: $Id: vecst.mod,v 1.491 2010/07/21 15:00:19 billl Exp $
:* COMMENT
COMMENT
thresh turns analog vec to BVBASE,1 vec separating at thresh (scalar or vec)
triplet return location of a triplet in a vector
onoff turns state vec on or off depending on values in other vecs
bpeval used by backprop: vo=outp*(1-outp)*del
w like where but sets chosen nums // modified from .wh in 1.23
whi find indices where vec equal to given values
dest.xing(src,tvec,thresh) determines where vector crosses in a positive direction
dest.snap(src,tvec,dt) interpolate src with tvec to prior dt step, saves only highest value
xzero count 0 crossings by putting in a 1 or -1
negwrap wrap negative values around to pos (with flag just set to 0)
indset(ind,val) sets spots indexed by ind to val
ismono([arg]) checks if a vector is monotonically increaseing (-1 decreasing)
count(num) count the number of nums in vec
muladd(mul,add) mul*x+add
binfind(num) find index for num in a sorted vector
scr.fewind(ind,veclist) // uses ind as index into other vecs
ind.findx(vecAlist,vecBlist) // uses ind as index into vecA's to load in vecB's
ind.sindx(vecAlist,vecBlist) // replace ind elements in vecA's with vecB's values
ind.sindv(vecAlist,valvec) // replace ind elements in vecA's with vals
scr.nind(ind,vec1,vec2[,vec3,vec4]) // uses ind to elim elems in other vecs
yv.circ(xv,x0,y0,rad) // put coords of circle into xv and yv
ind.keyind(key,vec1,vec2[,vec3,vec4]) // pick out bzw. values from vectors
ind.slct(key,args,veclist) // pick out bzw. values from vectors
ind.slor(key,args,veclist) // do OR rather than AND function of slct
vdest.intrp(flag) // interpolate numbers replacing numbers given as flag
v.insct(v1,v2) // return v1 intersect v2
vdest.cull(vsrc,key) // remove values found in key
vdest.redundout(vsrc[,INDFLAG]) // remove repeat values, with flag return indices
ind.mredundout(veclistA[,INDFLAG,veclistB]) // remove repeats from parallel vectors
v.cvlv(v1,v2) // convolve v1 with v2
v2d copy into a double block
d2v copy out of a double block NB: same as vec.from_double()
smgs rewrite of sumgauss form ivovect.cpp
smsy sum syn potentials off a tvec
iwr write integers
ird read integers
ident give pointer addresses and sizes
lcat concatentate all vectors from a list
fread2 like vec.fread but uses flag==6 for unsigned int
vfill fill vdest with multiple instances of vsrc until reach size
inv return inverse of number multiplied by optional num
slone(src,val) select indices where ==VAL from sorted vector SRC
piva.join(pivb,veclista,veclistb) copies values from one set of vecs to other
Non-vector routines
isojt compare 2 objects to see if they're of the same type
eqojt compare 2 object pointers to see if they point to same thing
sumabs return sum of absolute values
rnd round off to nearest integer
ENDCOMMENT
NEURON {
SUFFIX nothing
: BVBASE is bit vector base number (typically 0 or -1)
GLOBAL BVBASE, RES, VECST_INSTALLED, DEBUG_VECST, VERBOSE_VECST, INTERP_VECST, LOOSE
}
PARAMETER {
BVBASE = 0.
VECST_INSTALLED=0
DEBUG_VECST=0
VERBOSE_VECST=1
INTERP_VECST=1 : interpolation
LOOSE=1e-6
: code words
ERR= -1.3480e121
GET= -1.3479e121
SET= -1.3478e121
OK= -1.3477e121
NOP= -1.3476e121
: 0 args
ALL=-1.3479e120
NEG=-1.3478e120
POS=-1.3477e120
CHK=-1.3476e120
NOZ=-1.3475e120
: 1 arg
GTH=-1.3474e120
GTE=-1.3473e120
LTH=-1.3472e120
LTE=-1.3471e120
EQU=-1.3470e120
EQV=-1.3469e120 : value equal to same row value in parallel vector
EQW=-1.3468e120 : value found in other vector
EQX=-1.3467e120 : value found in sorted vector
EQY=-1.34665e120 : value found in sorted vector -- within LOOSE
NEQ=-1.3466e120
SEQ=-1.3465e120
RXP=-1.3464e120
: 2 args
IBE=-1.3463e120
EBI=-1.3462e120
IBI=-1.3461e120
EBE=-1.3460e120
}
ASSIGNED { RES }
VERBATIM
#include "misc.h"
ENDVERBATIM
VERBATIM
// Maintain parallel int vector to avoid slowness of repeated casts
int cmpdfn (double a, double b) {return ((a)<=(b))?(((a) == (b))?0:-1):1;}
static unsigned int bufsz=0;
unsigned int scrsz=0;
unsigned int *scr=0x0;
unsigned int dcrsz=0;
double *dcr=0x0;
int *iscr=0x0;
unsigned int iscrsz=0;
int *iscrset (int nx) {
if (nx>iscrsz) {
iscrsz=nx+10000;
if (iscrsz>0) { iscr=(int *)realloc((void*)iscr,(size_t)iscrsz*sizeof(int));
} else { iscr=(int *)ecalloc(iscrsz, sizeof(int)); }
}
return iscr;
}
unsigned int *scrset (int nx) {
if (nx>scrsz) {
scrsz=nx+10000;
if (scrsz>0) { scr=(unsigned int *)realloc((void*)scr,(size_t)scrsz*sizeof(int));
} else { scr=(unsigned int *)ecalloc(scrsz, sizeof(int)); }
}
return scr;
}
double *dcrset (int nx) {
if (nx>dcrsz) {
dcrsz=nx+10000;
if (dcrsz>0) { dcr=(double*) realloc((void*)dcr,(size_t)dcrsz*sizeof(double));
} else { dcr=(double*)ecalloc(dcrsz, sizeof(double)); }
}
return dcr;
}
ENDVERBATIM
:* v1.ident() gives addresses and sizes
VERBATIM
static double ident (void* vv) {
int nx,bsz; double* x;
nx = vector_instance_px(vv, &x);
bsz=vector_buffer_size((IvocVect*)vv);
printf("Obj*%x Dbl*%x Size: %d Bufsize: %d\n",vv,x,nx,bsz);
return (double)nx;
}
ENDVERBATIM
:* v1.indset(ind,x[,y]) sets indexed values to x and other values to optional y
: v1.indset(ind,vvec[,y]) sets indexed values to vvec values
: v1.indset(ind,"INC",1) increments values
: v1.indset(ind,"INC",-1) decrements values
: v1.indset(v2, "EQU",val,x[,y]) checks if v2 is EQU to val
VERBATIM
static double indset (void* vv) {
int i, nx, ny, nz, flag, equ; char *op;
double *x, *y, *z, val, val2, inc;
nx = vector_instance_px(vv, &x);
ny = vector_arg_px(1, &y);
val2=flag=equ=inc=0;
if (hoc_is_object_arg(2)) {
flag=1;
nz = vector_arg_px(2, &z);
if (ny!=nz) z=vector_newsize(vector_arg(2),ny);
} else if (hoc_is_double_arg(2)) {
val=*getarg(2);
} else if (hoc_is_str_arg(2)) {
op = gargstr(2);
if (strcmp(op,"EQU")==0) equ=1; else if (strcmp(op,"INC")==0) inc=1; else {
printf("indset %s not recog\n",op); hxe(); }
}
if (equ) {
val2 = *getarg(3); val=*getarg(4);
for (i=0; i<ny; i++) if (y[i]==val2) x[i]=val;
} else {
if (ifarg(3)) {
val2 = *getarg(3);
if (inc && val2==0) {printf("vecst:indset ERRA inc of 0\n"); hxe();}
if (inc) inc=val2; else for (i=0; i<nx; i++) { x[i]=val2; } // fill it
}
for (i=0; i<ny; i++) {
if (y[i] > nx) {printf("vecst:inset ERRB Index exceeds vector size %g %d\n",y[i],nx); hxe();}
if (inc!=0) x[(int)y[i]]+=inc; else if (flag) x[(int)y[i]]=z[i]; else x[(int)y[i]]=val;
}
}
return (double)i;
}
ENDVERBATIM
:* v1.mkind(ind) creates a simple index for starts of a sorted integer vector v1
VERBATIM
static double mkind(void* vv) {
int i, j, nx, ny, flag;
double *x, *y, flox, last, min, max;
nx = vector_instance_px(vv, &x);
ny = vector_arg_px(1, &y);
flag=ifarg(2)?(int)*getarg(2):0;
min=x[0]; max=x[nx-1];
ny=max-min+4+(flag?0:min);
if (ny>1e6) printf("vecst:mkind() WARNING: index of size %d being built\n",ny);
y=vector_newsize(vector_arg(1),ny);
y[0]=0.; y[ny-3]=nx; y[ny-2]=min; y[ny-1]=max; // last 2 record min,max
if (min==max) {printf("vecst:mkind() ERRA: min==max %g %g\n",min,max); hxe();}
if (!flag) for (j=1;j<=min;j++) y[j]=0.; else j=1;
for (i=1,last=floor(min); i<nx; i++) {
flox=floor(x[i]);
if (flox==last) continue;
if (flox<last) {printf("vecst:mkind() ERRB: non-mono vec.x[%d]<x[%d]\n",i,i-1);hxe();}
for (;flox>=last+1;j++,last++) y[j]=(double)i;
last=flox;
}
return min;
}
ENDVERBATIM
:* yv.circ(xv,x0,y0,rad) sets cartesian x,y coords for circle with center x0,y0; radius rad
VERBATIM
static double circ (void* vv) {
int i, nx, ny, flag, lnew;
double *x, *y, x0, y0, x1, y1, rad, theta;
lnew=0;
nx = vector_instance_px((IvocVect*)vv, &x);
ny = vector_arg_px(1, &y);
if (ny!=nx) { hoc_execerror("v.circ: Vector sizes don't match.", 0); }
x0=*getarg(2); y0=*getarg(3); rad=*getarg(4);
if (ifarg(6)) { // gives center and a point on the circle instead of radius
x1=rad; y1=*getarg(5);
rad=sqrt((x0-x1)*(x0-x1) + (y0-y1)*(y0-y1));
lnew=*getarg(6); // resize the vectors
} else if (ifarg(5)) lnew=*getarg(5); // resize the vectors
if (lnew) { nx=lnew; x=vector_newsize((IvocVect*)vv,nx); y=vector_newsize(vector_arg(1),ny=nx); }
for (i=0,theta=0; i<nx; theta+=2*M_PI/(nx-1),i++) {
x[i]=y0+rad*sin(theta); y[i]=x0+rad*cos(theta);
}
return rad;
}
ENDVERBATIM
:* v1.roton(x) rotate 1-10 values onto end of constant-length queue
VERBATIM
static double roton (void* vv) {
int i, j, nx, nz, flag;
double *x, *z, val[10];
nx = vector_instance_px(vv, &x);
flag=0;
if (hoc_is_object_arg(1)) {
flag=1; nz = vector_arg_px(1, &z);
} else {
for (i=1;i<=10 && ifarg(i);i++) val[i-1]= *getarg(i);
nz=i-1;
}
if (nz>nx) {printf("v.roton: Can't rotate %d vals on vec of size %d\n",nz,nx); hxe();}
for (i=nz,j=0; i<nx; i++,j++) x[j]=x[i];
for (i=nx-nz,j=0; j<nz; i++,j++) x[i]=flag?z[j]:val[j];
return (double)nz;
}
ENDVERBATIM
:* tmp.fewind(ind,veclist)
: picks out numbers from multiple vectors using index ind
VERBATIM
static double fewind (void* vv) {
int i, j, k, nx, ni, nv[VRRY], num, flag;
Object* ob;
double *x, *ind, *vvo[VRRY];
char *ix;
nx = vector_instance_px(vv, &x);
ni = vector_arg_px(1, &ind);
ob = *hoc_objgetarg(2);
if (ifarg(3)) flag=(int)*getarg(3); else flag=0; // flag==1 for handling non-uniq indices
num = ivoc_list_count(ob);
if (num>VRRY) hoc_execerror("ERR: fewind can only handle VRRY vectors", 0);
if (flag) ix=(char*)ecalloc(nx,sizeof(char));
if (!flag && nx<ni) {printf("fewind WARNING nx!=ni: %d!=%d, setting nonuniq flag\n",nx,ni);
flag=1; }
for (i=0;i<num;i++) {
nv[i] = list_vector_px(ob, i, &vvo[i]);
if (nx!=nv[i]) { printf("fewind ERR %d %d %d\n",i,nx,nv[i]);
hoc_execerror("Vectors must all be same size: ", 0); }
}
if (nx>scrsz) {
if (scrsz>0) { free(scr); scr=(unsigned int *)NULL; }
scrsz=nx+10000;
scr=(unsigned int *)ecalloc(scrsz, sizeof(int));
}
if (flag) {
for (i=0;i<nx;i++) ix[i]=0;
for (i=0,k=0;i<ni && k<nx;i++) {
j=(int)ind[i];
if (ix[j]==0) {
if (j>=nx || j<0) { printf("fewind ERR1A %d %d\n",j,nx); free(ix);hxe();}
scr[k]=j;
ix[j]=1; // indicate that has already been used
k++;
}
}
ni=nx; // index up to max
} else for (i=0;i<ni;i++) {
scr[i]=(int)ind[i]; // copy into integer array
if (scr[i]>=nx || scr[i]<0) { printf("fewind ERR1 %d %d\n",scr[i],nx);
hoc_execerror("Index vector out-of-bounds", 0); }
}
if (flag) for (i=0;i<ni;i++) if (ix[i]==0) {printf("fewind ERR2 %d\n",i); hxe();}
for (j=0;j<num;j++) {
for (i=0;i<ni;i++) x[i]=vvo[j][scr[i]];
for (i=0;i<ni;i++) vvo[j][i]=x[i];
vvo[j]=list_vector_resize(ob, j, ni);
}
if (flag) free(ix);
return (double)ni;
}
ENDVERBATIM
:* ind.findx(vecAlist,vecBlist)
: uses ind as index into vecA's to load in vecB's (for select); a nondestructive fewind()
VERBATIM
static double findx (void* vv) {
int i, j, ni, nx, av[VRRY], bv[VRRY], num;
Object *ob1, *ob2;
double *ind, *avo[VRRY], *bvo[VRRY];
ni = vector_instance_px((IvocVect*)vv, &ind);
ob1 = *hoc_objgetarg(1);
ob2 = *hoc_objgetarg(2);
num = ivoc_list_count(ob1);
i = ivoc_list_count(ob2);
if (i!=num) hoc_execerror("findx ****ERRA****: lists have different counts", 0);
if (num>VRRY) hoc_execerror("findx ****ERRB****: can only handle VRRY vectors", 0);
for (i=0;i<num;i++) {
av[i]=list_vector_px(ob1, i, &avo[i]); // source vectors
if (av[0]!=av[i]) { printf("findx ****ERRC**** %d %d %d\n",i,av[0],av[i]);
hoc_execerror("Src vectors must all be same size: ", 0); }
}
nx=av[0]; // size of source vecs
for (i=0;i<num;i++) {
bv[i]=list_vector_px2(ob2, i, &bvo[i], (IvocVect**)&vv); // dest vectors
if (vector_buffer_size((IvocVect*)vv)<ni) {
printf("findx ****ERRD**** arg#%d need:%d sz:%d\n",num+i+1,ni,vector_buffer_size((IvocVect*)vv));
hoc_execerror("Destination vector with insufficient size: ", 0);
} else {
vector_resize((IvocVect*)vv, ni);
}
}
if (ni>scrsz) {
if (scrsz>0) { free(scr); scr=(unsigned int *)NULL; }
scrsz=ni+10000;
scr=(unsigned int *)ecalloc(scrsz, sizeof(int));
}
for (i=0;i<ni;i++) { scr[i]=(int)ind[i]; // copy into integer array
if (scr[i]>=nx || scr[i]<0) { printf("findx ****ERRE**** **** IND:%d SZ:%d\n",scr[i],nx);
hoc_execerror("Index vector out-of-bounds", 0); }
}
for (j=0,i=0;j<num;j++) for (i=0;i<ni;i++) bvo[j][i]=avo[j][scr[i]];
return (double)ni;
}
ENDVERBATIM
:* ind.lma(vecAlist,vecBlist,beg,end[,mul,add])
: copy each vector in Alist to Blist indices from beg to end; with sequential mul/add
: ind picks out specific vectors if not doing all of them
VERBATIM
static double lma (void* vv) {
int i, j, k, ia, ib, ni, nj, nx, av[VRRY], bv[VRRY], num, numb, beg, end, *xx;
Object *ob1, *ob2;
double *ind, *avo[VRRY], *bvo[VRRY], mul,mmul,add,madd;
ni = vector_instance_px((IvocVect*)vv, &ind);
xx=iscrset(ni);
ob1 = *hoc_objgetarg(1); ob2 = *hoc_objgetarg(2);
beg = (int)*getarg(3); end= (int)*getarg(4);
mul=ifarg(5)?*getarg(5):1; add=ifarg(6)?*getarg(6):0;
num = ivoc_list_count(ob1);
numb = ivoc_list_count(ob2);
if ((ni==0 && numb!=num) || (ni>0 && ni!=num)) {
printf("lma ERRA: wrong# of outvecs: %d (inlist:%d,inds:%d)\n",numb,num,ni); hxe();}
for (i=0,j=0;i<ni;i++) {
if (ind[i]) xx[j++]=i; // make the index array out of a masking vector
if (j>num){printf("lma ERRA1 OOB: %d %d\n",j,num); hxe();}
}
nj=j;
if (num>VRRY){printf("lma ****ERRB****: can only handle %d vectors\n",VRRY); hxe();}
for (i=0;i<num;i++) {
av[i]=list_vector_px(ob1, i, &avo[i]); // source vectors
if (av[0]!=av[i]) { printf("lma ****ERRC**** %d %d %d\n",i,av[0],av[i]);
hoc_execerror("Src vectors must all be same size: ", 0); }
}
nx=av[0]; // size of source vecs
if (beg>=end || beg<0 || end>nx) {printf("lma ERRC1 OOB %d - %d (%d)\n",beg,end,nx); hxe();}
for (i=0;i<num;i++) {
bv[i]=list_vector_px2(ob2, i, &bvo[i], (IvocVect**)&vv); // dest vectors
if (bv[i]!=(end-beg)) bvo[i]=vector_newsize((IvocVect*)vv, end-beg);
}
if (nj>0) {
for (ia=0,ib=0,mmul=1.,madd=0.;ia<nj;ia++,ib++) {
j=xx[ia];
for (i=beg,k=0;i<end;i++,k++) bvo[ib][k]=mmul*avo[j][i]+madd;
if (mul!=1) mmul*=mul; if (add!=0) madd+=add;
}
} else for (j=0,mmul=1,madd=0;j<num;j++) {
for (i=beg,k=0;i<end;i++,k++) bvo[j][k]=mmul*avo[j][i]+madd;
if (mul!=1) mmul*=mul; if (add!=0) madd+=add;
}
return (double)j;
}
ENDVERBATIM
:* ind.sindx(vecAlist,vecBlist)
: uses ind as index into vecA's to replace with elements from vecB's
VERBATIM
static double sindx (void* vv) {
int i, j, ni, nx, av[VRRY], bv[VRRY], num;
Object *ob1, *ob2;
double *ind, *avo[VRRY], *bvo[VRRY];
ni = vector_instance_px(vv, &ind);
ob1 = *hoc_objgetarg(1);
ob2 = *hoc_objgetarg(2);
num = ivoc_list_count(ob1);
i = ivoc_list_count(ob2);
if (num!=i) hoc_execerror("sindx ****ERRA****: two vec lists have different counts", 0);
if (num>VRRY) hoc_execerror("sindx ****ERRB****: can only handle VRRY vectors", 0);
for (i=0;i<num;i++) {
av[i]=list_vector_px(ob1, i, &avo[i]); // dest vectors
if (av[0]!=av[i]) { printf("sindx ****ERRC**** %d %d %d\n",i,av[0],av[i]);
hoc_execerror("Dest. vectors must all be same size: ", 0); }
}
nx=av[0]; // size of dest vecs
for (i=0;i<num;i++) {
bv[i]=list_vector_px(ob2, i, &bvo[i]); // source vectors
if (bv[i]!=ni) {
printf("sindx ****ERRD**** arg#%d does note match ind length %d vs %d\n",num+i+1,ni,bv[i]);
hoc_execerror("Source vector with insufficient size: ", 0); }
}
if (ni>scrsz) {
if (scrsz>0) { free(scr); scr=(unsigned int *)NULL; }
scrsz=ni+10000;
scr=(unsigned int *)ecalloc(scrsz, sizeof(int));
}
for (i=0;i<ni;i++) { scr[i]=(int)ind[i]; // copy into integer array
if (scr[i]>=nx || scr[i]<0) {
printf("sindx ****ERRE**** IND:%d SZ:%d\n",scr[i],nx);
hoc_execerror("Index vector out-of-bounds", 0); }
}
for (j=0,i=0;j<num;j++) for (i=0;i<ni;i++) avo[j][scr[i]]=bvo[j][i];
return (double)ni;
}
ENDVERBATIM
:* ind.sindv(vecAlist,valvec)
: uses ind as index into vecA's to replace with values in valvec
VERBATIM
static double sindv(void* vv) {
int i, j, ni, nx, av[VRRY], bv, num;
Object* ob;
double *ind, *avo[VRRY], *bvo;
ni = vector_instance_px(vv, &ind);
ob = *hoc_objgetarg(1);
bv=vector_arg_px(2, &bvo); // source vector
num = ivoc_list_count(ob);
if (num>VRRY) hoc_execerror("sindv ****ERRA****: can only handle VRRY vectors", 0);
for (i=0;i<num;i++) {
av[i]=list_vector_px(ob, i, &avo[i]); // dest vectors
if (av[0]!=av[i]) { printf("sindv ****ERRC**** %d %d %d\n",i,av[0],av[i]);
hoc_execerror("Dest. vectors must all be same size: ", 0); }
}
nx=av[0]; // size of source vecs
if (bv!=num) {
printf("sindv ****ERRD**** Vector arg does note match list count %d vs %d\n",num,bv);
hoc_execerror("Source vector is wrong size: ", 0); }
if (ni>scrsz) {
if (scrsz>0) { free(scr); scr=(unsigned int *)NULL; }
scrsz=ni+10000;
scr=(unsigned int *)ecalloc(scrsz, sizeof(int));
}
for (i=0;i<ni;i++) { scr[i]=(int)ind[i]; // copy into integer array
if (scr[i]>=nx || scr[i]<0) {
printf("sindv ****ERRE**** IND:%d SZ:%d\n",scr[i],nx);
hoc_execerror("Index vector out-of-bounds", 0); }
}
for (j=0,i=0;j<num;j++) for (i=0;i<ni;i++) avo[j][scr[i]]=bvo[j];
return (double)ni;
}
ENDVERBATIM
:* ind.slct(key,args,veclist)
: picks out indices of numbers in key from multiple vectors
VERBATIM
static double slct (void* vv) {
int i, j, k, m, n, p, ni, nk, na, nv[VRRY], num, fl, lc, field[VRRY], lt, rt, flag;
Object* lob;
double *ind, *key, *arg, *vvo[VRRY], val;
ni = vector_instance_px(vv, &ind); // vv is ind
nk = vector_arg_px(1, &key);
na = vector_arg_px(2, &arg);
lob = *hoc_objgetarg(3);
if (ifarg(4)) flag=(int)*getarg(4); else flag=0;// flag==1 to return first found
num = ivoc_list_count(lob);
if (num>VRRY) hoc_execerror("ERR: vecst::slct can only handle VRRY vectors", 0);
for (i=0,j=0;i<num;i++,j++) { // pick up vectors
nv[i] = list_vector_px(lob, i, &vvo[i]);
if (key[j]>=EQV && key[j]<=EQY) { // EQV-EQY take extra vec arg of any size
i++;
nv[i] = list_vector_px(lob, i, &vvo[i]);// pick up extra vector of any size
} else if (ni!=nv[i]) {
printf("vecst::slct ERR %d %d %d %d %d\n",i,j,k,ni,nv[i]);
hoc_execerror("index and searched vectors must all be same size: ", 0);
}
}
for (j=0;j<nk;j++) { // look for fields in a mkcode() coded double
field[j]=-1;
if (key[j]<=EBE && key[j]>=ALL) { field[j]=0;
} else for (m=1;m<=5;m++) {
if (key[j]<=EBE*(m+1) && key[j]>=ALL*(m+1)) { // m is is field key 1-5
key[j]/=(m+1);
field[j]=m;
}
}
if (field[j]==-1) {printf("vecst::slct ERRF %d %g\n",j,key[j]); hxe(); }
}
if (2*nk!=na) { printf("vecst::slct ERR3 %d %d\n",nk,na);
hoc_execerror("Arg vector must be double key length",0); }
for (i=0,n=0;i<nk;i++) if (key[i]>=EQV && key[i]<=EQY) n++; // special cases take 2 vec args
if (nk+n!=num) {
printf("vecst::slct ERR2 %d(keys)+%d(EQV/W)!=%d(vecs)\n",nk,n,num);
hoc_execerror("Key length must be number of vecs + num of EQV/W",0); }
for (j=0,k=0,m=0;j<ni;j++) { // j steps through elements of vectors
for (i=0,m=0,n=0,fl=1;i<num;i++,n++,m+=2) { // i steps thru key, m thru args
if (field[n]==0) val=vvo[i][j]; else UNCODE(vvo[i][j],field[n],val);
if (key[n]==ALL) continue; // OK - do nothing
if (key[n]==NOZ) { if (val==0.) {fl=0; break;} else continue;
} else if (key[n]==POS) { if (val<=0.) {fl=0; break;} else continue;
} else if (key[n]==NEG) { if (val>=0.) {fl=0; break;} else continue;
} else if (key[n]==GTH) { if (val<=arg[m]) {fl=0; break;} else continue;
} else if (key[n]==GTE) { if (val< arg[m]) {fl=0; break;} else continue;
} else if (key[n]==LTH) { if (val>=arg[m]) {fl=0; break;} else continue;
} else if (key[n]==LTE) { if (val> arg[m]) {fl=0; break;} else continue;
} else if (key[n]==EQU) { if (val!=arg[m]) {fl=0; break;} else continue;
} else if (key[n]==EQV) { if (val!=vvo[i+1][j]) {
fl=0; break;} else { i++; continue; }
} else if (key[n]==EQW) { // check value against values in following vec
fl=0; // assume it's not going to match
for (p=0;p<nv[i+1];p++) if (val==vvo[i+1][p]) {fl=1; break;}
if (fl==0) break; else { i++; continue; }
} else if (key[n]==EQX) { // check value against values in sorted vec
fl=0; // assume it's not going to match
lt=0; rt=nv[i+1]-1;
while (lt <= rt) {
p = (lt+rt)/2;
if (val>vvo[i+1][p]) lt=p+1; else if (val<vvo[i+1][p]) rt=p-1; else {fl=1; break;}
}
if (fl==0) break; else { i++; continue; }
} else if (key[n]==EQY) { // check value against values in sorted vec
fl=0; // assume it's not going to match
lt=0; rt=nv[i+1]-1;
while (lt <= rt) {
p = (lt+rt)/2;
if (val>vvo[i+1][p]+LOOSE) lt=p+1; else if (val<vvo[i+1][p]-LOOSE) rt=p-1; else {
fl=1; break; }
}
if (fl==0) break; else { i++; continue; }
} else if (key[n]==NEQ) { if (val==arg[m]) {fl=0; break;} else continue;
} else if (key[n]==IBE) { if ((val< arg[m])||(val>=arg[m+1])) {
fl=0; break; } else continue; // IBE="[)" include-bracket-exclude
} else if (key[n]==EBI) { if ((val<=arg[m])||(val> arg[m+1])) {
fl=0; break; } else continue; // "(]" : exclude-bracket-include
} else if (key[n]==IBI) { if ((val< arg[m])||(val> arg[m+1])) {
fl=0; break; } else continue; // "[]" : include-bracket-include
} else if (key[n]==EBE) { if ((val<=arg[m])||(val>=arg[m+1])) {
fl=0; break; } else continue; // "()" : exclude-bracket-exclude
} else {printf("vecst::slct ERR4 %g\n",key[n]); hoc_execerror("Unknown key",0);}
}
if (fl) {
ind[k++]=j; // all equal
if (flag==1) break;
}
}
vector_resize((IvocVect*)vv, k);
return (double)k;
}
ENDVERBATIM
:* ind.slor(key,args,vec1,vec2[,vec3,vec4,...])
: picks out indices of numbers in key from multiple vectors
VERBATIM
static double slor (void* vv) {
int i, j, k, m, n, p, ni, nk, na, nv[VRRY], num, fl, field[VRRY], lt, rt;
Object* lob;
double *ind, *key, *arg, *vvo[VRRY], val;
ni = vector_instance_px(vv, &ind); // vv is ind
nk = vector_arg_px(1, &key);
na = vector_arg_px(2, &arg);
lob = *hoc_objgetarg(3);
num = ivoc_list_count(lob);
if (num>VRRY) hoc_execerror("ERR: vecst::slor can only handle VRRY vectors", 0);
for (i=0,j=0;i<num;i++,j++) { // pick up vectors
nv[i] = list_vector_px(lob, i, &vvo[i]);
if (key[j]>=EQV && key[j]<=EQY) { // EQV-EQY take extra vec arg of any size
i++;
nv[i] = list_vector_px(lob, i, &vvo[i]);// pick up extra vector of any size
} else if (ni!=nv[i]) {
printf("vecst::slor ERR %d %d %d %d %d\n",i,j,k,ni,nv[i]);
hoc_execerror("index and searched vectors must all be same size: ", 0);
}
}
for (j=0;j<num;j++) { // look for fields
field[j]=-1;
if (key[j]<=EBE && key[j]>=ALL) { field[j]=0;
} else for (m=1;m<=5;m++) {
if (key[j]<=EBE*(m+1) && key[j]>=ALL*(m+1)) { // m is is field key 1-5
key[j]/=(m+1);
field[j]=m;
}
}
if (field[j]==-1) {printf("vecst::slor ERRF %g\n",key[j]); hxe(); }
}
if (2*nk!=na) { printf("vecst::slor ERR3 %d %d\n",nk,na);
hoc_execerror("Arg vector must be double key length",0); }
for (i=0,n=0;i<nk;i++) if (key[i]>=EQV && key[i]<=EQY) n++; // special case takes 2 vec args
if (nk+n!=num) {
printf("vecst::slor ERR2 %d(keys)+%d(EQV)!=%d(vecs)\n",nk,n,num);
hoc_execerror("Key length must be number of vecs + num of EQV",0); }
for (j=0,k=0,m=0;j<ni;j++) { // j steps through elements of vectors
for (i=0,m=0,n=0,fl=0;i<num;i++,n++,m+=2) { // i steps thru key, m thru args
if (field[n]==0) val=vvo[i][j]; else UNCODE(vvo[i][j],field[n],val);
if (key[n]==ALL) {fl=1; break;} // OK - do nothing
if (key[n]==NOZ) { if (val==0.) continue; else {fl=1; break;}
} else if (key[n]==POS) { if (val<=0.) continue; else {fl=1; break;}
} else if (key[n]==NEG) { if (val>=0.) continue; else {fl=1; break;}
} else if (key[n]==GTH) { if (val<=arg[m]) continue; else {fl=1; break;}
} else if (key[n]==GTE) { if (val< arg[m]) continue; else {fl=1; break;}
} else if (key[n]==LTH) { if (val>=arg[m]) continue; else {fl=1; break;}
} else if (key[n]==LTE) { if (val> arg[m]) continue; else {fl=1; break;}
} else if (key[n]==EQU) { if (val!=arg[m]) continue; else {fl=1; break;}
} else if (key[n]==EQV) { if (val!=vvo[i+1][j]) continue; else {
i++; fl=1; break; }
} else if (key[n]==EQW) { // check value against values in following vec
fl=0; // assume it's not going to match
for (p=0;p<nv[i+1];p++) if (val==vvo[i+1][p]) {fl=1; break;}
if (fl==1) break; else { i++; continue; }
} else if (key[n]==EQX) { // check value against values in sorted vec
fl=0; // assume it's not going to match
lt=0; rt=nv[i+1]-1;
while (lt <= rt) {
p = (lt+rt)/2;
if (val>vvo[i+1][p]) lt=p+1; else if (val<vvo[i+1][p]) rt=p-1; else {fl=1; break;}
}
if (fl==1) break; else { i++; continue; }
} else if (key[n]==EQY) { // check value against values in sorted vec
printf("EQY not implemented for slor()\n"); hxe();
} else if (key[n]==NEQ) { if (val==arg[m]) continue; else {fl=1; break;}
} else if (key[n]==IBE) { if ((val< arg[m])||(val>=arg[m+1])) {
continue; } else {fl=1; break;} // IBE="[)" include-bracket-exclude
} else if (key[n]==EBI) { if ((val<=arg[m])||(val> arg[m+1])) {
continue; } else {fl=1; break;} // "(]" : exclude-bracket-include
} else if (key[n]==IBI) { if ((val< arg[m])||(val> arg[m+1])) {
continue; } else {fl=1; break;} // "[]" : include-bracket-include
} else if (key[n]==EBE) { if ((val<=arg[m])||(val>=arg[m+1])) {
continue; } else {fl=1; break;} // "()" : exclude-bracket-exclude
} else {printf("vecst::slor ERR4 %g\n",key[n]); hoc_execerror("Unknown key",0);}
}
if (fl) ind[k++]=j; // all equal
}
vector_resize((IvocVect*)vv, k);
return (double)k;
}
ENDVERBATIM
:* src.whi(valvec,indvec[,&i0,&i1,...]) returns index of first one for each val
VERBATIM
static double whi (void* vv) {
int i, j, nx, na, nb, cnt; double *x, *val, *ind;
nx = vector_instance_px(vv, &x);
i = vector_arg_px(1, &val);
na = vector_arg_px(2, &ind);
if (i!=na) {printf("vecst:whi() takes 2 eq length vecs:%d %d\n",i,na); hxe();}
scrset(na);
for (i=0;i<na;i++) {scr[i]=0; ind[i]=-1.;}
for (i=0,cnt=0;i<nx;i++) for (j=0;j<na;j++) {
if (x[i]==val[j]) {
if (scr[j]) printf("WARNING %g found mult times (%g,%d)\n",val[j],ind[j],i); else {
ind[j]=(double)i; scr[j]=1; cnt++;
}
}
}
for (nb=3;ifarg(nb);nb++) {} // count args
nb--;
if (nb>2) {
if (nb-2!=na) {printf("vecst:whi() wrong #args:%d %d\n",na,nb-2); hxe();}
for (i=3,j=0;j<na;i++,j++) *(hoc_pgetarg(i)) = ind[j];
}
return (double)cnt/na; // % found
}
ENDVERBATIM
:* v.iwr() write integers
VERBATIM
static double iwr (void* vv) {
int i, j, nx; size_t r;
double *x;
FILE* f;
f = hoc_obj_file_arg(1);
nx = vector_instance_px(vv, &x);
scrset(nx);
for (i=0;i<nx;i++) scr[i]=(int)x[i]; // copy into integer array
r=fwrite(&nx,sizeof(int),1,f); // write out the size
r=fwrite(scr,sizeof(int),nx,f);
return (double)nx;
}
ENDVERBATIM
:* v.ird() read integers
VERBATIM
static double ird (void* vv) {
int i, j, nx, n; size_t r;
double *x;
FILE* f;
f = hoc_obj_file_arg(1);
nx = vector_instance_px(vv, &x);
r=fread(&n,sizeof(int),1,f); // size
if (n>scrsz) {
if (scrsz>0) { free(scr); scr=(unsigned int *)NULL; }
scrsz=n+10000;
scr=(unsigned int *)ecalloc(scrsz, sizeof(int));
}
if (n!=nx) {
nx=vector_buffer_size((IvocVect*)vv);
if (n<=nx) {
vector_resize((IvocVect*)vv, n); nx=n;
} else {
printf("%d > %d :: ",n,nx);
hoc_execerror("Vector max capacity too small for ird ", 0);
}
}
r=fread(scr,sizeof(int),n,f);
for (i=0;i<nx;i++) x[i]=(double)scr[i];
return (double)n;
}
ENDVERBATIM
:* v.fread2()
VERBATIM
static double fread2 (void* vv) {
int i, j, nx, n, type, maxsz; size_t r;
double *x;
FILE* fp;
BYTEHEADER
fp = hoc_obj_file_arg(1);
nx = vector_instance_px(vv, &x);
maxsz=vector_buffer_size((IvocVect*)vv);
n = (int)*getarg(2);
type = (int)*getarg(3);
if (n>maxsz) {
printf("%d > %d :: ",n,maxsz);
hoc_execerror("Vector max capacity too small for fread2 ", 0);
} else {
vector_resize((IvocVect*)vv, n);
}
if (type==6 || type==16) { // unsigned ints
unsigned int *xs;
if (n>scrsz) {
if (scrsz>0) { free(scr); scr=(unsigned int *)NULL; }
scrsz=n+10000;
scr=(unsigned int *)ecalloc(scrsz, sizeof(int));
}
xs=(unsigned int*)scr;
r=fread(xs,sizeof(int),n,fp);
if (type==16) BYTESWAP_FLAG=1;
for (i=0;i<n;i++) {
BYTESWAP(scr[i],int)
x[i]=(double)scr[i];
}
return (double)n;
} if (type==3 || type==13) { // straight float reads
float *xf = (float *)malloc(n * (unsigned)sizeof(float));
r=fread(xf,sizeof(float),n,fp);
if (type==13) BYTESWAP_FLAG=1;
for (i=0;i<n;i++) {
BYTESWAP(xf[i],float)
x[i]=(double)xf[i];
}
free((char *)xf);
} else hoc_execerror("Type unsupported in fread2 ", 0);
return 0;
}
ENDVERBATIM
:* v.revec() -- append() except that sets vector to size 0 before appending
VERBATIM
static double revec (void* vv) {
int i,j,k, nx, ny; double *x, *y;
nx = vector_instance_px((IvocVect*)vv, &x);
if (nx==0) x=vector_newsize((IvocVect*)vv,nx=100);
for (i=1,k=0;ifarg(i);i++,k++) {
if (hoc_is_double_arg(i)) {
if (k>=nx) x=vector_newsize((IvocVect*)vv,nx*=4);
x[k]=*getarg(i);
} else {
ny=vector_arg_px(i, &y);
if (k+ny>=nx) x=vector_newsize((IvocVect*)vv,nx=2*(nx+ny));
for (j=0;j<ny;j++,k++) x[k]=y[j];
k--; // back up one
}
}
vector_resize((IvocVect*)vv,k);
return 0;
}
ENDVERBATIM
:* v.has(val[,outvec]) -- a contains that returns the results
VERBATIM
static double has (void* vv) {
int i, j, nx, ny;
double *x, *y, val; IvocVect* vc;
nx = vector_instance_px((IvocVect*)vv, &x);
val=*getarg(1);
ny=0;
if (ifarg(2)) if (hoc_is_object_arg(2)) {
ny=vector_arg_px(2, &y); vc=vector_arg(2);
if (ny==0) y=vector_newsize(vc,ny=100);
}
for (i=0,j=0;i<nx;i++) if (x[i]==val) {
if (ifarg(2)) {
if (ny) {
// append index to vector like indvwhere()
if (j>=ny) y=vector_newsize(vc,ny*=4);
y[j++]=(double)i;
} else {
*(hoc_pgetarg(2)) = (double)i;
return 1.0;
}
} else return 1;
}
if (j>0) vector_resize((IvocVect*)vc,j); // only fall through here when doing indvwhere
return (double)j;
}
ENDVERBATIM
:* ind.insct(v1,v2)
: return v1 intersect v2
VERBATIM
static double insct (void* vv) {
int i, j, k, nx, nv1, nv2, maxsz;
double *x, *v1, *v2;
nx = vector_instance_px((IvocVect*)vv, &x);
if (maxsz==0) maxsz=1000;
maxsz=vector_buffer_size((IvocVect*)vv);
x=vector_newsize((IvocVect*)vv, maxsz);
nv1 = vector_arg_px(1, &v1);
nv2 = vector_arg_px(2, &v2);
for (i=0,k=0;i<nv1;i++) for (j=0;j<nv2;j++) if (v1[i]==v2[j]) {
if (k==maxsz) x=vector_newsize((IvocVect*)vv, maxsz*=2);
x[k++]=v1[i];
}
vector_resize((IvocVect*)vv, k);
return (double)k;
}
ENDVERBATIM
:* ind.linsct(vlist,this_many)
: return indices that show up this_many times or more in the vectors in vlist
VERBATIM
static double linsct (void* vv) {
int i,j,k,nx,maxsz,min,cnt,lt,rt,p,iv,jv,jj,fl; ListVec* pL;
double *x, val;
nx = vector_instance_px((IvocVect*)vv, &x);
maxsz=vector_buffer_size((IvocVect*)vv);
if (maxsz==0) maxsz=1000;
x=vector_newsize((IvocVect*)vv, maxsz);
pL = AllocListVec(*hoc_objgetarg(1));
min= (int)*getarg(2);
for (iv=0;iv<pL->isz;iv++) {
if (!ismono1(pL->pv[iv],pL->plen[iv],2)){printf("linsct() ERRA not monotonic %d\n",iv); hxe();}
if (pL->pv[iv][0]<0){printf("linsct() ERRB neg value in %d is %g\n",iv,pL->pv[iv][0]);hxe();}
}
for (iv=0,k=0;iv<=pL->isz-min+1;iv++) for (j=0;j<pL->plen[iv];j++) {
val=pL->pv[iv][j];
for (i=0,fl=0;i<k;i++) if (val==x[i]) {fl=1; break;}
if (fl) continue; // already on the list
for (jv=iv+1,cnt=1;jv<pL->isz;jv++) {
fl=lt=0; rt=pL->plen[jv]-1;
while (lt <= rt) {
p = (lt+rt)/2;
if (val>pL->pv[jv][p]) lt=p+1; else if (val<pL->pv[jv][p]) rt=p-1; else {
fl=1; break;}
}
if (fl) cnt++;
if (cnt>=min) {
if (k==maxsz) x=vector_newsize((IvocVect*)vv, maxsz*=2);
x[k++]=val;
break;
}
}
}
vector_resize((IvocVect*)vv, k);
return (double)k;
}
ENDVERBATIM
:* vdest.vfill(vsrc)
: fill vdest with multiple instances of vsrc until reach size
VERBATIM
static double vfill (void* vv) {
int i, nx, nv1;
double *x, *v1;
nx = vector_instance_px(vv, &x);
nv1 = vector_arg_px(1, &v1);
for (i=0;i<nx;i++) x[i]=v1[i%nv1];
return 0;
}
ENDVERBATIM
:* vec.cull(src,key)
: remove numbers in vec that are found in the key
VERBATIM
static double cull (void* vv) {
int i, j, k, nx, nv1, nv2, flag;
double *x, *v1, *v2, val;
nx = vector_instance_px((IvocVect*)vv, &x);
nv1 = vector_arg_px(1, &v1);
if (hoc_is_double_arg(2)) { val=*getarg(2); nv2=0; } else nv2=vector_arg_px(2, &v2);
x=vector_newsize((IvocVect*)vv,nx=nv1);
for (i=0,k=0;i<nv1;i++) {
flag=1;
if (nv2) { for (j=0;j<nv2;j++) if (v1[i]==v2[j]) flag=0;
} else if (v1[i]==val ) flag=0;
if (flag) x[k++]=v1[i];
}
vector_resize((IvocVect*)vv, k);
return (double)k;
}
ENDVERBATIM
:* dest.redundout(src[,INDFLAG])
: flag redundant numbers; must sort src first
: with indflag set just returns indices of locations rather than values
VERBATIM
static double redundout (void* vv) {
int i, j, nx, nv1, maxsz, ncntr, indflag, cntflag;
double *x, *v1, *cntr, val;
void *vc;
if (ifarg(2)) indflag=(int)*getarg(2); else indflag=0;
if (ifarg(3)) { cntflag=1;
ncntr = vector_arg_px(3, &cntr); vc=vector_arg(3);
ncntr = vector_buffer_size((IvocVect*)vc); vector_resize((IvocVect*)vc, ncntr);
for (i=0;i<ncntr;i++) cntr[i]=1.; // will be at least 1 of each #
} else cntflag=0;
nx = vector_instance_px(vv, &x);
maxsz=vector_buffer_size((IvocVect*)vv); vector_resize((IvocVect*)vv, maxsz);
nv1 = vector_arg_px(1, &v1);
val=v1[0]; x[0]=(indflag?0:val);
if (cntflag) {
for (j=1,i=1;i<nv1&&j<maxsz&&j<ncntr;i++) {
if (v1[i]!=val) { val=v1[i]; x[j++]=(indflag?i:val); } else cntr[j-1]+=1;
}
} else {
for (j=1,i=1;i<nv1&&j<maxsz;i++) if (v1[i]!=val) { val=v1[i]; x[j++]=(indflag?i:val); }
}
if (j>=maxsz) {
printf("\tredundout WARNING: ran out of room: %d<needed\n",maxsz);
} else { vector_resize((IvocVect*)vv, j); }
if (cntflag) if (j>=ncntr) {
printf("\tredundout WARNING: cntr ran out of room: %d<needed\n",ncntr);
} else { vector_resize((IvocVect*)vc, j); }
return (double)j;
}
ENDVERBATIM
:* ind.mredundout(veclistA[,INDFLAG,veclistB])
: check redundancy across multiple parallel vectors veclistA
: with indflag 1, returns index of matchs in ind but does not alter vecs in veclistA
: will also remove from veclistB in parallel
: leaves the last of a series of matches
: with indflag set just returns indices of locations rather than values
: NB using indices will to .remove match items will give results that differ from
: direct use (last vs first of a series -- will be seen in the other columns -- ie veclistB)
VERBATIM
static double mredundout (void* vv) {
int i, j, k, m, p, q, maxsz, ns, nx, av[VRRY], bv[VRRY], num, numb, indflag, match;
Object *ob, *ob2;
double *x, *avo[VRRY], *bvo[VRRY], val[VRRY];
IvocVect *vva[VRRY],*vvb[VRRY];
nx = vector_instance_px((IvocVect*)vv, &x);
ob = *hoc_objgetarg(1);
if (ifarg(2)) indflag=(int)*getarg(2); else indflag=0;
if (ifarg(3)) {
ob2 = *hoc_objgetarg(3);
numb = ivoc_list_count(ob2);
} else numb=0;
maxsz=vector_buffer_size((IvocVect*)vv);
if (indflag) vector_resize((IvocVect*)vv, maxsz); // else vector is not used
num = ivoc_list_count(ob);
if (num>VRRY) hoc_execerror("mredundout ****ERRA****: can only handle VRRY vectors", 0);
for (i=0;i<num;i++) {
av[i]=list_vector_px2(ob, i, &avo[i], &vva[i]);
if (av[0]!=av[i]) { printf("mredundout ****ERRC**** %d %d %d\n",i,av[0],av[i]);
hoc_execerror("Vectors must all be same size: ", 0); }
}
ns=av[0]; // size of source vecs
for (i=0;i<numb;i++) {
bv[i]=list_vector_px2(ob2, i, &bvo[i], &vvb[i]);
if (ns!=bv[i]) { printf("mredundout ****ERRC2**** %d %d %d\n",i,ns,bv[i]);
hoc_execerror("Vectors must all be same size: ", 0); }
}
if (ns/4>scrsz) {
if (scrsz>0) { free(scr); scr=(unsigned int *)NULL; }
scrsz=ns/4+10000;
scr=(unsigned int *)ecalloc(scrsz, sizeof(int));
}
for (j=0;j<num;j++) val[j]=avo[j][0]; // initialize the val array
for (i=1,k=0;i<ns;i++) {
for (j=0,match=1;j<num;j++) {
if (val[j]!=avo[j][i]) { match=0; break; } // if no match say so
}
if (match) { // add this one to the list
if (k>=scrsz){printf("mredundout****ERRD**** over scr size %d\n",k);hxe();}
scr[k++]=i; // flag to get rid of this one
} else for (j=0;j<num;j++) val[j]=avo[j][i]; // copy next set of vals
}
if (indflag) { // just fill ind with indices of the repeats
if (k>maxsz){printf("mredundout****ERRE**** vec overflow %d>%d\n",k,maxsz);hxe();}
for (i=0;i<k;i++) x[i]=(double)scr[i];
vector_resize((IvocVect*)vv, k);
} else { // remove all the repeat rows
if (k == 0) return (double)k;
for (i=0,p=scr[0]; i<k-1; i++) { // iter thru the inds to remove
for (m=scr[i],p--; m<scr[i+1]; m++,p++) { // move everything down till next ind
for (j=0;j<num; j++) avo[j][p]=avo[j][m]; // go through all the A list vecs
for (j=0;j<numb;j++) bvo[j][p]=bvo[j][m]; // go through B list vecs
}
}
for (m=scr[i],p--; m<ns; m++,p++) { // finish up by moving down from last ind to end
for (j=0;j<num; j++) avo[j][p]=avo[j][m];
for (j=0;j<numb;j++) bvo[j][p]=bvo[j][m];
}
for (j=0;j<num; j++) vector_resize(vva[j], ns-k); // resize all the vectors
for (j=0;j<numb;j++) vector_resize(vvb[j], ns-k);
}
return (double)k;
}
ENDVERBATIM
:* PIVOTA.join(PIVOTB,VECLISTA,VECLISTB)
: NB must sort both pivots before use
VERBATIM
static double join (void* vv) {
int i, j, k, m, p, q, maxsz, npiva, npivb, av[VRRY], bv[VRRY], num, numb, indflag, match;
Object *ob, *ob2;
double *piva, *pivb, *avo[VRRY], *bvo[VRRY], val[VRRY];
IvocVect *vva[VRRY],*vvb[VRRY];
npiva = vector_instance_px((IvocVect*)vv, &piva);
npivb = vector_arg_px(1, &pivb);
ob = *hoc_objgetarg(2);
ob2 = *hoc_objgetarg(3);
num = ivoc_list_count(ob);
numb = ivoc_list_count(ob2);
if (num>VRRY) hoc_execerror("join ****ERRA****: can only handle VRRY vectors", 0);
if (num!=numb) hoc_execerror("join ****ERRB****: different #of vecs in lists", 0);
for (i=0;i<num;i++) {
av[i]=list_vector_px2(ob, i, &avo[i], &vva[i]);
if (av[0]!=av[i]) { printf("join ****ERRC**** %d %d %d\n",i,av[0],av[i]);
hoc_execerror("Vectors must all be same size: ", 0); }
}
for (i=0;i<numb;i++) {
bv[i]=list_vector_px2(ob2, i, &bvo[i], &vvb[i]);
if (bv[0]!=bv[i]) { printf("join ****ERRC2**** %d %d %d\n",i,bv[0],bv[i]);
hoc_execerror("Vectors must all be same size: ", 0); }
}
for (i=0,j=0;i<npiva;i++) {
for (;piva[i]!=pivb[j] && j<npivb;j++); // move forward to find matching pivb[j]
if (j==npivb) { printf("%g not found in PivotB\n",piva[i]);hxe();}
for (k=0;k<num;k++) avo[k][i]=bvo[k][j];
}
return (double)k;
}
ENDVERBATIM
:* vscl() will scale a vector to -1,1
VERBATIM
static double vscl (double *x, double n) {
int i;
double max,min,r,sf,b,a;
max=-1e9; min=1e9; a=-1; b=1;
for (i=0;i<n;i++) {
if (x[i]>max) max=x[i];
if (x[i]<min) min=x[i];
}
r=max-min; // range
sf = (b-a)/r; // scaling factor
for (i=0;i<n;i++) x[i]=(x[i]-min)*sf+a;
return 0;
}
ENDVERBATIM
:* vdest.scl(vsrc) nondestructive scaling
VERBATIM
static double scl (void* vv) {
int i, j, k, nx, nsrc, nfilt, ntmp;
double *x, *src, *filt, *tmp, sum, lpad, rpad;
nx = vector_instance_px(vv, &x);
nsrc = vector_arg_px(1, &src);
if (nx!=nsrc) { hoc_execerror("scl:Vectors not same size: ", 0); }
for (i=0;i<nx;i++) x[i]=src[i];
vscl(x,nx);
return 0;
}
ENDVERBATIM
:* vdest.sccvlv(vsrc,vfilt,tmp) // NOT CORRECT -- see scxing()
: scaled convolution -- scale section to -1,1 before multiplying by filter
VERBATIM
static double sccvlv (void* vv) {
int i, j, k, nx, nsrc, nfilt, ntmp;
double *x, *src, *filt, *tmp, sum, lpad, rpad;
nx = vector_instance_px(vv, &x);
nsrc = vector_arg_px(1, &src);
nfilt = vector_arg_px(2, &filt);
ntmp = vector_arg_px(3, &tmp);
if (nx!=nsrc) { hoc_execerror("sccvlv:Vectors not same size: ", 0); }
if (nfilt>nsrc) { hoc_execerror("sccvlv:Filter bigger than source ", 0); }
if (nfilt!=ntmp){hoc_execerror("sccvlv:Filter (arg2) and tmp vector (arg3) diff size", 0);}
for (i=0;i<nx;i++) {
x[i]=0.0;
for (j=0,k=i-(int)(nfilt/2);j<nfilt&&k>0&&k<nsrc;j++,k++) tmp[j]=src[k];
vscl(tmp,j-1);
for (k=0;k<j;k++) x[i]+=filt[k]*tmp[k];
}
return 0;
}
ENDVERBATIM
:* vdest.scxing(vsrc,tmp)
: scaled xing -- scale each section to -1,1 before checking # of 0-xing's
VERBATIM
static double scxing (void* vv) {
int i, j, k, nx, nsrc, f, ntmp, maxsz;
double *x, *src, *filt, *tmp, sum, maxsum, th;
nx = vector_instance_px(vv, &x);
nsrc = vector_arg_px(1, &src);
ntmp = vector_arg_px(2, &tmp);
if (nx!=nsrc) { hoc_execerror("scxing:Vectors not same size: ", 0); }
th=0.0;
maxsum=-1e9;
for (i=0;i<nx;i++) x[i]=0.; // clear
for (i=ntmp/2+1;i<nx-ntmp/2-1;i++) {
for (j=0,k=i-(int)(ntmp/2);j<ntmp;k++,j++) tmp[j]=src[k];
vscl(tmp,j-1); // scale from -1 to 1
for (k=0,f=0,sum=0.; k<nsrc; k++) {
if (tmp[k]>th) { // ? passing thresh
if (f==0) {
sum+=1; // just count the 0xing
f=1;
}
} else { // below thresh
if (f==1) {
f=0; // just passed going down
sum+=1;
}
}
}
if (sum>maxsum) maxsum=sum;
x[i]=sum;
}
return (double)maxsum;
}
ENDVERBATIM
:* vdest.cvlv(vsrc,vfilt)
: convolution
VERBATIM
static double cvlv (void* vv) {
int i, j, k, nx, nsrc, nfilt;
double *x, *src, *filt, sum, lpad, rpad;
nx = vector_instance_px(vv, &x);
nsrc = vector_arg_px(1, &src);
nfilt = vector_arg_px(2, &filt);
if (nx!=nsrc) { hoc_execerror("Vectors not same size: ", 0); }
if (nfilt>nsrc) { hoc_execerror("Filter bigger than source ", 0); }
for (i=0;i<nx;i++) {
x[i]=0.0;
for (j=0,k=i-(int)(nfilt/2);j<nfilt;j++,k++) {
if (k>0 && k<nsrc-1) x[i]+=filt[j]*src[k];
}
}
return 0;
}
ENDVERBATIM
:* vdest.intrp(flag)
: interpolate numbers replacing numbers given as flag
VERBATIM
static double intrp (void* vv) {
int i, la, lb, nx;
double *x, fl, a, b;
nx = vector_instance_px(vv, &x);
fl = *getarg(1);
i=0; a=x[0]; la=0;
if (a==fl) a=0;
while (i<nx-1) {
for (i=la+1;x[i]==fl && i<nx-1; i++) ; // find the next one
b=x[i]; lb=i;
for (i=la+1; i<lb; i++) x[i]= a + (b-a)/(lb-la)*(i-la);
a=b; la=lb;
}
return (double)fl;
}
ENDVERBATIM
:* vec.sumabs()
: return sum of abs values
VERBATIM
static double sumabs (void* vv) {
int i, nx;
double *x, sum;
nx = vector_instance_px(vv, &x);
for (sum=0,i=0;i<nx; i++) sum+=fabs(x[i]);
return sum;
}
ENDVERBATIM
:* vec.inv([NUMERATOR])
: element=NUMERATOR/element
VERBATIM
static double inv (void* vv) {
int i, nx;
double *x, nume;
nx = vector_instance_px(vv, &x);
if (ifarg(1)) nume=*getarg(1); else nume=1.;
for (i=0;i<nx; i++) x[i]=nume/x[i];
return (double)i;
}
ENDVERBATIM
:* tmp.nind(ind,vec1,vec2[,vec3,vec4,...])
: picks out numbers not in ind from multiple vectors
: ind must be sorted
VERBATIM
static double nind (void* vv) {
int i, j, k, m, nx, ni, nv[VRRY], num, c, last;
double *x, *ind, *vvo[VRRY];
nx = vector_instance_px(vv, &x);
for (i=0;ifarg(i);i++);
if (i>VRRY) hoc_execerror("ERR: nind can only handle VRRY vectors", 0);
num = i-2; // number of vectors to be picked apart
for (i=0;i<num;i++) {
nv[i] = vector_arg_px(i+2, &vvo[i]);
if (nx!=nv[i]) { printf("nind ERR %d %d %d\n",i,nx,nv[i]);
hoc_execerror("Vectors must all be same size: ", 0); }
}
ni = vector_arg_px(1, &ind);
c = nx-ni; // the elems indexed are to be eliminated
if (ni>scrsz) {
if (scrsz>0) { free(scr); scr=(unsigned int *)NULL; }
scrsz=ni+10000;
scr=(unsigned int *)ecalloc(scrsz, sizeof(int));
}
for (i=0,last=-1;i<ni;i++) {
scr[i]=(int)ind[i]; // copy into integer array
if (scr[i]<0 || scr[i]>=nx) hoc_execerror("nind(): Index out of bounds", 0);
if (scr[i]<=last) hoc_execerror("nind(): indices should mono increase", 0);
last=scr[i];
}
for (j=0;j<num;j++) { // each output vec
for (i=0,last=-1,m=0;i<ni;i++) { // the indices of ind
for (k=last+1;k<scr[i];k++) { x[m++]=vvo[j][k]; }
last=scr[i];
}
for (k=last+1;k<nx;k++,m++) { x[m]=vvo[j][k]; }
for (i=0;i<c;i++) vvo[j][i]=x[i];
vv=vector_arg(j+2); vector_resize((IvocVect*)vv, c);
}
return c;
}
ENDVERBATIM
:* ind.keyind(key,vec1,vec2[,vec3,vec4,...])
: picks out indices of numbers in key from multiple vectors
VERBATIM
static double keyind (void* vv) {
int i, j, k, ni, nk, nv[VRRY], num;
double *ind, *key, *vvo[VRRY];
ni = vector_instance_px(vv, &ind); // vv is ind
for (i=0;ifarg(i);i++) {} i--; // drop back by one to get numarg()
if (i>VRRY) hoc_execerror("ERR: keyind can only handle VRRY vectors", 0);
num = i-1; // number of vectors to be picked apart
for (i=0;i<num;i++) {
nv[i] = vector_arg_px(i+2, &vvo[i]);
if (ni!=nv[i]) { printf("keyind ERR %d %d %d\n",i,ni,nv[i]);
hoc_execerror("Non-key vectors must be same size: ", 0); }
}
nk = vector_arg_px(1, &key);
if (nk!=num) { printf("keyind ERR2 %d %d\n",nk,num);
hoc_execerror("Key length must be number of vecs",0); }
k=0;
for (j=0;j<ni;j++) { // j steps through elements of vectors
for (i=0;i<nk;i++) { // i steps through the key
if (key[i]==ALL) continue; // OK - do nothing
if (key[i]==NOZ) { if (vvo[i][j]==0.) break; else continue;
} else if (key[i]==POS) { if (vvo[i][j]<=0.) break; else continue;
} else if (key[i]==NEG) { if (vvo[i][j]>=0.) break; else continue;
} else if (key[i]!=vvo[i][j]) break; // default
}
if (i==nk) ind[k++]=j; // all equal
}
vector_resize((IvocVect*)vv, k);
return (double)k;
}
ENDVERBATIM
:* v1.thresh() threshold above and below thresh
VERBATIM
static double thresh (void* vv) {
int i, nx, ny, cnt;
double *x, *y, th;
nx = vector_instance_px(vv, &x);
cnt=0;
if (hoc_is_object_arg(1)) {
ny = vector_arg_px(1, &y); th=0;
if (nx!=ny) { hoc_execerror("Vector sizes don't match in thresh.", 0); }
for (i=0; i<nx; i++) { if (x[i]>=y[i]) { x[i]= 1.; cnt++;} else { x[i]= BVBASE; } }
} else { th = *getarg(1);
for (i=0; i<nx; i++) { if (x[i] >= th) { x[i]= 1.; cnt++;} else { x[i]= BVBASE; } }
}
return cnt;
}
ENDVERBATIM
:* v1.nearall(max,v2,tql)
: tql from {tq=new NQS("diff","tmid","t1","t2") tq.listvecs(tql)}
: max is maximum diff to add to the tq db
VERBATIM
static double nearall (void* vv) {
int lo, hi, mid;
int i, j, k, kk, nx, ny, minind, nv[4];
Object *ob;
IvocVect* vvl[4];
double *x, *y, *vvo[4], targ, dist, new_, max_, tmp;
nx = vector_instance_px(vv, &x);
max_ = *getarg(1);
ny = vector_arg_px(2, &y);
ob = *hoc_objgetarg(3);
if ((nv[0]=ivoc_list_count(ob))!=4) {printf("VECST::nearall() ERRA: %d\n",nv[0]); hxe();}
for (i=0;i<4;i++) { nv[i] = list_vector_px3(ob, i, &vvo[i], &vvl[i]);
if (nv[i]!=nv[0]){printf("nearall ERRC: %d %d\n",nv[i],nv[0]); hxe();}
}
for (j=0,k=0;j<ny;j++) {
targ=y[j];
lo=0; hi=nx-1; mid=lo; // binary search from K&R Ch. 6, p. 125
while (lo<=hi) {
mid = (hi+lo)/2;
if ((tmp=x[mid]-targ)>0.) hi=mid-1; else if (tmp<0) lo=mid+1; else break;
}
dist=fabs(x[mid]-targ); minind=mid;
for (i=-1;i<=1;i+=2) { kk=mid+i; // check the flanking values
if (kk>0 && kk<nx && (new_=fabs(x[kk]-targ))<dist) {
dist=new_;
minind=kk;
}
}
if (dist<=max_) {
if (k>=nv[1]) { printf("nearall WARN: oor %d %d\n",k,nv[1]); return -1.; }
vvo[0][k]=dist; vvo[2][k]=targ; vvo[3][k]=x[minind];
k++;
}
}
if (k>scrsz) {
if (scrsz>0) { free(scr); scr=(unsigned int *)NULL; }
scrsz=k+10000;
scr=(unsigned int *)ecalloc(scrsz, sizeof(int));
}
for (kk=0,i=0;i<k;) {
dist=vvo[0][i]; targ=vvo[3][i]; // value from x[]
for (minind=i,j=i+1;vvo[3][j]==targ;j++) {
if (vvo[0][j]<dist) { minind=j; dist=vvo[0][j]; } // find the closest of these
}
i=j;
scr[kk++]=minind;
}
for (i=0;i<kk;i++) {
vvo[0][i]=vvo[0][scr[i]];
vvo[1][i]=(vvo[2][scr[i]]+vvo[3][scr[i]])/2.;
vvo[2][i]=vvo[2][scr[i]];
vvo[3][i]=vvo[3][scr[i]];
}
for (i=0;i<4;i++) vector_resize(vvl[i],kk);
return (double)kk;
}
ENDVERBATIM
:* v1.nearest(val,&dist) value of v1 nearest to val, returns index and optional dist
VERBATIM
static double nearest (void* vv) {
int i, nx, minind, flag=0;
double *x, targ, dist, new_, *to;
nx = vector_instance_px(vv, &x);
targ = *getarg(1);
if (ifarg(3)) flag = (int)*getarg(3);
dist = 1e9;
for (i=0; i<nx; i++) if ((new_=fabs(x[i]-targ))<dist) {
if (flag && new_==0) continue; // flag signals to not pick self
dist=new_;
minind=i;
}
if (ifarg(2)) *(hoc_pgetarg(2)) = dist;
return (double)minind;
}
ENDVERBATIM
:* v1.approx(v2,epsilon) -- like .eq but looser -- good when have saved and restored a vec
VERBATIM
static double approx (void* vv) {
int i, j, nx, ny;
double *x, *y, epsilon;
nx = vector_instance_px(vv, &x);
ny = vector_arg_px(1, &y);
if (nx!=ny) { printf("approx different size vectors %d %d\n",nx,ny); return 0; }
epsilon = (ifarg(2)?*getarg(2):LOOSE);
for (i=0; i<nx; i++) if (x[i]<y[i]-epsilon || x[i]>y[i]+epsilon) return 0;
return 1;
}
ENDVERBATIM
:* v1.samp(VEC,rate) does something like a resample
VERBATIM
//linear interpolation
static double samp (void* vv) {
int i, nx, cnt, iOrigSz, maxsz, iNewSz, isrcidx,isrcidx1;
double *x, *y, dNewSz, scale, dsrcidx, frac;
nx = vector_instance_px(vv, &x); // dest
iOrigSz = vector_arg_px(1, &y); // source
dNewSz = *getarg(2); // new size
maxsz=vector_buffer_size((IvocVect*)vv);
iNewSz = (int)dNewSz;
if (iNewSz>maxsz) {printf("VECST samp ERRA: dest vec too small: %d %d\n",iNewSz,maxsz); hxe();}
vector_resize((IvocVect*)vv,iNewSz);
scale = (double) iOrigSz / (double) iNewSz;
for(i=0;i<iNewSz;i++){
dsrcidx = i * scale;
isrcidx = (int) dsrcidx;
isrcidx1 = isrcidx+1 < iOrigSz-1 ? isrcidx+1 : iOrigSz-1;
frac = dsrcidx - isrcidx;
x[i] = (1-frac) * y[isrcidx] + frac * y[isrcidx1];
}
return iNewSz;
}
ENDVERBATIM
:* v1.triplet() return location of a triplet
VERBATIM
static double triplet (void* vv) {
int i, nx;
double *x, *y, a, b;
nx = vector_instance_px(vv, &x);
a = *getarg(1); b = *getarg(2);
for (i=0; i<nx; i+=3) if (x[i]==a&&x[i+1]==b) break;
if (i<nx) return (double)i; else return -1.;
}
ENDVERBATIM
:* state.onoff(volts,OBon,thresh,dur,refr)
: looks at volts vector to decide if have reached threshold thresh
: OBon takes account of burst dur and refractory period
VERBATIM
static double onoff (void* vv) {
int i, j, n, nv, non, nt, nd, nr, num;
double *st, *vol, *obon, *thr, *dur, *refr;
n = vector_instance_px(vv, &st);
nv = vector_arg_px(1, &vol);
non = vector_arg_px(2, &obon);
nt = vector_arg_px(3, &thr);
nd = vector_arg_px(4, &dur);
nr = vector_arg_px(5, &refr);
if (n!=nv||n!=non||n!=nt||n!=nd||n!=nr) {
hoc_execerror("v.onoff: vectors not all same size", 0); }
for (i=0,num=0;i<n;i++) {
obon[i]--;
if (obon[i]>0.) { st[i]=1.; continue; } // cell must fire
if (vol[i]>=thr[i] && obon[i]<= -refr[i]) { // past refractory period
st[i]=1.; obon[i]=dur[i]; num++;
} else { st[i]= BVBASE; }
}
return (double)num;
}
ENDVERBATIM
:* vo.bpeval(outp,del)
: service routine for back-prop: vo=outp*(1-outp)*del
VERBATIM
static double bpeval (void* vv) {
int i, n, no, nd, flag=0;
double add,div;
double *vo, *outp, *del;
n = vector_instance_px(vv, &vo);
no = vector_arg_px(1, &outp);
nd = vector_arg_px(2, &del);
if (ifarg(3) && ifarg(4)) { add= *getarg(3); div= *getarg(4); flag=1;}
if (n!=no||n!=nd) hoc_execerror("v.bpeval: vectors not all same size", 0);
if (flag) {
for (i=0;i<n;i++) vo[i]=((outp[i]+add)/div)*(1.-1.*((outp[i]+add)/div))*del[i];
} else {
for (i=0;i<n;i++) vo[i]=outp[i]*(1.-1.*outp[i])*del[i];
}
return 0;
}
ENDVERBATIM
:* v1.sedit() string edit
VERBATIM
static double sedit (void* vv) {
int i, n, ni, f=0;
double *x, *ind, th, val;
Symbol* s; char *op;
op = gargstr(1);
n = vector_instance_px(vv, &x);
sprintf(op,"hello world");
return (double)n;
}
ENDVERBATIM
:* v1.w() a .where that sets elements in source vector
VERBATIM
static double w (void* vv) {
int i, n, ni, c, f;
double *x, *ind, th, val;
Symbol* s; char *op;
if (! ifarg(1)) {
printf("v1.w('op',thresh[,val,v2])\n");
printf(" a .where that sets elements in v1 to val (default 0), if v2 => only look at these elements\n");
printf(" 'op'=='function name' is a .apply targeted by v2 called as func(x[i],thresh,val)\n");
return -1.;
}
op = gargstr(1);
n = vector_instance_px(vv, &x);
th = *getarg(2);
f=c=0;
if (ifarg(3)) { val = *getarg(3); } else { val = 0.0; }
if (ifarg(4)) {ni = vector_arg_px(4, &ind); f=1;} // just look at the spots indexed
if (!strcmp(op,"==")) {
if (f==1) {for (i=0; i<ni;i++) {if (x[(int)ind[i]]==th) { x[(int)ind[i]]=val;c++;}}
} else {for (i=0; i<n; i++) {if (x[i]==th) { x[i]=val;c++;}}}
} else if (!strcmp(op,"!=")) {
if (f==1) {for (i=0; i<ni;i++) {if (x[(int)ind[i]]!=th) { x[(int)ind[i]]=val;c++;}}
} else {for (i=0; i<n; i++) {if (x[i]!=th) { x[i]=val;c++;}}}
} else if (!strcmp(op,">")) {
if (f==1) {for (i=0; i<ni;i++) {if (x[(int)ind[i]]>th) { x[(int)ind[i]]=val;c++;}}
} else {for (i=0; i<n; i++) {if (x[i]>th) { x[i]=val;c++;}}}
} else if (!strcmp(op,"<")) {
if (f==1) {for (i=0; i<ni;i++) {if (x[(int)ind[i]]<th) { x[(int)ind[i]]=val;c++;}}
} else {for (i=0; i<n; i++) {if (x[i]<th) { x[i]=val;c++;}}}
} else if (!strcmp(op,">=")) {
if (f==1) {for (i=0; i<ni;i++) {if (x[(int)ind[i]]>=th) { x[(int)ind[i]]=val;c++;}}
} else {for (i=0; i<n; i++) {if (x[i]>=th) { x[i]=val;c++;}}}
} else if (!strcmp(op,"<=")) {
if (f==1) {for (i=0; i<ni;i++) {if (x[(int)ind[i]]<=th) { x[(int)ind[i]]=val;c++;}}
} else {for (i=0; i<n; i++) {if (x[i]<=th) { x[i]=val;c++;}}}
} else if ((s=hoc_lookup(op))) { // same as .apply but only does indexed ones
if (f==1) {for (i=0; i<ni;i++) {
hoc_pushx(x[(int)ind[i]]); hoc_pushx(th); hoc_pushx(val);
x[(int)ind[i]]=hoc_call_func(s, 3);}
} else {for (i=0; i<n;i++) {hoc_pushx(x[i]); hoc_pushx(th); hoc_pushx(val);
x[i]=hoc_call_func(s, 3);}}
}
return (double)c;
}
ENDVERBATIM
:* ind.slone(SRC,VAL) select indices where ==VAL from sorted vector SRC
VERBATIM
static double slone (void* vv) {
int i, j, n, ni, nsrc, maxsz;
double *x, *src, val, max, min;
n = vector_instance_px(vv, &x);
maxsz=vector_buffer_size((IvocVect*)vv); vector_resize((IvocVect*)vv, maxsz);
nsrc = vector_arg_px(1, &src);
val = *getarg(2);
if (ifarg(3)) ni=(int)*getarg(3); else {
min=src[0]; max=src[nsrc-1];
ni=(int)(val-min)/(max-min)*(double)(nsrc-1); // where expect to find it
}
if (src[ni]<val) {
for (i=ni;src[i]!=val&&i<nsrc;i++);
} else {
for (i=ni;src[i]!=val&&i>=0;i--);
for ( ;src[i]==val&&i>=0;i--);
i++; // go back to the first one
}
for (j=0;src[i]==val && j<maxsz && i<nsrc;i++,j++) x[j]=i;
if (j==maxsz) printf("vecst slone WARN: OOR %d %d\n",j,maxsz);
vector_resize((IvocVect*)vv, j);
return (double)(i-1);
}
ENDVERBATIM
:* dest.xing(src,tvec,thresh)
: dest.xing(src,thresh) -- returns indices, change into time by .mul(tstep)
: dest.xing(src) -- default thresh=0; returns indices
: a .where that looks for threshold crossings and then doesn't pick another till
: comes back down again; places values from tvec in dest; interpolates with INTERP_VECST set
VERBATIM
static double xing (void* vv) {
int i, j, d2f, nsrc, ndest, ntvec, f, maxsz, tvf;
double *src, *dest, *dest2, *tvec, th;
th=0.; tvf=0; // tvf==1: tvec being used
ndest = vector_instance_px(vv, &dest);
nsrc = vector_arg_px(1, &src);
i=2;
if (ifarg(i)) {
if (hoc_is_double_arg(i)) th=*getarg(i); else {ntvec=vector_arg_px(i, &tvec); tvf=1;}
i++;
if (ifarg(i) && hoc_is_double_arg(i)) th=*getarg(i++);
}
maxsz=vector_buffer_size((IvocVect*)vv);
vector_resize((IvocVect*)vv, maxsz);
if (ifarg(i)){dest2=vector_newsize(vector_arg(i),maxsz); d2f=i;} else d2f=0;
if (tvf && nsrc!=ntvec) hoc_execerror("v.xing: vectors not all same size", 0);
for (i=0,f=0,j=0; i<nsrc; i++) {
if (src[i]>th) { // ? passing thresh
if (f==0) {
if (j>=maxsz) {
printf("(%d) :: ",maxsz);
hoc_execerror("Dest vec too small in xing ", 0);
}
if (i>0) { // don't record if first value is above thresh
if (INTERP_VECST) {
if (tvf) {
dest[j++] = tvec[i-1] + (tvec[i]-tvec[i-1])*(th-src[i-1])/(src[i]-src[i-1]);
} else {
dest[j++] = (i-1) + (th-src[i-1])/(src[i]-src[i-1]);
}
} else {
if (tvf) dest[j++]=tvec[i]; else dest[j++]=i;
}
}
f=1;
}
} else { // below thresh
if (f==1) { f=0; } // just passed going down
if (d2f) {
if (INTERP_VECST) {
if (tvf) {
dest2[j++] = tvec[i-1] + (tvec[i]-tvec[i-1])*(th-src[i-1])/(src[i]-src[i-1]);
} else {
dest2[j++] = (i-1) + (th-src[i-1])/(src[i]-src[i-1]);
}
} else {
if (tvf) dest2[j++]=tvec[i]; else dest2[j++]=i;
}
}
}
}
vector_resize((IvocVect*)vv, j);
if (d2f) vector_resize((IvocVect*)vector_arg(d2f),j);
return (double)j;
}
ENDVERBATIM
:* dest.snap(src,tvec,dt)
: interpolate src with tvec to prior dt step, saves only highest value in each interval
: an .interpolate that doesn't loose spikes
VERBATIM
static double snap (void* vv) {
int i, j, nsrc, ndest, ntvec, f, maxsz, size;
double *src, *dest, *tvec, mdt, tstop, tt, val;
ndest = vector_instance_px(vv, &dest);
nsrc = vector_arg_px(1, &src);
ntvec = vector_arg_px(2, &tvec);
mdt = *getarg(3);
maxsz=vector_buffer_size((IvocVect*)vv);
tstop = tvec[nsrc-1];
size=(int)tstop/mdt;
if (size>maxsz) {
printf("%d > %d\n",size,maxsz);
hoc_execerror("v.snap: insufficient room in dest", 0); }
vector_resize((IvocVect*)vv, size);
if (nsrc!=ntvec) hoc_execerror("v.snap: src and tvec not same size", 0);
for (tt=0,i=0;i<size && tt<=tvec[0];i++,tt+=mdt) dest[i]=src[0];
for (j=1, i--, tt-=mdt; i<size; i++, val=-1e9, tt+=mdt) {
if (tvec[j]>tt) dest[i]=src[j-1]; else {
for (;j<nsrc && tvec[j]<=tt;j++) if (src[j]>val) val=src[j];
if (val==-1e9) printf("vecst:snap() internal ERROR\n");
dest[i]=val;
}
}
return (double)size;
}
ENDVERBATIM
:* v1.xzero() looks for zero crossings
VERBATIM
static double xzero (void* vv) {
int i, n, nv, up;
double *x, *vc, th, cnt=0.;
n = vector_instance_px(vv, &x);
nv = vector_arg_px(1, &vc);
if (ifarg(2)) { th = *getarg(2); } else { th=0.0;}
if (vc[0]<th) up=0; else up=1; // F or T
if (nv!=n) hoc_execerror("Vector size doesn't match.", 0);
for (i=0; i<nv; i++) {
x[i]=0.;
if (up) { // look for passing down
if (vc[i]<th) { x[i]=-1; up=0; cnt++; }
} else if (vc[i]>th) { up=x[i]=1; cnt++; }
}
return cnt;
}
ENDVERBATIM
:* v1.negwrap([FLAG]) wrap neg values to pos, FLAG==0 set them to 0, FLAG!=0 wrap
: above FLAG
VERBATIM
static double negwrap (void* vv) {
int i, n;
double *x, cnt, sig;
n = vector_instance_px(vv, &x);
if (ifarg(1)) sig = (int)*getarg(1); else sig=1e9; // default: do wrap
if (sig==0.) {
for (i=0,cnt=0; i<n; i++) if (x[i]<0) {
x[i]=0.;
cnt++;
}
} else if (sig==1e9) {
for (i=0,cnt=0; i<n; i++) if (x[i]<0) {
x[i]=-x[i];
cnt++;
}
} else {
for (i=0,cnt=0; i<n; i++) if (x[i]<sig) {
x[i]=2*sig-x[i]; // sig+(sig-x[i]) wraps around sig
cnt++;
}
}
return cnt;
}
ENDVERBATIM
:* v1.sw(FROM,TO) switchs all FROMs to TO
VERBATIM
static double sw (void* vv) {
int i, n;
double *x, fr, to;
n = vector_instance_px(vv, &x);
fr = *getarg(1);
to = *getarg(2);
for (i=0; i<n; i++) {
if (x[i]==fr) { x[i] = to;}
}
return (double)n;
}
ENDVERBATIM
:* v.b2v(bytevec) copies from vector to bytevec
VERBATIM
static double b2v (void* vv) {
int i, n, num;
double *x; bvec* to; Object *ob;
n = vector_instance_px(vv, &x);
ob = *(hoc_objgetarg(1));
to = (bvec*)ob->u.this_pointer; // doesn't check that this is actually a bvec
if (to->size!=n) { hoc_execerror("Vector and bytevec sizes don't match.", 0); }
for (i=0; i<n; i++) x[i] = (double)to->x[i];
return (double)n;
}
ENDVERBATIM
:* v.v2d(&x) copies from vector to double area -- a seg error waiting to happen
VERBATIM
static double v2d (void* vv) {
int i, n, num;
double *x, *to;
n = vector_instance_px(vv, &x);
to = hoc_pgetarg(1);
if (ifarg(2)) { num = *getarg(2); } else { num=-1;}
if (num>-1 && num!=n) { hoc_execerror("Vector size doesn't match.", 0); }
for (i=0; i<n; i++) {to[i] = x[i];}
return (double)n;
}
ENDVERBATIM
:* v.v2p(&x0[,&x1,&x2...]) copies from vector or vectors to doubles
VERBATIM
static double v2p (void* vv) {
int i, j, n, cnt;
double *x;
n = vector_instance_px(vv, &x);
for (i=0,j=1,cnt=0;ifarg(j) && i<n;i++,j++) {
if (hoc_is_double_arg(j)) continue; // skip this one
*hoc_pgetarg(j)=x[i];
cnt++;
}
return (double)cnt;
}
ENDVERBATIM
:* v.l2p(veclist,index,[&x0,&x1,&x2...]) copies from list of vectors to vector and doubles
VERBATIM
static double l2p (void* vv) {
int ix, i, j, n, num, cnt;
double *x, *y; Object* lob;
n = vector_instance_px((IvocVect*)vv, &x);
lob = *hoc_objgetarg(1);
ix=(int)*getarg(2);
num = ivoc_list_count(lob);
x=vector_newsize((IvocVect*)vv,num);
for (i=0;i<num;i++) { // pick up vectors
cnt = list_vector_px(lob, i, &y);
if (ix>=cnt) {printf("vecst:l2p() ERRA: %d %d %d\n",i,ix,cnt); hxe();}
x[i]=y[ix];
}
for (i=0,j=3,cnt=0;ifarg(j) && i<num;i++,j++) {
if (hoc_is_double_arg(j)) continue; // skip this one
*hoc_pgetarg(j)=x[i];
cnt++;
}
return (double)cnt;
}
ENDVERBATIM
:* v.fetch(val,list,vec) fetches first eg NQS row where v holds val
:* v.fetch(val,list,&x0[,&x1,&x2...])
VERBATIM
static double fetch (void* vv) {
int ix, i, j, n, ny, cnt;
double *x, *y, val, ret; ListVec* pL;
n = vector_instance_px(vv, &x);
val = *getarg(1);
pL = AllocListVec(*hoc_objgetarg(2));
for (ix=0;ix<n;ix++) if (x[ix]==val) break;
if (ix==n) {if (VERBOSE_VECST) printf("vecst:fetch() WARNING: %g not found\n",val); return ERR;}
if (hoc_is_object_arg(3)) {
ny = vector_arg_px(3, &y);
if (ny>pL->isz) vector_resize((IvocVect*)vector_arg(3),pL->isz); // don't make bigger if only want a few
for (i=0,j=0,cnt=0;i<pL->isz && j<ny;i++,j++) {
if (ix>pL->plen[i]) {printf("vecst:fetch()ERRB: %d %d %x\n",i,ix,pL->pv[i]);
FreeListVec(&pL); hxe();}
y[j]=pL->pv[i][ix];
cnt++;
}
ret=y[j-1]; // final value
} else {
for (i=0,j=3,cnt=0;i<pL->isz && ifarg(j);i++,j++) {
if (hoc_is_double_arg(j)) continue; // skip this one
if (ix>pL->plen[i]) {printf("vecst:fetch()ERRB1: %d %d %x\n",i,ix,pL->pv[i]);
FreeListVec(&pL); hxe();}
*hoc_pgetarg(j)=ret=pL->pv[i][ix];
cnt++;
}
}
FreeListVec(&pL);
return ret;
}
ENDVERBATIM
:* v.covar(list,vec) generates covariance matrix in vec form
: generally data are in the columns; here data are in the vectors -- ie as if in the rows
VERBATIM
static double covar (void* vv) {
int ix, i, j, j2, n, m;
double *x, *y, *mean; ListVec* pL;
n = vector_instance_px(vv, &x); // number of data vectors
if (n==0) { pL = AllocListVec(*hoc_objgetarg(1)); // get all of them
} else pL = AllocILV(*hoc_objgetarg(1),n,x);
if (pL->isz<2) {printf("vecst:covar()ERRA: %d\n",pL->isz); FreeListVec(&pL); hxe();}
n=pL->isz; // number of data points
m=pL->plen[0]; // dimensionality of data
for (i=1;i<pL->isz;i++) if (m!=pL->plen[i]) {
printf("vecst:covar()ERRB: sz mismatch %d %d@%d\n",m,pL->plen[i],i);FreeListVec(&pL);hxe();}
y=vector_newsize(vector_arg(2),m*m);
// pL->pv[i][j] -- i goes through the list and j goes through each vector
mean=(double*)malloc(sizeof(double)*m);
for (j=0;j<m;j++) { // Determine means of column vectors of input data matrix
for (i=0,mean[j]=0.;i<n;i++) mean[j]+=pL->pv[i][j];
mean[j]/=(double)n;
}
for (i=0;i<n;i++) for (j=0;j<m;j++) pL->pv[i][j] -= mean[j]; // center the vectors
for (j=0;j<m;j++) for (j2=j;j2<m;j2++) { // Calculate the m*m covariance matrix
for (i=0,y[j*m+j2]=0.;i<n;i++) y[j*m+j2]+=pL->pv[i][j]*pL->pv[i][j2];
y[j*m+j2]/=(n-1);
y[j2*m+j]=y[j*m+j2];
}
for (i=0;i<n;i++) for (j=0;j<m;j++) pL->pv[i][j] += mean[j]; // restore vectors
free(mean);
FreeListVec(&pL);
return m;
}
ENDVERBATIM
:* ind.vlxpose(src_list,dest_list) does 'transpose'
VERBATIM
static double vlxpose (void* vv) {
int i, j, k, n, c, c2, sz, err;
double *x; ListVec *pL, *pL2; Object* obl;
err=0;
n = vector_instance_px(vv, &x); // vector of indices
if (n==0) { pL = AllocListVec(*hoc_objgetarg(1)); // get all of them
} else pL = AllocILV(*hoc_objgetarg(1),n,x);
pL2 = AllocListVec(obl=*hoc_objgetarg(2));
c=pL->isz; c2=pL2->isz; // number of columns (list length)
// pL->pv[i][j] -- i goes through the list and j goes through each vector
for (j=0;j<c;j++) list_vector_resize(obl,j,pL2->pbuflen[j]);
n=pL->plen[0]; // length of vector
if (n!=c2) err=1;
for (j=1;j<c;j++) if (n!=pL->plen[j] || err) {
printf("vecst:vlxpose()ERRA: %d %d %d\n",n,pL->plen[j],c2);
FreeListVec(&pL); FreeListVec(&pL2); hxe(); }
for (j=0,k=0;j<c;j++,k++) for (i=0;i<c2;i++) {
if (k>=pL2->pbuflen[i]) { sz=pL2->pbuflen[i]; // need to grow vector
sz=(sz<10)?100:(sz*2);
pL2->pv[i]=list_vector_resize(obl, i, pL2->pbuflen[i]=sz);
}
pL2->pv[i][k]=pL->pv[j][i];
}
for (j=0;j<c2;j++) list_vector_resize(obl,j,k);
FreeListVec(&pL); FreeListVec(&pL2);
return (double)n;
}
ENDVERBATIM
:* ind.ixsort(vec,list) does list.o(ind.x[i]).append(vec.x[i])
VERBATIM
static double ixsort (void* vv) {
int i, j, n, ntv, c;
double *x, *tv; ListVec* pL; Object* obl;
n = vector_instance_px(vv, &x); // vector of indices
ntv = vector_arg_px(1, &tv);
if (ntv!=n) {printf("vecst:ixsort()ERR0: diff size %d %d\n",n,ntv); hxe();}
pL = AllocListVec(obl=*hoc_objgetarg(2));
if (pL->isz<2) {printf("vecst:ixsort()ERRA: %d\n",pL->isz); FreeListVec(&pL); hxe();}
c=pL->isz; // number of columns (list length)
// pL->pv[i][j] -- i goes through the list and j goes through each vector
for (j=0;j<c;j++) list_vector_resize(obl, j, pL->pbuflen[j]);
for (j=0;j<n;j++) {
i=x[j];
if (i>=c) {printf("vecst:ixsort()ERRB: OOB %d %d\n",i,c); FreeListVec(&pL); hxe();}
if (pL->plen[i]>=pL->pbuflen[i]) {
if (pL->pbuflen[i]) pL->pbuflen[i]*=2; else pL->pbuflen[i]=100;
pL->pv[i]=list_vector_resize(obl, i, pL->pbuflen[i]);
}
pL->pv[i][pL->plen[i]++]=tv[j];
}
for (j=0;j<c;j++) list_vector_resize(obl, j, pL->plen[j]);
FreeListVec(&pL);
return (double)n;
}
ENDVERBATIM
:* v.d2v(&x) copies from double area to vector -- a seg error waiting to happen
VERBATIM
static double d2v (void* vv) {
int i, n, num;
double *x, *fr;
n = vector_instance_px(vv, &x);
fr = hoc_pgetarg(1);
if (ifarg(2)) { num = *getarg(2); } else { num=-1;}
if (num>-1 && num!=n) { hoc_execerror("Vector size doesn't match.", 0); }
for (i=0; i<n; i++) {x[i] = fr[i];}
return (double)n;
}
ENDVERBATIM
:* v.lcat(LIST)
VERBATIM
static double lcat (void* vv) {
int i, j, k, n, lc, cap, maxsz;
Object *ob1;
double *x, *fr;
IvocVect *vw;
n = vector_instance_px(vv, &x);
vector_resize((IvocVect*)vv,maxsz=vector_buffer_size((IvocVect*)vv)); // open it up fully
ob1 = *hoc_objgetarg(1);
lc = ivoc_list_count(ob1);
for (i=0,j=0;i<lc && j<maxsz;i++) {
cap = list_vector_px2(ob1, i, &fr, &vw);
for (k=0;k<cap && j<maxsz;k++,j++) x[j]=fr[k];
}
if (i<lc || k<cap) printf("vecst lcat WARN: not all vecs copied\n");
vector_resize((IvocVect*)vv,j);
return (double)j;
}
ENDVERBATIM
:* v.mkcode(LIST,BITS) -- put together integer vectors from list by bit concatenating
VERBATIM
static double mkcode (void* vv) {
int i, j, k, n, num, bits;
Object *ob;
double *x, *vvo[5];
n = vector_instance_px(vv, &x);
ob = *hoc_objgetarg(1);
if (ifarg(2)) bits = *getarg(2); else bits=3;
num = ivoc_list_count(ob);
if (num!=5) hoc_execerror("mkcode ****ERRA****: can only handle 5 vectors", 0);
for (i=0;i<num;i++) { j=list_vector_px(ob, i, &vvo[i]);
if (n!=j) { printf("mkcode ****ERRC**** %d %d %d\n",i,n,j);
hoc_execerror("Vectors must all be same size: ", 0); }}
for (i=0;i<n;i++) { // go through the vec length
for (j=0,x[i]=0;j<5;j++) {
if (vvo[j][i]<0. || vvo[j][i]>=sc[4] || floor(vvo[j][i]+0.5)!=vvo[j][i]) {
printf("vec.mkcode OOB %g>%g in vec[%d].x[%d]\n",vvo[j][i],sc[4],j,i); hxe(); }
x[i]+=vvo[j][i]*sc[j+1];
}
}
return (double)i;
}
ENDVERBATIM
:* v.uncode(val) -- take apart val and place in vector
: v.uncode(VECLIST) -- take apart vector items and place in vectors in list (cf uncodf)
: v.uncode(vec,field) -- take apart v entries and place requested field in vec
: v.uncode(field,val) -- replace field in v with val (cf recodf)
: v.uncode(field,vec) -- replace field in v with values from vec
VERBATIM
static double uncode (void* vv) {
int i, j, n, ny, num, field;
Object *ob;
double *x, *y, *vvo[5], val, old;
void *vvv[5];
n = vector_instance_px(vv, &x);
field=0;
if (!ifarg(1)) { // numarg()==0
printf("\tv.uncode(val) -- take apart val and place in vector\n\tv.uncode(VECLIST) -- take apart vector items and place in vectors in list (cf uncodf)\n\tv.uncode(vec,field) -- take apart vector items and place requested field in vector\n\tv.uncode(field,val) -- replace field in v with val (cf recodf)\n\tv.uncode(field,vec) -- replace field in v with values from vec\n"); return 0.;
} else if (!ifarg(2)) { // numarg()==1
if (hoc_is_double_arg(1)) {
val = *getarg(1);
if (vector_buffer_size((IvocVect*)vv)<5) {
hoc_execerror("uncode ****ERRA****: vector too small to resize(5)", 0);}
vector_resize((IvocVect*)vv,5);
for (i=1;i<=5;i++) UNCODE(val,i,x[i-1])
return x[0];
} else {
ob = *hoc_objgetarg(1);
num = ivoc_list_count(ob);
if (num>5) hoc_execerror("uncode ****ERRA****: can only handle 5 vectors", 0);
for (i=0;i<num;i++) if (! list_vector_px4(ob, i, &vvo[i], n)) {
printf("uncode ****ERRC**** %d\n",i);
hoc_execerror("Vectors not big enough: ", 0);
}
for (i=0;i<n;i++) for (j=1;j<=num;j++) UNCODE(x[i],j,vvo[j-1][i]);
return (double)i;
}
} else { // numarg()==2
if (hoc_is_double_arg(1)) { // replace values
field = (int)chkarg(1,1.,5.);
ny=-1;
if (hoc_is_double_arg(2)) {
val=chkarg(2,0.,sc[4]-1);
if (floor(val+0.5)!=val) hoc_execerror("uncode(vec) ****ERRG****: non-int val", 0);
} else {
ny=vector_arg_px(2, &y);
if (ny!=n) hoc_execerror("uncode(vec) ****ERRH****: diff sized vecs", 0);
}
for (i=0;i<n;i++) {
UNCODE(x[i],field,old)
if (ny>0) {
if (y[i]<0.||y[i]>=sc[4]||floor(y[i]+0.5)!=y[i]) {
printf("vec.uncode ERRJ OOB %g (%g max) at %d\n",y[i],sc[4],i);hxe();}
x[i] += sc[field]*(y[i]-old);
} else {
x[i] += sc[field]*(val -old);
}
}
return (double)i;
} else { // fill single vector with values
ny = vector_arg_px(1, &y);
field = (int)chkarg(2,1.,5.);
if (ny!=n) hoc_execerror("uncode(vec) ****ERRI****: diff sized vecs", 0);
for (i=0;i<n;i++) UNCODE(x[i],field,y[i])
return (double)i;
}
}
}
ENDVERBATIM
VERBATIM
//* list_vector_px(LIST,ITEM#,DOUBLE PTR ADDRESS)
// modeled on vector_arg_px() picks up a vec from a list
int list_vector_px (Object *ob, int i, double** px) {
Object* obv;
int sz;
obv = ivoc_list_item(ob, i);
if (! ISVEC(obv)) return -1;
sz = vector_capacity((IvocVect*)obv->u.this_pointer);
*px = vector_vec((IvocVect*)obv->u.this_pointer);
return sz;
}
//* list_vector_px2(LIST,ITEM#,DOUBLE PTR ADDRESS,VEC POINTER ADDRESS)
// returns the vector pointer as well as the double pointer
int list_vector_px2 (Object *ob, int i, double** px, IvocVect** vv) {
Object* obv;
int sz;
obv = ivoc_list_item(ob, i);
if (! ISVEC(obv)) return -1;
sz = vector_capacity((IvocVect*)obv->u.this_pointer);
*px = vector_vec((IvocVect*)obv->u.this_pointer);
*vv = (IvocVect*) obv->u.this_pointer;
return sz;
}
//* list_vector_px3(LIST,ITEM#,DOUBLE PTR ADDRESS,VEC POINTER ADDRESS)
// same as px2 but returns max vec size instead of current vecsize
// side effect -- increase vector size to maxsize
int list_vector_px3 (Object *ob, int i, double** px, IvocVect** vv) {
Object* obv;
int sz;
obv = ivoc_list_item(ob, i);
if (! ISVEC(obv)) return -1;
sz = vector_buffer_size((IvocVect*)obv->u.this_pointer);
*px = vector_vec((IvocVect*)obv->u.this_pointer);
*vv = (IvocVect*) obv->u.this_pointer;
vector_resize(*vv,sz);
return sz;
}
//* list_vector_px4(LIST,ITEM#,DOUBLE PTR ADDRESS,desired size)
// does resizing and returns true
int list_vector_px4 (Object *ob, int i, double** px, unsigned int n) {
Object* obv;
void* vv;
int sz;
obv = ivoc_list_item(ob, i);
if (! ISVEC(obv)) return -1;
sz = vector_buffer_size((IvocVect*)obv->u.this_pointer);
*px = vector_vec((IvocVect*)obv->u.this_pointer);
vv = (void*) obv->u.this_pointer;
if (n>sz) {
printf("List vector WARNING: unable to resize to %d requested (%d)\n",n,sz);
vector_resize((IvocVect*)vv,sz);
return 0;
} else vector_resize((IvocVect*)vv,n);
return 1;
}
//* list_vector_resize(LIST,ITEM#,NEW SIZE)
double *list_vector_resize (Object *ob, int i, int sz) {
Object* obv;
obv = ivoc_list_item(ob, i);
if (! ISVEC(obv)) return 0x0;
vector_resize((IvocVect*)obv->u.this_pointer,sz);
return vector_vec((IvocVect*)obv->u.this_pointer);
}
ENDVERBATIM
:* v1.ismono([arg]) asks whether is monotonically increasing, with arg==-1 - decreasing
: with arg==0:all same; 2:no consec ==; 3: incrementing by 1
VERBATIM
double ismono1 (double *x, int n, int flag) {
int i; double last, gap, ret;
last=x[0]; ret=1.; // default return value
if (flag==1) {
for (i=1; i<n && x[i]>=last; i++) last=x[i];
} else if (flag==-1) {
for (i=1; i<n && x[i]<=last; i++) last=x[i];
} else if (flag==0) {
for (i=1; i<n && x[i]==last; i++) ;
} else if (flag==2) {
for (i=1; i<n && x[i]>last; i++) last=x[i];
} else if (flag==-2) {
for (i=1; i<n && x[i]<last; i++) last=x[i];
} else if (flag==3) {
for (i=1; i<n && x[i]==last+1; i++) last=x[i];
} else if (flag==4) {
gap=x[1]-last; ret=gap;
for (i=1; i<n && x[i]==last+gap; i++) last=x[i];
} else if (flag==-3) {
for (i=1; i<n && x[i]==last-1; i++) last=x[i];
}
if (i==n) return ret; else return 0.;
}
static double ismono (void* vv) {
int i, n, flag;
double *x,last;
n = vector_instance_px(vv, &x);
if (ifarg(1)) { flag = (int)*getarg(1); } else { flag = 1; }
return (double)ismono1(x,n,flag);
}
ENDVERBATIM
:* v1.count(num) returns number of instances of num
VERBATIM
static double count (void* vv) {
int i, n, cnt;
double *x,num;
n = vector_instance_px(vv, &x);
num = *getarg(1);
for (cnt=0,i=0; i<n; i++) if (x[i]==num) cnt++;
return cnt;
}
ENDVERBATIM
:* v1.muladd(mul,add) mul*x+add
: eg v1.muladd(-1,1) will swap 0s and 1s
VERBATIM
static double muladd (void* vv) {
int i,n;
double *x,mul,add;
n = vector_instance_px(vv, &x);
mul = *getarg(1);
add = *getarg(2);
for (i=0; i<n; i++) x[i]=x[i]*mul+add;
return x[0];
}
ENDVERBATIM
:* v1.binfind(num) looks at sorted list to see if contains num
VERBATIM
static double binfind (void* vv) {
int i, n, lt, rt, mid;
double *x,num;
n = vector_instance_px(vv, &x);
num = *getarg(1);
lt=0; rt=n-1;
while (lt <= rt) {
mid = (lt+rt)/2;
if (num>x[mid]) lt=mid+1; else if (num<x[mid]) rt=mid-1; else return (double)mid;
}
return -1;
}
ENDVERBATIM
:* v1.uniq() returns number of unique values in vec
: v1.uniq(v2) -- v2 has the uniq values
: v1.uniq(List) L.o(0) has the uniq values; .o(1) has counts
: v1.uniq(List,1) L.o(1) has the uniq values with preserved order
VERBATIM
static double uniq (void* vv) {
int i, j, k, n, cnt, ny, nz, flag, lt, rt, mid, res;
double *x, *y, *z, lastx, num;
IvocVect* voi[2]; Object* ob; char *ix;
n = vector_instance_px(vv, &x);
flag=ny=nz=0;
if (n==0) {printf("vecst:uniq WARNA empty input vector\n"); return 0;}
if (ifarg(1)) {
ny=openvec(1,&y);
if (ny==-1) { // list
ob= *hoc_objgetarg(1);
ny=list_vector_px3(ob, 0, &y, &voi[0]);
nz=list_vector_px3(ob,1,&z,&voi[1]);
if (nz==0) z=vector_newsize(voi[1],nz=100);
} else {
voi[0]=vector_arg(1); // save vector pointer
}
if (ny==0) y=vector_newsize(voi[0],ny=100);
}
if (ifarg(2)) {
if (hoc_is_double_arg(2)) {
flag=*getarg(2);
ix=(char*)ecalloc(n,sizeof(char));
nz=0;
} else {
if (nz>0) {printf("ERROR: uniq(list,vec)\n"); hxe();}
voi[1]=vector_arg(2);
if ((nz=openvec(2,&z))==0) z=vector_newsize(voi[1],nz=100);
}
}
scrset(n);
for (i=0;i<n;i++) scr[i]=i;
nrn_mlh_gsort(x, (int*)scr, n, cmpdfn);
if (ny) y[0]=x[scr[0]];
if (nz>0) z[0]=1.;
for (i=1, lastx=x[scr[0]], cnt=1; i<n; i++) {
if (x[scr[i]]>lastx+hoc_epsilon) {
if (ny) {
if (cnt>=ny) y=vector_newsize(voi[0],ny*=3);
y[cnt]=x[scr[i]];
}
if (nz>0) {
if (cnt>=nz) z=vector_newsize(voi[1],nz*=3);
z[cnt]=1.;
}
cnt++;
lastx=x[scr[i]];
} else if (nz>0) z[cnt-1]++;
}
if (ny) vector_resize(voi[0], cnt);
if (nz>0) vector_resize(voi[1], cnt);
if (flag) { // refill z with the unique values in proper order
z=vector_newsize(voi[1], cnt);
for (i=0;i<cnt;i++) ix[i]=1;
for (i=0,j=0;i<n;i++) {
lt=0; rt=cnt-1; res=-1; num=x[i];
while (lt<=rt) { // look for the number in sorted y vector
mid=(lt+rt)/2;
if (num>y[mid]) lt=mid+1; else if (num<y[mid]) rt=mid-1; else {res=mid; break;}
}
if (y[res]!=num) {printf("uniq ERRC: %d %g %g\n",res,y[res],num); hxe();}
if (ix[res]) { // haven't got this one yet
z[j++]=num;
ix[res]=0;
}
if (i%1000==0) {
for (k=0;k<cnt;k++) if (ix[k]) break;
if (k==cnt) break; // ix[] filled in completely so exit for loop
}
}
free(ix);
}
return (double)cnt;
}
//** uniq2() should be called with 3 double arrays and their size
int uniq2 (int n, double *x, double *y, double *z) {
int i, j, k, cnt, lt, rt, mid, res; double lastx, num;
if (n==0) return 0;
scrset(n);
for (i=0;i<n;i++) scr[i]=i;
nrn_mlh_gsort(x, (int*)scr, n, cmpdfn); // sort x
y[0]=x[scr[0]]; // first value
for (i=1, lastx=x[scr[0]], cnt=1; i<n; i++) {
if (x[scr[i]]>lastx+hoc_epsilon) {
y[cnt]=x[scr[i]];
cnt++;
lastx=x[scr[i]];
}
}
for (i=0;i<cnt;i++) scr[i]=1; // markers for cnt unique values in y
// places uniq num in y into z in order from original redund x
for (i=0,j=0;i<n;i++) { // go through all the x values
lt=0; rt=cnt-1; res=-1; num=x[i]; // num is x value
while (lt<=rt) { // look for num in sorted y vector -- binary search
mid=(lt+rt)/2;
if (num>y[mid]) lt=mid+1; else if (num<y[mid]) rt=mid-1; else {res=mid; break;}
}
if (y[res]!=num) {printf("uniq2 ERRC: %d %g %g\n",res,y[res],num); hxe();}
if (scr[res]) { // haven't got this one yet
z[j++]=num;
scr[res]=0; // mark that one as being taken care of
}
if (i%10*cnt==0) { // check if we're done every few iterations
for (k=0;k<cnt;k++) if (scr[k]) break; // still some that haven't been found
if (k==cnt) break; // scr[] cleared completely so finished
}
}
return cnt;
}
// x.unq(y,z) calls uniq2() -- functionality same as uniq(List,1)
static double unq (void* vv) {
int n, cnt; double *x, *y, *z;
n=vector_instance_px(vv, &x);
y=vector_newsize(vector_arg(1),n); // all same size
z=vector_newsize(vector_arg(2),n);
cnt=uniq2(n,x,y,z);
y=vector_newsize(vector_arg(1),cnt);
z=vector_newsize(vector_arg(2),cnt);
return (double)cnt;
}
// v1.nqsvt() for nqs vt iterator
static double nqsvt (void* vv) {
int i, j, n, flag, cols;
double *col, *fcd, *ind, *vvo[100];
Object *fcdo, *vl, *obo;
Symbol* s; char *proc;
if ((cols=vector_instance_px(vv, &col))>100) {printf("nqsvt ERRD only 100 cols\n"); hxe();}
proc = gargstr(1);
if (!(s=hoc_lookup(proc))) {printf("nqsvt ERRA: proc %s not found\n",proc); hxe();}
fcdo=*hoc_objgetarg(2);
vector_arg_px(3, &fcd);
vl=*hoc_objgetarg(4);
if (ifarg(5)) {vector_arg_px(5, &ind); flag=1;} else flag=0;
n=list_vector_px(vl,(int)col[0],&vvo[0]);
for (i=1; i<cols; i++) if ((j=list_vector_px(vl,(int)col[i],&vvo[i]))!=n) {
printf("nqvt ERRB irreg cols %d %d %d\n",i,n,j); hxe(); }
if (flag) { // selected only -- need to write
} else for (i=0; i<n; i++) {
for (j=0; j<cols; j++) {
if (fcd[(int)col[j]]==0) {
hoc_pushx(vvo[j][i]);
} else if (fcd[(int)col[j]]==1) {
obo=ivoc_list_item(fcdo, (int)vvo[j][i]);
hoc_pushobj(&obo);
} else { printf("nqvt ERRC unhandled type: %g\n",fcd[j]); hxe(); }
}
hoc_pushx((double)i);
hoc_call_func(s, cols+1);
}
return (double)n;
}
// openvec() will pick up and open up a single vector but also will look for a list
int openvec (int arg, double **y) {
int max; void* vv;
Object* ob;
ob = *hoc_objgetarg(arg);
if (! ISVEC(ob)) return -1;
vector_arg_px(arg, y);
vv=vector_arg(arg);
max=vector_buffer_size((IvocVect*)vv);
vector_resize((IvocVect*)vv, max);
if (max==0) printf("openvec(): 0 size vec\n");
return max;
}
// vector_newsize() will also increase size of vector
double *vector_newsize (IvocVect* vv, int n) {
vector_resize(vv,n);
return vector_vec(vv);
}
ENDVERBATIM
:* v1.rnd([flag]) rounds off to nearest integer, with flag==1 rounds down
VERBATIM
static double rnd (void* vv) {
int i, n, flag;
double *x;
flag=(ifarg(1)?(int)*getarg(1):0);
n = vector_instance_px(vv, &x);
if (flag) {for (i=0; i<n; i++) x[i]=floor(x[i]);
} else for (i=0; i<n; i++) x[i]=floor(x[i]+0.5);
return (double)i;
}
ENDVERBATIM
:* v1.pop() removes last entry and shortens vector
VERBATIM
static double pop (void* vv) {
int n;
double *x;
n = vector_instance_px(vv, &x);
if (n==0) {printf("vec.pop ERR: empty vec\n");hxe();}
vector_resize((IvocVect*)vv,n-1);
return x[n-1];
}
ENDVERBATIM
PROCEDURE Expo (x) {
TABLE RES FROM -20 TO 20 WITH 5000
RES = exp(x)
}
FUNCTION EXP (x) {
if (x>20 || x<-20) { printf("EXP(%g) called with OOB value [-20,20]\n",x)
EXP=ERR
} else {
Expo(x)
EXP=RES
}
}
FUNCTION SUMEXP () {
VERBATIM
double i,min,max,step,sum;
if (ifarg(2)) { min=*getarg(1); max=*getarg(2); step=ifarg(3)?*getarg(3):1.;
} else { max=*getarg(1); min=0.; step=1.; }
if (max>20. || min<-20.) {
printf("SUMEXP() called with OOB value: %g %g [-20,20]\n",min,max);
sum=ERR;
} else for (i=min,sum=0;i<=max+hoc_epsilon;i+=step) {
Expo(i);
sum+=RES;
}
_lSUMEXP=sum;
ENDVERBATIM
}
:* dest.smgs(src,low,high,step,var)
: rewrite of v.sumgauss() in nrn5.3::ivoc/ivocvect.cpp:1078
: NEEDS DEBUGGING -- see drline.hoc:smgs()
VERBATIM
static double smgs (void* vv) {
int i, j, nx, xv, nsum, points, maxsz;
double *x, *sum;
double low , high , step , var , svar , scale , arg;
nsum = vector_instance_px(vv, &sum);
nx = vector_arg_px(1,&x);
low = *getarg(2);
high = *getarg(3);
step = *getarg(4);
var = *getarg(5);
points = (int)((high-low)/step+hoc_epsilon);
if (nsum!=points) {
maxsz=vector_buffer_size((IvocVect*)vv);
if (points<=maxsz) {
nsum=points; vector_resize((IvocVect*)vv, nsum);
} else {
printf("%d > %d :: ",points,maxsz);
hoc_execerror("Vector max capacity too small in smgs ", 0);
}
}
svar = -2.*var*var/step/step;
scale = 1./sqrt(2.*M_PI)/var;
for (j=0; j<points;j++) sum[j] = 0.;
for (i=0;i<nx;i++) {
xv = (int)((x[i]-low)/step + 0.5);
for (j=xv; j<points && (arg=(j-xv)*(j-xv)/svar)>-20;j++) {
Expo(arg);
sum[j] += RES;
}
for (j=xv-1; j>=0 && (arg=(j-xv)*(j-xv)/svar)>-20;j--) {
Expo(arg);
sum[j] += RES;
}
}
for (j=0; j<points;j++) sum[j] *= scale;
return svar;
}
ENDVERBATIM
:* dest.smsy(tvec,CVLV_VEC,tstop[,dt,del])
: sum CVLV_VEC starting at each point given in tvec with optional delay
: used for summing up syn potentials
VERBATIM
static double smsy (void* vv) {
int i, j, k, nx, nc, nsum, points, maxsz;
double *x, *sum, *c;
double del,tstop,mdt;
if (! ifarg(1)) { printf("dest.smsy(tvec,CVLV_VEC,tstop[,dt,del])\n"); return -1.; }
del=0.; mdt=0.2;
nsum = vector_instance_px(vv, &sum);
nx = vector_arg_px(1,&x);
nc = vector_arg_px(2,&c);
tstop = *getarg(3);
if (ifarg(4)) mdt = *getarg(4);
if (ifarg(5)) del = *getarg(5);
points=(int)(tstop/mdt+hoc_epsilon);
if (nsum!=points) {
maxsz=vector_buffer_size((IvocVect*)vv);
if (points<=maxsz) {
vector_resize((IvocVect*)vv, points); points=nsum;
} else {
printf("%d > %d :: ",points,maxsz);
hoc_execerror("Dest vector too small in smsy ", 0);
}
}
// don't zero out dest vec
for (i=0;i<nx;i++) for (j=0,k=(x[i]+del)/mdt;j<nc && k<nsum;j++,k++) sum[k] += c[j];
return points;
}
ENDVERBATIM
:* int.vrdh(FILE,veclist,code)
: vector read header will read the headers from vecs saved with vread()
: needs to be generalized so reads code as well, also should do BYTESWAP
VERBATIM
static double vrdh (void* vv) {
int code, i, num, n[2], maxsz; size_t r;
double *x;
FILE* f;
num = vector_instance_px(vv, &x);
maxsz=vector_buffer_size((IvocVect*)vv);
f = hoc_obj_file_arg(1);
num = (int)*getarg(2); // number of vectors to look for
if (maxsz<2*num){printf("vrdh ERR0 need %d room in vec\n",2*num);hxe();}
vector_resize((IvocVect*)vv, 2*num);
for (i=0;i<num;i++) {
r=fread(&n,sizeof(int),2,f); // n[1] is type
if (n[1]!=3){printf("vrdh ERRA code 3 only implemented %d:%d\n",i,n[1]);hxe();}
x[2*i]=(double)n[0]; // size
x[2*i+1]=(double)n[1];
fseek(f,(long)n[1],SEEK_CUR);
}
return (double)num;
}
ENDVERBATIM
:* rdmany(FILE,{veclist or vec},code[,num])
VERBATIM
static double rdmany (void* vv) {
int code, i, j, ni, vsz, ny, nv, num, cnt, n[2], sz, hd, vflag, iflag, last;
Object* ob; size_t r;
double *vvo[100], sf[2], *ind, *y;
FILE* f;
vflag=iflag=0;
ni = vector_instance_px(vv, &ind);
f = hoc_obj_file_arg(1);
ob = *hoc_objgetarg(2);
if (ifarg(3)) cnt=(int)*getarg(3); else { cnt=ni; iflag=1; }
if (strncmp(hoc_object_name(ob),"Vector",6)==0) vflag=1;
i=2*sizeof(int) + 2*sizeof(double); // size of header with scaling
j=2*sizeof(int); // size of header without scaling
r=fread(&n,sizeof(int),2,f);
vsz=n[0]; code=n[1];
fseek(f,(long)-2*sizeof(int),SEEK_CUR); // go back
if (DEBUG_VECST) printf("rdmanyDBA: %ld %d %d\n",ftell(f),vsz,code);
switch (code) {
// case 1:sz=1; hd=i; break; // char
case 2:sz=2; hd=i; break; // short
case 3:sz=4; hd=j; break; // float
case 4:sz=8; hd=j; break; // double
// case 5:sz=4; hd=i; break; // int
default: hoc_execerror("rdmany ERRE: code not recognized", 0);
}
if (vflag) {
ny = vector_arg_px(2, &y);
num= cnt;
if (vsz*cnt!=ny) {
printf("rdmany ERRD: wrong size vec: %d statt (%d*%d) %d\n",ny,vsz,cnt,vsz*cnt); hxe();}
} else {
num = ivoc_list_count(ob);
if (num>100) hoc_execerror("rdmany ERRA: can only handle 100 vectors", 0);
if (num!=cnt) {printf("rdmany ERRB: %d != %d",num,cnt); hxe();}
for (i=0;i<num;i++) {
nv = list_vector_px(ob, i, &vvo[i]);
if (vsz!=nv){printf("rdmany ERRC: Vectors must all be same size %d %d %d\n",i,vsz,nv);hxe();}
}
}
if (vsz*sz>bufsz) {
if (scrsz>0) { free(scr); scr=(unsigned int *)NULL; }
scrsz=vsz+10;
scr=(unsigned int *)ecalloc(scrsz, sz);
bufsz=scrsz*sz; // number of chars available
}
if (code==2) {
unsigned short *xs;
xs=(unsigned short *)scr;
for (last=-1,i=0;i<num;i++) {
if (iflag) { // iflag // "i flag" not "if lag"
fseek(f,(long)((int)ind[i]-last-1)*(hd+vsz*sizeof(short)),SEEK_CUR);
if (DEBUG_VECST) printf("rdmanyDBB %ld ",ftell(f));
last=(int)ind[i];
}
r=fread(&n,sizeof(int),2,f);
r=fread(&sf,sizeof(double),2,f);
if (n[0]!=vsz){printf("rdmany ERRA vec(%d) %d vs %d\n",iflag?(int)ind[i]:i,vsz,n[0]);hxe();}
if (n[1]!=code){printf("rdmany ERRB code mismatch %d %d\n",n[1],code);hxe();}
r=fread(xs,sizeof(short),n[0],f);
for (j=0;j<vsz;j++) if (vflag) {
y[i*vsz+j]=(double)(xs[j]/sf[0] + sf[1]);
} else vvo[i][j]=(double)(xs[j]/sf[0] + sf[1]);
}
} else if (code==3) {
float *xs;
xs=(float *)scr;
for (last=-1,i=0;i<num;i++) {
if (iflag) {
fseek(f,(long)((int)ind[i]-last-1)*(hd+vsz*sizeof(float)),SEEK_CUR);
last=(int)ind[i];
}
if (DEBUG_VECST) printf("rdmanyDBC:%ld ",ftell(f));
r=fread(&n,sizeof(int),2,f);
if (n[0]!=vsz){printf("rdmany ERRA vec(%d) %d vs %d\n",iflag?(int)ind[i]:i,vsz,n[0]);hxe();}
if (n[1]!=code){printf("rdmany ERRB code mismatch %d %d\n",n[1],code);hxe();}
r=fread(xs,sizeof(float),n[0],f);
for (j=0;j<n[0];j++) if (vflag) {
y[i*vsz+j]=(double)xs[j];
} else vvo[i][j]=(double)xs[j];
}
} else if (code==4) {
double *xs;
xs=(double *)scr;
for (last=-1,i=0;i<num;i++) {
if (iflag) {
fseek(f,(long)((int)ind[i]-last-1)*(hd+vsz*sizeof(double)),SEEK_CUR);
last=(int)ind[i];
}
if (DEBUG_VECST) printf("rdmanyDBD %ld ",ftell(f));
r=fread(&n,sizeof(int),2,f);
if (n[0]!=vsz){printf("rdmany ERRA vec(%d) %d vs %d\n",iflag?(int)ind[i]:i,vsz,n[0]);hxe();}
if (n[1]!=code){printf("rdmany ERRB code mismatch %d %d\n",n[1],code);hxe();}
r=fread(xs,sizeof(double),n[0],f); // should just read directly into final array
for (j=0;j<n[0];j++) if (vflag) y[i*vsz+j]=xs[j]; else vvo[i][j]=xs[j];
}
} else printf("rdmany() code %d not implemented\n",code);
return (double)num;
}
ENDVERBATIM
:* rdfile(FILE,{veclist or vec})
: should check speed for reading in and then later picking up individual vec
: would set up internal global pointers *vvo, *vnq but not copy in till needed
: also would want global size,type,scale,offset -- put all in a struct
VERBATIM
static double rdfile (void* vv) {
int i, j, k, ni, vsz, ty, ny, nv, num, cnt, n[2], hd, vflag;
IvocVect* vnq[10000]; size_t r;
size_t sz;
char* xc; int *xi; float *xf; double *xd; void* xv; unsigned short* xus;
Object* ob;
double *vvo[10000], sf[2], *ind, *y;
FILE* f;
vflag=0;
ni = vector_instance_px(vv, &ind);
f = hoc_obj_file_arg(1);
ob = *hoc_objgetarg(2);
if (strncmp(hoc_object_name(ob),"Vector",6)==0) vflag=1;
fseek(f,0,SEEK_END); sz=(int)ftell(f); rewind(f); // get size
if (DEBUG_VECST) printf("Size %d\n",sz);
if (sz>scrsz*sizeof(int)) {
if (scrsz>0) { free(scr); scr=(unsigned int *)NULL; }
scr=(unsigned int *)ecalloc(1, sz);
scrsz=sz/sizeof(int); // number of chars available
}
xc=(char *)scr;
r=fread(xc,(size_t)sz,1,f);
if (vflag) {
ny = vector_arg_px(2, &y);
} else {
num = ivoc_list_count(ob);
if (num>10000) { printf("rdfile ERRA: can only handle 10000 vectors"); hxe();}
for (i=0;i<num;i++) {
nv = list_vector_px3(ob, i, &vvo[i], &vnq[i]);
if (i==0) vsz=nv;
if (vsz!=nv){printf("rdfile ERRC: Vectors must all be same size %d %d %d\n",i,vsz,nv);hxe();}
}
}
for (i=0,k=0,cnt=0;i<sz;cnt++) { // increment i from within loop
xi=(int*) (xc+i);
vsz=xi[0];
ty= xi[1]; i+=(2*sizeof(int)); // picked up 2 ints
if (vsz<=0 || ty<1 || ty>5) {
printf("rdfile ERRB: bad size/type: %d/%d in vec# %d\n",vsz,ty,cnt); hxe();}
if (DEBUG_VECST) printf("%d:%d:%d ",i,ty,vsz);
if (vflag) { // vector
if (k+vsz>=ny) {
printf("rdfile ERRC: No more room in vec: %d %d %d %d\n",ny,k+vsz,cnt,ty); hxe(); }
} else { // a list
if (cnt>=num) {
printf("rdfile ERRD: out of vecs: %d %d %d\n",num,cnt,ty); hxe(); }
if (vsz>nv) {
printf("rdfile ERRE: No more room in vec: %d %d %d %d\n",nv,vsz,cnt,ty); hxe(); }
}
if (ty==3) { // float must be recast
xf=(float*)(xc+i);
if (vflag) {
for (j=0;j<vsz;j++) y[k+j]=(double)xf[j];
k+=vsz;
} else {
for (j=0;j<vsz;j++) vvo[cnt][j]=(double)xf[j];
vector_resize(vnq[cnt],vsz);
}
i+=(vsz*sizeof(float));
} else if (ty==4) { // double is just a memcpy
xv=(void*)(xc+i);
if (vflag) {
memcpy((void*)(y+k),xv,(size_t)(vsz*sizeof(double)));
k+=vsz;
} else {
memcpy((void*)(&vvo[cnt][0]),xv,(size_t)(vsz*sizeof(double)));
vector_resize(vnq[cnt],vsz);
}
i+=(vsz*sizeof(double));
} else if (ty==2) { // short must be shifted and scaled
xd =(double *)(xc+i); i+=2*sizeof(double);
for (j=0;j<2;j++) sf[j]=xd[j];
xus=(unsigned short*)(xc+i);
if (vflag) {
for (j=0;j<vsz;j++) y[k+j]=((double)xus[j])/sf[0] + sf[1];
k+=vsz;
} else {
for (j=0;j<vsz;j++) vvo[cnt][j]=((double)xus[j])/sf[0] + sf[1];
vector_resize(vnq[cnt],vsz);
}
i+=(vsz*sizeof(short));
} else printf("rdfile() type %d not implemented\n",ty);
}
if (vflag) vector_resize((IvocVect*)vector_arg(2), k);
if (scrsz>1e7) { free(scr); scr=(unsigned int *)NULL; scrsz=0; }
return (double)num;
}
ENDVERBATIM
:* PROCEDURE install_vecst()
PROCEDURE install_vecst () {
if (VECST_INSTALLED==1) {
printf("$Id: vecst.mod,v 1.491 2010/07/21 15:00:19 billl Exp $\n")
} else {
VECST_INSTALLED=1
VERBATIM {
int i,j;
install_vector_method("indset", indset);
install_vector_method("mkind", mkind);
install_vector_method("circ", circ);
install_vector_method("thresh", thresh);
install_vector_method("triplet", triplet);
install_vector_method("onoff", onoff);
install_vector_method("bpeval", bpeval);
install_vector_method("w", w);
install_vector_method("whi", whi);
install_vector_method("sedit", sedit);
install_vector_method("xing", xing);
install_vector_method("scxing", scxing);
install_vector_method("cvlv", cvlv);
install_vector_method("sccvlv", sccvlv);
install_vector_method("scl", scl);
install_vector_method("revec", revec);
install_vector_method("has", has);
install_vector_method("intrp", intrp);
install_vector_method("xzero", xzero);
install_vector_method("negwrap", negwrap);
install_vector_method("sw", sw);
install_vector_method("ismono", ismono);
install_vector_method("count", count);
install_vector_method("muladd", muladd);
install_vector_method("binfind", binfind);
install_vector_method("unq", unq);
install_vector_method("uniq", uniq);
install_vector_method("rnd", rnd);
install_vector_method("fewind", fewind);
install_vector_method("findx", findx);
install_vector_method("lma", lma);
install_vector_method("sindx", sindx);
install_vector_method("sindv", sindv);
install_vector_method("nind", nind);
install_vector_method("keyind", keyind);
install_vector_method("slct", slct);
install_vector_method("slor", slor);
install_vector_method("insct", insct);
install_vector_method("linsct", linsct);
install_vector_method("cull", cull);
install_vector_method("redundout", redundout);
install_vector_method("mredundout", mredundout);
install_vector_method("d2v", d2v);
install_vector_method("v2d", v2d);
install_vector_method("v2p", v2p);
install_vector_method("l2p", l2p);
install_vector_method("fetch", fetch);
install_vector_method("covar", covar);
install_vector_method("ixsort", ixsort);
install_vector_method("vlxpose", vlxpose);
install_vector_method("b2v", b2v);
install_vector_method("iwr", iwr);
install_vector_method("ird", ird);
install_vector_method("smgs", smgs);
install_vector_method("smsy", smsy);
install_vector_method("ident", ident);
install_vector_method("lcat", lcat);
install_vector_method("snap", snap);
install_vector_method("fread2", fread2);
install_vector_method("vfill", vfill);
install_vector_method("vrdh", vrdh);
install_vector_method("mkcode", mkcode);
install_vector_method("uncode", uncode);
install_vector_method("sumabs", sumabs);
install_vector_method("inv", inv);
install_vector_method("join", join);
install_vector_method("slone", slone);
install_vector_method("pop", pop);
install_vector_method("rdmany", rdmany);
install_vector_method("rdfile", rdfile);
install_vector_method("samp", samp);
install_vector_method("nearest", nearest);
install_vector_method("nearall", nearall);
install_vector_method("approx", approx);
install_vector_method("nqsvt", nqsvt);
install_vector_method("roton", roton);
for (i=0,j=5;i<=5;i++,j--) sc[i]=pow(2,10*j);
}
ENDVERBATIM
}
}
:* isojt(OB1,EXAMPLE_OBJ) return whether OB1 is an instance of EXAMPLE_OBJ
FUNCTION isojt () {
VERBATIM {
Object *ob1, *ob2;
ob1 = *hoc_objgetarg(1); ob2 = *hoc_objgetarg(2);
if (!ob1) if (!ob2) return 1; else return 0;
#define ctemplate template
#ifdef NRN_VERSION_GTEQ_8_2_0
#if NRN_VERSION_GTEQ(9, 0, 0)
#undef ctemplate
#define ctemplate ctemplate
#endif
#endif
if (!ob2 || ob1->ctemplate != ob2->ctemplate) {
#undef ctemplate
return 0;
}
return 1;
}
ENDVERBATIM
}
: isojn(OB1,NAME) return whether OB1 is an instance of EXAMPLE_OBJ
FUNCTION isojn () {
VERBATIM {
Object *ob1; char* name;
ob1 = *hoc_objgetarg(1); name = gargstr(2);
if (strncmp(hoc_object_name(ob1),name,3)==0) _lisojn=1.; else _lisojn=0.;
}
ENDVERBATIM
}
: ojtnum(OBJ) returns object number
: returns internal number of object, eg if vec[3] is Vector[432] returns 432
FUNCTION ojtnum () {
VERBATIM {
Object *ob1; char name[50]; int ii;
ob1 = *hoc_objgetarg(1);
if (!ob1) return -1;
if (ifarg(2)) {
strncpy(name, hoc_object_name(ob1),50);
for (ii=strlen(name);ii>1;ii--) if (name[ii]==91) {name[ii]=0; break;} // 91 is [
hoc_assign_str(hoc_pgargstr(2),name);
}
return (double)ob1->index;
}
ENDVERBATIM
}
: eqojt(OB1,OB2) return whether OB1 and OB2 point to same object
FUNCTION eqojt () {
VERBATIM {
Object *ob1, *ob2;
ob1 = *hoc_objgetarg(1); ob2 = *hoc_objgetarg(2);
if (ob1 && ob2 && ob1==ob2) {
return 1;
}
return 0;
}
ENDVERBATIM
}
:* byteswap(FILE)
FUNCTION byteswap () {
VERBATIM {
int n[2]; size_t r;
double ret;
FILE* f;
BYTEHEADER
f = hoc_obj_file_arg(1);
r=fread(&n,sizeof(int),2,f);
if (n[1] < 1 || n[1] > 5) {
BYTESWAP_FLAG = 1;
ret = 1.;
} else ret = 0.;
BYTESWAP(n[1],int)
if (n[1] < 1 || n[1] > 5) {
printf("byteswap: Something wrong with location sampled: %d\n",n[1]);
ret = -1.;
}
fseek(f,-2*sizeof(int),SEEK_CUR); // go back to where we started
return ret;
}
ENDVERBATIM
}
: mkcodf(val1,val2,val3,val4,val5) stuff 5 vals<=999 into a single double
FUNCTION mkcodf () {
VERBATIM {
int i;
double x,a;
if (ifarg(6)) {printf("mkcodf() ERR: can only encode 5 values\n"); hxe();}
for (x=0.,i=1;i<=5;i++) {
a=(ifarg(i))?*getarg(i):0.0;
if (a<0. || a>=sc[4] || floor(a+0.5)!=a) {
printf("mkcodf restricted to integers %g [0,%g]\n",a,sc[4]-1);hxe(); }
x+=a*sc[i];
}
return x;
}
ENDVERBATIM
}
: uncodf(code,i) returns field i (1-5) from code
FUNCTION uncodf () {
VERBATIM {
int i;
double x,ret, *ptr;
x=*getarg(1);
if (hoc_is_double_arg(2)) {
i=(int)*getarg(2);
if (i<1||i>5) {printf("2nd arg must be field# 1-5 (%d)\n",i); hxe();}
UNCODE(x,i,ret);
return ret;
} else {
for (i=2;i<=6;i++) if (ifarg(i)) {
ptr = hoc_pgetarg(i);
UNCODE(x,i-1,*ptr);
} else break;
return *ptr;
}
}
ENDVERBATIM
}
: recodf(i,code,new) replaces field i (1-5) from code with new
FUNCTION recodf () {
VERBATIM {
int i;
double x, y, old;
i=(int)chkarg(1,1.,5.); x=*getarg(2); y=chkarg(3,0.,sc[4]-1);
UNCODE(x,i,old);
return x + sc[i]*(y-old);
}
ENDVERBATIM
}
: flor(val)
FUNCTION flor () {
VERBATIM {
return floor(*getarg(1));
}
ENDVERBATIM
}
: ceilg(val)
FUNCTION ceilg () {
VERBATIM {
return ceil(*getarg(1));
}
ENDVERBATIM
}
: MINxy(val1,val2)
FUNCTION MINxy () {
VERBATIM {
return MIN(*getarg(1),*getarg(2));
}
ENDVERBATIM
}
: MAXxy(val1,val2)
FUNCTION MAXxy () {
VERBATIM {
return MAX(*getarg(1),*getarg(2));
}
ENDVERBATIM
}
:* PROCEDURE fspitchar
PROCEDURE fspitchar(c) {
VERBATIM
{
FILE* f;
f = hoc_obj_file_arg(2);
fprintf(f, "%c", (int)_lc);
}
ENDVERBATIM
}
:* PROCEDURE fgchar
FUNCTION fgchar() {
VERBATIM
{
FILE* f;
f = hoc_obj_file_arg(1);
_lfgchar = (double)fgetc(f);
}
ENDVERBATIM
}
:* FUNCTION Str2Num takes a string arg and returns the # as a double
FUNCTION Str2Num () {
VERBATIM
{
double d;
char* c;
c = gargstr(1);
d = atof(c);
return d;
}
ENDVERBATIM
}
:* FUNCTION vlsz() resize all the vectors in a list
FUNCTION vlsz () {
VERBATIM
{
int i,j,c,n; double *x, sz, fill; void *vv;
ListVec* pL; Object* obl;
pL = AllocListVec(obl=*hoc_objgetarg(1));
sz=*getarg(2);
if (ifarg(3)) fill=*getarg(3); else fill=OK;
c=pL->isz; // list length
for (i=0;i<c;i++) {
pL->pv[i]=list_vector_resize(obl, i, (int)sz);
if (fill!=OK) for (j=0;j<(int)sz;j++) pL->pv[i][j]=fill;
}
FreeListVec(&pL);
_lvlsz = (double)sz*c;
}
ENDVERBATIM
}
VERBATIM
void FreeListVec(ListVec** pp) {
ListVec* p = *pp;
if(p->pv){
free(p->pv);
p->pv=0;
}
if(p->plen){
free(p->plen);
p->plen=0;
}
free(p);
*pp=0;
}
ListVec* AllocListVec (Object* p) {
int i, iSz; ListVec* pList; Object* obv;
if(!IsList(p)){printf("AllocListVec ERRA: arg must be list object!\n"); hxe();}
pList = (ListVec*)malloc(sizeof(ListVec));
if(!pList) hxe();
pList->pL=p; pList->isz=0; pList->pv=0; pList->plen=0;
iSz = pList->isz = ivoc_list_count(p);
if(iSz < 1) return pList;
pList->plen = (unsigned int*)malloc(sizeof(int)*iSz);
if(!pList->plen){printf("AllocListVec ERRB: Out of memory!\n"); hxe();}
pList->pbuflen = (unsigned int*)malloc(sizeof(int)*iSz);
pList->pv = (double**)malloc(sizeof(double*)*iSz);
if(!pList->pv){free(pList->plen); printf("AllocListVec ERRC: Out of memory!\n"); hxe();}
for(i=0;i<pList->isz;i++) {
obv = ivoc_list_item(p,i);
pList->pv[i]=vector_vec((IvocVect*)obv->u.this_pointer);
pList->plen[i]=vector_capacity((IvocVect*)obv->u.this_pointer);
pList->pbuflen[i]=vector_buffer_size((IvocVect*)obv->u.this_pointer);;
}
return pList;
}
// Allocate a list vec that is indexed
ListVec* AllocILV (Object* p, int nx, double *x) {
int i, j, iSz, ilc; ListVec* pList; Object* obv;
if(!IsList(p)){printf("AllocILV ERRA: arg must be list object!\n"); hxe();}
pList = (ListVec*)malloc(sizeof(ListVec));
if(!pList) hxe();
pList->pL=p; iSz=pList->isz=nx; pList->pv=0; pList->plen=0;
ilc=ivoc_list_count(p);
if(iSz<1) return pList;
pList->plen = (unsigned int*)malloc(sizeof(int)*iSz);
if(!pList->plen){printf("AllocILV ERRB: Out of memory!\n"); hxe();}
pList->pbuflen = (unsigned int*)malloc(sizeof(int)*iSz);
pList->pv = (double**)malloc(sizeof(double*)*iSz);
if(!pList->pv){free(pList->plen); printf("AllocILV ERRC: Out of memory!\n"); hxe();}
for(i=0;i<iSz;i++){
if ((j=(int)x[i])>=ilc){printf("AllocILV ERRD: index OOB: %d>=%d\n",j,ilc); hxe();}
obv = ivoc_list_item(p,j);
pList->pv[i]=vector_vec((IvocVect*)obv->u.this_pointer);
pList->plen[i]=vector_capacity((IvocVect*)obv->u.this_pointer);
pList->pbuflen[i]=vector_buffer_size((IvocVect*)obv->u.this_pointer);;
}
return pList;
}
void ListVecResize (ListVec* p,int newsz) {
int i,j; Object* obv;
for(i=0;i<p->isz;i++){
obv = ivoc_list_item(p->pL, i);
p->pv[i]=vector_newsize((IvocVect*)obv->u.this_pointer,newsz);
p->plen[i]=newsz;
}
}
void FillListVec (ListVec* p,double dval) {
int i,j;
for(i=0;i<p->isz;i++){
for(j=0;j<p->plen[i];j++){
p->pv[i][j]=dval;
}
}
}
int IsObj (Object* p,char* s){
if(!p) return 0;
if(!s || !strlen(s)) return 0;
return !strncmp(hoc_object_name(p),s,strlen(s));
}
int IsVector (Object* p){ return IsObj(p,"Vector"); }
int IsList (Object* p){return IsObj(p,"List"); }
int** getint2D(int rows,int cols) {
int **pp,*pool,*curPtr; int i;
pp = (int**) malloc(sizeof(int*)*rows);
if(!pp) { printf("ERR: out of memory!\n"); return 0x0; }
pool = (int*) malloc(sizeof(int)*rows*cols);
if(!pool) { printf("ERR: out of memory!\n"); free(pp); return 0x0; }
curPtr = pool;
for(i = 0; i < rows; i++) {
pp[i] = curPtr;
curPtr += cols;
}
return pp;
}
void freeint2D(int*** ppp,int rows) {
int** pp;
pp = *ppp;
free(pp[0]);
free(pp);
*ppp = 0;
}
double** getdouble2D(int rows,int cols) {
double **pp,*pool,*curPtr; int i;
pp = (double**) malloc(sizeof(double*)*rows);
if(!pp) { printf("ERR: out of memory!\n"); return 0x0; }
pool = (double*) malloc(sizeof(double)*rows*cols);
if(!pool) { printf("ERR: out of memory!\n"); free(pp); return 0x0; }
curPtr = pool;
for(i = 0; i < rows; i++) {
pp[i] = curPtr;
curPtr += cols;
}
return pp;
}
void freedouble2D(double*** ppp,int rows) {
double** pp;
pp = *ppp;
free(pp[0]);
free(pp);
*ppp = 0;
}
ENDVERBATIM