Copyright 1990 Regents of the University of California. All rights reserved.
Author: 1988 Wayne A. Christopher, U. C. Berkeley CAD Group
Modified: 2000 AlansFixes, 2013/2015 patch by Krzysztof Blaszkowski
**********/
* This module replaces the old "writedata" routines in nutmeg.
* Unlike the writedata routines, the OUT routines are only called by
* the simulator routines, and only call routines in nutmeg. The rest
* of nutmeg doesn't deal with OUT at all.
*/
#include "ngspice/ngspice.h"
#include "ngspice/cpdefs.h"
#include "ngspice/ftedefs.h"
#include "ngspice/dvec.h"
#include "ngspice/plot.h"
#include "ngspice/sim.h"
#include "ngspice/inpdefs.h"
#include "ngspice/ifsim.h"
#include "ngspice/jobdefs.h"
#include "ngspice/iferrmsg.h"
#include "circuits.h"
#include "outitf.h"
#include "variable.h"
#include <fcntl.h>
#include "ngspice/cktdefs.h"
#include "ngspice/inpdefs.h"
#include "breakp2.h"
#include "runcoms.h"
#include "plotting/graf.h"
#include "../misc/misc_time.h"
extern char *spice_analysis_get_name(int index);
extern char *spice_analysis_get_description(int index);
extern int EVTsetup_plot(CKTcircuit* ckt, char* plotname);
extern IFsimulator SIMinfo;
extern char Spice_Build_Date[];
static int beginPlot(JOB *analysisPtr, CKTcircuit *circuitPtr, char *cktName, char *analName,
char *refName, int refType, int numNames, char **dataNames, int dataType,
bool windowed, runDesc **runp);
static int addDataDesc(runDesc *run, char *name, int type, int ind, int meminit);
static int addSpecialDesc(runDesc *run, char *name, char *devname, char *param, int depind, int meminit);
static void fileInit(runDesc *run);
static void fileInit_pass2(runDesc *run);
static void fileStartPoint(FILE *fp, bool bin, int num);
static void fileAddRealValue(FILE *fp, bool bin, double value);
static void fileAddComplexValue(FILE *fp, bool bin, IFcomplex value);
static void fileEndPoint(FILE *fp, bool bin);
static void fileEnd(runDesc *run);
static void plotInit(runDesc *run);
static void plotAddRealValue(dataDesc *desc, double value);
static void plotAddComplexValue(dataDesc *desc, IFcomplex value);
static void plotEnd(runDesc *run);
static bool parseSpecial(char *name, char *dev, char *param, char *ind);
static bool name_eq(char *n1, char *n2);
static bool getSpecial(dataDesc *desc, runDesc *run, IFvalue *val);
static void freeRun(runDesc *run);
static int InterpFileAdd(runDesc *plotPtr, IFvalue *refValue, IFvalue *valuePtr);
static int InterpPlotAdd(runDesc *plotPtr, IFvalue *refValue, IFvalue *valuePtr);
#ifdef TCL_MODULE
#include "ngspice/tclspice.h"
#elif defined SHARED_MODULE
extern int sh_ExecutePerLoop(void);
extern int sh_vecinit(runDesc *run);
#endif
#ifndef HAS_WINGUI
extern bool orflag;
#endif
int fixme_onoise_type = SV_NOTYPE;
int fixme_inoise_type = SV_NOTYPE;
#define DOUBLE_PRECISION 15
static clock_t lastclock, currclock, startclock;
static double *rowbuf;
static size_t column, rowbuflen;
static bool shouldstop = FALSE;
static bool interpolated = FALSE;
static double *valueold, *valuenew;
#ifdef SHARED_MODULE
static bool savenone = FALSE;
#endif
int
OUTpBeginPlot(CKTcircuit *circuitPtr, JOB *analysisPtr,
IFuid analName,
IFuid refName, int refType,
int numNames, IFuid *dataNames, int dataType, runDesc **plotPtr)
{
char *name;
if (ft_curckt->ci_ckt == circuitPtr)
name = ft_curckt->ci_name;
else
name = "circuit name";
return (beginPlot(analysisPtr, circuitPtr, name,
analName, refName, refType, numNames,
dataNames, dataType, FALSE,
plotPtr));
}
int
OUTwBeginPlot(CKTcircuit *circuitPtr, JOB *analysisPtr,
IFuid analName,
IFuid refName, int refType,
int numNames, IFuid *dataNames, int dataType, runDesc **plotPtr)
{
return (beginPlot(analysisPtr, circuitPtr, "circuit name",
analName, refName, refType, numNames,
dataNames, dataType, TRUE,
plotPtr));
}
static int
beginPlot(JOB *analysisPtr, CKTcircuit *circuitPtr, char *cktName, char *analName, char *refName, int refType, int numNames, char **dataNames, int dataType, bool windowed, runDesc **runp)
{
runDesc *run;
struct save_info *saves;
bool *savesused = NULL;
int numsaves;
int i, j, depind = 0;
char namebuf[BSIZE_SP], parambuf[BSIZE_SP], depbuf[BSIZE_SP];
char *ch, tmpname[BSIZE_SP];
bool saveall = TRUE;
bool savealli = FALSE;
bool savenosub = FALSE;
char *an_name;
int initmem;
*All it does is reassign the file pointer and return (requires *runp to be NULL if this is not needed)
*/
if (dataType == 666 && numNames == 666) {
run = *runp;
run->writeOut = ft_getOutReq(&run->fp, &run->runPlot, &run->binary,
run->type, run->name);
} else {
if (cp_getvar("printinfo", CP_BOOL, NULL, 0))
fprintf(cp_err, "(debug printing enabled)\n");
if (cp_getvar("interp", CP_BOOL, NULL, 0)) {
interpolated = TRUE;
fprintf(cp_out, "Warning: Interpolated raw file data!\n\n");
}
*runp = run = TMALLOC(struct runDesc, 1);
run->analysis = analysisPtr;
run->circuit = circuitPtr;
run->name = copy(cktName);
run->type = copy(analName);
run->windowed = windowed;
run->numData = 0;
an_name = spice_analysis_get_name(analysisPtr->JOBtype);
ft_curckt->ci_last_an = an_name;
* reference vector. Then toss in anything that getSaves() tells
* us to save that we can find in the name list. Finally unpack
* the remaining saves into parameters.
*/
numsaves = ft_getSaves(&saves);
if (numsaves) {
savesused = TMALLOC(bool, numsaves);
saveall = FALSE;
for (i = 0; i < numsaves; i++) {
if (saves[i].analysis && !cieq(saves[i].analysis, an_name)) {
savesused[i] = TRUE;
continue;
}
if (cieq(saves[i].name, "all") || cieq(saves[i].name, "allv")) {
saveall = TRUE;
savesused[i] = TRUE;
saves[i].used = 1;
continue;
}
if (cieq(saves[i].name, "alli")) {
savealli = TRUE;
savesused[i] = TRUE;
saves[i].used = 1;
continue;
}
if (cieq(saves[i].name, "nosub")) {
savenosub = TRUE;
savesused[i] = TRUE;
saves[i].used = 1;
continue;
}
#ifdef SHARED_MODULE
if (cieq(saves[i].name, "none")) {
savenone = TRUE;
saveall = TRUE;
savesused[i] = TRUE;
saves[i].used = 1;
continue;
}
#endif
}
}
if (numsaves && !saveall && !savenosub)
initmem = numsaves;
else
initmem = numNames;
if (refName) {
addDataDesc(run, refName, refType, -1, initmem);
for (i = 0; i < numsaves; i++)
if (!savesused[i] && name_eq(saves[i].name, refName)) {
savesused[i] = TRUE;
saves[i].used = 1;
}
} else {
run->refIndex = -1;
}
if (numsaves && !saveall && !savenosub) {
for (i = 0; i < numsaves; i++) {
if (!savesused[i]) {
for (j = 0; j < numNames; j++) {
if (name_eq(saves[i].name, dataNames[j])) {
addDataDesc(run, dataNames[j], dataType, j, initmem);
savesused[i] = TRUE;
saves[i].used = 1;
break;
}
else if (ft_ngdebug && refName && eq(refName, "time") && eq(saves[i].name, "speedcheck")) {
addDataDesc(run, "speedcheck", IF_REAL, j, initmem);
savesused[i] = TRUE;
saves[i].used = 1;
break;
}
}
}
}
} else {
for (i = 0; i < numNames; i++)
if (!refName || !name_eq(dataNames[i], refName))
if (!(savenosub && strchr(dataNames[i], '.')) &&
!strstr(dataNames[i], "#internal") &&
!strstr(dataNames[i], "#source") &&
!strstr(dataNames[i], "#drain") &&
!strstr(dataNames[i], "#collector") &&
!strstr(dataNames[i], "#collCX") &&
!strstr(dataNames[i], "#emitter") &&
!strstr(dataNames[i], "probe_int_") &&
!strstr(dataNames[i], "#base"))
{
addDataDesc(run, dataNames[i], dataType, i, initmem);
}
if (ft_ngdebug && refName && eq(refName, "time")) {
addDataDesc(run, "speedcheck", IF_REAL, numNames, initmem);
}
}
This is a new pass which searches for all the internal device
nodes, and saves the terminal currents instead */
if (savealli) {
depind = 0;
for (i = 0; i < numNames; i++) {
if (strstr(dataNames[i], "#internal") ||
strstr(dataNames[i], "#source") ||
strstr(dataNames[i], "#drain") ||
strstr(dataNames[i], "#collector") ||
strstr(dataNames[i], "#collCX") ||
strstr(dataNames[i], "#emitter") ||
strstr(dataNames[i], "#base"))
{
tmpname[0] = '@';
tmpname[1] = '\0';
strncat(tmpname, dataNames[i], BSIZE_SP-1);
ch = strchr(tmpname, '#');
if (strstr(ch, "#collector")) {
strcpy(ch, "[ic]");
} else if (strstr(ch, "#collCX")) {
strcpy(ch, "[ic]");
} else if (strstr(ch, "#base")) {
strcpy(ch, "[ib]");
} else if (strstr(ch, "#emitter")) {
strcpy(ch, "[ie]");
if (parseSpecial(tmpname, namebuf, parambuf, depbuf))
addSpecialDesc(run, tmpname, namebuf, parambuf, depind, initmem);
strcpy(ch, "[is]");
} else if (strstr(ch, "#drain")) {
strcpy(ch, "[id]");
if (parseSpecial(tmpname, namebuf, parambuf, depbuf))
addSpecialDesc(run, tmpname, namebuf, parambuf, depind, initmem);
strcpy(ch, "[ig]");
} else if (strstr(ch, "#source")) {
strcpy(ch, "[is]");
if (parseSpecial(tmpname, namebuf, parambuf, depbuf))
addSpecialDesc(run, tmpname, namebuf, parambuf, depind, initmem);
strcpy(ch, "[ib]");
} else if (strstr(ch, "#internal") && (tmpname[1] == 'd')) {
strcpy(ch, "[id]");
} else {
fprintf(cp_err,
"Debug: could output current for %s\n", tmpname);
continue;
}
if (parseSpecial(tmpname, namebuf, parambuf, depbuf)) {
if (*depbuf) {
fprintf(stderr,
"Warning : unexpected dependent variable on %s\n", tmpname);
} else {
addSpecialDesc(run, tmpname, namebuf, parambuf, depind, initmem);
}
}
}
}
}
for (i = 0; i < numsaves; i++) {
if (savesused[i])
continue;
if (!parseSpecial(saves[i].name, namebuf, parambuf, depbuf)) {
if (saves[i].analysis)
fprintf(cp_err, "Warning: can't parse '%s': ignored\n",
saves[i].name);
continue;
}
if (*depbuf) {
for (j = 0; j < run->numData; j++)
if (name_eq(depbuf, run->data[j].name))
break;
if (j == run->numData) {
for (j = 0; j < numNames; j++)
if (name_eq(depbuf, dataNames[j]))
break;
if (j == numNames) {
fprintf(cp_err,
"Warning: can't find '%s': value '%s' ignored\n",
depbuf, saves[i].name);
continue;
}
addDataDesc(run, dataNames[j], dataType, j, initmem);
savesused[i] = TRUE;
saves[i].used = 1;
depind = j;
} else {
depind = run->data[j].outIndex;
}
}
addSpecialDesc(run, saves[i].name, namebuf, parambuf, depind, initmem);
}
if (numsaves) {
for (i = 0; i < numsaves; i++) {
tfree(saves[i].analysis);
tfree(saves[i].name);
}
tfree(saves);
tfree(savesused);
}
if (numNames &&
((run->numData == 1 && run->refIndex != -1) ||
(run->numData == 0 && run->refIndex == -1)))
{
fprintf(cp_err, "Error: no data saved for %s; analysis not run\n",
spice_analysis_get_description(analysisPtr->JOBtype));
return E_NOTFOUND;
}
* nutmeg wants us to do.
*/
run->writeOut = ft_getOutReq(&run->fp, &run->runPlot, &run->binary,
run->type, run->name);
if (run->writeOut) {
fileInit(run);
} else {
plotInit(run);
if (refName)
run->runPlot->pl_ndims = 1;
#ifdef XSPICE
if (run->runPlot->pl_typename)
EVTsetup_plot(run->circuit, run->runPlot->pl_typename);
#endif
}
}
if (interpolated && run->circuit->CKTcurJob->JOBtype == 4) {
valueold = TMALLOC(double, run->numData);
for (i = 0; i < run->numData; i++)
valueold[i] = 0.0;
valuenew = TMALLOC(double, run->numData);
}
#ifdef TCL_MODULE
blt_init(run);
#elif defined SHARED_MODULE
sh_vecinit(run);
#endif
startclock = clock();
return (OK);
}
Add a standard vector to this plot */
static int
addDataDesc(runDesc *run, char *name, int type, int ind, int meminit)
{
dataDesc *data;
if (!run->numData) {
run->data = TMALLOC(dataDesc, ++meminit);
run->maxData = meminit;
}
else if (run->numData == run->maxData) {
run->maxData = (int)(run->maxData * 1.1) + 1;
run->data = TREALLOC(dataDesc, run->data, run->maxData);
}
data = &run->data[run->numData];
memset(data, 0, sizeof(dataDesc));
data->name = copy(name);
data->type = type;
data->gtype = GRID_LIN;
data->regular = TRUE;
data->outIndex = ind;
if (ind == -1)
run->refIndex = run->numData;
run->numData++;
return (OK);
}
Add a special vector (e.g. @q1[ib]) to this plot */
static int
addSpecialDesc(runDesc *run, char *name, char *devname, char *param, int depind, int meminit)
{
dataDesc *data;
char *unique, *freeunique;
int ret;
if (!run->numData) {
run->data = TMALLOC(dataDesc, ++meminit);
run->maxData = meminit;
}
else if (run->numData == run->maxData) {
run->maxData = (int)(run->maxData * 1.1) + 1;
run->data = TREALLOC(dataDesc, run->data, run->maxData);
}
data = &run->data[run->numData];
memset(data, 0, sizeof(dataDesc));
data->name = copy(name);
freeunique = unique = copy(devname);
ret = INPinsertNofree(&unique, ft_curckt->ci_symtab);
data->specName = unique;
if (ret == E_EXISTS)
tfree(freeunique);
data->specParamName = copy(param);
data->specIndex = depind;
data->specType = -1;
data->specFast = NULL;
data->regular = FALSE;
run->numData++;
return (OK);
}
static void
OUTpD_memory(runDesc *run, IFvalue *refValue, IFvalue *valuePtr)
{
int i, n = run->numData;
for (i = 0; i < n; i++) {
dataDesc *d;
#ifdef TCL_MODULE
blt_lockvec(i);
#endif
d = &run->data[i];
if (d->outIndex == -1) {
if (d->type == IF_REAL)
plotAddRealValue(d, refValue->rValue);
else if (d->type == IF_COMPLEX)
plotAddComplexValue(d, refValue->cValue);
} else if (d->regular) {
if (ft_ngdebug && d->type == IF_REAL && eq(d->name, "speedcheck")) {
clock_t cl = clock();
double tt = ((double)cl - (double)startclock) / CLOCKS_PER_SEC;
plotAddRealValue(d, tt);
}
else if (d->type == IF_REAL)
plotAddRealValue(d, valuePtr->v.vec.rVec[d->outIndex]);
else if (d->type == IF_COMPLEX)
plotAddComplexValue(d, valuePtr->v.vec.cVec[d->outIndex]);
} else {
IFvalue val;
if (!getSpecial(d, run, &val))
continue;
if (d->type == IF_REAL)
plotAddRealValue(d, val.rValue);
else if (d->type == IF_COMPLEX)
plotAddComplexValue(d, val.cValue);
else
fprintf(stderr, "OUTpData: unsupported data type\n");
}
#ifdef TCL_MODULE
blt_relink(i, d->vec);
#endif
}
}
int
OUTpData(runDesc *plotPtr, IFvalue *refValue, IFvalue *valuePtr)
{
runDesc *run = plotPtr;
int i;
run->pointCount++;
#ifdef TCL_MODULE
steps_completed = run->pointCount;
#endif
if (interpolated && run->circuit->CKTcurJob->JOBtype == 4) {
if (run->writeOut) {
InterpFileAdd(run, refValue, valuePtr);
}
else {
InterpPlotAdd(run, refValue, valuePtr);
}
return OK;
}
else if (run->writeOut) {
if (run->pointCount == 1) {
fileInit_pass2(run);
}
fileStartPoint(run->fp, run->binary, run->pointCount);
if (run->refIndex != -1) {
if (run->isComplex) {
fileAddComplexValue(run->fp, run->binary, refValue->cValue);
every quarter of a second, to give some feedback without using
too much CPU time */
#ifndef HAS_WINGUI
if (!orflag && !ft_norefprint && !cp_background) {
currclock = clock();
if ((currclock-lastclock) > (0.25*CLOCKS_PER_SEC)) {
fprintf(stdout, " Reference value : % 12.5e\r",
refValue->cValue.real);
fflush(stdout);
lastclock = currclock;
}
}
#endif
}
else {
fileAddRealValue(run->fp, run->binary, refValue->rValue);
#ifndef HAS_WINGUI
if (!orflag && !ft_norefprint && !cp_background) {
currclock = clock();
if ((currclock-lastclock) > (0.25*CLOCKS_PER_SEC)) {
fprintf(stdout, " Reference value : % 12.5e\r",
refValue->rValue);
fflush(stdout);
lastclock = currclock;
}
}
#endif
}
}
for (i = 0; i < run->numData; i++) {
if (run->data[i].outIndex == -1) {
continue;
}
#ifdef TCL_MODULE
blt_add(i, refValue ? refValue->rValue : NAN);
#endif
if (run->data[i].regular) {
if (ft_ngdebug && run->data[i].type == IF_REAL && eq(run->data[i].name, "speedcheck")) {
clock_t cl = clock();
double tt = ((double)cl - (double)startclock) / CLOCKS_PER_SEC;
fileAddRealValue(run->fp, run->binary, tt);
}
else if (run->data[i].type == IF_REAL)
fileAddRealValue(run->fp, run->binary,
valuePtr->v.vec.rVec [run->data[i].outIndex]);
else if (run->data[i].type == IF_COMPLEX)
fileAddComplexValue(run->fp, run->binary,
valuePtr->v.vec.cVec [run->data[i].outIndex]);
else
fprintf(stderr, "OUTpData: unsupported data type\n");
}
else {
IFvalue val;
if (!getSpecial(&run->data[i], run, &val)) {
variables, since this has not already been checked */
if (run->pointCount == 1)
fprintf(stderr, "Warning: unrecognized variable - %s\n",
run->data[i].name);
if (run->isComplex) {
val.cValue.real = 0;
val.cValue.imag = 0;
fileAddComplexValue(run->fp, run->binary, val.cValue);
}
else {
val.rValue = 0;
fileAddRealValue(run->fp, run->binary, val.rValue);
}
continue;
}
if (run->data[i].type == IF_REAL)
fileAddRealValue(run->fp, run->binary, val.rValue);
else if (run->data[i].type == IF_COMPLEX)
fileAddComplexValue(run->fp, run->binary, val.cValue);
else
fprintf(stderr, "OUTpData: unsupported data type\n");
}
#ifdef TCL_MODULE
blt_add(i, valuePtr->v.vec.rVec [run->data[i].outIndex]);
#endif
}
fileEndPoint(run->fp, run->binary);
if (ferror(run->fp)) {
fprintf(stderr, "Warning: rawfile write error !!\n");
shouldstop = TRUE;
}
}
else {
OUTpD_memory(run, refValue, valuePtr);
variable just the same */
#ifndef HAS_WINGUI
if (!orflag && !ft_norefprint && !cp_background) {
currclock = clock();
if ((currclock-lastclock) > (0.25*CLOCKS_PER_SEC)) {
if (run->isComplex) {
fprintf(stdout, " Reference value : % 12.5e\r",
refValue ? refValue->cValue.real : NAN);
} else {
fprintf(stdout, " Reference value : % 12.5e\r",
refValue ? refValue->rValue : NAN);
}
fflush(stdout);
lastclock = currclock;
}
}
#endif
gr_iplot(run->runPlot);
}
if (ft_bpcheck(run->runPlot, run->pointCount) == FALSE)
shouldstop = TRUE;
#ifdef TCL_MODULE
Tcl_ExecutePerLoop();
#elif defined SHARED_MODULE
sh_ExecutePerLoop();
#endif
return OK;
}
int OUTwReference(runDesc*plotPtr, IFvalue *valuePtr, void **refPtr)
{
NG_IGNORE(refPtr);
NG_IGNORE(valuePtr);
NG_IGNORE(plotPtr);
return OK;
}
int
OUTwData(runDesc *plotPtr, int dataIndex, IFvalue *valuePtr, void *refPtr)
{
NG_IGNORE(refPtr);
NG_IGNORE(valuePtr);
NG_IGNORE(dataIndex);
NG_IGNORE(plotPtr);
return OK;
}
int
OUTwEnd(runDesc *plotPtr)
{
NG_IGNORE(plotPtr);
return OK;
}
int
OUTendPlot(runDesc *plotPtr)
{
if (plotPtr->writeOut) {
fileEnd(plotPtr);
} else {
gr_end_iplot();
plotEnd(plotPtr);
}
tfree(valueold);
tfree(valuenew);
freeRun(plotPtr);
return (OK);
}
int
OUTbeginDomain(runDesc *plotPtr, IFuid refName, int refType, IFvalue *outerRefValue)
{
NG_IGNORE(outerRefValue);
NG_IGNORE(refType);
NG_IGNORE(refName);
NG_IGNORE(plotPtr);
return (OK);
}
int
OUTendDomain(runDesc *plotPtr)
{
NG_IGNORE(plotPtr);
return (OK);
}
int
OUTattributes(runDesc *plotPtr, IFuid varName, int param, IFvalue *value)
{
runDesc *run = plotPtr;
GRIDTYPE type;
struct dvec *d;
NG_IGNORE(value);
if (param == OUT_SCALE_LIN)
type = GRID_LIN;
else if (param == OUT_SCALE_LOG)
type = GRID_XLOG;
else
return E_UNSUPP;
if (run->writeOut) {
if (varName) {
int i;
for (i = 0; i < run->numData; i++)
if (!strcmp(varName, run->data[i].name))
run->data[i].gtype = type;
} else {
run->data[run->refIndex].gtype = type;
}
} else {
if (varName) {
for (d = run->runPlot->pl_dvecs; d; d = d->v_next)
if (!strcmp(varName, d->v_name))
d->v_gridtype = type;
} else if (param == PLOT_COMB) {
for (d = run->runPlot->pl_dvecs; d; d = d->v_next)
d->v_plottype = PLOT_COMB;
} else {
run->runPlot->pl_scale->v_gridtype = type;
}
}
return (OK);
}
Write a raw file in batch mode (-b and -r flags).
Writing a raw file in interactive or control mode is handled
by raw_write() in rawfile.c */
static void
fileInit(runDesc *run)
{
char buf[513];
int i;
size_t n;
lastclock = clock();
run->isComplex = FALSE;
for (i = 0; i < run->numData; i++)
if (run->data[i].type == IF_COMPLEX)
run->isComplex = TRUE;
n = 0;
sprintf(buf, "Title: %s\n", run->name);
n += strlen(buf);
fputs(buf, run->fp);
sprintf(buf, "Date: %s\n", datestring());
n += strlen(buf);
fputs(buf, run->fp);
sprintf(buf, "Command: %s-%s, Build %s\n", ft_sim->simulator, ft_sim->version, Spice_Build_Date);
n += strlen(buf);
fputs(buf, run->fp);
sprintf(buf, "Plotname: %s\n", run->type);
n += strlen(buf);
fputs(buf, run->fp);
sprintf(buf, "Flags: %s\n", run->isComplex ? "complex" : "real");
n += strlen(buf);
fputs(buf, run->fp);
sprintf(buf, "No. Variables: %d\n", run->numData);
n += strlen(buf);
fputs(buf, run->fp);
sprintf(buf, "No. Points: ");
n += strlen(buf);
fputs(buf, run->fp);
fflush(run->fp);
if (run->fp == stdout || (run->pointPos = ftell(run->fp)) <= 0)
run->pointPos = (long) n;
fprintf(run->fp, "0 \n");
fprintf(run->fp, "Variables:\n");
printf("No. of Data Columns : %d \n", run->numData);
}
or special parameter names for @ vecors. FIXME This guessing may fail
due to the many options, especially for the @ vectors. */
static int
guess_type(const char *name, char* pltypename)
{
int type;
if (substring("#branch", name))
type = SV_CURRENT;
else if (cieq(name, "time"))
type = SV_TIME;
else if ( cieq(name, "speedcheck"))
type = SV_TIME;
else if (cieq(name, "frequency"))
type = SV_FREQUENCY;
else if (ciprefix("inoise", name))
type = fixme_inoise_type;
else if (ciprefix("onoise", name))
type = fixme_onoise_type;
else if (cieq(name, "temp-sweep"))
type = SV_TEMP;
else if (cieq(name, "res-sweep"))
type = SV_RES;
else if (cieq(name, "i-sweep"))
type = SV_CURRENT;
else if (strstr(name, ":power\0"))
type = SV_POWER;
else if (pltypename && ciprefix("sp", pltypename) && ciprefix("S_", name))
type = SV_SPARAM;
else if (pltypename && ciprefix("sp", pltypename) && ciprefix("Y_", name))
type = SV_ADMITTANCE;
else if (pltypename && ciprefix("sp", pltypename) && ciprefix("Z_", name))
type = SV_IMPEDANCE;
else if (pltypename && ciprefix("sp", pltypename) && cieq(name, "NF"))
type = SV_DB;
else if (pltypename && ciprefix("sp", pltypename) && cieq(name, "NFmin"))
type = SV_DB;
else if (pltypename && ciprefix("sp", pltypename) && cieq(name, "Rn"))
type = SV_IMPEDANCE;
else if (pltypename && ciprefix("sp", pltypename) && cieq(name, "SOpt"))
type = SV_NOTYPE;
else if (pltypename && ciprefix("sp", pltypename) && ciprefix("Cy_", name))
type = SV_CURRENT;
else if (substring("@i", name) && (substring("[c]", name) || substring("[dc]", name) || substring("[current]", name)))
type = SV_CURRENT;
else if ((*name == '@') && substring("[g", name))
type = SV_ADMITTANCE;
else if ((*name == '@') && substring("[c", name))
type = SV_CAPACITANCE;
else if ((*name == '@') && substring("[i", name))
type = SV_CURRENT;
else if ((*name == '@') && substring("[q", name))
type = SV_CHARGE;
else if ((*name == '@') && substring("[p]", name))
type = SV_POWER;
else
type = SV_VOLTAGE;
return type;
}
static void
fileInit_pass2(runDesc *run)
{
int i, type;
bool keepbranch = cp_getvar("keep#branch", CP_BOOL, NULL, 0);
for (i = 0; i < run->numData; i++) {
char *name = run->data[i].name;
type = guess_type(name, NULL);
if (type == SV_CURRENT && !keepbranch) {
char *branch = strstr(name, "#branch");
if (branch)
*branch = '\0';
fprintf(run->fp, "\t%d\ti(%s)\t%s", i, name, ft_typenames(type));
if (branch)
*branch = '#';
} else if (type == SV_VOLTAGE) {
fprintf(run->fp, "\t%d\tv(%s)\t%s", i, name, ft_typenames(type));
} else {
fprintf(run->fp, "\t%d\t%s\t%s", i, name, ft_typenames(type));
}
if (run->data[i].gtype == GRID_XLOG)
fprintf(run->fp, "\tgrid=3");
fprintf(run->fp, "\n");
}
fprintf(run->fp, "%s:\n", run->binary ? "Binary" : "Values");
fflush(run->fp);
if (run->binary) {
rowbuflen = (size_t) (run->numData);
if (run->isComplex)
rowbuflen *= 2;
rowbuf = TMALLOC(double, rowbuflen);
} else {
rowbuflen = 0;
rowbuf = NULL;
}
}
static void
fileStartPoint(FILE *fp, bool bin, int num)
{
if (!bin)
fprintf(fp, "%d\t", num - 1);
column = 0;
}
static void
fileAddRealValue(FILE *fp, bool bin, double value)
{
if (bin)
rowbuf[column++] = value;
else
fprintf(fp, "\t%.*e\n", DOUBLE_PRECISION, value);
}
static void
fileAddComplexValue(FILE *fp, bool bin, IFcomplex value)
{
if (bin) {
rowbuf[column++] = value.real;
rowbuf[column++] = value.imag;
} else {
fprintf(fp, "\t%.*e,%.*e\n", DOUBLE_PRECISION, value.real,
DOUBLE_PRECISION, value.imag);
}
}
static void
fileEndPoint(FILE *fp, bool bin)
{
if (bin)
fwrite(rowbuf, sizeof(double), rowbuflen, fp);
}
static void
fileEnd(runDesc *run)
{
if (run->fp != stdout) {
long place = ftell(run->fp);
fseek(run->fp, run->pointPos, SEEK_SET);
fprintf(run->fp, "%d", run->pointCount);
fprintf(stdout, "\nNo. of Data Rows : %d\n", run->pointCount);
fseek(run->fp, place, SEEK_SET);
} else {
fprintf(stderr, "@@@ %ld %d\n", run->pointPos, run->pointCount);
}
fflush(run->fp);
tfree(rowbuf);
}
static void
plotInit(runDesc *run)
{
struct plot *pl = plot_alloc(run->type);
struct dvec *v;
int i;
pl->pl_title = copy(run->name);
pl->pl_name = copy(run->type);
pl->pl_date = copy(datestring());
pl->pl_ndims = 0;
plot_new(pl);
plot_setcur(pl->pl_typename);
run->runPlot = pl;
run->isComplex = FALSE;
for (i = 0; i < run->numData; i++)
if (run->data[i].type == IF_COMPLEX)
run->isComplex = TRUE;
for (i = 0; i < run->numData; i++) {
dataDesc *dd = &run->data[i];
char *name;
if (isdigit_c(dd->name[0]))
name = tprintf("V(%s)", dd->name);
else
name = copy(dd->name);
v = dvec_alloc(name,
guess_type(name, pl->pl_typename),
run->isComplex
? (VF_COMPLEX | VF_PERMANENT)
: (VF_REAL | VF_PERMANENT),
0, NULL);
vec_new(v);
dd->vec = v;
}
}
If new, and tran or pss, length is TSTOP / TSTEP plus some margin.
If allocated length is exceeded, check progress. When > 20% then extrapolate memory needed,
if less than 20% then just double the size.
If not tran or pss, return fixed value (1024) of memory to be added.
*/
static inline int
vlength2delta(int len)
{
#ifdef SHARED_MODULE
if (savenone)
return 1;
#endif
int points = ft_curckt->ci_ckt->CKTtimeListSize;
if ((ft_curckt->ci_ckt->CKTmode & MODETRAN) && len == 0 && points > 0) {
return points + 100;
}
else if ((ft_curckt->ci_ckt->CKTmode & MODETRAN) && points > 0) {
double timerel = ft_curckt->ci_ckt->CKTtime / ft_curckt->ci_ckt->CKTfinalTime;
the anticipated total time has passed */
if (timerel > 0.2) {
int proposed = (int)(len / timerel) - len + 1;
if (proposed > 0)
return proposed;
return 16;
} else {
return len;
}
}
else if (ft_curckt->ci_ckt->CKTmode & MODEDCOP) {
return 1;
}
else
return 1024;
}
static void
plotAddRealValue(dataDesc *desc, double value)
{
struct dvec *v = desc->vec;
#ifdef SHARED_MODULE
if (savenone)
v->v_length = 0;
#endif
if (v->v_length >= v->v_alloc_length)
dvec_extend(v, v->v_length + vlength2delta(v->v_length));
if (isreal(v)) {
v->v_realdata[v->v_length] = value;
} else {
v->v_compdata[v->v_length].cx_real = value;
v->v_compdata[v->v_length].cx_imag = 0.0;
}
v->v_length++;
v->v_dims[0] = v->v_length;
}
static void
plotAddComplexValue(dataDesc *desc, IFcomplex value)
{
struct dvec *v = desc->vec;
#ifdef SHARED_MODULE
if (savenone)
v->v_length = 0;
#endif
if (v->v_length >= v->v_alloc_length)
dvec_extend(v, v->v_length + vlength2delta(v->v_length));
v->v_compdata[v->v_length].cx_real = value.real;
v->v_compdata[v->v_length].cx_imag = value.imag;
v->v_length++;
v->v_dims[0] = v->v_length;
}
static void
plotEnd(runDesc *run)
{
fprintf(stdout, "\nNo. of Data Rows : %d\n", run->pointCount);
}
* out name, param, andstrchr.
*/
static bool
parseSpecial(char *name, char *dev, char *param, char *ind)
{
char *s;
*dev = *param = *ind = '\0';
if (*name != '@')
return FALSE;
name++;
s = dev;
while (*name && (*name != '['))
*s++ = *name++;
*s = '\0';
if (!*name)
return TRUE;
name++;
s = param;
while (*name && (*name != ',') && (*name != ']'))
*s++ = *name++;
*s = '\0';
if (*name == ']')
return (!name[1] ? TRUE : FALSE);
else if (!*name)
return FALSE;
name++;
s = ind;
while (*name && (*name != ']'))
*s++ = *name++;
*s = '\0';
if (*name && !name[1])
return TRUE;
else
return FALSE;
}
static bool
name_eq(char *n1, char *n2)
{
char buf1[BSIZE_SP], buf2[BSIZE_SP], *s;
if ((s = strchr(n1, '(')) != NULL) {
strcpy(buf1, s);
if ((s = strchr(buf1, ')')) == NULL)
return FALSE;
*s = '\0';
n1 = buf1;
}
if ((s = strchr(n2, '(')) != NULL) {
strcpy(buf2, s);
if ((s = strchr(buf2, ')')) == NULL)
return FALSE;
*s = '\0';
n2 = buf2;
}
return (strcmp(n1, n2) ? FALSE : TRUE);
}
static bool
getSpecial(dataDesc *desc, runDesc *run, IFvalue *val)
{
IFvalue selector;
struct variable *vv;
selector.iValue = desc->specIndex;
if (INPaName(desc->specParamName, val, run->circuit, &desc->specType,
desc->specName, &desc->specFast, ft_sim, &desc->type,
&selector) == OK) {
desc->type &= (IF_REAL | IF_COMPLEX);
return TRUE;
}
if ((vv = if_getstat(run->circuit, &desc->name[1])) != NULL) {
desc->type = IF_REAL;
if (vv->va_type == CP_REAL)
val->rValue = vv->va_real;
else if (vv->va_type == CP_NUM)
val->rValue = vv->va_num;
else if (vv->va_type == CP_BOOL)
val->rValue = (vv->va_bool ? 1.0 : 0.0);
else
return FALSE;
tfree(vv);
return TRUE;
}
return FALSE;
}
static void
freeRun(runDesc *run)
{
int i;
for (i = 0; i < run->numData; i++) {
tfree(run->data[i].name);
tfree(run->data[i].specParamName);
}
tfree(run->data);
tfree(run->type);
tfree(run->name);
tfree(run);
}
int
OUTstopnow(void)
{
if (ft_intrpt || shouldstop) {
ft_intrpt = shouldstop = FALSE;
return (1);
}
return (0);
}
static struct mesg {
char *string;
long flag;
} msgs[] = {
{ "Warning", ERR_WARNING } ,
{ "Fatal error", ERR_FATAL } ,
{ "Panic", ERR_PANIC } ,
{ "Note", ERR_INFO } ,
{ NULL, 0 }
};
void
OUTerror(int flags, char *format, IFuid *names)
{
struct mesg *m;
char buf[BSIZE_SP], *s, *bptr;
int nindex = 0;
if ((flags == ERR_INFO) && cp_getvar("printinfo", CP_BOOL, NULL, 0))
return;
for (m = msgs; m->flag; m++)
if (flags & m->flag)
fprintf(cp_err, "%s: ", m->string);
for (s = format, bptr = buf; *s; s++) {
if (*s == '%' && (s == format || s[-1] != '%') && s[1] == 's') {
if (names[nindex])
strcpy(bptr, names[nindex]);
else
strcpy(bptr, "(null)");
bptr += strlen(bptr);
s++;
nindex++;
} else {
*bptr++ = *s;
}
}
*bptr = '\0';
fprintf(cp_err, "%s\n", buf);
fflush(cp_err);
}
void
OUTerrorf(int flags, const char *format, ...)
{
struct mesg *m;
va_list args;
if ((flags == ERR_INFO) && cp_getvar("printinfo", CP_BOOL, NULL, 0))
return;
for (m = msgs; m->flag; m++)
if (flags & m->flag)
fprintf(cp_err, "%s: ", m->string);
va_start (args, format);
vfprintf(cp_err, format, args);
fputc('\n', cp_err);
fflush(cp_err);
va_end(args);
}
static int
InterpFileAdd(runDesc *run, IFvalue *refValue, IFvalue *valuePtr)
{
int i;
static double timeold = 0.0, timenew = 0.0, timestep = 0.0;
bool nodata = FALSE;
bool interpolatenow = FALSE;
if (run->pointCount == 1) {
fileInit_pass2(run);
timestep = run->circuit->CKTinitTime + run->circuit->CKTstep;
}
if (run->refIndex != -1) {
if (refValue->rValue == run->circuit->CKTinitTime) {
fileStartPoint(run->fp, run->binary, run->pointCount);
fileAddRealValue(run->fp, run->binary, run->circuit->CKTinitTime);
interpolatenow = nodata = FALSE;
}
else if (refValue->rValue == run->circuit->CKTfinalTime) {
fileStartPoint(run->fp, run->binary, run->pointCount);
fileAddRealValue(run->fp, run->binary, run->circuit->CKTfinalTime);
interpolatenow = nodata = FALSE;
}
else if (refValue->rValue == timestep) {
fileStartPoint(run->fp, run->binary, run->pointCount);
fileAddRealValue(run->fp, run->binary, timestep);
timestep += run->circuit->CKTstep;
interpolatenow = nodata = FALSE;
}
else if (refValue->rValue > timestep) {
fileStartPoint(run->fp, run->binary, run->pointCount);
timenew = refValue->rValue;
fileAddRealValue(run->fp, run->binary, timestep);
timestep += run->circuit->CKTstep;
nodata = FALSE;
interpolatenow = TRUE;
}
else {
run->pointCount--;
nodata = TRUE;
interpolatenow = FALSE;
}
#ifndef HAS_WINGUI
if (!orflag && !ft_norefprint && !cp_background) {
currclock = clock();
if ((currclock-lastclock) > (0.25*CLOCKS_PER_SEC)) {
fprintf(stdout, " Reference value : % 12.5e\r",
refValue->rValue);
fflush(stdout);
lastclock = currclock;
}
}
#endif
}
for (i = 0; i < run->numData; i++) {
if (run->data[i].outIndex == -1)
continue;
#ifdef TCL_MODULE
blt_add(i, refValue ? refValue->rValue : NAN);
#endif
if (run->data[i].regular) {
if (!interpolatenow && !nodata) {
valueold[i] = valuePtr->v.vec.rVec [run->data[i].outIndex];
fileAddRealValue(run->fp, run->binary, valueold[i]);
}
else if (interpolatenow) {
double newval;
valuenew[i] = valuePtr->v.vec.rVec [run->data[i].outIndex];
newval = (timestep - run->circuit->CKTstep - timeold)/(timenew - timeold) * (valuenew[i] - valueold[i]) + valueold[i];
fileAddRealValue(run->fp, run->binary, newval);
valueold[i] = valuenew[i];
}
else if (nodata)
but do not store to file */
valueold[i] = valuePtr->v.vec.rVec [run->data[i].outIndex];
} else {
IFvalue val;
if (!getSpecial(&run->data[i], run, &val)) {
variables, since this has not already been checked */
if (run->pointCount == 1)
fprintf(stderr, "Warning: unrecognized variable - %s\n",
run->data[i].name);
val.rValue = 0;
fileAddRealValue(run->fp, run->binary, val.rValue);
continue;
}
if (!interpolatenow && !nodata) {
valueold[i] = val.rValue;
fileAddRealValue(run->fp, run->binary, valueold[i]);
}
else if (interpolatenow) {
double newval;
valuenew[i] = val.rValue;
newval = (timestep - run->circuit->CKTstep - timeold)/(timenew - timeold) * (valuenew[i] - valueold[i]) + valueold[i];
fileAddRealValue(run->fp, run->binary, newval);
valueold[i] = valuenew[i];
}
else if (nodata)
but do not store to file */
valueold[i] = val.rValue;
}
#ifdef TCL_MODULE
blt_add(i, valuePtr->v.vec.rVec [run->data[i].outIndex]);
#endif
}
timeold = refValue->rValue;
fileEndPoint(run->fp, run->binary);
if (ferror(run->fp)) {
fprintf(stderr, "Warning: rawfile write error !!\n");
shouldstop = TRUE;
}
if (ft_bpcheck(run->runPlot, run->pointCount) == FALSE)
shouldstop = TRUE;
#ifdef TCL_MODULE
Tcl_ExecutePerLoop();
#elif defined SHARED_MODULE
sh_ExecutePerLoop();
#endif
return(OK);
}
static int
InterpPlotAdd(runDesc *run, IFvalue *refValue, IFvalue *valuePtr)
{
int i, iscale = -1;
static double timeold = 0.0, timenew = 0.0, timestep = 0.0;
bool nodata = FALSE;
bool interpolatenow = FALSE;
if (run->pointCount == 1)
timestep = run->circuit->CKTinitTime + run->circuit->CKTstep;
for (i = 0; i < run->numData; i++)
if (run->data[i].outIndex == -1) {
iscale = i;
break;
}
if (iscale == -1)
fprintf(stderr, "Error: no scale vector found\n");
#ifdef TCL_MODULE
blt_lockvec(iscale);
#endif
if (refValue->rValue == run->circuit->CKTinitTime) {
plotAddRealValue(&run->data[iscale], refValue->rValue);
interpolatenow = nodata = FALSE;
}
else if (refValue->rValue == run->circuit->CKTfinalTime) {
plotAddRealValue(&run->data[iscale], run->circuit->CKTfinalTime);
interpolatenow = nodata = FALSE;
}
else if (refValue->rValue == timestep) {
plotAddRealValue(&run->data[iscale], timestep);
timestep += run->circuit->CKTstep;
interpolatenow = nodata = FALSE;
}
else if (refValue->rValue > timestep) {
timenew = refValue->rValue;
plotAddRealValue(&run->data[iscale], timestep);
timestep += run->circuit->CKTstep;
nodata = FALSE;
interpolatenow = TRUE;
}
else {
run->pointCount--;
nodata = TRUE;
interpolatenow = FALSE;
}
#ifdef TCL_MODULE
blt_relink(iscale, (run->data[iscale]).vec);
#endif
#ifndef HAS_WINGUI
if (!orflag && !ft_norefprint && !cp_background) {
currclock = clock();
if ((currclock-lastclock) > (0.25*CLOCKS_PER_SEC)) {
fprintf(stdout, " Reference value : % 12.5e\r",
refValue->rValue);
fflush(stdout);
lastclock = currclock;
}
}
#endif
for (i = 0; i < run->numData; i++) {
if (i == iscale)
continue;
#ifdef TCL_MODULE
blt_lockvec(i);
#endif
if (run->data[i].regular) {
if (!interpolatenow && !nodata) {
valueold[i] = valuePtr->v.vec.rVec [run->data[i].outIndex];
plotAddRealValue(&run->data[i], valueold[i]);
}
else if (interpolatenow) {
double newval;
valuenew[i] = valuePtr->v.vec.rVec [run->data[i].outIndex];
newval = (timestep - run->circuit->CKTstep - timeold)/(timenew - timeold) * (valuenew[i] - valueold[i]) + valueold[i];
plotAddRealValue(&run->data[i], newval);
valueold[i] = valuenew[i];
}
else if (nodata)
but do not store to file */
valueold[i] = valuePtr->v.vec.rVec [run->data[i].outIndex];
} else {
IFvalue val;
if (!getSpecial(&run->data[i], run, &val))
continue;
if (!interpolatenow && !nodata) {
valueold[i] = val.rValue;
plotAddRealValue(&run->data[i], valueold[i]);
}
else if (interpolatenow) {
double newval;
valuenew[i] = val.rValue;
newval = (timestep - run->circuit->CKTstep - timeold)/(timenew - timeold) * (valuenew[i] - valueold[i]) + valueold[i];
plotAddRealValue(&run->data[i], newval);
valueold[i] = valuenew[i];
}
else if (nodata)
but do not store to file */
valueold[i] = val.rValue;
}
#ifdef TCL_MODULE
blt_relink(i, (run->data[i]).vec);
#endif
}
timeold = refValue->rValue;
gr_iplot(run->runPlot);
if (ft_bpcheck(run->runPlot, run->pointCount) == FALSE)
shouldstop = TRUE;
#ifdef TCL_MODULE
Tcl_ExecutePerLoop();
#elif defined SHARED_MODULE
sh_ExecutePerLoop();
#endif
return(OK);
}