require 'rspec'
$: << File::join(File::dirname(__FILE__), '..', 'build_SWIG')
require 'SylphideMath.so'
require 'matrix'
shared_examples 'Matrix' do
let(:params){{
:rc => [8, 8],
:acceptable_delta => 1E-10,
}}
describe "initializer" do
let(:compare_with){
params[:rc][0].times.map{params[:rc][1].times.map{gen_elm.call}}
}
it 'accepts (i,j)' do
expect{ mat_type::new(*params[:rc]) }.not_to raise_error
expect( mat_type::new(*params[:rc]).rows ).to equal(params[:rc][0])
expect( mat_type::new(*params[:rc]).columns ).to equal(params[:rc][1])
end
it 'declines negative number argument' do
[[-1, 1], [1, -1]].each{|sf|
r, c = params[:rc].zip(sf).collect{|v1, v2| v1 * v2}
expect{ mat_type::new(r, c) }.to raise_error(ArgumentError)
}
end
it 'accepts ([[]])' do
expect{ mat_type::new(compare_with) }.not_to raise_error
expect( mat_type::new(compare_with).rows ).to equal(params[:rc][0])
expect( mat_type::new(compare_with).columns ).to equal(params[:rc][1])
end
it 'accepts (Matrix)' do
expect{ mat_type::new(Matrix::build(*params[:rc]){0}) }.not_to raise_error
expect( mat_type::new(Matrix::build(*params[:rc]){0}).rows ).to equal(params[:rc][0])
expect( mat_type::new(Matrix::build(*params[:rc]){0}).columns ).to equal(params[:rc][1])
end
it 'accepts (custom class)' do
r, c = params[:rc]
a_gen = proc{Class.new{
define_method(:row_size){r}
define_method(:column_size){c}
define_method(:[]){|i, j| i + j}
}::new}
a = a_gen.call
expect{ mat_type::new(a) }.not_to raise_error
expect( mat_type::new(a).rows ).to equal(params[:rc][0])
expect( mat_type::new(a).columns ).to equal(params[:rc][1])
a.define_singleton_method(:[]){|i, j| raise(IndexError) if i != j; 0}
expect{ mat_type::new(a) }.to raise_error(IndexError)
[:row_size, :column_size].each{|f|
a = a_gen.call
a.define_singleton_method(f){-1}
expect{ mat_type::new(a) }.to raise_error(RuntimeError)
}
end
it 'is invoked with I, identity, unit' do
[:I, :identity, :unit].each{|f|
expect{ mat_type::send(f, params[:rc][0]) }.not_to raise_error
expect( mat_type::send(f, params[:rc][0]).rows ).to equal(params[:rc][0])
expect( mat_type::send(f, params[:rc][0]).columns ).to equal(params[:rc][1])
}
end
it 'is invoked with scalar' do
expect{ mat_type::scalar(params[:rc][0], 1) }.not_to raise_error
expect( mat_type::scalar(params[:rc][0], 1).rows ).to equal(params[:rc][0])
expect( mat_type::scalar(params[:rc][0], 1).columns ).to equal(params[:rc][1])
end
it 'sets its elements with [], [[]], Matrix' do
expect( mat_type::new(params[:rc][0], params[:rc][1], compare_with.flatten).to_a ).to eq(compare_with)
expect{ mat_type::new(params[:rc][0], params[:rc][1], compare_with.flatten[0..-2]) }.to raise_error(RuntimeError)
expect( mat_type::new(params[:rc][0], params[:rc][1], compare_with.flatten + [gen_elm.call]).to_a ).to eq(compare_with)
expect{ mat_type::new(params[:rc][0], params[:rc][1], compare_with.flatten[0..-2] + [nil]) }.to raise_error(RuntimeError)
expect( mat_type::new(params[:rc][0], params[:rc][1], compare_with).to_a ).to eq(compare_with)
expect{ mat_type::new(params[:rc][0], params[:rc][1], compare_with[0..-2]) }.to raise_error(RuntimeError)
expect( mat_type::new(params[:rc][0], params[:rc][1], compare_with + [params[:rc][1].times.map{gen_elm.call}]).to_a ).to eq(compare_with)
expect( mat_type::new(compare_with).to_a ).to eq(compare_with)
expect( mat_type::new(Matrix[*compare_with]).to_a ).to eq(compare_with)
end
it 'sets its elements with {}' do
expect( mat_type::new(*params[:rc]){|i, j| compare_with[i][j]}.to_a ).to eq(compare_with)
expect{ mat_type::new(*params[:rc]){nil}.to_a }.to raise_error(RuntimeError)
expect{ mat_type::new(compare_with){|i, j| compare_with[i][j]} }.to raise_error(ArgumentError)
expect{ mat_type::new(Matrix[*compare_with]){|i, j| compare_with[i][j]} }.to raise_error(ArgumentError)
expect{ mat_type::new(*params[:rc]){raise(IndexError) } }.to raise_error(IndexError)
end
end
describe 'property' do
let(:mat){{
:square => proc{
k = 0
mat_type::new(params[:rc][0], params[:rc][0]){|i, j| k += 1}
}.call,
:not_square => proc{
k = 0
mat_type::new(params[:rc][0], params[:rc][0] * 2){|i, j| k += 1}
}.call,
:diagonal => mat_type::new(params[:rc][0], params[:rc][0]){|i, j| i == j ? 1 : 0},
:symmetric => mat_type::new(params[:rc][0], params[:rc][0]){|i, j| i + j},
}}
describe 'is checked with' do
it 'square?' do
expect(mat[:square].square?) .to eq(true)
expect(mat[:not_square].square?).to eq(false)
expect(mat[:diagonal].square?) .to eq(true)
expect(mat[:symmetric].square?) .to eq(true)
end
it 'diagonal?' do
expect(mat[:square].diagonal?) .to eq(false)
expect(mat[:not_square].diagonal?) .to eq(false)
expect(mat[:diagonal].diagonal?) .to eq(true)
expect(mat[:symmetric].diagonal?) .to eq(false)
end
it 'symmetric?' do
expect(mat[:square].symmetric?) .to eq(false)
expect(mat[:not_square].symmetric?) .to eq(false)
expect(mat[:diagonal].symmetric?) .to eq(true)
expect(mat[:symmetric].symmetric?) .to eq(true)
end
it 'different_size?' do
mat.keys.combination(2).each{|mat1, mat2|
expect(mat[mat1].different_size?(mat[mat2])).to eq([mat1, mat2].include?(:not_square))
}
end
end
describe 'is calculated with' do
it 'trace, tr' do
[:trace, :tr].each{|f|
expect(mat[:square].send(f)).to eq(Matrix[*mat[:square].to_a].trace)
expect{mat[:not_square].send(f)}.to raise_error(RuntimeError)
}
end
it 'sum' do
expect(mat[:square].sum).to eq(Matrix[*mat[:square].to_a].sum)
expect(mat[:not_square].sum).to eq(Matrix[*mat[:not_square].to_a].sum)
end
it 'determinant, det' do
[:determinant, :det].each{|f|
#expect(mat[:square].send(f)).to eq(Matrix[*mat[:square].to_a].det)
expect{mat[:not_square].send(f)}.to raise_error(RuntimeError)
}
end
end
end
describe 'element' do
let(:compare_with){
2.times.collect{params[:rc][0].times.map{params[:rc][1].times.map{gen_elm.call}}}
}
let(:mat){
compare_with.collect{|item| mat_type::new(item)}
}
it 'is accessible with []' do
params[:rc][0].times{|i|
params[:rc][1].times{|j|
expect(mat[0][i, j]).to eq(compare_with[0][i][j])
}
}
end
it 'is changeable with []=' do
params[:rc][0].times{|i|
params[:rc][1].times{|j|
mat[0][i, j] = compare_with[1][i][j]
expect(mat[0][i, j]).to eq(compare_with[1][i][j])
}
}
end
it 'is inaccessible and unchangeable with negative number arguments' do
[[-1, 0], [0, -1]].each{|i, j|
[[:[], i, j], [:[]=, i, j, 0]].each{|args|
expect{ mat[0].send(*args) }.to raise_error{|err|
expect(err).to be_a(RangeError).or be_a(ArgumentError)
}
}
}
end
end
describe 'elements' do
let(:compare_with){
2.times.collect{params[:rc][0].times.map{params[:rc][1].times.map{gen_elm.call}}}
}
let(:mat){
compare_with.collect{|item| mat_type::new(item)}
}
it 'is cloneable with copy' do
mat_orig, mat_clone = [mat[0], mat[0].copy]
expect(mat_clone).not_to equal(mat_orig)
expect(mat_clone.to_a).to eq(mat_orig.to_a)
mat_clone[0, 0] *= 2
expect(mat_clone.to_a).not_to eq(mat_orig.to_a)
end
it 'is replaceable by using replace! with [], [[]], Matrix or {}' do
[
compare_with[1].flatten, # []
compare_with[1], # [[]]
mat[1], # Matrix
Matrix[*compare_with[1]], # Matrix(builtin)
proc{|i, j| mat[1][i, j]}, # {}
].each{|arg|
mat_orig = mat[0].copy
mat_replaced = arg.kind_of?(Proc) ? mat_orig.send(:replace!, &arg) : mat_orig.send(:replace!, arg)
expect(mat_replaced).to equal(mat_orig)
expect(mat_replaced).not_to equal(mat[1])
expect(mat_replaced.to_a).to eq(mat[1].to_a)
}
end
it 'is swappable with swap_rows! or swap_cloumns!' do
mat_builtin = Matrix[*compare_with[0]]
[:swap_rows!, :swap_columns!].each.with_index{|func, i|
params[:rc][i].times.to_a.combination(2).to_a{|a, b|
mat[0].send(func, a, b)
mat_builtin.send(func, a, b)
expect(mat[0].to_a).to eq(mat_builtin.to_a)
}
}
end
it 'is checked in their equality by using ==' do
expect(mat[0] == mat[0]).to be(true)
expect(mat[0] == mat[0].copy).to be(true)
expect(mat[0].to_a == compare_with[0]).to be(true)
expect{mat[0] == compare_with[0]}.to raise_error(ArgumentError)
expect(mat[0].to_a == Matrix[*compare_with[0]].to_a).to be(true)
expect{mat[0] == Matrix[*compare_with[0]]}.to raise_error(ArgumentError)
end
end
describe 'view' do
let(:compare_with){params[:rc][0].times.map{params[:rc][1].times.map{gen_elm.call}}}
let(:mat){mat_type::new(compare_with)}
it 'supports transposed with transpose, t' do
expect(mat.transpose.to_a).to eq(Matrix[*compare_with].transpose.to_a)
expect(mat.t.to_a).to eq(Matrix[*compare_with].t.to_a)
end
it 'supports conjugated with conjugate' do
expect(mat.conjugate.to_a).to eq(Matrix[*compare_with].conjugate.to_a) if mat.respond_to?(:conjugate)
expect(mat.conjugate.to_a).to eq(Matrix[*compare_with].conj.to_a)
end
it 'supports adjointed with adjoint' do
expect(mat.adjoint.to_a).to eq(Matrix[*compare_with].conjugate.transpose.to_a) if mat.respond_to?(:adjoint)
expect(mat.adjoint.to_a).to eq(Matrix[*compare_with].conj.t.to_a)
end
it 'supports submatrix with partial' do
expect(mat.partial(params[:rc][0] - 1, params[:rc][1] - 1, 1, 1).to_a) \
.to eq(Matrix[*compare_with[1..-1].collect{|values| values[1..-1]}].to_a)
end
it 'supports row_vector with row_vector' do
params[:rc][0].times{|i|
expect(mat.row_vector(i).to_a[0]) \
.to eq(Matrix[*compare_with].row_vectors[i].to_a)
}
end
it 'supports column_vector with column_vector' do
params[:rc][1].times{|j|
expect(mat.column_vector(j).to_a.flatten) \
.to eq(Matrix[*compare_with].column_vectors[j].to_a)
}
end
it 'generates circular matrix with circular' do
params[:rc][0].times{|i|
params[:rc][1].times{|j|
expect(mat.circular(*([i, j] + params[:rc])).to_a) \
.to eq(Matrix[*compare_with.collect{|v| v.rotate(j)}.rotate(i)].to_a)
}
}
end
end
describe 'iterator' do
let(:compare_with){params[:rc][0].times.map{params[:rc][1].times.map{gen_elm.call}}}
let(:mat){mat_type::new(compare_with)}
let(:opt){{
nil => params[:rc][0].times.to_a.product(params[:rc][1].times.to_a),
:all => params[:rc][0].times.to_a.product(params[:rc][1].times.to_a),
:diagonal => params[:rc].min.times.collect{|i| [i, i]},
:off_diagonal => params[:rc][0].times.to_a.product(params[:rc][1].times.to_a).reject{|i, j| i == j},
:lower => params[:rc][0].times.to_a.product(params[:rc][1].times.to_a).select{|i, j| i >= j},
:upper => params[:rc][0].times.to_a.product(params[:rc][1].times.to_a).select{|i, j| i <= j},
:strict_lower => params[:rc][0].times.to_a.product(params[:rc][1].times.to_a).select{|i, j| i > j},
:strict_upper => params[:rc][0].times.to_a.product(params[:rc][1].times.to_a).select{|i, j| i < j},
}}
it 'supports each, each_with_index' do
[:each, :each_with_index].each{|func|
opt.each{|k, indices|
candidates = (func.to_s =~ /with_index$/) \
? indices.collect{|i, j| [compare_with[i][j], i, j]} \
: indices.collect{|i, j| [compare_with[i][j]]}
mat.send(*[func, k].compact){|*v|
i = candidates.find_index(v)
expect(i).not_to be(nil)
candidates.delete_at(i)
}
expect(candidates.empty?).to be(true)
}
}
end
it 'supports map, collect, map_with_index, collect_with_index' do
[:map, :collect, :map_with_index, :collect_with_index].each{|func|
opt.each{|k, indices|
candidates = (func.to_s =~ /with_index$/) \
? indices.collect{|i, j| [compare_with[i][j], i, j]} \
: indices.collect{|i, j| [compare_with[i][j]]}
mat2 = mat.send(*[func, k].compact){|*v|
i = candidates.find_index(v)
expect(i).not_to be(nil)
candidates.delete_at(i)
v[0] * 2
}
expect(candidates.empty?).to be(true)
expect(mat.to_a).to eq(compare_with)
expect(mat2.to_a).to eq(compare_with.collect.with_index{|values, i|
values.collect.with_index{|v, j|
indices.include?([i, j]) ? (v * 2) : v
}
})
}
}
end
it 'supports map!, collect!, map_with_index!, collect_with_index!' do
[:map!, :collect!].each{|func|
opt.each{|k, indices|
candidates = (func.to_s =~ /with_index$/) \
? indices.collect{|i, j| [compare_with[i][j], i, j]} \
: indices.collect{|i, j| [compare_with[i][j]]}
mat = mat_type::new(compare_with)
mat2 = mat.send(*[func, k].compact){|*v|
i = candidates.find_index(v)
expect(i).not_to be(nil)
candidates.delete_at(i)
v[0] * 2
}
expect(candidates.empty?).to be(true)
expect(mat2.to_a).to eq(mat.to_a)
expect(mat2.to_a).to eq(compare_with.collect.with_index{|values, i|
values.collect.with_index{|v, j|
indices.include?([i, j]) ? (v * 2) : v
}
})
}
}
end
end
describe 'operators' do
let(:compare_with){ # [N*N, N*N, N*(N+1), N*(N+1)]
2.times.collect{params[:rc][0].times.map{params[:rc][0].times.map{gen_elm.call}}} \
+ 2.times.collect{params[:rc][0].times.map{(params[:rc][0] + 1).times.map{gen_elm.call}}}
}
let(:mat){
compare_with.collect{|item| mat_type::new(item)}
}
it 'have unary -' do
[0, 2].each{|i|
expect((-mat[i]).to_a).to eq((Matrix[*compare_with[i]] * -1).to_a)
}
end
it 'have +(scalar)' do
expect((mat[0] + 1).to_a).to eq((Matrix[*compare_with[0]] + Matrix::unit(params[:rc][0])).to_a)
expect{mat[2] + 1}.to raise_error(RuntimeError)
end
it 'have +(mat)' do
[[0, 1], [2, 3]].each{|i, j|
expect((mat[i] + mat[j]).to_a).to eq((Matrix[*compare_with[i]] + Matrix[*compare_with[j]]).to_a)
}
end
it 'have -(scalar)' do
expect((mat[0] - 1).to_a).to eq((Matrix[*compare_with[0]] - Matrix::unit(params[:rc][0])).to_a)
expect{mat[2] - 1}.to raise_error(RuntimeError)
end
it 'have -(mat)' do
[[0, 1], [2, 3]].each{|i, j|
expect((mat[i] - mat[j]).to_a).to eq((Matrix[*compare_with[i]] - Matrix[*compare_with[j]]).to_a)
}
end
it 'have *(scalar)' do
[0, 2].each{|i|
expect((mat[i] * 2).to_a).to eq((Matrix[*compare_with[i]] * 2).to_a)
}
end
it 'have *(mat)' do
expect((mat[0] * mat[1]).to_a).to eq((Matrix[*compare_with[0]] * Matrix[*compare_with[1]]).to_a)
expect{mat[2] * mat[3]}.to raise_error(RuntimeError)
expect((mat[2] * mat[3].t).to_a).to eq((Matrix[*compare_with[2]] * Matrix[*compare_with[3]].t).to_a)
end
it 'have /(scalar)' do
expect((mat[0] / 2).to_a).to eq((Matrix[*compare_with[0]] / 2).to_a)
expect((mat[2] / 2).to_a).to eq((Matrix[*compare_with[2]] / 2).to_a)
end
let(:inversible){
# L * U
mat_type::new(compare_with[0]).map_with_index!{|v, i, j| (i >= j) ? (i == j ? 1 : v) : 0} \
* mat_type::new(compare_with[1]).map_with_index!{|v, i, j| (i <= j) ? (i == j ? 1 : v) : 0}
}
it 'have inverse, inv' do
[:inverse, :inv].each{|func|
(Matrix[*(inversible.send(func).to_a)] - Matrix[*(inversible.to_a)].send(func)).each{|v|
expect(v.abs).to be < params[:acceptable_delta]
}
expect{mat[2].send(func)}.to raise_error(RuntimeError)
}
end
it 'have /(mat)' do
(Matrix[*((mat[0] / mat[1]).to_a)] - (Matrix[*compare_with[0]] / Matrix[*compare_with[1]])).each{|v|
expect(v.abs).to be < params[:acceptable_delta]
}
expect{mat[2] / mat[3]}.to raise_error(RuntimeError)
end
it 'have resize!' do
[-1, :sym].each{|arg|
[[arg, nil], [nil, arg]].each{|args|
expect{mat[0].resize!(*args)}.to raise_error{|err|
expect(err).to be_a(TypeError).or be_a(ArgumentError)
}
}
}
mat_orig = mat[0].to_a
r, c = [:rows, :columns].collect{|f| mat[0].send(f)}
expect(mat[0].resize!(r, c).to_a).to eq(mat_orig)
expect(mat[0].resize!(r, nil).to_a).to eq(mat_orig)
expect(mat[0].resize!(nil, c).to_a).to eq(mat_orig)
expect(mat[0].resize!(nil, nil).to_a).to eq(mat_orig)
expect(mat[0].resize!(r * 2, c * 2).to_a).to \
eq(Matrix::build(r * 2, c * 2){|i, j| (i < r && j < c) ? mat_orig[i][j] : 0}.to_a)
end
end
describe 'decomposition' do
let(:compare_with){ params[:rc][0].times.map{params[:rc][0].times.map{gen_elm.call} } }
let(:mat){{
:L => mat_type::new(compare_with).map_with_index!{|v, i, j| (i >= j) ? (i == j ? 1 : v) : 0},
:U => mat_type::new(compare_with).map_with_index!{|v, i, j| (i <= j) ? (i == j ? 1 : v) : 0},
:D => mat_type::new(compare_with).map_with_index!{|v, i, j| (i == j) ? v : 0},
:Q => mat_type::new(params[:rc][0].times.map{(params[:rc][0] * 2).times.map{gen_elm.call}}).qr[0],
}}
it 'supports LU' do
src = mat_type::new(Matrix[*mat[:L].to_a] * Matrix[*mat[:U].to_a])
[:lup, :lup_decomposition].each{|func|
mat_l, mat_u, mat_p = src.send(func).collect{|item| Matrix[*item.to_a]}
expect(mat_l.lower_triangular?).to be(true)
expect(mat_u.upper_triangular?).to be(true)
((mat_l * mat_u * mat_p) - Matrix[*src.to_a]).each{|v|
expect(v.abs).to be < params[:acceptable_delta]
}
}
end
it 'supports QR' do
src = mat_type::new(Matrix[*mat[:L].to_a] * Matrix[*mat[:U].to_a])
[:qr, :qr_decomposition].each{|func|
[[0, 0], [2, 0], [0, 2]].each{|i, j|
src2 = src.partial(src.rows - i, src.columns - j, i, j)
mat_q, mat_r = src2.send(func).collect{|item| Matrix[*item.to_a]}
expect(mat_r.upper_triangular?).to be(true)
expect((mat_q.det - 1).abs).to be < params[:acceptable_delta]
((mat_q * mat_r) - Matrix[*src2.to_a]).each{|v|
expect(v.abs).to be < params[:acceptable_delta]
}
((mat_q * mat_q.t.conj) - Matrix::unit(mat_q.row_size)).each{|v|
expect(v.abs).to be < params[:acceptable_delta]
}
}
}
end
it 'supports eigenvalue' do
mat_q, mat_u = [:Q, :U].collect{|k| Matrix[*mat[k].map{|v| v}.to_a]}
expect((mat_q.det - 1).abs).to be < params[:acceptable_delta]
expect(mat_u.det).to eq(1)
src = mat_q * mat_u * Matrix[*mat[:D].to_a]
mat_v, mat_d = mat_type::new(src.to_a).eigen.collect{|item| Matrix[*item.to_a]}
expect(mat_d.diagonal?).to be(true)
mat_d.row_size.times{|i|
(src * mat_v.column_vectors[0] - mat_v.column_vectors[0] * mat_d[0, 0]).each{|v|
expect(v.abs).to be < params[:acceptable_delta]
}
}
end
end
end
=begin
TODO
:debug
:to_s
:to_a
=end
describe SylphideMath::MatrixD do
let(:mat_type){SylphideMath::MatrixD}
let(:gen_elm){proc{rand}}
include_examples 'Matrix'
describe 'decomposition' do
let(:compare_with){ params[:rc][0].times.map{params[:rc][0].times.map{gen_elm.call} } }
let(:mat){{
:U => mat_type::new(compare_with).map_with_index!{|v, i, j| (i <= j) ? (i == j ? 1 : v) : 0},
:D => mat_type::new(compare_with).map_with_index!{|v, i, j| (i == j) ? v : 0},
}}
it 'supports UD' do
src = mat_type::new((Matrix[*mat[:U].to_a] * Matrix[*mat[:D].to_a] * Matrix[*mat[:U].t.to_a]).to_a)
src.map_with_index!(:strict_upper){|v, i, j| src[j, i]}
expect(Matrix[*src.to_a].symmetric?).to be(true)
[:ud, :ud_decomposition].each{|func|
mat_u, mat_d = src.send(func).collect{|item| Matrix[*item.to_a]}
expect(mat_u.upper_triangular?).to be(true)
expect(mat_d.diagonal?).to be(true)
((mat_u * mat_d * mat_u.t) - Matrix[*src.to_a]).each{|v|
expect(v.abs).to be < params[:acceptable_delta]
}
}
end
end
end
describe SylphideMath::MatrixComplexD do
let(:mat_type){SylphideMath::MatrixComplexD}
let(:gen_elm){proc{Complex(rand, rand)}}
include_examples 'Matrix'
end