrix.columns([column])
else
Matrix.columns([[column]])
end
end
# initializing
def initialize(init_method, *argv)
self.send(init_method, *argv)
end
def init_rows(rows, copy)
if copy
@rows = rows.collect{|row| row.dup}
else
@rows = rows
end
self
end
private :init_rows
#accessing
def [](i, j)
@rows[i][j]
end
def row_size
@rows.size
end
def column_size
@rows[0].size
end
def row(i)
if block_given?
for e in @rows[i]
yield e
end
else
Vector.elements(@rows[i])
end
end
def column(j)
if block_given?
0.upto(row_size - 1) do
|i|
yield @rows[i][j]
end
else
col = (0 .. row_size - 1).collect {
|i|
@rows[i][j]
}
Vector.elements(col, false)
end
end
def collect
rows = @rows.collect{|row| row.collect{|e| yield e}}
Matrix.rows(rows, false)
end
alias map collect
#
# param: (from_row, row_size, from_col, size_col)
# (from_row..to_row, from_col..to_col)
#
def minor(*param)
case param.size
when 2
from_row = param[0].first
size_row = param[0].size
from_col = param[1].first
size_col = param[1].size
when 4
from_row = param[0]
size_row = param[1]
from_col = param[2]
size_col = param[3]
else
Matrix.Raise ArgumentError, param.inspect
end
rows = @rows[from_row, size_row].collect{
|row|
row[from_col, size_col]
}
Matrix.rows(rows, false)
end
# TESTING
def regular?
square? and rank == column_size
end
def singular?
not regular?
end
def square?
column_size == row_size
end
# COMPARING
def ==(other)
return false unless Matrix === other
other.compare_by_row_vectors(@rows)
end
alias eql? ==
def compare_by_row_vectors(rows)
return false unless @rows.size == rows.size
0.upto(@rows.size - 1) do
|i|
return false unless @rows[i] == rows[i]
end
true
end
def clone
Matrix.rows(@rows)
end
def hash
value = 0
for row in @rows
for e in row
value ^= e.hash
end
end
return value
end
# ARITHMETIC
def *(m) # m is matrix or vector or number
case(m)
when Numeric
rows = @rows.collect {
|row|
row.collect {
|e|
e * m
}
}
return Matrix.rows(rows, false)
when Vector
m = Matrix.column_vector(m)
r = self * m
return r.column(0)
when Matrix
Matrix.Raise ErrDimensionMismatch if column_size != m.row_size
rows = (0 .. row_size - 1).collect {
|i|
(0 .. m.column_size - 1).collect {
|j|
vij = 0
0.upto(column_size - 1) do
|k|
vij += self[i, k] * m[k, j]
end
vij
}
}
return Matrix.rows(rows, false)
else
x, y = m.coerce(self)
return x * y
end
end
def +(m)
case m
when Numeric
Matrix.Raise ErrOperationNotDefined, "+"
when Vector
m = Matrix.column_vector(m)
when Matrix
else
x, y = m.coerce(self)
return x + y
end
Matrix.Raise ErrDimensionMismatch unless row_size == m.row_size and column_size == m.column_size
rows = (0 .. row_size - 1).collect {
|i|
(0 .. column_size - 1).collect {
|j|
self[i, j] + m[i, j]
}
}
Matrix.rows(rows, false)
end
def -(m)
case m
when Numeric
Matrix.Raise ErrOperationNotDefined, "-"
when Vector
m = Matrix.column_vector(m)
when Matrix
else
x, y = m.coerce(self)
return x - y
end
Matrix.Raise ErrDimensionMismatch unless row_size == m.row_size and column_size == m.column_size
rows = (0 .. row_size - 1).collect {
|i|
(0 .. column_size - 1).collect {
|j|
self[i, j] - m[i, j]
}
}
Matrix.rows(rows, false)
end
def /(other)
case other
when Numeric
rows = @rows.collect {
|row|
row.collect {
|e|
e / other
}
}
return Matrix.rows(rows, false)
when Matrix
return self * other.inverse
else
x, y = other.coerce(self)
rerurn x / y
end
end
def inverse
Matrix.Raise ErrDimensionMismatch unless square?
Matrix.I(row_size).inverse_from(self)
end
alias inv inverse
def inverse_from(src)
size = row_size - 1
a = src.to_a
for k in 0..size
if (akk = a[k][k]) == 0
i = k
begin
Matrix.Raise ErrNotRegular if (i += 1) > size
end while a[i][k] == 0
a[i], a[k] = a[k], a[i]
@rows[i], @rows[k] = @rows[k], @rows[i]
akk = a[k][k]
end
for i in 0 .. size
next if i == k
q = a[i][k] / akk
a[i][k] = 0
(k + 1).upto(size) do
|j|
a[i][j] -= a[k][j] * q
end
0.upto(size) do
|j|
@rows[i][j] -= @rows[k][j] * q
end
end
(k + 1).upto(size) do
|j|
a[k][j] /= akk
end
0.upto(size) do
|j|
@rows[k][j] /= akk
end
end
self
end
#alias reciprocal inverse
def ** (other)
if other.kind_of?(Integer)
x = self
if other <= 0
x = self.inverse
return Matrix.identity(self.column_size) if other == 0
other = -other
end
z = x
n = other - 1
while n != 0
while (div, mod = n.divmod(2)
mod == 0)
x = x * x
n = div
end
z *= x
n -= 1
end
z
elsif other.kind_of?(Float) || defined?(Rational) && other.kind_of?(Rational)
Matrix.Raise ErrOperationNotDefined, "**"
else
Matrix.Raise ErrOperationNotDefined, "**"
end
end
# Matrix functions
def determinant
return 0 unless square?
size = row_size - 1
a = to_a
det = 1
k = 0
begin
if (akk = a[k][k]) == 0
i = k
begin
return 0 if (i += 1) > size
end while a[i][k] == 0
a[i], a[k] = a[k], a[i]
akk = a[k][k]
det *= -1
end
(k + 1).upto(size) do
|i|
q = a[i][k] / akk
(k + 1).upto(size) do
|j|
a[i][j] -= a[k][j] * q
end
end
det *= akk
end while (k += 1) <= size
det
end
alias det determinant
def rank
if column_size > row_size
a = transpose.to_a
a_column_size = row_size
a_row_size = column_size
else
a = to_a
a_column_size = column_size
a_row_size = row_size
end
rank = 0
k = 0
begin
if (akk = a[k][k]) == 0
i = k
exists = true
begin
if (i += 1) > a_column_size - 1
exists = false
break
end
end while a[i][k] == 0
if exists
a[i], a[k] = a[k], a[i]
akk = a[k][k]
else
i = k
exists = true
begin
if (i += 1) > a_row_size - 1
exists = false
break
end
end while a[k][i] == 0
if exists
k.upto(a_column_size - 1) do
|j|
a[j][k], a[j][i] = a[j][i], a[j][k]
end
akk = a[k][k]
else
next
end
end
end
(k + 1).upto(a_row_size - 1) do
|i|
q = a[i][k] / akk
(k + 1).upto(a_column_size - 1) do
|j|
a[i][j] -= a[k][j] * q
end
end
rank += 1
end while (k += 1) <= a_column_size - 1
return rank
end
def trace
tr = 0
0.upto(column_size - 1) do
|i|
tr += @rows[i][i]
end
tr
end
alias tr trace
def transpose
Matrix.columns(@rows)
end
alias t transpose
# CONVERTING
def coerce(other)
case other
when Numeric
return Scalar.new(other), self
else
raise TypeError, "#{type} can't be coerced into #{other.type}"
end
end
def row_vectors
rows = (0 .. row_size - 1).collect {
|i|
row(i)
}
rows
end
def column_vectors
columns = (0 .. column_size - 1).collect {
|i|
column(i)
}
columns
end
def to_a
@rows.collect{|row| row.collect{|e| e}}
end
def to_f
collect{|e| e.to_f}
end
def to_i
collect{|e| e.to_i}
end
def to_r
collect{|e| e.to_r}
end
# PRINTING
def to_s
"Matrix[" + @rows.collect{
|row|
"[" + row.collect{|e| e.to_s}.join(", ") + "]"
}.join(", ")+"]"
end
def inspect
"Matrix"+@rows.inspect
end
# Private CLASS
class Scalar < Numeric
include ExceptionForMatrix
def initialize(value)
@value = value
end
# ARITHMETIC
def +(other)
case other
when Numeric
Scalar.new(@value + other)
when Vector, Matrix
Scalar.Raise WrongArgType, other.type, "Numeric or Scalar"
when Scalar
Scalar.new(@value + other.value)
else
x, y = other.coerce(self)
x + y
end
end
def -(other)
case other
when Numeric
Scalar.new(@value - other)
when Vector, Matrix
Scalar.Raise WrongArgType, other.type, "Numeric or Scalar"
when Scalar
Scalar.new(@value - other.value)
else
x, y = other.coerce(self)
x - y
end
end
def *(other)
case other
when Numeric
Scalar.new(@value * other)
when Vector, Matrix
other.collect{|e| @value * e}
else
x, y = other.coerce(self)
x * y
end
end
def / (other)
case other
when Numeric
Scalar.new(@value / other)
when Vector
Scalar.Raise WrongArgType, other.type, "Numeric or Scalar or Matrix"
when Matrix
self * _M.inverse
else
x, y = other.coerce(self)
x / y
end
end
def ** (other)
case other
when Numeric
Scalar.new(@value ** other)
when Vector
Scalar.Raise WrongArgType, other.type, "Numeric or Scalar or Matrix"
when Matrix
other.powered_by(self)
else
x, y = other.coerce(self)
x ** y
end
end
end
end
#----------------------------------------------------------------------
#
# -
#
#----------------------------------------------------------------------
class Vector
include ExceptionForMatrix
#INSTANCE CREATION
private_class_method :new
def Vector.[](*array)
new(:init_elements, array, copy = false)
end
def Vector.elements(array, copy = true)
new(:init_elements, array, copy)
end
def initialize(method, array, copy)
self.send(method, array, copy)
end
def init_elements(array, copy)
if copy
@elements = array.dup
else
@elements = array
end
end
# ACCSESSING
def [](i)
@elements[i]
end
def size
@elements.size
end
# ENUMRATIONS
def each2(v)
Vector.Raise ErrDimensionMismatch if size != v.size
0.upto(size - 1) do
|i|
yield @elements[i], v[i]
end
end
def collect2(v)
Vector.Raise ErrDimensionMismatch if size != v.size
(0 .. size - 1).collect do
|i|
yield @elements[i], v[i]
end
end
# COMPARING
def ==(other)
return false unless Vector === other
other.compare_by(@elements)
end
alias eqn? ==
def compare_by(elements)
@elements == elements
end
def clone
Vector.elements(@elements)
end
def hash
@elements.hash
end
# ARITHMETIC
def *(x) #x is matrix or number
case x
when Numeric
els = @elements.collect{|e| e * x}
Vector.elements(els, false)
when Matrix
self.covector * x
else
s, x = X.coerce(self)
s * x
end
end
def +(v)
case v
when Vector
Vector.Raise ErrDimensionMismatch if size != v.size
els = collect2(v) {
|v1, v2|
v1 + v2
}
Vector.elements(els, false)
when Matrix
Matrix.column_vector(self) + v
else
s, x = v.coerce(self)
s + x
end
end
def -(v)
case v
when Vector
Vector.Raise ErrDimensionMismatch if size != v.size
els = collect2(v) {
|v1, v2|
v1 - v2
}
Vector.elements(els, false)
when Matrix
Matrix.column_vector(self) - v
else
s, x = v.coerce(self)
s - x
end
end
# VECTOR FUNCTIONS
def inner_product(v)
Vector.Raise ErrDimensionMismatch if size != v.size
p = 0
each2(v) {
|v1, v2|
p += v1 * v2
}
p
end
def collect
els = @elements.collect {
|v|
yield v
}
Vector.elements(els, false)
end
alias map collect
def map2(v)
els = collect2(v) {
|v1, v2|
yield v1, v2
}
Vector.elements(els, false)
end
def r
v = 0
for e in @elements
v += e*e
end
return Math.sqrt(v)
end
# CONVERTING
def covector
Matrix.row_vector(self)
end
def to_a
@elements.dup
end
def to_f
collect{|e| e.to_f}
end
def to_i
collect{|e| e.to_i}
end
def to_r
collect{|e| e.to_r}
end
def coerce(other)
case other
when Numeric
return Scalar.new(other), self
else
raise TypeError, "#{type} can't be coerced into #{other.type}"
end
end
# PRINTING
def to_s
"Vector[" + @elements.join(", ") + "]"
end
def inspect
str = "Vector"+@elements.inspect
end
end