src/util/rmatrix.c

#ifndef lint
static const char RCSid[] = "$Id: rmatrix.c,v 2.78 2024/02/29 03:11:13 greg Exp $";
#endif
/*
 * General matrix operations.
 */

#include <stdlib.h>
#include <errno.h>
#include "rtio.h"
#include "platform.h"
#include "resolu.h"
#include "paths.h"
#include "rmatrix.h"
#if !defined(_WIN32) && !defined(_WIN64)
#include <sys/mman.h>
#endif

static const char       rmx_mismatch_warn[] = "WARNING: data type mismatch\n";

/* Initialize a RMATRIX struct but don't allocate array space */
RMATRIX *
rmx_new(int nr, int nc, int n)
{
        RMATRIX *dnew;

        if (n <= 0)
                return(NULL);

        dnew = (RMATRIX *)calloc(1, sizeof(RMATRIX));
        if (!dnew)
                return(NULL);

        dnew->dtype = DTdouble;
        dnew->nrows = nr;
        dnew->ncols = nc;
        dnew->ncomp = n;
        setcolor(dnew->cexp, 1.f, 1.f, 1.f);
        memcpy(dnew->wlpart, WLPART, sizeof(dnew->wlpart));

        return(dnew);
}

/* Prepare a RMATRIX for writing (allocate array if needed) */
int
rmx_prepare(RMATRIX *rm)
{
        if (!rm) return(0);
        if (rm->mtx)
                return(1);
        if ((rm->nrows <= 0) | (rm->ncols <= 0) | (rm->ncomp <= 0))
                return(0);
        rm->mtx = (double *)malloc(rmx_array_size(rm));
        rm->pflags |= RMF_OURMEM;
        return(rm->mtx != NULL);
}

/* Call rmx_new() and rmx_prepare() */
RMATRIX *
rmx_alloc(int nr, int nc, int n)
{
        RMATRIX *dnew = rmx_new(nr, nc, n);

        if (dnew && !rmx_prepare(dnew)) {
                rmx_free(dnew);
                dnew = NULL;
        }
        return(dnew);
}

/* Clear state by freeing info and matrix data */
void
rmx_reset(RMATRIX *rm)
{
        if (!rm) return;
        if (rm->info) {
                free(rm->info);
                rm->info = NULL;
        }
        if (rm->mtx && rm->pflags & RMF_OURMEM) {
#ifdef MAP_FILE
                if (rm->mapped) {
                        munmap(rm->mapped, rmx_mapped_size(rm));
                        rm->mapped = NULL;
                } else
#endif
                        free(rm->mtx);
                rm->pflags &= ~RMF_OURMEM;
        }
        rm->mtx = NULL;
}

/* Free an RMATRIX struct and data */
void
rmx_free(RMATRIX *rm)
{
        if (!rm) return;
        rmx_reset(rm);
        free(rm);
}

/* Resolve data type based on two input types (returns 0 for mismatch) */
int
rmx_newtype(int dtyp1, int dtyp2)
{
        if ((dtyp1==DTxyze) | (dtyp1==DTrgbe) | (dtyp1==DTspec) |
                        (dtyp2==DTxyze) | (dtyp2==DTrgbe) | (dtyp2==DTspec)
                        && dtyp1 != dtyp2)
                return(0);
        if (dtyp1 < dtyp2)
                return(dtyp1);
        return(dtyp2);
}

/* Append header information associated with matrix data */
int
rmx_addinfo(RMATRIX *rm, const char *info)
{
        int     oldlen = 0;

        if (!rm || !info || !*info)
                return(0);
        if (!rm->info) {
                rm->info = (char *)malloc(strlen(info)+1);
                if (rm->info) rm->info[0] = '\0';
        } else {
                oldlen = strlen(rm->info);
                rm->info = (char *)realloc(rm->info,
                                oldlen+strlen(info)+1);
        }
        if (!rm->info)
                return(0);
        strcpy(rm->info+oldlen, info);
        return(1);
}

static int
get_dminfo(char *s, void *p)
{
        RMATRIX *ip = (RMATRIX *)p;
        char    fmt[MAXFMTLEN];
        int     i;

        if (headidval(NULL, s))
                return(0);
        if (isncomp(s)) {
                ip->ncomp = ncompval(s);
                return(0);
        }
        if (!strncmp(s, "NROWS=", 6)) {
                ip->nrows = atoi(s+6);
                return(0);
        }
        if (!strncmp(s, "NCOLS=", 6)) {
                ip->ncols = atoi(s+6);
                return(0);
        }
        if ((i = isbigendian(s)) >= 0) {
                if (nativebigendian() != i)
                        ip->pflags |= RMF_SWAPIN;
                else
                        ip->pflags &= ~RMF_SWAPIN;
                return(0);
        }
        if (isexpos(s)) {
                float   f = exposval(s);
                scalecolor(ip->cexp, f);
                return(0);
        }
        if (iscolcor(s)) {
                COLOR   ctmp;
                colcorval(ctmp, s);
                multcolor(ip->cexp, ctmp);
                return(0);
        }
        if (iswlsplit(s)) {
                wlsplitval(ip->wlpart, s);
                return(0);
        }
        if (!formatval(fmt, s)) {
                rmx_addinfo(ip, s);
                return(0);
        }                       /* else check format */
        for (i = 1; i < DTend; i++)
                if (!strcmp(fmt, cm_fmt_id[i])) {
                        ip->dtype = i;
                        return(0);
                }
        return(-1);
}

static int
rmx_load_ascii(double *drp, const RMATRIX *rm, FILE *fp)
{
        int     j, k;

        for (j = 0; j < rm->ncols; j++)
                for (k = rm->ncomp; k-- > 0; )
                        if (fscanf(fp, "%lf", drp++) != 1)
                                return(0);
        return(1);
}

static int
rmx_load_float(double *drp, const RMATRIX *rm, FILE *fp)
{
        int     j, k;
        float   val[100];

        if (rm->ncomp > 100) {
                fputs("Unsupported # components in rmx_load_float()\n", stderr);
                exit(1);
        }
        for (j = 0; j < rm->ncols; j++) {
                if (getbinary(val, sizeof(val[0]), rm->ncomp, fp) != rm->ncomp)
                        return(0);
                if (rm->pflags & RMF_SWAPIN)
                        swap32((char *)val, rm->ncomp);
                for (k = 0; k < rm->ncomp; k++)
                        *drp++ = val[k];
        }
        return(1);
}

static int
rmx_load_double(double *drp, const RMATRIX *rm, FILE *fp)
{
        if (getbinary(drp, sizeof(*drp)*rm->ncomp, rm->ncols, fp) != rm->ncols)
                return(0);
        if (rm->pflags & RMF_SWAPIN)
                swap64((char *)drp, rm->ncols*rm->ncomp);
        return(1);
}

static int
rmx_load_rgbe(double *drp, const RMATRIX *rm, FILE *fp)
{
        COLR    *scan;
        COLOR   col;
        int     j;

        if (rm->ncomp != 3)
                return(0);
        scan = (COLR *)tempbuffer(sizeof(COLR)*rm->ncols);
        if (!scan)
                return(0);
        if (freadcolrs(scan, rm->ncols, fp) < 0)
                return(0);
        for (j = 0; j < rm->ncols; j++) {
                colr_color(col, scan[j]);
                *drp++ = colval(col,RED);
                *drp++ = colval(col,GRN);
                *drp++ = colval(col,BLU);
        }
        return(1);
}

static int
rmx_load_spec(double *drp, const RMATRIX *rm, FILE *fp)
{
        uby8    *scan;
        SCOLOR  scol;
        int     j, k;

        if ((rm->ncomp < 3) | (rm->ncomp > MAXCSAMP))
                return(0);
        scan = (uby8 *)tempbuffer((rm->ncomp+1)*rm->ncols);
        if (!scan)
                return(0);
        if (freadscolrs(scan, rm->ncomp, rm->ncols, fp) < 0)
                return(0);
        for (j = 0; j < rm->ncols; j++) {
                scolr2scolor(scol, scan+j*(rm->ncomp+1), rm->ncomp);
                for (k = 0; k < rm->ncomp; k++)
                        *drp++ = scol[k];
        }
        return(1);
}

/* Read matrix header from input stream (cannot be XML) */
int
rmx_load_header(RMATRIX *rm, FILE *fp)
{
        if (!rm | !fp)
                return(0);
        rmx_reset(rm);                          /* clear state */
        if (rm->nrows | rm->ncols | !rm->dtype) {
                rm->nrows = rm->ncols = 0;
                rm->ncomp = 3;
                setcolor(rm->cexp, 1.f, 1.f, 1.f);
                memcpy(rm->wlpart, WLPART, sizeof(rm->wlpart));
                rm->pflags = 0;
        }
        rm->dtype = DTascii;                    /* assumed w/o FORMAT */
        if (getheader(fp, get_dminfo, rm) < 0) {
                fputs("Unrecognized matrix format\n", stderr);
                return(0);
        }
        if ((rm->dtype == DTrgbe) | (rm->dtype == DTxyze) &&
                        rm->ncomp != 3)
                return(0);
        if (rm->ncols <= 0 &&                   /* resolution string? */
                        !fscnresolu(&rm->ncols, &rm->nrows, fp))
                return(0);
        if (rm->dtype == DTascii)               /* set file type (WINDOWS) */
                SET_FILE_TEXT(fp);
        else
                SET_FILE_BINARY(fp);
        return(1);
}

/* Load next row as double (cannot be XML) */
int
rmx_load_row(double *drp, const RMATRIX *rm, FILE *fp)
{
        switch (rm->dtype) {
        case DTascii:
                return(rmx_load_ascii(drp, rm, fp));
        case DTfloat:
                return(rmx_load_float(drp, rm, fp));
        case DTdouble:
                return(rmx_load_double(drp, rm, fp));
        case DTrgbe:
        case DTxyze:
                return(rmx_load_rgbe(drp, rm, fp));
        case DTspec:
                return(rmx_load_spec(drp, rm, fp));
        default:
                fputs("Unsupported data type in rmx_load_row()\n", stderr);
        }
        return(0);
}

/* Allocate & load post-header data from stream given type set in rm->dtype */
int
rmx_load_data(RMATRIX *rm, FILE *fp)
{
        int     i;
#ifdef MAP_FILE
        long    pos;            /* map memory for file > 1MB if possible */
        if ((rm->dtype == DTdouble) & !(rm->pflags & RMF_SWAPIN) &&
                        rmx_array_size(rm) >= 1L<<20 &&
                        (pos = ftell(fp)) >= 0 && !(pos % sizeof(double))) {
                rm->mapped = mmap(NULL, rmx_array_size(rm)+pos, PROT_READ|PROT_WRITE,
                                        MAP_PRIVATE, fileno(fp), 0);
                if (rm->mapped != MAP_FAILED) {
                        rm->mtx = (double *)rm->mapped + pos/sizeof(double);
                        rm->pflags |= RMF_OURMEM;
                        return(1);
                }               /* else fall back on reading into memory */
                rm->mapped = NULL;
        }
#endif
        if (!rmx_prepare(rm)) { /* need in-core matrix array */
                fprintf(stderr, "Cannot allocate %g MByte matrix array\n",
                                (1./(1L<<20))*(double)rmx_array_size(rm));
                return(0);
        }
        for (i = 0; i < rm->nrows; i++)
                if (!rmx_load_row(rmx_lval(rm,i,0), rm, fp))
                        return(0);
        return(1);
}

/* Load matrix from supported file type */
RMATRIX *
rmx_load(const char *inspec, RMPref rmp)
{
        FILE            *fp;
        RMATRIX         *dnew;
        int             ok;

        if (!inspec)
                inspec = stdin_name;
        else if (!*inspec)
                return(NULL);
        if (inspec == stdin_name)               /* reading from stdin? */
                fp = stdin;
        else if (inspec[0] == '!')
                fp = popen(inspec+1, "r");
        else {
                const char      *sp = inspec;   /* check suffix */
                while (*sp)
                        ++sp;
                while (sp > inspec && sp[-1] != '.')
                        --sp;
                if (!strcasecmp(sp, "XML")) {   /* assume it's a BSDF */
                        CMATRIX *cm = rmp==RMPnone ? (CMATRIX *)NULL :
                                        rmp==RMPtrans ? cm_loadBTDF(inspec) :
                                        cm_loadBRDF(inspec, rmp==RMPreflB) ;
                        if (!cm)
                                return(NULL);
                        dnew = rmx_from_cmatrix(cm);
                        cm_free(cm);
                        dnew->dtype = DTascii;
                        return(dnew);           /* return here */
                }                               /* else open it ourselves */
                fp = fopen(inspec, "r");
        }
        if (!fp) {
                fprintf(stderr, "Cannot open for reading: %s\n", inspec);
                return(NULL);
        }
#ifdef getc_unlocked
        flockfile(fp);
#endif
        SET_FILE_BINARY(fp);                    /* load header info */
        if (!rmx_load_header(dnew = rmx_new(0,0,3), fp)) {
                fprintf(stderr, "Bad header in: %s\n", inspec);
                if (inspec[0] == '!') pclose(fp);
                else fclose(fp);
                rmx_free(dnew);
                return(NULL);
        }
        ok = rmx_load_data(dnew, fp);           /* allocate & load data */

        if (fp != stdin) {                      /* close input stream */
                if (inspec[0] == '!')
                        pclose(fp);
                else
                        fclose(fp);
        }
#ifdef getc_unlocked
        else
                funlockfile(fp);
#endif
        if (!ok) {                              /* load failure? */
                fprintf(stderr, "Error loading data from: %s\n", inspec);
                rmx_free(dnew);
                return(NULL);
        }
                                                /* undo exposure? */
        if ((dnew->cexp[0] != 1.f) |
                        (dnew->cexp[1] != 1.f) | (dnew->cexp[2] != 1.f)) {
                double  cmlt[MAXCSAMP];
                int     i;
                cmlt[0] = 1./dnew->cexp[0];
                cmlt[1] = 1./dnew->cexp[1];
                cmlt[2] = 1./dnew->cexp[2];
                if (dnew->ncomp > MAXCSAMP) {
                        fprintf(stderr, "Excess spectral components in: %s\n",
                                        inspec);
                        rmx_free(dnew);
                        return(NULL);
                }
                for (i = dnew->ncomp; i-- > 3; )
                        cmlt[i] = cmlt[1];
                rmx_scale(dnew, cmlt);
                setcolor(dnew->cexp, 1.f, 1.f, 1.f);
        }
        return(dnew);
}

static int
rmx_write_ascii(const double *dp, int nc, int len, FILE *fp)
{
        while (len-- > 0) {
                int     k = nc;
                while (k-- > 0)
                        fprintf(fp, " %.7e", *dp++);
                fputc('\t', fp);
        }
        return(fputc('\n', fp) != EOF);
}

static int
rmx_write_float(const double *dp, int len, FILE *fp)
{
        float   val;

        while (len--) {
                val = *dp++;
                if (putbinary(&val, sizeof(float), 1, fp) != 1)
                        return(0);
        }
        return(1);
}

static int
rmx_write_rgbe(const double *dp, int nc, int len, FILE *fp)
{
        COLR    *scan;
        int     j;

        if ((nc != 1) & (nc != 3)) return(0);
        scan = (COLR *)tempbuffer(sizeof(COLR)*len);
        if (!scan) return(0);

        for (j = 0; j < len; j++, dp += nc)
                if (nc == 1)
                        setcolr(scan[j], dp[0], dp[0], dp[0]);
                else
                        setcolr(scan[j], dp[0], dp[1], dp[2]);

        return(fwritecolrs(scan, len, fp) >= 0);
}

static int
rmx_write_spec(const double *dp, int nc, int len, FILE *fp)
{
        uby8    *scan;
        SCOLOR  scol;
        int     j, k;

        if (nc < 3) return(0);
        scan = (uby8 *)tempbuffer((nc+1)*len);
        if (!scan) return(0);
        for (j = 0; j < len; j++, dp += nc) {
                for (k = nc; k--; )
                        scol[k] = dp[k];
                scolor2scolr(scan+j*(nc+1), scol, nc);
        }
        return(fwritescolrs(scan, nc, len, fp) >= 0);
}

/* Check if CIE XYZ primaries were specified */
static int
findCIEprims(const char *info)
{
        RGBPRIMS        prims;

        if (!info)
                return(0);
        info = strstr(info, PRIMARYSTR);
        if (!info || !primsval(prims, info))
                return(0);

        return((prims[RED][CIEX] > .99) & (prims[RED][CIEY] < .01) &&
                        (prims[GRN][CIEX] < .01) & (prims[GRN][CIEY] > .99) &&
                        (prims[BLU][CIEX] < .01) & (prims[BLU][CIEY] < .01));
}

/* Finish writing header data with resolution and format, returning type used */
int
rmx_write_header(const RMATRIX *rm, int dtype, FILE *fp)
{
        if (!rm | !fp || rm->ncols <= 0)
                return(0);
        if (rm->info)
                fputs(rm->info, fp);
        if (dtype == DTfromHeader)
                dtype = rm->dtype;
        else if (dtype == DTrgbe && (rm->dtype == DTxyze ||
                                        findCIEprims(rm->info)))
                dtype = DTxyze;
        else if ((dtype == DTxyze) & (rm->dtype == DTrgbe))
                dtype = DTrgbe;
        if ((dtype < DTspec) & (rm->ncomp > 3))
                dtype = DTspec;
        else if ((dtype == DTspec) & (rm->ncomp <= 3))
                return(0);

        if (dtype == DTascii)                   /* set file type (WINDOWS) */
                SET_FILE_TEXT(fp);
        else
                SET_FILE_BINARY(fp);
                                                /* write exposure? */
        if (rm->ncomp == 3 && (rm->cexp[RED] != rm->cexp[GRN]) |
                        (rm->cexp[GRN] != rm->cexp[BLU]))
                fputcolcor(rm->cexp, fp);
        else if (rm->cexp[GRN] != 1.f)
                fputexpos(rm->cexp[GRN], fp);
                                                /* matrix size? */
        if ((dtype > DTspec) | (rm->nrows <= 0)) {
                if (rm->nrows > 0)
                        fprintf(fp, "NROWS=%d\n", rm->nrows);
                fprintf(fp, "NCOLS=%d\n", rm->ncols);
        }
        if (dtype >= DTspec) {                  /* # components & split? */
                fputncomp(rm->ncomp, fp);
                if (rm->ncomp > 3 &&
                                memcmp(rm->wlpart, WLPART, sizeof(WLPART)))
                        fputwlsplit(rm->wlpart, fp);
        } else if ((rm->ncomp != 3) & (rm->ncomp != 1))
                return(0);                      /* wrong # components */
        if ((dtype == DTfloat) | (dtype == DTdouble))
                fputendian(fp);                 /* important to record */
        fputformat(cm_fmt_id[dtype], fp);
        fputc('\n', fp);                        /* end of header */
        if ((dtype <= DTspec) & (rm->nrows > 0))
                fprtresolu(rm->ncols, rm->nrows, fp);
        return(dtype);
}

/* Write out matrix data (usually by row) */
int
rmx_write_data(const double *dp, int nc, int len, int dtype, FILE *fp)
{
        switch (dtype) {
        case DTascii:
                return(rmx_write_ascii(dp, nc, len, fp));
        case DTfloat:
                return(rmx_write_float(dp, nc*len, fp));
        case DTdouble:
                return(putbinary(dp, sizeof(*dp)*nc, len, fp) == len);
        case DTrgbe:
        case DTxyze:
                return(rmx_write_rgbe(dp, nc, len, fp));
        case DTspec:
                return(rmx_write_spec(dp, nc, len, fp));
        }
        return(0);
}

/* Write matrix using file format indicated by dtype */
int
rmx_write(const RMATRIX *rm, int dtype, FILE *fp)
{
        int     ok = 0;
        int     i;
                                                /* complete header */
        dtype = rmx_write_header(rm, dtype, fp);
        if (dtype <= 0)
                return(0);
#ifdef getc_unlocked
        flockfile(fp);
#endif
        if (dtype == DTdouble)                  /* write all at once? */
                ok = rmx_write_data(rm->mtx, rm->ncomp,
                                rm->nrows*rm->ncols, dtype, fp);
        else                                    /* else row by row */
                for (i = 0; i < rm->nrows; i++) {
                        ok = rmx_write_data(rmx_val(rm,i,0), rm->ncomp,
                                        rm->ncols, dtype, fp);
                        if (!ok) break;
                }

        if (ok) ok = (fflush(fp) == 0);
#ifdef getc_unlocked
        funlockfile(fp);
#endif
        if (!ok) fputs("Error writing matrix\n", stderr);
        return(ok);
}

/* Allocate and assign square identity matrix with n components */
RMATRIX *
rmx_identity(const int dim, const int n)
{
        RMATRIX *rid = rmx_alloc(dim, dim, n);
        int     i, k;

        if (!rid)
                return(NULL);
        memset(rid->mtx, 0, rmx_array_size(rid));
        for (i = dim; i--; ) {
            double      *dp = rmx_lval(rid,i,i);
            for (k = n; k--; )
                dp[k] = 1.;
        }
        return(rid);
}

/* Duplicate the given matrix (may be unallocated) */
RMATRIX *
rmx_copy(const RMATRIX *rm)
{
        RMATRIX *dnew;

        if (!rm)
                return(NULL);
        dnew = rmx_new(rm->nrows, rm->ncols, rm->ncomp);
        if (!dnew)
                return(NULL);
        if (rm->mtx) {
                if (!rmx_prepare(dnew)) {
                        rmx_free(dnew);
                        return(NULL);
                }
                memcpy(dnew->mtx, rm->mtx, rmx_array_size(dnew));
        }
        rmx_addinfo(dnew, rm->info);
        dnew->dtype = rm->dtype;
        copycolor(dnew->cexp, rm->cexp);
        memcpy(dnew->wlpart, rm->wlpart, sizeof(dnew->wlpart));
        return(dnew);
}

/* Replace data in first matrix with data from second */
int
rmx_transfer_data(RMATRIX *rdst, RMATRIX *rsrc, int dometa)
{
        if (!rdst | !rsrc || (rdst->nrows != rsrc->nrows) |
                        (rdst->ncols != rsrc->ncols) |
                        (rdst->ncomp != rsrc->ncomp))
                return(0);

        if (dometa) {           /* transfer everything? */
                rmx_reset(rdst);
                *rdst = *rsrc;
                rsrc->info = NULL; rsrc->mapped = NULL; rsrc->mtx = NULL;
                return(1);
        }
        if (rdst->pflags & RMF_OURMEM) {
#ifdef MAP_FILE                 /* just matrix data -- leave metadata */
                if (rdst->mapped)
                        munmap(rdst->mapped, rmx_mapped_size(rdst));
                else
#endif
                if (rdst->mtx)
                        free(rdst->mtx);
        }
        rdst->mapped = rsrc->mapped;
        rdst->mtx = rsrc->mtx;
        if (rsrc->pflags & RMF_OURMEM)
                rdst->pflags |= RMF_OURMEM;
        else
                rdst->pflags &= ~RMF_OURMEM;
        rsrc->mapped = NULL; rsrc->mtx = NULL;
        return(1);
}

/* Allocate and assign transposed matrix */
RMATRIX *
rmx_transpose(const RMATRIX *rm)
{
        RMATRIX *dnew;
        int     i, j;

        if (!rm || !rm->mtx)
                return(0);
        if ((rm->nrows == 1) | (rm->ncols == 1)) {
                dnew = rmx_copy(rm);
                if (!dnew)
                        return(NULL);
                dnew->nrows = rm->ncols;
                dnew->ncols = rm->nrows;
                return(dnew);
        }
        dnew = rmx_alloc(rm->ncols, rm->nrows, rm->ncomp);
        if (!dnew)
                return(NULL);
        if (rm->info) {
                rmx_addinfo(dnew, rm->info);
                rmx_addinfo(dnew, "Transposed rows and columns\n");
        }
        dnew->dtype = rm->dtype;
        copycolor(dnew->cexp, rm->cexp);
        memcpy(dnew->wlpart, rm->wlpart, sizeof(dnew->wlpart));
        for (j = dnew->ncols; j--; )
            for (i = dnew->nrows; i--; )
                memcpy(rmx_lval(dnew,i,j), rmx_val(rm,j,i),
                                sizeof(double)*dnew->ncomp);
        return(dnew);
}

/* Multiply (concatenate) two matrices and allocate the result */
RMATRIX *
rmx_multiply(const RMATRIX *m1, const RMATRIX *m2)
{
        RMATRIX *mres;
        int     i, j, k, h;

        if (!m1 | !m2 || !m1->mtx | !m2->mtx |
                        (m1->ncomp != m2->ncomp) | (m1->ncols != m2->nrows))
                return(NULL);
        mres = rmx_alloc(m1->nrows, m2->ncols, m1->ncomp);
        if (!mres)
                return(NULL);
        i = rmx_newtype(m1->dtype, m2->dtype);
        if (i)
                mres->dtype = i;
        else
                rmx_addinfo(mres, rmx_mismatch_warn);
        for (i = mres->nrows; i--; )
            for (j = mres->ncols; j--; )
                for (k = mres->ncomp; k--; ) {
                    double      d = 0;
                    for (h = m1->ncols; h--; )
                        d += rmx_val(m1,i,h)[k] * rmx_val(m2,h,j)[k];
                    rmx_lval(mres,i,j)[k] = d;
                }
        return(mres);
}

/* Element-wise multiplication (or division) of m2 into m1 */
int
rmx_elemult(RMATRIX *m1, const RMATRIX *m2, int divide)
{
        int     zeroDivides = 0;
        int     i, j, k;

        if (!m1 | !m2 || !m1->mtx | !m2->mtx |
                         (m1->ncols != m2->ncols) | (m1->nrows != m2->nrows))
                return(0);
        if ((m2->ncomp > 1) & (m2->ncomp != m1->ncomp))
                return(0);
        i = rmx_newtype(m1->dtype, m2->dtype);
        if (i)
                m1->dtype = i;
        else
                rmx_addinfo(m1, rmx_mismatch_warn);
        for (i = m1->nrows; i--; )
            for (j = m1->ncols; j--; )
                if (divide) {
                    double      d;
                    if (m2->ncomp == 1) {
                        d = rmx_val(m2,i,j)[0];
                        if (d == 0) {
                            ++zeroDivides;
                            for (k = m1->ncomp; k--; )
                                rmx_lval(m1,i,j)[k] = 0;
                        } else {
                            d = 1./d;
                            for (k = m1->ncomp; k--; )
                                rmx_lval(m1,i,j)[k] *= d;
                        }
                    } else
                        for (k = m1->ncomp; k--; ) {
                            d = rmx_val(m2,i,j)[k];
                            if (d == 0) {
                                ++zeroDivides;
                                rmx_lval(m1,i,j)[k] = 0;
                            } else
                                rmx_lval(m1,i,j)[k] /= d;
                        }
                } else {
                    if (m2->ncomp == 1) {
                        const double    d = rmx_val(m2,i,j)[0];
                        for (k = m1->ncomp; k--; )
                            rmx_lval(m1,i,j)[k] *= d;
                    } else
                        for (k = m1->ncomp; k--; )
                            rmx_lval(m1,i,j)[k] *= rmx_val(m2,i,j)[k];
                }
        if (zeroDivides) {
                rmx_addinfo(m1, "WARNING: zero divide(s) corrupted results\n");
                errno = ERANGE;
        }
        return(1);
}

/* Sum second matrix into first, applying scale factor beforehand */
int
rmx_sum(RMATRIX *msum, const RMATRIX *madd, const double sf[])
{
        double  *mysf = NULL;
        int     i, j, k;

        if (!msum | !madd || !msum->mtx | !madd->mtx |
                        (msum->nrows != madd->nrows) |
                        (msum->ncols != madd->ncols) |
                        (msum->ncomp != madd->ncomp))
                return(0);
        if (!sf) {
                mysf = (double *)malloc(sizeof(double)*msum->ncomp);
                if (!mysf)
                        return(0);
                for (k = msum->ncomp; k--; )
                        mysf[k] = 1;
                sf = mysf;
        }
        i = rmx_newtype(msum->dtype, madd->dtype);
        if (i)
                msum->dtype = i;
        else
                rmx_addinfo(msum, rmx_mismatch_warn);
        for (i = msum->nrows; i--; )
            for (j = msum->ncols; j--; ) {
                const double    *da = rmx_val(madd,i,j);
                double          *ds = rmx_lval(msum,i,j);
                for (k = msum->ncomp; k--; )
                     ds[k] += sf[k] * da[k];
            }
        if (mysf)
                free(mysf);
        return(1);
}

/* Scale the given matrix by the indicated scalar component vector */
int
rmx_scale(RMATRIX *rm, const double sf[])
{
        int     i, j, k;

        if (!rm | !sf || !rm->mtx)
                return(0);
        for (i = rm->nrows; i--; )
            for (j = rm->ncols; j--; ) {
                double  *dp = rmx_lval(rm,i,j);
                for (k = rm->ncomp; k--; )
                    dp[k] *= sf[k];
            }
        if (rm->info)
                rmx_addinfo(rm, "Applied scalar\n");
        /* XXX: should record as exposure for COLR and SCOLR types? */
        return(1);
}

/* Allocate new matrix and apply component transformation */
RMATRIX *
rmx_transform(const RMATRIX *msrc, int n, const double cmat[])
{
        int     i, j, ks, kd;
        RMATRIX *dnew;

        if (!msrc | (n <= 0) | !cmat || !msrc->mtx)
                return(NULL);
        dnew = rmx_alloc(msrc->nrows, msrc->ncols, n);
        if (!dnew)
                return(NULL);
        if (msrc->info) {
                char    buf[128];
                sprintf(buf, "Applied %dx%d component transform\n",
                                dnew->ncomp, msrc->ncomp);
                rmx_addinfo(dnew, msrc->info);
                rmx_addinfo(dnew, buf);
        }
        dnew->dtype = msrc->dtype;
        for (i = dnew->nrows; i--; )
            for (j = dnew->ncols; j--; ) {
                const double    *ds = rmx_val(msrc,i,j);
                for (kd = dnew->ncomp; kd--; ) {
                    double      d = 0;
                    for (ks = msrc->ncomp; ks--; )
                        d += cmat[kd*msrc->ncomp + ks] * ds[ks];
                    rmx_lval(dnew,i,j)[kd] = d;
                }
            }
        return(dnew);
}

/* Convert a color matrix to newly allocated RMATRIX buffer */
RMATRIX *
rmx_from_cmatrix(const CMATRIX *cm)
{
        int     i, j;
        RMATRIX *dnew;

        if (!cm)
                return(NULL);
        dnew = rmx_alloc(cm->nrows, cm->ncols, 3);
        if (!dnew)
                return(NULL);
        dnew->dtype = DTfloat;
        for (i = dnew->nrows; i--; )
            for (j = dnew->ncols; j--; ) {
                const COLORV    *cv = cm_lval(cm,i,j);
                double          *dp = rmx_lval(dnew,i,j);
                dp[0] = cv[0];
                dp[1] = cv[1];
                dp[2] = cv[2];
            }
        return(dnew);
}

/* Convert general matrix to newly allocated CMATRIX buffer */
CMATRIX *
cm_from_rmatrix(const RMATRIX *rm)
{
        int     i, j;
        CMATRIX *cnew;

        if (!rm || !rm->mtx | (rm->ncomp == 2))
                return(NULL);
        cnew = cm_alloc(rm->nrows, rm->ncols);
        if (!cnew)
                return(NULL);
        for (i = cnew->nrows; i--; )
            for (j = cnew->ncols; j--; ) {
                const double    *dp = rmx_val(rm,i,j);
                COLORV          *cv = cm_lval(cnew,i,j);
                switch (rm->ncomp) {
                case 3:
                    setcolor(cv, dp[0], dp[1], dp[2]);
                    break;
                case 1:
                    setcolor(cv, dp[0], dp[0], dp[0]);
                    break;
                default: {
                        SCOLOR  scol;
                        int     k;
                        for (k = rm->ncomp; k--; )
                                scol[k] = dp[k];
                        scolor2color(cv, scol, rm->ncomp, rm->wlpart);
                    } break;
                }
            }
        return(cnew);
}
Revision:	2.79
Committed:	Sun May 19 15:32:24 2024 UTC (4 days, 5 hours ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	HEAD
Changes since 2.78:	+32 -22 lines
Log Message:	feat: Added facility for app-managed matrix memory