#### Matrix Factorizations --- of all kinds
library(Matrix)
source(system.file("test-tools.R", package = "Matrix"))# identical3() etc
doExtras
(is64bit <- .Machine$sizeof.pointer == 8)
### "sparseQR" : Check consistency of methods
## --------
data(KNex); mm <- KNex$mm; y <- KNex$y
stopifnot(is((Y <- Matrix(y)), "dgeMatrix"))
md <- as(mm, "matrix") # dense
(cS <- system.time(Sq <- qr(mm)))
(cD <- system.time(Dq <- qr(md))) # 1.1 sec. (lynne, 2011); 0.535 sec. (lynne, 2014)
cD[1] / cS[1] # dense is much ( ~ 100--170 times) slower
## MM__FIXME__: move these functions to ../inst/test-tools.R
chkQR <- function(a,
y = seq_len(nrow(a)),## RHS: made to contain no 0
a.qr = qr(a), tol = 1e-11, # 1e-13 failing very rarely (interesting)
##----------
Qinv.chk = !sp.rank.def, QtQ.chk = !sp.rank.def,
verbose = getOption("Matrix.verbose", FALSE), giveRE = verbose,
quiet = FALSE)
{
d <- dim(a)
stopifnot((n <- d[1]) >= (p <- d[2]), is.numeric(y))
kind <- if(is.qr(a.qr)) "qr" else
if(is(a.qr, "sparseQR")) "spQR" else stop("unknown qr() class: ", class(a.qr))
if(!missing(verbose) && verbose) {
op <- options(Matrix.verbose = verbose)
on.exit(options(op))
}
## rank.def <- switch(kind,
## "qr" = a.qr$rank < length(a.qr$pivot),
## "spQR" = a.qr@V@Dim[1] > a.qr@Dim[1])
sp.rank.def <- (kind == "spQR") && (a.qr@V@Dim[1] > a.qr@Dim[1])
if(sp.rank.def && !quiet && (missing(Qinv.chk) || missing(QtQ.chk)))
message("is sparse *structurally* rank deficient: Qinv.chk=",
Qinv.chk,", QtQ.chk=",QtQ.chk)
if(is.na(QtQ.chk )) QtQ.chk <- !sp.rank.def
if(is.na(Qinv.chk)) Qinv.chk <- !sp.rank.def
if(Qinv.chk) { ## qr.qy and qr.qty should be inverses, Q'Q y = y = QQ' y :
## FIXME: Fails for structurally rank deficient sparse a's, but never for classical
assert.EQ(drop(qr.qy (a.qr, qr.qty(a.qr, y))), y, giveRE=giveRE, tol = tol/64)
assert.EQ(drop(qr.qty(a.qr, qr.qy (a.qr, y))), y, giveRE=giveRE, tol = tol/64)
}
piv <- switch(kind,
"qr" = a.qr$pivot,
"spQR" = 1L + a.qr@q)# 'q', not 'p' !!
invP <- sort.list(piv)
.ckQR <- function(cmpl) { ## local function, using parent's variables
if(verbose) cat("complete = ",cmpl,":\n", sep="")
Q <- qr.Q(a.qr, complete=cmpl)
R <- qr.R(a.qr, complete=cmpl)
rr <- if(cmpl) n else p
stopifnot(dim(Q) == c(n,rr),
dim(R) == c(rr,p))
assert.EQ.Mat(a, Q %*% R[, invP], giveRE=giveRE, tol=tol)
## = ===============
if(QtQ.chk)
assert.EQ.mat(crossprod(Q), diag(rr), giveRE=giveRE, tol=tol)
## =========== ====
}
.ckQR(FALSE)
.ckQR(TRUE)
invisible(a.qr)
}## end{chkQR}
##' Check QR-consistency of dense and sparse
chk.qr.D.S <- function(d., s., y, Y = Matrix(y), force = FALSE, tol = 1e-10) {
stopifnot(is.qr(d.), is(s., "sparseQR"))
cc <- qr.coef(d.,y)
rank.def <- any(is.na(cc)) && d.$rank < length(d.$pivot)
if(rank.def && force) cc <- mkNA.0(cc) ## set NA's to 0 .. ok, in some case
## when system is rank deficient, have differing cases, not always just NA <-> 0 coef
## FIXME though: resid & fitted should be well determined
if(force || !rank.def) stopifnot(
### FIXME: temporary:
### is.all.equal3( cc , drop(qr.coef (s.,y)), drop(qr.coef (s.,Y)), tol=tol),
is.all.equal3( unname( cc ) , drop(qr.coef (s.,y)), drop(qr.coef (s.,Y)), tol=tol),
### END{FIXME}
is.all.equal3(qr.resid (d.,y), drop(qr.resid (s.,y)), drop(qr.resid (s.,Y)), tol=tol),
is.all.equal3(qr.fitted(d.,y), drop(qr.fitted(s.,y)), drop(qr.fitted(s.,Y)), tol=tol)
)
}
##' "Combi" calling chkQR() on both "(sparse)Matrix" and 'traditional' version
##' ------ and combine the two qr decomp.s using chk.qr.D.S()
##'
##' @title check QR-decomposition, and compare sparse and dense one
##' @param A a 'Matrix' , typically 'sparseMatrix'
##' @param Qinv.chk
##' @param QtQ.chk
##' @param quiet
##' @return list with 'qA' (sparse QR) and 'qa' (traditional (dense) QR)
##' @author Martin Maechler
checkQR.DS.both <- function(A, Qinv.chk, QtQ.chk=NA,
quiet=FALSE, giveRE=TRUE, tol = 1e-13)
{
stopifnot(is(A,"Matrix"))
if(!quiet) cat("classical: ")
qa <- chkQR(as.matrix(A), Qinv.chk=TRUE, QtQ.chk=TRUE, tol=tol, giveRE=giveRE)# works always
if(!quiet) cat("[Ok] --- sparse: ")
qA <- chkQR(A, Qinv.chk=Qinv.chk, QtQ.chk=QtQ.chk, tol=tol, giveRE=giveRE)
validObject(qA)
if(!quiet) cat("[Ok]\n")
chk.qr.D.S(qa, qA, y = 10 + 1:nrow(A), tol = 256*tol)# ok [not done in rank deficient case!]
invisible(list(qA=qA, qa=qa))
}
if(doExtras) system.time({ ## ~ 20 sec {"large" example} + 2x qr.R() warnings
cat("chkQR( <KNex> ) .. takes time .. ")
chkQR(mm, y=y, a.qr = Sq, verbose=TRUE)
chkQR(md, y=y, a.qr = Dq, verbose=TRUE)
cat(" done: [Ok]\n")
})
## consistency of results dense and sparse
chk.qr.D.S(Dq, Sq, y, Y)
## rank deficient QR cases: ---------------
## From Simon (15 Jul 2009) + dimnames (11 May 2015)
set.seed(10)
a <- matrix(round(10 * runif(90)), 10,9, dimnames =
list(LETTERS[1:10], paste0("c", 1:9)))
a[a < 7.5] <- 0
(A <- Matrix(a))# first column = all zeros
qD <- chkQR(a, giveRE=TRUE) ## using base qr
qS <- chkQR(A, giveRE=TRUE) ## using Matrix "sparse qr" -- "structurally rank deficient!
validObject(qS)# with the validity now (2012-11-18) -- ok, also for "bad" case
chk.qr.D.S(qD, qS, y = 10 + 1:nrow(A), force=TRUE)# 6 warnings: "structurally rank deficient"
try( ## NOTE: *Both* checks currently fail here:
chkQR(A, Qinv.chk=TRUE, QtQ.chk=TRUE)
)
## Larger Scale random testing
oo <- options(Matrix.quiet.qr.R = TRUE, Matrix.verbose = TRUE)
set.seed(101)
for(N in 1:(if(doExtras) 1008 else 24)) {
A <- rsparsematrix(8,5, nnz = rpois(1, lambda=16))
cat(sprintf("%4d -", N))
checkQR.DS.both(A, Qinv.chk= NA, QtQ.chk=NA,
## --- => FALSE if struct. rank deficient
giveRE = FALSE, tol = if(is64bit) 2e-13 else 1e-12)
}
unique(warnings())
## Look at single "hard" cases: --------------------------------------
## This is *REALLY* nice and small :
A0 <- new("dgCMatrix", Dim = 4:3, i = c(0:3, 3L), p = c(0L, 3:5), x = rep(1,5))
A0
checkQR.DS.both(A0, Qinv.chk = FALSE, QtQ.chk=FALSE)
## ----- *both* still needed :
try( checkQR.DS.both(A0, TRUE, FALSE) )
try( checkQR.DS.both(A0, FALSE, TRUE) )
## and the same when dropping the first row { --> 3 x 3 }:
A1 <- A0[-1 ,]
checkQR.DS.both(A1, Qinv.chk = FALSE, QtQ.chk=FALSE)
## ----- *both* still needed :
try( checkQR.DS.both(A1, TRUE, FALSE) )
try( checkQR.DS.both(A1, FALSE, TRUE) )
qa <- qr(as.matrix(A0))
qA <- qr(A0)
drop0(crossprod( Qd <- qr.Q(qa) ), 1e-15) # perfect = diag( 3 )
drop0(crossprod( Qs <- qr.Q(qA) ), 1e-15) # R[3,3] == 0 -- OOPS!
## OTOH, qr.R() is fine, as checked in the checkQR.DS.both(A0, *) above
## zero-row *and* zero-column :
(A2 <- new("dgCMatrix", i = c(0L, 1L, 4L, 7L, 5L, 2L, 4L)
, p = c(0L, 3L, 4L, 4L, 5L, 7L)
, Dim = c(8L, 5L)
, x = c(0.92, 1.06, -1.74, 0.74, 0.19, -0.63, 0.68)))
checkQR.DS.both(A2, Qinv.chk = FALSE, QtQ.chk=FALSE)
## ----- *both* still needed :
try( checkQR.DS.both(A2, TRUE, FALSE) )
try( checkQR.DS.both(A2, FALSE, TRUE) )
## Case of *NO* zero-row or zero-column:
(A3 <- new("dgCMatrix", Dim = 6:5
, i = c(0L, 2L, 4L, 0L, 1L, 5L, 1L, 3L, 0L)
, p = c(0L, 1L, 3L, 6L, 8L, 9L)
, x = c(40, -54, -157, -28, 75, 166, 134, 3, -152)))
checkQR.DS.both(A3, Qinv.chk = FALSE, QtQ.chk=FALSE)
## ----- *both* still needed :
try( checkQR.DS.both(A3, TRUE, FALSE) )
try( checkQR.DS.both(A3, FALSE, TRUE) )
(A4 <- new("dgCMatrix", Dim = c(7L, 5L)
, i = c(1:2, 4L, 6L, 1L, 5L, 0:3, 0L, 2:4)
, p = c(0L, 4L, 6L, 10L, 10L, 14L)
, x = c(9, -8, 1, -9, 1, 10, -1, -2, 6, 14, 10, 2, 12, -9)))
checkQR.DS.both(A4, Qinv.chk = FALSE, QtQ.chk=FALSE)
## ----- *both* still needed :
try( checkQR.DS.both(A4, TRUE, FALSE) )
try( checkQR.DS.both(A4, FALSE, TRUE) )
(A5 <- new("dgCMatrix", Dim = c(4L, 4L)
, i = c(2L, 2L, 0:1, 0L, 2:3), p = c(0:2, 4L, 7L)
, x = c(48, 242, 88, 18, -167, -179, 18)))
checkQR.DS.both(A5, Qinv.chk = FALSE, QtQ.chk=FALSE)
## ----- *both* still needed :
try( checkQR.DS.both(A5, TRUE, FALSE) )
try( checkQR.DS.both(A5, FALSE, TRUE) )
for(N in 1:(if(doExtras) 2^12 else 128)) {
A <- round(100*rsparsematrix(5,3, nnz = min(15,rpois(1, lambda=10))))
if(any(apply(A, 2, function(x) all(x == 0)))) ## "column of all 0"
next
cat(sprintf("%4d -", N))
checkQR.DS.both(A, Qinv.chk=NA, giveRE=FALSE, tol = 1e-12)
## --- => FALSE if struct. rank deficient
}
unique(warnings())
options(oo)
### "denseLU"
## Testing expansions of factorizations {was ./expand.R, then in simple.R }
## new: [m x n] where m and n may differ
x. <- c(2^(0:5),9:1,-3:8, round(sqrt(0:16)))
set.seed(1)
for(nnn in 1:100) {
y <- sample(x., replace=TRUE)
m <- sample(2:6, 1)
n <- sample(2:7, 1)
x <- suppressWarnings(matrix(y, m,n))
lux <- lu(x)# occasionally a warning about exact singularity
xx <- with(expand(lux), (P %*% L %*% U))
print(dim(xx))
assert.EQ.mat(xx, x, tol = 16*.Machine$double.eps)
}
### "sparseLU"
por1 <- readMM(system.file("external/pores_1.mtx", package = "Matrix"))
lu1 <- lu(por1)
pm <- as(por1, "CsparseMatrix")
(pmLU <- lu(pm)) # -> show(<MatrixFactorization>)
xp <- expand(pmLU)
## permute rows and columns of original matrix
ppm <- pm[pmLU@p + 1:1, pmLU@q + 1:1]
Ppm <- pmLU@L %*% pmLU@U
## identical only as long as we don't keep the original class info:
stopifnot(identical3(lu1, pmLU, pm@factors$LU),# TODO === por1@factors$LU
identical(ppm, with(xp, P %*% pm %*% t(Q))),
sapply(xp, is, class="Matrix"))
Ipm <- solve(pm, sparse=FALSE)
Spm <- solve(pm, sparse=TRUE) # is not sparse at all, here
assert.EQ.Mat(Ipm, Spm, giveRE=TRUE, tol = 1e-13)# seen 7.36e-15 only on 32-bit
stopifnot(abs(as.vector(solve(Diagonal(30, x=10) %*% pm) / Ipm) - 1/10) < 1e-7,
abs(as.vector(solve(rep.int(4, 30) * pm) / Ipm) - 1/ 4) < 1e-7)
## these two should be the same, and `are' in some ways:
assert.EQ.mat(ppm, as(Ppm, "matrix"), tol = 1e-14, giveRE=TRUE)
## *however*
length(ppm@x)# 180
length(Ppm@x)# 317 !
table(Ppm@x == 0)# (194, 123) - has 123 "zero" and 14 ``almost zero" entries
##-- determinant() and det() --- working via LU ---
m <- matrix(c(0, NA, 0, NA, NA, 0, 0, 0, 1), 3,3)
m0 <- rbind(0,cbind(0,m))
M <- as(m,"Matrix"); M ## "dsCMatrix" ...
M0 <- rBind(0, cBind(0, M))
dM <- as(M, "denseMatrix")
dM0 <- as(M0,"denseMatrix")
try( lum <- lu(M) )# Err: "near-singular A"
(lum <- lu(M, errSing=FALSE))# NA --- *BUT* it is not stored in @factors
(lum0 <- lu(M0, errSing=FALSE))# NA --- and it is stored in M0@factors[["LU"]]
## "FIXME" - TODO: Consider
replNA <- function(x, value) { x[is.na(x)] <- value ; x }
(EL.1 <- expand(lu.1 <- lu(M.1 <- replNA(M, -10))))
## so it's quite clear how lu() of the *singular* matrix M should work
## but it's not supported by the C code in ../src/cs.c which errors out
stopifnot(all.equal(M.1, with(EL.1, P %*% L %*% U %*% Q)),
is.na(det(M)), is.na(det(dM)),
is.na(det(M0)), is.na(det(dM0)) )
###________ Cholesky() ________
##-------- LDL' ---- small exact examples
set.seed(1)
for(n in c(5:12)) {
cat("\nn = ",n,"\n-------\n")
rr <- mkLDL(n)
## -------- from 'test-tools.R'
stopifnot(all(with(rr, A ==
as(L %*% D %*% t(L), "symmetricMatrix"))),
all(with(rr, A == tcrossprod(L %*% sqrt(D)))))
d <- rr$d.half
A <- rr$A
R <- chol(A)
assert.EQ.Mat(R, chol(as(A, "TsparseMatrix"))) # gave infinite recursion
print(d. <- diag(R))
D. <- Diagonal(x= d.^2)
L. <- t(R) %*% Diagonal(x = 1/d.)
stopifnot(all.equal(as.matrix(D.), as.matrix(rr$ D)),
all.equal(as.matrix(L.), as.matrix(rr$ L)))
##
CAp <- Cholesky(A)# perm=TRUE --> Permutation:
p <- CAp@perm + 1L
P <- as(p, "pMatrix")
## the inverse permutation:
invP <- solve(P)@perm
lDet <- sum(2* log(d))# the "true" value
ldetp <- Matrix:::.diag.dsC(Chx = CAp, res.kind = "sumLog")
ldetp. <- sum(log(Matrix:::.diag.dsC(Chx = CAp, res.kind = "diag") ))
##
CA <- Cholesky(A,perm=FALSE)
ldet <- Matrix:::.diag.dsC(Chx = CA, res.kind = "sumLog")
## not printing CAp : ends up non-integer for n >= 11
mCAp <- as(CAp,"sparseMatrix")
print(mCA <- drop0(as(CA, "sparseMatrix")))
stopifnot(identical(A[p,p], as(P %*% A %*% t(P),
"symmetricMatrix")),
relErr(d.^2, Matrix:::.diag.dsC(Chx= CA, res.kind="diag")) < 1e-14,
relErr(A[p,p], tcrossprod(mCAp)) < 1e-14)
if(FALSE)
rbind(lDet,ldet, ldetp, ldetp.)
## ==> Empirically, I see lDet = ldet != ldetp == ldetp.
## if(rr$rcond.A < ...) warning("condition number of A ..." ## <- TODO
cat(1,""); assert.EQ.(lDet, ldet, tol = 1e-14)
cat(2,""); assert.EQ.(ldetp, ldetp., tol = 1e-14)
cat(3,""); assert.EQ.(lDet, ldetp, tol = n^2* 1e-7)# extreme: have seen 0.0011045 !!
}## for()
mkCholhash <- function(r.all) {
## r.all %*% (2^(2:0)), but only those that do not have NA / "?" :
stopifnot(is.character(rn <- rownames(r.all)),
is.matrix(r.all), is.logical(r.all))
c.rn <- vapply(rn, function(ch) strsplit(ch, " ")[[1]], character(3))
## Now
h1 <- function(i) {
ok <- c.rn[,i] != "?"
r.all[i, ok] %*% 2^((2:0)[ok])
}
vapply(seq_len(nrow(r.all)), h1, numeric(1))
}
set.seed(17)
(rr <- mkLDL(4))
(CA <- Cholesky(rr$A))
stopifnot(all.equal(determinant(rr$A) -> detA,
determinant(as(rr$A, "matrix"))),
is.all.equal3(c(detA$modulus), log(det(rr$D)), sum(log(rr$D@x))))
A12 <- mkLDL(12, 1/10)
(r12 <- allCholesky(A12$A))[-1]
aCh.hash <- mkCholhash(r12$r.all)
if(FALSE)## if(require("sfsmisc"))
split(rownames(r12$r.all), Duplicated(aCh.hash))
## TODO: find cases for both choices when we leave it to CHOLMOD to choose
for(n in 1:50) { ## used to seg.fault at n = 10 !
mkA <- mkLDL(1+rpois(1, 30), 1/10)
cat(sprintf("n = %3d, LDL-dim = %d x %d ", n, nrow(mkA$A), ncol(mkA$A)))
r <- allCholesky(mkA$A, silentTry=TRUE)
## Compare .. apart from the NAs that happen from (perm=FALSE, super=TRUE)
iNA <- apply(is.na(r$r.all), 1, any)
cat(sprintf(" -> %3s NAs\n", if(any(iNA)) format(sum(iNA)) else "no"))
stopifnot(aCh.hash[!iNA] == mkCholhash(r$r.all[!iNA,]))
## cat("--------\n")
}
## This is a relatively small "critical example" :
A. <-
new("dsCMatrix", Dim = c(25L, 25L), uplo = "U"
, i = as.integer(
c(0, 1, 2, 3, 4, 2, 5, 6, 0, 8, 8, 9, 3, 4, 10, 11, 6, 12, 13, 4,
10, 14, 15, 1, 2, 5, 16, 17, 0, 7, 8, 18, 9, 19, 10, 11, 16, 20,
0, 6, 7, 16, 17, 18, 20, 21, 6, 9, 12, 14, 19, 21, 22, 9, 11, 19,
20, 22, 23, 1, 16, 24))
##
, p = c(0:6, 8:10, 12L, 15:16, 18:19, 22:23, 27:28, 32L, 34L, 38L, 46L, 53L, 59L, 62L)
##
, x = c(1, 1, 1, 1, 2, 100, 2, 40, 1, 2, 100, 6700, 100, 100, 13200,
1, 50, 4100, 1, 5, 400, 20, 1, 40, 100, 5600, 9100, 5000, 5,
100, 100, 5900, 100, 6200, 30, 20, 9, 2800, 1, 100, 8, 10, 8000,
100, 600, 23900, 30, 100, 2800, 50, 5000, 3100, 15100, 100, 10,
5600, 800, 4500, 5500, 7, 600, 18200))
validObject(A.)
## A1: the same pattern as A. just simply filled with '1's :
A1 <- A.; A1@x[] <- 1; A1@factors <- list()
A1.8 <- A1; diag(A1.8) <- 8
##
nT. <- as(AT <- as(A., "TsparseMatrix"),"nMatrix")
stopifnot(all(nT.@i <= nT.@j),
identical(qr(A1.8), qr(as(A1.8, "dgCMatrix"))))
CA <- Cholesky(A.)
stopifnotValid(CAinv <- solve(CA), "dsCMatrix")
MA <- as(CA, "Matrix") # with a confusing warning -- FIXME!
stopifnotValid(MAinv <- solve(MA), "dtCMatrix")
## comparing MAinv with some solve(CA, system="...") .. *not* trivial? - TODO
##
CAinv2 <- solve(CA, Diagonal(nrow(A.)))
CAinv2 <- as(CAinv2, "symmetricMatrix")
stopifnot(identical(CAinv, CAinv2))
## FINALLY fix "TODO": (not implemented *symbolic* factorization of nMatrix)
try( tc <- Cholesky(nT.) )
for(p in c(FALSE,TRUE))
for(L in c(FALSE,TRUE))
for(s in c(FALSE,TRUE, NA)) {
cat(sprintf("p,L,S = (%2d,%2d,%2d): ", p,L,s))
r <- tryCatch(Cholesky(A., perm=p, LDL=L, super=s),
error = function(e)e)
cat(if(inherits(r, "error")) " *** E ***" else
sprintf("%3d", r@type),"\n", sep="")
}
str(A., max=3) ## look at the 'factors'
facs <- A.@factors
names(facs) <- sub("Cholesky$", "", names(facs))
facs <- facs[order(names(facs))]
sapply(facs, class)
str(lapply(facs, slot, "type"))
## super = TRUE currently always entails LDL=FALSE :
## hence isLDL is TRUE for ("D" and not "S"):
sapply(facs, isLDL)
chkCholesky <- function(chmf, A) {
stopifnot(is(chmf, "CHMfactor"),
is(A, "Matrix"), isSymmetric(A))
if(!is(A, "dsCMatrix"))
A <- as(A, "dsCMatrix")
L <- drop0(zapsmall(L. <- as(chmf, "Matrix")))
cat("no. nonzeros in L {before / after drop0(zapsmall(.))}: ",
c(nnzero(L.), nnzero(L)), "\n") ## 112, 95
ecc <- expand(chmf)
A... <- with(ecc, crossprod(crossprod(L,P)))
stopifnot(all.equal(L., ecc$L, tolerance = 1e-14),
all.equal(A, A..., tolerance = 1e-14, factorsCheck = FALSE))
invisible(ecc)
}
c1.8 <- try(Cholesky(A1.8, super = TRUE))# works "always", interestingly ...
chkCholesky(c1.8, A1.8)
## --- now a "large" (712 x 712) real data example ---------------------------
data(KNex)
mtm <- with(KNex, crossprod(mm))
ld.3 <- .Call("dsCMatrix_LDL_D", mtm, perm=TRUE, "sumLog")
stopifnot(names(mtm@factors) == "sPDCholesky")
ld.4 <- .Call("dsCMatrix_LDL_D", mtm, perm=FALSE, "sumLog")# clearly slower
stopifnot(names(mtm@factors) == paste(c("sPD", "spD"),"Cholesky", sep=''))
c2 <- Cholesky(mtm, super = TRUE)
stopifnot(names(mtm@factors) == paste(c("sPD", "spD", "SPd"),
"Cholesky", sep=''))
r <- allCholesky(mtm)
r[-1]
## is now taken from cache
c1 <- Cholesky(mtm)
bv <- 1:nrow(mtm) # even integer
b <- matrix(bv)
## solve(c2, b) by default solves Ax = b, where A = c2'c2 !
x <- solve(c2,b)
stopifnot(identical3(x, solve(c2, bv), solve(c2, b, system = "A")),
all.equal(x, solve(mtm, b)))
for(sys in c("A", "LDLt", "LD", "DLt", "L", "Lt", "D", "P", "Pt")) {
x <- solve(c2, b, system = sys)
cat(sys,":\n"); print(head(x))
stopifnot(dim(x) == c(712, 1),
identical(x, solve(c2, bv, system = sys)))
}
## log(|LL'|) - check if super = TRUE and simplicial give same determinant
ld1 <- .Call("CHMfactor_ldetL2", c1)
ld2 <- .Call("CHMfactor_ldetL2", c2)
(ld1. <- determinant(mtm))
## experimental
ld3 <- .Call("dsCMatrix_LDL_D", mtm, TRUE, "sumLog")
ld4 <- .Call("dsCMatrix_LDL_D", mtm, FALSE, "sumLog")
stopifnot(all.equal(ld1, ld2),
is.all.equal3(ld2, ld3, ld4),
all.equal(ld.3, ld3, tolerance = 1e-14),
all.equal(ld.4, ld4, tolerance = 1e-14),
all.equal(ld1, as.vector(ld1.$modulus), tolerance = 1e-14))
## Some timing measurements
mtm <- with(KNex, crossprod(mm))
I <- .symDiagonal(n=nrow(mtm))
set.seed(101); r <- runif(100)
system.time(D1 <- sapply(r, function(rho) Matrix:::ldet1.dsC(mtm + (1/rho) * I)))
## 0.842 on fast cmath-5
system.time(D2 <- sapply(r, function(rho) Matrix:::ldet2.dsC(mtm + (1/rho) * I)))
## 0.819
system.time(D3 <- sapply(r, function(rho) Matrix:::ldet3.dsC(mtm + (1/rho) * I)))
## 0.810
stopifnot(is.all.equal3(D1,D2,D3, tol = 1e-13))
## Updating LL' should remain LL' and not become LDL' :
cholCheck <- function(Ut, tol = 1e-12, super = FALSE, LDL = !super) {
L <- Cholesky(UtU <- tcrossprod(Ut), super=super, LDL=LDL, Imult = 1)
L1 <- update(L, UtU, mult = 1)
L2 <- update(L, Ut, mult = 1)
stopifnot(is.all.equal3(L, L1, L2, tol = tol),
all.equal(update(L, UtU, mult = pi),
update(L, Ut, mult = pi), tolerance = tol)
)
}
## Inspired by
## data(Dyestuff, package = "lme4")
## Zt <- as(Dyestuff$Batch, "sparseMatrix")
Zt <- new("dgCMatrix", Dim = c(6L, 30L), x = 2*1:30,
i = rep(0:5, each=5),
p = 0:30, Dimnames = list(LETTERS[1:6], NULL))
cholCheck(0.78 * Zt, tol=1e-14)
for(i in 1:120) {
set.seed(i); cat(sprintf("%3d: ", i))
M <- rspMat(n=rpois(1,50), m=rpois(1,20), density = 1/(4*rpois(1, 4)))
for(super in c(FALSE,TRUE)) {
cat("super=",super," M: ")
cholCheck( M , super=super); cat(" M': ")
cholCheck(t(M), super=super)
}
cat(" [Ok]\n")
}
.updateCHMfactor
## TODO: (--> ../TODO "Cholesky"):
## ----
## allow Cholesky(A,..) when A is not symmetric *AND*
## we really want to factorize AA' ( + beta * I)
## Schur() ----------------------
checkSchur <- function(A, SchurA = Schur(A), tol = 1e-14) {
stopifnot(is(SchurA, "Schur"),
isOrthogonal(Q <- SchurA@Q),
all.equal(as.mat(A),
as.mat(Q %*% SchurA@T %*% t(Q)), tolerance = tol))
}
SH <- Schur(H5 <- Hilbert(5))
checkSchur(H5, SH)
checkSchur(Diagonal(x = 9:3))
p <- 4L
uTp <- new("dtpMatrix", x=c(2, 3, -1, 4:6, -2:1), Dim = c(p,p))
(uT <- as(uTp, "dtrMatrix"))
## Schur ( <general> ) <--> Schur( <triangular> )
Su <- Schur(uT) ; checkSchur(uT, Su)
gT <- as(uT,"generalMatrix")
Sg <- Schur(gT) ; checkSchur(gT, Sg)
Stg <- Schur(t(gT));checkSchur(t(gT), Stg)
Stu <- Schur(t(uT));checkSchur(t(uT), Stu)
stopifnot(identical3(Sg@T, uT, Su@T),
identical(Sg@Q, as(diag(p), "dgeMatrix")),
identical(Stg@T, as(t(gT[,p:1])[,p:1], "triangularMatrix")),
identical(Stg@Q, as(diag(p)[,p:1], "dgeMatrix")),
identical(Stu@T, Stg@T))
assert.EQ.mat(Stu@Q, as(Stg@Q,"matrix"), tol=0)
## the pedigreemm example where solve(.) failed:
p <- new("dtCMatrix", i = c(2L, 3L, 2L, 5L, 4L, 4:5), p = c(0L, 2L, 4:7, 7L),
Dim = c(6L, 6L), Dimnames = list(as.character(1:6), NULL),
x = rep.int(-0.5, 7), uplo = "L", diag = "U")
Sp <- Schur(p)
Sp. <- Schur(as(p,"generalMatrix"))
Sp.p <- Schur(crossprod(p))
## the last two failed
ip <- solve(p)
assert.EQ.mat(solve(ip), as(p,"matrix"))
## chol2inv() for a traditional matrix
assert.EQ.mat( crossprod(chol2inv(chol(Diagonal(x = 5:1)))),
C <- crossprod(chol2inv(chol( diag(x = 5:1)))))
stopifnot(all.equal(C, diag((5:1)^-2)))
## failed in some versions because of a "wrong" implicit generic
## From [Bug 14834] New: chol2inv *** caught segfault ***
n <- 1e6 # was 595362
A <- chol( D <- Diagonal(n) )
stopifnot(identical(A,D)) # A remains (unit)diagonal
is(tA <- as(A,"triangularMatrix"))# currently a dtTMatrix
stopifnotValid(tA, "dsparseMatrix")
CA <- as(tA, "CsparseMatrix")
selectMethod(solve, c("dtCMatrix","missing"))
##--> .Call(dtCMatrix_sparse_solve, a, .trDiagonal(n)) in ../src/dtCMatrix.c
sA <- solve(CA)## -- R_CheckStack() segfault in Matrix <= 1.0-4
nca <- diagU2N(CA)
stopifnot(identical(sA, nca))
## same check with non-unit-diagonal D :
A <- chol(D <- Diagonal(n, x = 0.5))
ia <- chol2inv(A)
stopifnot(is(ia, "diagonalMatrix"),
all.equal(ia@x, rep(2,n), tolerance = 1e-15))
cat('Time elapsed: ', proc.time(),'\n') # for ``statistical reasons''
if(!interactive()) warnings()
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