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R/fit.model.R
In rama: Robust Analysis of MicroArrays
Defines functions
fit.model
Documented in
fit.model
fit.model<-function(sample1,sample2,B=1000,min.iter=0,batch=10,shift=NULL,mcmc.obj=NULL,
dye.swap=FALSE, nb.col1=NULL, all.out=FALSE, ci=0.95,verbose=FALSE)
{
### Only take the finite observations
indf1<-is.row.na(sample1)
indf2<-is.row.na(sample2)
sample1<-as.matrix(sample1[indf1 & indf2,])
sample2<-as.matrix(sample2[indf1 & indf2,])
n<-dim(sample1)
vec1<-as.double(t(sample1))
vec1[is.finite(vec1)==FALSE]<- -9999999
vec2<-as.double(t(sample2))
vec2[is.finite(vec2)==FALSE]<- -9999999
df.choice<-c(1:10,seq(20,100,10))
w.out<-rep(0,n[1]*n[2])
a.gamma<-1
b.gamma<-0.005
if(dye.swap==TRUE)
{
if(length(nb.col1)==0)
stop("No value has been set for nb.col1" , call. = TRUE)
else if(nb.col1>=(n[2]-1) | nb.col1<=1)
stop("nb.col1 should be at least 2 and at most n-2" , call. = TRUE)
}
else ## just set a value for the code to run
nb.col1<-n[2]/2
if(length(shift)==0) ## No shift has been specified
{
## Estimate the shift
m1<-max(0,-min(vec1)+0.01)
m2<-max(0,-min(vec2)+0.01)
shift<-max(m1,m2)
mcmc.obj.shift<-est.shift(sample1,sample2,B=2000,min.iter=1000,batch=10,mcmc.obj=NULL,dye.swap=dye.swap,nb.col1=nb.col1,verbose=verbose)
shift<-mean(mcmc.obj.shift$shift)
}
if(length(mcmc.obj)>0)
{
if(class(mcmc.obj)!="mcmc")
stop("'mcmc.obj' should be of type 'mcmc'" , call. = TRUE)
n.iter<-length(mcmc.obj$mu)
print(n.iter)
lambda.eps1<-mcmc.obj$lambda.eps1[,n.iter]
lambda.eps2<-mcmc.obj$lambda.eps2[,n.iter]
lambda.gamma1<-mcmc.obj$lambda.gamma1[n.iter]
lambda.gamma2<-mcmc.obj$lambda.gamma2[n.iter]
a.eps<-mcmc.obj$a.eps[n.iter]
b.eps<-mcmc.obj$b.eps[n.iter]
rho<-mcmc.obj$rho[n.iter]
df.in<-mcmc.obj$df[,n.iter]
w.in<-matrix(mcmc.obj$w)
w.in<-as.double(t(w.in))
mu<-mcmc.obj$mu[n.iter]
alpha2<-mcmc.obj$alpha[n.iter]
gamma1<-mcmc.obj$gamma1[,n.iter]
gamma2<-mcmc.obj$gamma2[,n.iter]
beta2<-mcmc.obj$beta[n.iter]
delta22<-mcmc.obj$delta22[n.iter]
eta<-mcmc.obj$eta[,n.iter]
}
else
{
obj<-ls.effect(log2(sample1+shift),log2(sample2+shift),dye.swap=TRUE,nb.col1=nb.col1)
mu<-obj$mu
alpha2<-obj$alpha2
gamma1<-obj$gamma1
gamma2<-obj$gamma2
if(dye.swap==TRUE)
{
beta2<-obj$beta2
delta22<-obj$delta22
}
else
{
beta2<-0
delta22<-0
}
eta<-obj$eta
if(n[2]>1)
{
lambda.eps1<-1/mat.mean(obj$R1^2)[,1]
lambda.eps2<-1/mat.mean(obj$R2^2)[,1]
}
else
{
lambda.eps1<-rep(1,n[1])
lambda.eps2<-rep(1,n[1])
}
lambda.gamma1<-0.5
lambda.gamma2<-0.5
a.eps<-median(lambda.eps1)
b.eps<-mad(lambda.eps1)
df.in<-rep(10,n[2])
w.in<-rep(1,n[1]*n[2])
rho<-.8
}
### Main code linked to a c function
if(all.out==TRUE)
length<-(B-min.iter)/batch
else
length<-1
obj<-.C("ex_R_link_mcmc",
log2(vec1+shift),
log2(vec2+shift),
as.integer(n[1]),
as.integer(n[2]),
as.integer(nb.col1),
as.integer(B),
as.integer(dye.swap),
as.double(gamma1),
gamma1=double(length*n[1]),
as.double(gamma2),
gamma2=double(length*n[1]),
as.double(mu),
mu=double(length),
as.double(beta2),
beta2=double(length),
as.double(alpha2),
alpha2=double(length),
as.double(delta22),
delta22=double(length),
as.double(eta),
eta=double(n[2]*length),
as.double(lambda.eps1),
lambda.eps1=double(length*n[1]),
as.double(lambda.eps2),
lambda.eps2=double(length*n[1]),
as.double(a.eps),
as.double(b.eps),
a.eps=double(length),
b.eps=double(length),
as.double(w.in),
as.double(df.choice),
as.integer(length(df.choice)),
as.double(df.in),
df=double(n[2]*length),
w=as.double(w.out),
as.double(rho),
rho=double(length),
as.double(lambda.gamma1),
as.double(lambda.gamma2),
lambda.gamma1=double(length),
lambda.gamma2=double(length),
as.integer(min.iter),
as.integer(batch),
as.integer(all.out), as.integer(verbose),
PACKAGE="rama")
gamma1<-t(matrix(obj$gamma1,length,n[1],byrow=TRUE))
gamma2<-t(matrix(obj$gamma2,length,n[1],byrow=TRUE))
if(all.out==TRUE)
{
q.low<-rep(0,n[1])
q.up<-rep(0,n[1])
for(i in 1:(n[1]))
{
q.low[i]<-quantile(gamma1[i,]-gamma2[i,],probs=(1.-ci)/2)
q.up[i]<-quantile(gamma1[i,]-gamma2[i,],probs=1.-(1.-ci)/2)
}
}
else
{
q.low<-NULL
q.up<-NULL
}
### Create a new object
new.mcmc<-list(gamma1=gamma1,
gamma2=gamma2,
q.low=q.low,q.up=q.up,
mu=obj$mu, beta2=obj$beta2, alpha2=obj$alpha2,delta22=obj$delta22,
lambda.eps1=t(matrix(obj$lambda.eps1,length,n[1],byrow=TRUE)),
lambda.eps2=t(matrix(obj$lambda.eps2,length,n[1],byrow=TRUE)),
lambda.gamma1=obj$lambda.gamma1,lambda.gamma2=obj$lambda.gamma2,rho=obj$rho,
w=matrix(obj$w,n[1],n[2]),
df=t(matrix(obj$df,length,n[2],byrow=TRUE)),
eta=t(matrix(obj$eta,length,n[2],byrow=TRUE)),
a.eps=obj$a.eps,b.eps=obj$b.eps,shift=shift)
### Give it the right class
class(new.mcmc)<-"mcmc"
return(new.mcmc)
}
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rama documentation built on Nov. 8, 2020, 8:02 p.m.
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Defines functions fit.model
Documented in fit.model
fit.model<-function(sample1,sample2,B=1000,min.iter=0,batch=10,shift=NULL,mcmc.obj=NULL,
dye.swap=FALSE, nb.col1=NULL, all.out=FALSE, ci=0.95,verbose=FALSE)
{
### Only take the finite observations
indf1<-is.row.na(sample1)
indf2<-is.row.na(sample2)
sample1<-as.matrix(sample1[indf1 & indf2,])
sample2<-as.matrix(sample2[indf1 & indf2,])
n<-dim(sample1)
vec1<-as.double(t(sample1))
vec1[is.finite(vec1)==FALSE]<- -9999999
vec2<-as.double(t(sample2))
vec2[is.finite(vec2)==FALSE]<- -9999999
df.choice<-c(1:10,seq(20,100,10))
w.out<-rep(0,n[1]*n[2])
a.gamma<-1
b.gamma<-0.005
if(dye.swap==TRUE)
{
if(length(nb.col1)==0)
stop("No value has been set for nb.col1" , call. = TRUE)
else if(nb.col1>=(n[2]-1) | nb.col1<=1)
stop("nb.col1 should be at least 2 and at most n-2" , call. = TRUE)
}
else ## just set a value for the code to run
nb.col1<-n[2]/2
if(length(shift)==0) ## No shift has been specified
{
## Estimate the shift
m1<-max(0,-min(vec1)+0.01)
m2<-max(0,-min(vec2)+0.01)
shift<-max(m1,m2)
mcmc.obj.shift<-est.shift(sample1,sample2,B=2000,min.iter=1000,batch=10,mcmc.obj=NULL,dye.swap=dye.swap,nb.col1=nb.col1,verbose=verbose)
shift<-mean(mcmc.obj.shift$shift)
}
if(length(mcmc.obj)>0)
{
if(class(mcmc.obj)!="mcmc")
stop("'mcmc.obj' should be of type 'mcmc'" , call. = TRUE)
n.iter<-length(mcmc.obj$mu)
print(n.iter)
lambda.eps1<-mcmc.obj$lambda.eps1[,n.iter]
lambda.eps2<-mcmc.obj$lambda.eps2[,n.iter]
lambda.gamma1<-mcmc.obj$lambda.gamma1[n.iter]
lambda.gamma2<-mcmc.obj$lambda.gamma2[n.iter]
a.eps<-mcmc.obj$a.eps[n.iter]
b.eps<-mcmc.obj$b.eps[n.iter]
rho<-mcmc.obj$rho[n.iter]
df.in<-mcmc.obj$df[,n.iter]
w.in<-matrix(mcmc.obj$w)
w.in<-as.double(t(w.in))
mu<-mcmc.obj$mu[n.iter]
alpha2<-mcmc.obj$alpha[n.iter]
gamma1<-mcmc.obj$gamma1[,n.iter]
gamma2<-mcmc.obj$gamma2[,n.iter]
beta2<-mcmc.obj$beta[n.iter]
delta22<-mcmc.obj$delta22[n.iter]
eta<-mcmc.obj$eta[,n.iter]
}
else
{
obj<-ls.effect(log2(sample1+shift),log2(sample2+shift),dye.swap=TRUE,nb.col1=nb.col1)
mu<-obj$mu
alpha2<-obj$alpha2
gamma1<-obj$gamma1
gamma2<-obj$gamma2
if(dye.swap==TRUE)
{
beta2<-obj$beta2
delta22<-obj$delta22
}
else
{
beta2<-0
delta22<-0
}
eta<-obj$eta
if(n[2]>1)
{
lambda.eps1<-1/mat.mean(obj$R1^2)[,1]
lambda.eps2<-1/mat.mean(obj$R2^2)[,1]
}
else
{
lambda.eps1<-rep(1,n[1])
lambda.eps2<-rep(1,n[1])
}
lambda.gamma1<-0.5
lambda.gamma2<-0.5
a.eps<-median(lambda.eps1)
b.eps<-mad(lambda.eps1)
df.in<-rep(10,n[2])
w.in<-rep(1,n[1]*n[2])
rho<-.8
}
### Main code linked to a c function
if(all.out==TRUE)
length<-(B-min.iter)/batch
else
length<-1
obj<-.C("ex_R_link_mcmc",
log2(vec1+shift),
log2(vec2+shift),
as.integer(n[1]),
as.integer(n[2]),
as.integer(nb.col1),
as.integer(B),
as.integer(dye.swap),
as.double(gamma1),
gamma1=double(length*n[1]),
as.double(gamma2),
gamma2=double(length*n[1]),
as.double(mu),
mu=double(length),
as.double(beta2),
beta2=double(length),
as.double(alpha2),
alpha2=double(length),
as.double(delta22),
delta22=double(length),
as.double(eta),
eta=double(n[2]*length),
as.double(lambda.eps1),
lambda.eps1=double(length*n[1]),
as.double(lambda.eps2),
lambda.eps2=double(length*n[1]),
as.double(a.eps),
as.double(b.eps),
a.eps=double(length),
b.eps=double(length),
as.double(w.in),
as.double(df.choice),
as.integer(length(df.choice)),
as.double(df.in),
df=double(n[2]*length),
w=as.double(w.out),
as.double(rho),
rho=double(length),
as.double(lambda.gamma1),
as.double(lambda.gamma2),
lambda.gamma1=double(length),
lambda.gamma2=double(length),
as.integer(min.iter),
as.integer(batch),
as.integer(all.out), as.integer(verbose),
PACKAGE="rama")
gamma1<-t(matrix(obj$gamma1,length,n[1],byrow=TRUE))
gamma2<-t(matrix(obj$gamma2,length,n[1],byrow=TRUE))
if(all.out==TRUE)
{
q.low<-rep(0,n[1])
q.up<-rep(0,n[1])
for(i in 1:(n[1]))
{
q.low[i]<-quantile(gamma1[i,]-gamma2[i,],probs=(1.-ci)/2)
q.up[i]<-quantile(gamma1[i,]-gamma2[i,],probs=1.-(1.-ci)/2)
}
}
else
{
q.low<-NULL
q.up<-NULL
}
### Create a new object
new.mcmc<-list(gamma1=gamma1,
gamma2=gamma2,
q.low=q.low,q.up=q.up,
mu=obj$mu, beta2=obj$beta2, alpha2=obj$alpha2,delta22=obj$delta22,
lambda.eps1=t(matrix(obj$lambda.eps1,length,n[1],byrow=TRUE)),
lambda.eps2=t(matrix(obj$lambda.eps2,length,n[1],byrow=TRUE)),
lambda.gamma1=obj$lambda.gamma1,lambda.gamma2=obj$lambda.gamma2,rho=obj$rho,
w=matrix(obj$w,n[1],n[2]),
df=t(matrix(obj$df,length,n[2],byrow=TRUE)),
eta=t(matrix(obj$eta,length,n[2],byrow=TRUE)),
a.eps=obj$a.eps,b.eps=obj$b.eps,shift=shift)
### Give it the right class
class(new.mcmc)<-"mcmc"
return(new.mcmc)
}
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