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Merge pull request #177 from LRossman/contributor-lr

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Changes to get Net1.inp to run
This commit is contained in:
Michael Tryby
2018-06-15 11:53:20 -04:00
committed by GitHub
parent 5b75bde91d f11308fc72
commit 7e73de860a
10 changed files with 321 additions and 167 deletions
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4
LICENSE
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@@ -1,7 +1,11 @@
MIT License
<<<<<<< HEAD
Works are copyright (c) 2018 their respective AUTHORS,
unless such work is in the Public Domain (again, see AUTHORS)
=======
Copyright (c) 2017 Open Water Analytics
>>>>>>> master
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal

28
appveyor.yml
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@@ -9,8 +9,23 @@
version: 2.0.{build}
image:
- Visual Studio 2013
matrix:
allow_failures:
#GROUP: (SUPPORTED/EXPERIMENTAL)
#EXPERIMENTAL is allowed to fail under build matrix
- GROUP: "EXPERIMENTAL"
environment:
matrix:
- APPVEYOR_BUILD_WORKER_IMAGE: Visual Studio 2013
GENERATOR: "Visual Studio 10 2010"
GROUP: "SUPPORTED"
BOOST_ROOT: "C:/Libraries/boost"
# New build on Visual Studio 15 2017
- APPVEYOR_BUILD_WORKER_IMAGE: Visual Studio 2017
GENERATOR: "Visual Studio 15 2017"
GROUP: "EXPERIMENTAL"
BOOST_ROOT: "C:/Libraries/boost_1_67_0"
# called before repo cloning
init:
@@ -18,8 +33,11 @@ init:
- set BUILD_HOME=buildprod
- set TEST_HOME=nrtestsuite
- set NRTEST_SCRIPT=C:\Python27\Scripts
- set GENERATOR="Visual Studio 10 2010"
- set BOOST_ROOT="C:\\Libraries\\boost"
# See values set
- echo %APPVEYOR_BUILD_WORKER_IMAGE%
- echo %BUILD_HOME%
- echo %GENERATOR%
- echo %BOOST_ROOT%
# called after repo clone
install:
@@ -29,7 +47,7 @@ install:
before_build:
- mkdir %BUILD_HOME%
- cd %BUILD_HOME%
- cmake -G %GENERATOR%
- cmake -G "%GENERATOR%"
-DBUILD_TESTS=1
-DBOOST_ROOT="%BOOST_ROOT%"
-DBoost_USE_STATIC_LIBS="ON" ..

13
run/main.c
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@@ -5,9 +5,9 @@
#define MAXMSG 255 /* Max. # characters in message text */
#define MAXWARNCODE 99
/* text copied here, no more need of include "text.h" */
#define FMT01 "\nEPANET Version %d.%d.%d\n"
#define FMT01 "\nEPANET Version %d.%d.%d"
#define FMT03 "\n Correct syntax is:\n %s <input file> <output file>\n"
#define FMT09 "\nEPANET completed.\n"
#define FMT09 "\n\nEPANET completed."
#define FMT10 "\nEPANET completed. There are warnings."
#define FMT11 "\nEPANET completed. There are errors."
@@ -87,7 +87,8 @@ int main(int argc, char *argv[])
/* Call the main control function */
if (strlen(f2)> 0) {
/* use stdout for progress messages */
errcode = ENepanet(f1,f2,f3,writeConsole);
//errcode = ENepanet(f1,f2,f3,writeConsole);
errcode = ENepanet(f1, f2, f3, NULL);
}
else {
/* use stdout for reporting, no progress messages */
@@ -101,21 +102,21 @@ int main(int argc, char *argv[])
return(0);
}
else {
if (errcode > MAXWARNCODE) printf("\n Fatal Error: ");
ENgeterror(errcode, errmsg, MAXMSG);
writeConsole(errmsg);
if (errcode > MAXWARNCODE) {
/* error */
// error //
writeConsole(FMT11);
return(errcode);
}
else {
/* warning */
// warning //
writeConsole(FMT10);
return(0);
}
}
} /* End of main */

138
src/epanet.c
View File

@@ -108,6 +108,10 @@ execute function x and set the error code equal to its return value.
#ifdef __WIN32__
#define WINDOWS
#endif
#ifdef WINDOWS
#include <windows.h>
#endif
/************************************************************/
#include <stdio.h>
@@ -125,7 +129,6 @@ execute function x and set the error code equal to its return value.
#include "text.h"
#include "types.h"
#define EXTERN
#include "epanet2.h"
#include "vars.h"
/****************************************************************
@@ -166,218 +169,295 @@ int DLLEXPORT ENepanet(char *f1, char *f2, char *f3,
EN_free(_defaultModel);
return (errcode);
}
int DLLEXPORT ENopen(char *f1, char *f2, char *f3) {
int errcode = 0;
ERRCODE(EN_alloc(&_defaultModel));
EN_open(_defaultModel, f1, f2, f3);
return (errcode);
}
int DLLEXPORT ENsaveinpfile(char *filename) {
return EN_saveinpfile(_defaultModel, filename);
}
int DLLEXPORT ENclose() { return EN_close(_defaultModel); }
int DLLEXPORT ENsolveH() { return EN_solveH(_defaultModel); }
int DLLEXPORT ENsaveH() { return EN_saveH(_defaultModel); }
int DLLEXPORT ENopenH() { return EN_openH(_defaultModel); }
int DLLEXPORT ENinitH(int flag) { return EN_initH(_defaultModel, flag); }
int DLLEXPORT ENrunH(long *t) { return EN_runH(_defaultModel, t); }
int DLLEXPORT ENnextH(long *tstep) { return EN_nextH(_defaultModel, tstep); }
int DLLEXPORT ENcloseH() { return EN_closeH(_defaultModel); }
int DLLEXPORT ENsavehydfile(char *filename) {
return EN_savehydfile(_defaultModel, filename);
}
int DLLEXPORT ENusehydfile(char *filename) {
return EN_usehydfile(_defaultModel, filename);
}
int DLLEXPORT ENsolveQ() { return EN_solveQ(_defaultModel); }
int DLLEXPORT ENopenQ() { return EN_openQ(_defaultModel); }
int DLLEXPORT ENinitQ(int saveflag) {
return EN_initQ(_defaultModel, saveflag);
}
int DLLEXPORT ENrunQ(long *t) { return EN_runQ(_defaultModel, t); }
int DLLEXPORT ENnextQ(long *tstep) { return EN_nextQ(_defaultModel, tstep); }
int DLLEXPORT ENstepQ(long *tleft) { return EN_stepQ(_defaultModel, tleft); }
int DLLEXPORT ENcloseQ() { return EN_closeQ(_defaultModel); }
int DLLEXPORT ENwriteline(char *line) {
return EN_writeline(_defaultModel, line);
}
int DLLEXPORT ENreport() { return EN_report(_defaultModel); }
int DLLEXPORT ENresetreport() { return EN_resetreport(_defaultModel); }
int DLLEXPORT ENsetreport(char *s) { return EN_setreport(_defaultModel, s); }
int DLLEXPORT ENgetversion(int *v) { return EN_getversion(v); }
int DLLEXPORT ENgetcontrol(int cindex, int *ctype, int *lindex,
EN_API_FLOAT_TYPE *setting, int *nindex,
EN_API_FLOAT_TYPE *level) {
return EN_getcontrol(_defaultModel, cindex, ctype, lindex, setting, nindex,
level);
}
int DLLEXPORT ENgetcount(int code, int *count) {
return EN_getcount(_defaultModel, (EN_CountType)code, count);
}
int DLLEXPORT ENgetoption(int code, EN_API_FLOAT_TYPE *value) {
return EN_getoption(_defaultModel, (EN_Option)code, value);
}
int DLLEXPORT ENgettimeparam(int code, long *value) {
return EN_gettimeparam(_defaultModel, code, value);
}
int DLLEXPORT ENgetflowunits(int *code) {
return EN_getflowunits(_defaultModel, code);
}
int DLLEXPORT ENsetflowunits(int code) {
return EN_setflowunits(_defaultModel, code);
}
int DLLEXPORT ENgetpatternindex(char *id, int *index) {
return EN_getpatternindex(_defaultModel, id, index);
}
int DLLEXPORT ENgetpatternid(int index, char *id) {
return EN_getpatternid(_defaultModel, index, id);
}
int DLLEXPORT ENgetpatternlen(int index, int *len) {
return EN_getpatternlen(_defaultModel, index, len);
}
int DLLEXPORT ENgetpatternvalue(int index, int period,
EN_API_FLOAT_TYPE *value) {
return EN_getpatternvalue(_defaultModel, index, period, value);
}
int DLLEXPORT ENgetcurveindex(char *id, int *index) {
return EN_getcurveindex(_defaultModel, id, index);
}
int DLLEXPORT ENgetcurveid(int index, char *id) {
return EN_getcurveid(_defaultModel, index, id);
}
int DLLEXPORT ENgetcurvelen(int index, int *len) {
return EN_getcurvelen(_defaultModel, index, len);
}
int DLLEXPORT ENgetcurvevalue(int index, int pnt, EN_API_FLOAT_TYPE *x,
EN_API_FLOAT_TYPE *y) {
return EN_getcurvevalue(_defaultModel, index, pnt, x, y);
}
int DLLEXPORT ENgetqualtype(int *qualcode, int *tracenode) {
return EN_getqualtype(_defaultModel, qualcode, tracenode);
}
int DLLEXPORT ENgetqualinfo(int *qualcode, char *chemname, char *chemunits,
int *tracenode) {
return EN_getqualinfo(_defaultModel, qualcode, chemname, chemunits,
tracenode);
}
int DLLEXPORT ENgeterror(int errcode, char *errmsg, int n) {
return EN_geterror(errcode, errmsg, n);
}
int DLLEXPORT ENgetstatistic(int code, EN_API_FLOAT_TYPE *value) {
return EN_getstatistic(_defaultModel, code, value);
}
int DLLEXPORT ENgetnodeindex(char *id, int *index) {
return EN_getnodeindex(_defaultModel, id, index);
}
int DLLEXPORT ENgetnodeid(int index, char *id) {
return EN_getnodeid(_defaultModel, index, id);
}
int DLLEXPORT ENgetnodetype(int index, int *code) {
return EN_getnodetype(_defaultModel, index, code);
}
int DLLEXPORT ENgetcoord(int index, EN_API_FLOAT_TYPE *x,
EN_API_FLOAT_TYPE *y) {
return EN_getcoord(_defaultModel, index, x, y);
}
int DLLEXPORT ENsetcoord(int index, EN_API_FLOAT_TYPE x, EN_API_FLOAT_TYPE y) {
return EN_setcoord(_defaultModel, index, x, y);
}
int DLLEXPORT ENgetnodevalue(int index, int code, EN_API_FLOAT_TYPE *value) {
return EN_getnodevalue(_defaultModel, index, code, value);
}
int DLLEXPORT ENgetlinkindex(char *id, int *index) {
return EN_getlinkindex(_defaultModel, id, index);
}
int DLLEXPORT ENgetlinkid(int index, char *id) {
return EN_getlinkid(_defaultModel, index, id);
}
int DLLEXPORT ENgetlinktype(int index, EN_LinkType *code) {
return EN_getlinktype(_defaultModel, index, code);
}
int DLLEXPORT ENgetlinknodes(int index, int *node1, int *node2) {
return EN_getlinknodes(_defaultModel, index, node1, node2);
}
int DLLEXPORT ENgetlinkvalue(int index, int code, EN_API_FLOAT_TYPE *value) {
return EN_getlinkvalue(_defaultModel, index, (EN_LinkProperty)code, value);
}
int DLLEXPORT ENgetcurve(int curveIndex, char *id, int *nValues,
EN_API_FLOAT_TYPE **xValues,
EN_API_FLOAT_TYPE **yValues) {
return EN_getcurve(_defaultModel, curveIndex, id, nValues, xValues, yValues);
}
int DLLEXPORT ENsetcontrol(int cindex, int ctype, int lindex,
EN_API_FLOAT_TYPE setting, int nindex,
EN_API_FLOAT_TYPE level) {
return EN_setcontrol(_defaultModel, cindex, ctype, lindex, setting, nindex,
level);
}
int DLLEXPORT ENsetnodevalue(int index, int code, EN_API_FLOAT_TYPE v) {
return EN_setnodevalue(_defaultModel, index, code, v);
}
int DLLEXPORT ENsetlinkvalue(int index, int code, EN_API_FLOAT_TYPE v) {
return EN_setlinkvalue(_defaultModel, index, code, v);
}
int DLLEXPORT ENaddpattern(char *id) {
return EN_addpattern(_defaultModel, id);
}
int DLLEXPORT ENsetpattern(int index, EN_API_FLOAT_TYPE *f, int n) {
return EN_setpattern(_defaultModel, index, f, n);
}
int DLLEXPORT ENsetpatternvalue(int index, int period,
EN_API_FLOAT_TYPE value) {
return EN_setpatternvalue(_defaultModel, index, period, value);
}
int DLLEXPORT ENaddcurve(char *id) { return EN_addcurve(_defaultModel, id); }
int DLLEXPORT ENsetcurve(int index, EN_API_FLOAT_TYPE *x, EN_API_FLOAT_TYPE *y,
int n) {
return EN_setcurve(_defaultModel, index, x, y, n);
}
int DLLEXPORT ENsetcurvevalue(int index, int pnt, EN_API_FLOAT_TYPE x,
EN_API_FLOAT_TYPE y) {
return EN_setcurvevalue(_defaultModel, index, pnt, x, y);
}
int DLLEXPORT ENsettimeparam(int code, long value) {
return EN_settimeparam(_defaultModel, code, value);
}
int DLLEXPORT ENsetoption(int code, EN_API_FLOAT_TYPE v) {
return EN_setoption(_defaultModel, code, v);
}
int DLLEXPORT ENsetstatusreport(int code) {
return EN_setstatusreport(_defaultModel, code);
}
int DLLEXPORT ENsetqualtype(int qualcode, char *chemname, char *chemunits,
char *tracenode) {
return EN_setqualtype(_defaultModel, qualcode, chemname, chemunits,
tracenode);
}
int DLLEXPORT ENgetheadcurveindex(int index, int *curveindex) {
return EN_getheadcurveindex(_defaultModel, index, curveindex);
}
int DLLEXPORT ENsetheadcurveindex(int index, int curveindex) {
return EN_setheadcurveindex(_defaultModel, index, curveindex);
}
int DLLEXPORT ENgetpumptype(int index, int *type) {
return EN_getpumptype(_defaultModel, index, type);
}
int DLLEXPORT ENgetnumdemands(int nodeIndex, int *numDemands) {
return EN_getnumdemands(_defaultModel, nodeIndex, numDemands);
}
int DLLEXPORT ENgetbasedemand(int nodeIndex, int demandIdx,
EN_API_FLOAT_TYPE *baseDemand) {
return EN_getbasedemand(_defaultModel, nodeIndex, demandIdx, baseDemand);
}
int DLLEXPORT ENsetbasedemand(int nodeIndex, int demandIdx,
EN_API_FLOAT_TYPE baseDemand) {
return EN_setbasedemand(_defaultModel, nodeIndex, demandIdx, baseDemand);
}
int DLLEXPORT ENgetdemandpattern(int nodeIndex, int demandIdx, int *pattIdx) {
return EN_getdemandpattern(_defaultModel, nodeIndex, demandIdx, pattIdx);
}
int DLLEXPORT ENgetaveragepatternvalue(int index, EN_API_FLOAT_TYPE *value) {
return EN_getaveragepatternvalue(_defaultModel, index, value);
}
int DLLEXPORT ENgetrule(int index, int *nPremises, int *nTrueActions, int *nFalseActions, EN_API_FLOAT_TYPE *priority) {
int DLLEXPORT ENgetrule(int index, int *nPremises, int *nTrueActions,
int *nFalseActions, EN_API_FLOAT_TYPE *priority) {
return EN_getrule(_defaultModel, index, nPremises, nTrueActions, nFalseActions, priority);
}
@@ -405,19 +485,23 @@ int DLLEXPORT ENsetpremisevalue(int indexRule, int indexPremise, EN_API_FLOAT_TY
return EN_setpremisevalue(_defaultModel, indexRule, indexPremise, value);
}
int DLLEXPORT ENgettrueaction(int indexRule, int indexAction, int *indexLink, int *status, EN_API_FLOAT_TYPE *setting){
int DLLEXPORT ENgettrueaction(int indexRule, int indexAction, int *indexLink,
int *status, EN_API_FLOAT_TYPE *setting){
return EN_gettrueaction(_defaultModel, indexRule, indexAction, indexLink, status, setting);
}
int DLLEXPORT ENsettrueaction(int indexRule, int indexAction, int indexLink, int status, EN_API_FLOAT_TYPE setting){
int DLLEXPORT ENsettrueaction(int indexRule, int indexAction, int indexLink,
int status, EN_API_FLOAT_TYPE setting){
return EN_settrueaction(_defaultModel, indexRule, indexAction, indexLink, status, setting);
}
int DLLEXPORT ENgetfalseaction(int indexRule, int indexAction, int *indexLink, int *status, EN_API_FLOAT_TYPE *setting){
int DLLEXPORT ENgetfalseaction(int indexRule, int indexAction, int *indexLink,
int *status, EN_API_FLOAT_TYPE *setting){
return EN_getfalseaction(_defaultModel, indexRule, indexAction, indexLink, status, setting);
}
int DLLEXPORT ENsetfalseaction(int indexRule, int indexAction, int indexLink, int status, EN_API_FLOAT_TYPE setting){
int DLLEXPORT ENsetfalseaction(int indexRule, int indexAction, int indexLink,
int status, EN_API_FLOAT_TYPE setting){
return EN_setfalseaction(_defaultModel, indexRule, indexAction, indexLink, status, setting);
}
@@ -428,16 +512,20 @@ int DLLEXPORT ENgetruleID(int indexRule, char* id){
int DLLEXPORT ENsetlinktype(char *id, EN_LinkType toType) {
return EN_setlinktype(_defaultModel, id, toType);
}
int DLLEXPORT ENaddnode(char *id, EN_NodeType nodeType) {
return EN_addnode(_defaultModel, id, nodeType);
}
int DLLEXPORT ENaddlink(char *id, EN_LinkType linkType, char *fromNode,
char *toNode) {
return EN_addlink(_defaultModel, id, linkType, fromNode, toNode);
}
int DLLEXPORT ENdeletelink(int index) {
return EN_deletelink(_defaultModel, index);
}
int DLLEXPORT ENdeletenode(int index) {
return EN_deletenode(_defaultModel, index);
}
@@ -707,7 +795,6 @@ int DLLEXPORT EN_solveH(EN_Project *p)
tstep = 0;
ERRCODE(EN_runH(p, &t));
ERRCODE(EN_nextH(p, &tstep));
/*** Updated 6/24/02 ***/
writecon("\b\b\b\b\b\b\b\b\b\b");
} while (tstep > 0);
@@ -825,8 +912,10 @@ int DLLEXPORT EN_initH(EN_Project *p, int flag)
errcode = openhydfile(p);
if (!errcode)
p->save_options.Saveflag = TRUE;
else
else {
errmsg(p, errcode);
return errcode;
}
}
/* Initialize hydraulics */
@@ -1546,7 +1635,7 @@ int DLLEXPORT EN_geterror(int errcode, char *errmsg, int n) {
strncpy(errmsg, WARN6, n);
break;
default:
geterrmsg(n, newMsg);
geterrmsg(errcode, newMsg);
strncpy(errmsg, newMsg, n);
}
if (strlen(errmsg) == 0)
@@ -3330,7 +3419,7 @@ int openhydfile(EN_Project *p)
out->HydFile = NULL;
switch (out->Hydflag) {
case SCRATCH:
getTmpName(p, out->HydFname);
getTmpName(out->HydFname);
out->HydFile = fopen(out->HydFname, "w+b");
break;
case SAVE:
@@ -3423,7 +3512,7 @@ int openoutfile(EN_Project *p)
// else if ( (OutFile = tmpfile()) == NULL)
else
{
getTmpName(p, out->OutFname);
getTmpName(out->OutFname);
if ((out->OutFile = fopen(out->OutFname, "w+b")) == NULL)
{
writecon(FMT08);
@@ -3441,7 +3530,7 @@ int openoutfile(EN_Project *p)
if (!errcode) {
if (rep->Tstatflag != SERIES) {
// if ( (TmpOutFile = tmpfile()) == NULL) errcode = 304;
getTmpName(p, out->TmpFname);
getTmpName(out->TmpFname);
out->TmpOutFile = fopen(out->TmpFname, "w+b");
if (out->TmpOutFile == NULL)
errcode = 304;
@@ -3748,17 +3837,35 @@ void freedata(EN_Project *p)
----------------------------------------------------------------
*/
/*** New function for 2.00.12 ***/
char *getTmpName(EN_Project *p, char *fname)
char *getTmpName(char *fname)
//
// Input: fname = file name string
// Output: returns pointer to file name
// Purpose: creates a temporary file name with path prepended to it.
//
{
out_file_t *out = &p->out_files;
#ifdef _WIN32
char* name = NULL;
// --- use Windows _tempnam function to get a pointer to an
// unused file name that begins with "en"
name = _tempnam(NULL, "en");
if (name == NULL) return NULL;
// --- copy the file name to fname
if (strlen(name) < MAXFNAME) strncpy(fname, name, MAXFNAME);
else fname = NULL;
// --- free the pointer returned by _tempnam
if (name) free(name);
/*
/////////////////// DEPRECATED /////////////////////////////////////
// --- for Windows systems:
#ifdef WINDOWS
out_file_t *out = &p->out_files;
// --- use system function tmpnam() to create a temporary file name
char name[MAXFNAME + 1];
int n;
@@ -3782,6 +3889,7 @@ char *getTmpName(EN_Project *p, char *fname)
// --- now add the prefix to the file name
strcat(fname, name);
*/
// --- for non-Windows systems:
#else

272
src/funcs.h
View File

@@ -31,32 +31,32 @@ AUTHOR: L. Rossman
#include "types.h"
void initpointers(EN_Project *p); /* Initializes pointers */
int allocdata(EN_Project *p); /* Allocates memory */
void freeTmplist(STmplist *); /* Frees items in linked list */
void freeFloatlist(SFloatlist *); /* Frees list of floats */
void freedata(EN_Project *p); /* Frees allocated memory */
void initpointers(EN_Project *p); /* Initializes pointers */
int allocdata(EN_Project *p); /* Allocates memory */
void freeTmplist(STmplist *); /* Frees items in linked list */
void freeFloatlist(SFloatlist *); /* Frees list of floats */
void freedata(EN_Project *p); /* Frees allocated memory */
int openfiles(EN_Project *p, char *,char *,char *); /* Opens input & report files */
int openhydfile(EN_Project *p); /* Opens hydraulics file */
int openoutfile(EN_Project *p); /* Opens binary output file */
int strcomp(char *, char *); /* Compares two strings */
char* getTmpName(EN_Project *p, char* fname); /* Gets temporary file name */
double interp(int, double *,double *, double); /* Interpolates a data curve */
int openhydfile(EN_Project *p); /* Opens hydraulics file */
int openoutfile(EN_Project *p); /* Opens binary output file */
int strcomp(char *, char *); /* Compares two strings */
char* getTmpName(char* fname); /* Gets temporary file name */
double interp(int, double *,double *, double); /* Interpolates a data curve */
int findnode(EN_Network *n, char *); /* Finds node's index from ID */
int findlink(EN_Network *n, char *); /* Finds link's index from ID */
int findtank(EN_Network *n, int); /* Find tank index from node index */ // (AH)
int findvalve(EN_Network *n, int); /* Find valve index from node index */ // (AH)
int findpump(EN_Network *n, int); /* Find pump index from node index */ // (AH)
char *geterrmsg(int errcode, char *msg); /* Gets text of error message */
void errmsg(EN_Project *p, int); /* Reports program error */
void writecon(char *); /* Writes text to console */
int findnode(EN_Network *n, char *); /* Finds node's index from ID */
int findlink(EN_Network *n, char *); /* Finds link's index from ID */
int findtank(EN_Network *n, int); /* Find tank index from node index */ // (AH)
int findvalve(EN_Network *n, int); /* Find valve index from node index */ // (AH)
int findpump(EN_Network *n, int); /* Find pump index from node index */ // (AH)
char *geterrmsg(int errcode, char *msg); /* Gets text of error message */
void errmsg(EN_Project *p, int); /* Reports program error */
void writecon(char *); /* Writes text to console */
void writewin(void (*vp)(char *), char *); /* Passes text to calling app */
/* ------- INPUT1.C --------------------*/
int getdata(EN_Project *pr); /* Gets network data */
void setdefaults(EN_Project *pr); /* Sets default values */
void initreport(report_options_t *r); /* Initializes report options */
void initreport(report_options_t *r); /* Initializes report options */
void adjustdata(EN_Project *pr); /* Adjusts input data */
int inittanks(EN_Project *pr); /* Initializes tank levels */
void initunits(EN_Project *pr); /* Determines reporting units */
@@ -65,23 +65,23 @@ void convertunits(EN_Project *pr); /* Converts data to std. uni
/* -------- INPUT2.C -------------------*/
int netsize(EN_Project *pr); /* Determines network size */
int readdata(EN_Project *pr); /* Reads in network data */
int newline(EN_Project *pr, int, char *); /* Processes new line of data */
int addnodeID(EN_Network *n, int, char *); /* Adds node ID to data base */
int addlinkID(EN_Network *n, int, char *); /* Adds link ID to data base */
int addpattern(parser_data_t *par, char *); /* Adds pattern to data base */
int addcurve(parser_data_t *par, char *); /* Adds curve to data base */
STmplist *findID(char *, STmplist *); /* Locates ID on linked list */
int newline(EN_Project *pr, int, char *); /* Processes new line of data */
int addnodeID(EN_Network *n, int, char *); /* Adds node ID to data base */
int addlinkID(EN_Network *n, int, char *); /* Adds link ID to data base */
int addpattern(parser_data_t *par, char *); /* Adds pattern to data base */
int addcurve(parser_data_t *par, char *); /* Adds curve to data base */
STmplist *findID(char *, STmplist *); /* Locates ID on linked list */
int unlinked(EN_Project *pr); /* Checks for unlinked nodes */
int getpumpparams(EN_Project *pr); /* Computes pump curve coeffs.*/
int getpatterns(EN_Project *pr); /* Gets pattern data from list*/
int getcurves(EN_Project *pr); /* Gets curve data from list */
int findmatch(char *, char *[]); /* Finds keyword in line */
int match(const char *, const char *); /* Checks for word match */
int findmatch(char *, char *[]); /* Finds keyword in line */
int match(const char *, const char *); /* Checks for word match */
int gettokens(char *s, char** Tok, int maxToks, char *comment); /* Tokenizes input line */
int getfloat(char *, double *); /* Converts string to double */
double hour(char *, char *); /* Converts time to hours */
int setreport(EN_Project *pr, char *); /* Processes reporting command*/
void inperrmsg(EN_Project *pr, int,int,char *); /* Input error message */
int getfloat(char *, double *); /* Converts string to double */
double hour(char *, char *); /* Converts time to hours */
int setreport(EN_Project *pr, char *); /* Processes reporting command*/
void inperrmsg(EN_Project *pr, int,int,char *); /* Input error message */
/* ---------- INPUT3.C -----------------*/
int juncdata(EN_Project *pr); /* Processes junction data */
@@ -104,188 +104,206 @@ int statusdata(EN_Project *pr); /* Processes link status dat
int reportdata(EN_Project *pr); /* Processes report options */
int timedata(EN_Project *pr); /* Processes time options */
int optiondata(EN_Project *pr); /* Processes analysis options */
int optionchoice(EN_Project *pr, int); /* Processes option choices */
int optionvalue(EN_Project *pr, int); /* Processes option values */
int getpumpcurve(EN_Project *pr, int); /* Constructs a pump curve */
int powercurve(double, double, double,/* Coeffs. of power pump curve*/
int optionchoice(EN_Project *pr, int); /* Processes option choices */
int optionvalue(EN_Project *pr, int); /* Processes option values */
int getpumpcurve(EN_Project *pr, int); /* Constructs a pump curve */
int powercurve(double, double, double, /* Coeffs. of power pump curve*/
double, double, double *,
double *, double *);
int valvecheck(EN_Project *pr, int, int, int); /* Checks valve placement */
int valvecheck(EN_Project *pr, int, int, int); /* Checks valve placement */
void changestatus(EN_Network *net, int, StatType, double); /* Changes status of a link */
/* -------------- RULES.C --------------*/
void initrules(rules_t *rules); /* Initializes rule base */
void addrule(parser_data_t *par, char *); /* Adds rule to rule base */
void addrule(parser_data_t *par, char *); /* Adds rule to rule base */
int allocrules(EN_Project *pr); /* Allocates memory for rule */
int ruledata(EN_Project *pr); /* Processes rule input data */
int checkrules(EN_Project *pr, long); /* Checks all rules */
int checkrules(EN_Project *pr, long); /* Checks all rules */
void freerules(EN_Project *pr); /* Frees rule base memory */
int writeRuleinInp(EN_Project *pr, FILE *f, /* Writes rule to an INP file */
int RuleIdx);
/* ------------- REPORT.C --------------*/
int writereport(EN_Project *pr); /* Writes formatted report */
void writelogo(EN_Project *pr); /* Writes program logo */
void writesummary(EN_Project *pr); /* Writes network summary */
void writehydstat(EN_Project *pr, int,double); /* Writes hydraulic status */
void writehydstat(EN_Project *pr, int,double); /* Writes hydraulic status */
void writeenergy(EN_Project *pr); /* Writes energy usage */
int writeresults(EN_Project *pr); /* Writes node/link results */
void writeheader(EN_Project *pr, int,int); /* Writes heading on report */
void writeline(EN_Project *pr, char *); /* Writes line to report file */
void writerelerr(EN_Project *pr, int, double); /* Writes convergence error */
void writeheader(EN_Project *pr, int,int); /* Writes heading on report */
void writeline(EN_Project *pr, char *); /* Writes line to report file */
void writerelerr(EN_Project *pr, int, double); /* Writes convergence error */
void writestatchange(EN_Project *pr, int,char,char); /* Writes link status change */
void writecontrolaction(EN_Project *pr, int, int); /* Writes control action taken*/
void writeruleaction(EN_Project *pr, int, char *); /* Writes rule action taken */
int writehydwarn(EN_Project *pr, int,double); /* Writes hydraulic warnings */
void writehyderr(EN_Project *pr, int); /* Writes hydraulic error msg.*/
int disconnected(EN_Project *pr); /* Checks for disconnections */
int disconnected(EN_Project *pr); /* Checks for disconnections */
void marknodes(EN_Project *pr, int, int *, char *); /* Identifies connected nodes */
void getclosedlink(EN_Project *pr, int, char *); /* Finds a disconnecting link */
void writelimits(EN_Project *pr, int,int); /* Writes reporting limits */
int checklimits(report_options_t *rep, double *,int,int); /* Checks variable limits */
void writetime(EN_Project *pr, char *); /* Writes current clock time */
char *clocktime(char *, long); /* Converts time to hrs:min */
char *fillstr(char *, char, int); /* Fills string with character*/
int getnodetype(EN_Network *net, int); /* Determines node type */
char *clocktime(char *, long); /* Converts time to hrs:min */
char *fillstr(char *, char, int); /* Fills string with character*/
int getnodetype(EN_Network *net, int); /* Determines node type */
/* --------- HYDRAUL.C -----------------*/
int openhyd(EN_Project *pr); /* Opens hydraulics solver */
/*** Updated 3/1/01 ***/
void inithyd(EN_Project *pr, int initFlags); /* Re-sets initial conditions */
void inithyd(EN_Project *pr, int initFlags); /* Re-sets initial conditions */
int runhyd(EN_Project *pr, long *); /* Solves 1-period hydraulics */
int nexthyd(EN_Project *pr, long *); /* Moves to next time period */
int runhyd(EN_Project *pr, long *); /* Solves 1-period hydraulics */
int nexthyd(EN_Project *pr, long *); /* Moves to next time period */
void closehyd(EN_Project *pr); /* Closes hydraulics solver */
int allocmatrix(EN_Project *pr); /* Allocates matrix coeffs. */
void freematrix(EN_Project *pr); /* Frees matrix coeffs. */
void initlinkflow(EN_Project *pr, int, char, double); /* Initializes link flow */
void setlinkflow(EN_Project *pr, int, double); /* Sets link flow via headloss*/
void setlinkstatus(EN_Project *pr, int, char, StatType *, double *); /* Sets link status */
void initlinkflow(EN_Project *pr, int, char,
double); /* Initializes link flow */
void setlinkflow(EN_Project *pr, int, double); /* Sets link flow via headloss*/
void setlinkstatus(EN_Project *pr, int, char,
StatType *, double *); /* Sets link status */
void setlinksetting(EN_Project *pr, int, double, StatType *, double *); /* Sets pump/valve setting */
void setlinksetting(EN_Project *pr, int, double,
StatType *, double *); /* Sets pump/valve setting */
void resistance(EN_Project *pr, int); /* Computes resistance coeff. */
void resistance(EN_Project *pr, int); /* Computes resistance coeff. */
void demands(EN_Project *pr); /* Computes current demands */
int controls(EN_Project *pr); /* Controls link settings */
long timestep(EN_Project *pr); /* Computes new time step */
int tanktimestep(EN_Project *pr, long *); /* Time till tanks fill/drain */
void controltimestep(EN_Project *pr, long *); /* Time till control action */
void ruletimestep(EN_Project *pr, long *); /* Time till rule action */
void addenergy(EN_Project *pr, long); /* Accumulates energy usage */
void getenergy(EN_Project *pr, int, double *, double *); /* Computes link energy use */
void tanklevels(EN_Project *pr, long); /* Computes new tank levels */
double tankvolume(EN_Project *pr, int,double); /* Finds tank vol. from grade */
double tankgrade(EN_Project *pr, int,double); /* Finds tank grade from vol. */
int netsolve(EN_Project *pr, int *,double *); /* Solves network equations */
int badvalve(EN_Project *pr, int); /* Checks for bad valve */
int tanktimestep(EN_Project *pr, long *); /* Time till tanks fill/drain */
void controltimestep(EN_Project *pr, long *); /* Time till control action */
void ruletimestep(EN_Project *pr, long *); /* Time till rule action */
void addenergy(EN_Project *pr, long); /* Accumulates energy usage */
void getenergy(EN_Project *pr, int, double *,
double *); /* Computes link energy use */
void tanklevels(EN_Project *pr, long); /* Computes new tank levels */
double tankvolume(EN_Project *pr, int,double); /* Finds tank vol. from grade */
double tankgrade(EN_Project *pr, int,double); /* Finds tank grade from vol. */
int netsolve(EN_Project *pr, int *,double *); /* Solves network equations */
int badvalve(EN_Project *pr, int); /* Checks for bad valve */
int valvestatus(EN_Project *pr); /* Updates valve status */
int linkstatus(EN_Project *pr); /* Updates link status */
StatType cvstatus(EN_Project *pr, StatType,double,double); /* Updates CV status */
StatType pumpstatus(EN_Project *pr, int,double); /* Updates pump status */
StatType prvstatus(EN_Project *pr, int,StatType,double,double,double); /* Updates PRV status */
StatType cvstatus(EN_Project *pr, StatType,
double,double); /* Updates CV status */
StatType pumpstatus(EN_Project *pr, int,double); /* Updates pump status */
StatType prvstatus(EN_Project *pr, int,StatType,
double,double,double); /* Updates PRV status */
StatType psvstatus(EN_Project *pr, int,StatType,double,double,double); /* Updates PSV status */
StatType psvstatus(EN_Project *pr, int,StatType,
double,double,double); /* Updates PSV status */
StatType fcvstatus(EN_Project *pr, int,StatType,double,double); /* Updates FCV status */
StatType fcvstatus(EN_Project *pr, int,StatType,
double,double); /* Updates FCV status */
void tankstatus(EN_Project *pr, int,int,int); /* Checks if tank full/empty */
void tankstatus(EN_Project *pr, int,int,int); /* Checks if tank full/empty */
int pswitch(EN_Project *pr); /* Pressure switch controls */
double newflows(EN_Project *pr); /* Updates link flows */
void newcoeffs(EN_Project *pr); /* Computes matrix coeffs. */
void linkcoeffs(EN_Project *pr); /* Computes link coeffs. */
void nodecoeffs(EN_Project *pr); /* Computes node coeffs. */
void valvecoeffs(EN_Project *pr); /* Computes valve coeffs. */
void pipecoeff(EN_Project *pr, int); /* Computes pipe coeff. */
double DWcoeff(EN_Project *pr, int, double *); /* Computes D-W coeff. */
void pumpcoeff(EN_Project *pr, int); /* Computes pump coeff. */
void pipecoeff(EN_Project *pr, int); /* Computes pipe coeff. */
double DWcoeff(EN_Project *pr, int, double *); /* Computes D-W coeff. */
void pumpcoeff(EN_Project *pr, int); /* Computes pump coeff. */
/*** Updated 10/25/00 ***/
/*** Updated 12/29/00 ***/
void curvecoeff(EN_Project *pr, int,double,double *,double *); /* Computes curve coeffs. */
void curvecoeff(EN_Project *pr, int,double,
double *,double *); /* Computes curve coeffs. */
void gpvcoeff(EN_Project *pr, int iLink); /* Computes GPV coeff. */
void pbvcoeff(EN_Project *pr, int iLink); /* Computes PBV coeff. */
void tcvcoeff(EN_Project *pr, int iLink); /* Computes TCV coeff. */
void prvcoeff(EN_Project *pr, int iLink, int n1, int n2); /* Computes PRV coeff. */
void psvcoeff(EN_Project *pr, int iLink, int n1, int n2); /* Computes PSV coeff. */
void fcvcoeff(EN_Project *pr, int iLink, int n1, int n2); /* Computes FCV coeff. */
void gpvcoeff(EN_Project *pr, int iLink); /* Computes GPV coeff. */
void pbvcoeff(EN_Project *pr, int iLink); /* Computes PBV coeff. */
void tcvcoeff(EN_Project *pr, int iLink); /* Computes TCV coeff. */
void prvcoeff(EN_Project *pr, int iLink, int n1, int n2); /* Computes PRV coeff. */
void psvcoeff(EN_Project *pr, int iLink, int n1, int n2); /* Computes PSV coeff. */
void fcvcoeff(EN_Project *pr, int iLink, int n1, int n2); /* Computes FCV coeff. */
void emittercoeffs(EN_Project *pr); /* Computes emitter coeffs. */
double emitflowchange(EN_Project *pr, int); /* Computes new emitter flow */
double emitflowchange(EN_Project *pr, int); /* Computes new emitter flow */
/* ----------- SMATRIX.C ---------------*/
int createsparse(EN_Project *pr); /* Creates sparse matrix */
int allocsparse(EN_Project *pr); /* Allocates matrix memory */
void freesparse(EN_Project *pr); /* Frees matrix memory */
int buildlists(EN_Project *pr, int); /* Builds adjacency lists */
int paralink(EN_Project *pr, int, int, int); /* Checks for parallel links */
int buildlists(EN_Project *pr, int); /* Builds adjacency lists */
int paralink(EN_Project *pr, int, int, int); /* Checks for parallel links */
void xparalinks(EN_Project *pr); /* Removes parallel links */
void freelists(EN_Project *pr); /* Frees adjacency lists */
void countdegree(EN_Project *pr); /* Counts links at each node */
int reordernodes(EN_Project *pr); /* Finds a node re-ordering */
int mindegree(solver_t *s, int, int); /* Finds min. degree node */
int growlist(EN_Project *pr, int); /* Augments adjacency list */
int newlink(EN_Project *pr, Padjlist); /* Adds fill-ins for a node */
int linked(EN_Network *net, int, int); /* Checks if 2 nodes linked */
int addlink(EN_Network *net, int, int, int); /* Creates new fill-in */
int storesparse(EN_Project *pr, int); /* Stores sparse matrix */
int ordersparse(hydraulics_t *h, int); /* Orders matrix storage */
void transpose(int,int *,int *, /* Transposes sparse matrix */
int mindegree(solver_t *s, int, int); /* Finds min. degree node */
int growlist(EN_Project *pr, int); /* Augments adjacency list */
int newlink(EN_Project *pr, Padjlist); /* Adds fill-ins for a node */
int linked(EN_Network *net, int, int); /* Checks if 2 nodes linked */
int addlink(EN_Network *net, int, int, int); /* Creates new fill-in */
int storesparse(EN_Project *pr, int); /* Stores sparse matrix */
int ordersparse(hydraulics_t *h, int); /* Orders matrix storage */
void transpose(int,int *,int *, /* Transposes sparse matrix */
int *,int *,int *,int *,int *);
int linsolve(solver_t *s, int); /* via Cholesky factorization */
int linsolve(solver_t *s, int); /* Solves set of linear eqns. */
/* ----------- QUALITY.C ---------------*/
int openqual(EN_Project *pr); /* Opens WQ solver system */
void initqual(EN_Project *pr); /* Initializes WQ solver */
int runqual(EN_Project *pr, long *); /* Gets current WQ results */
int nextqual(EN_Project *pr, long *); /* Updates WQ by hyd.timestep */
int stepqual(EN_Project *pr, long *); /* Updates WQ by WQ time step */
int runqual(EN_Project *pr, long *); /* Gets current WQ results */
int nextqual(EN_Project *pr, long *); /* Updates WQ by hyd.timestep */
int stepqual(EN_Project *pr, long *); /* Updates WQ by WQ time step */
int closequal(EN_Project *pr); /* Closes WQ solver system */
int gethyd(EN_Project *pr, long *, long *); /* Gets next hyd. results */
int gethyd(EN_Project *pr, long *, long *); /* Gets next hyd. results */
char setReactflag(EN_Project *pr); /* Checks for reactive chem. */
void transport(EN_Project *pr, long); /* Transports mass in network */
void transport(EN_Project *pr, long); /* Transports mass in network */
void initsegs(EN_Project *pr); /* Initializes WQ segments */
void reorientsegs(EN_Project *pr); /* Re-orients WQ segments */
void updatesegs(EN_Project *pr, long); /* Updates quality in segments*/
void removesegs(EN_Project *pr, int); /* Removes a WQ segment */
void addseg(EN_Project *pr, int,double,double); /* Adds a WQ segment to pipe */
void accumulate(EN_Project *pr, long); /* Sums mass flow into node */
void updatenodes(EN_Project *pr, long); /* Updates WQ at nodes */
void sourceinput(EN_Project *pr, long); /* Computes source inputs */
void release(EN_Project *pr, long); /* Releases mass from nodes */
void updatetanks(EN_Project *pr, long); /* Updates WQ in tanks */
void updatesourcenodes(EN_Project *pr, long); /* Updates WQ at source nodes */
void tankmix1(EN_Project *pr, int, long); /* Complete mix tank model */
void tankmix2(EN_Project *pr, int, long); /* 2-compartment tank model */
void tankmix3(EN_Project *pr, int, long); /* FIFO tank model */
void tankmix4(EN_Project *pr, int, long); /* LIFO tank model */
double sourcequal(EN_Project *pr, Psource); /* Finds WQ input from source */
double avgqual(EN_Project *pr, int); /* Finds avg. quality in pipe */
void updatesegs(EN_Project *pr, long); /* Updates quality in segments*/
void removesegs(EN_Project *pr, int); /* Removes a WQ segment */
void addseg(EN_Project *pr, int,double,double); /* Adds a WQ segment to pipe */
void accumulate(EN_Project *pr, long); /* Sums mass flow into node */
void updatenodes(EN_Project *pr, long); /* Updates WQ at nodes */
void sourceinput(EN_Project *pr, long); /* Computes source inputs */
void release(EN_Project *pr, long); /* Releases mass from nodes */
void updatetanks(EN_Project *pr, long); /* Updates WQ in tanks */
void updatesourcenodes(EN_Project *pr, long); /* Updates WQ at source nodes */
void tankmix1(EN_Project *pr, int, long); /* Complete mix tank model */
void tankmix2(EN_Project *pr, int, long); /* 2-compartment tank model */
void tankmix3(EN_Project *pr, int, long); /* FIFO tank model */
void tankmix4(EN_Project *pr, int, long); /* LIFO tank model */
double sourcequal(EN_Project *pr, Psource); /* Finds WQ input from source */
double avgqual(EN_Project *pr, int); /* Finds avg. quality in pipe */
void ratecoeffs(EN_Project *pr); /* Finds wall react. coeffs. */
double piperate(EN_Project *pr, int); /* Finds wall react. coeff. */
double pipereact(EN_Project *pr, int,double,double,long);/* Reacts water in a pipe */
double tankreact(EN_Project *pr, double,double,double,long); /* Reacts water in a tank */
double bulkrate(EN_Project *pr, double,double,double); /* Finds bulk reaction rate */
double wallrate(EN_Project *pr, double,double,double,double);/* Finds wall reaction rate */
double piperate(EN_Project *pr, int); /* Finds wall react. coeff. */
double pipereact(EN_Project *pr, int,double,
double,long); /* Reacts water in a pipe */
double tankreact(EN_Project *pr, double,double,
double,long); /* Reacts water in a tank */
double bulkrate(EN_Project *pr, double,double,
double); /* Finds bulk reaction rate */
double wallrate(EN_Project *pr, double,double,
double,double); /* Finds wall reaction rate */
/* ------------ OUTPUT.C ---------------*/
int savenetdata(EN_Project *pr); /* Saves basic data to file */
int savehyd(EN_Project *pr, long *); /* Saves hydraulic solution */
int savehydstep(EN_Project *pr, long *); /* Saves hydraulic timestep */
int savehyd(EN_Project *pr, long *); /* Saves hydraulic solution */
int savehydstep(EN_Project *pr, long *); /* Saves hydraulic timestep */
int saveenergy(EN_Project *pr); /* Saves energy usage */
int readhyd(EN_Project *pr, long *); /* Reads hydraulics from file */
int readhydstep(FILE *hydFile, long *); /* Reads time step from file */
int readhyd(EN_Project *pr, long *); /* Reads hydraulics from file */
int readhydstep(FILE *hydFile, long *); /* Reads time step from file */
int saveoutput(EN_Project *pr); /* Saves results to file */
int nodeoutput(EN_Project *pr, int, REAL4 *, double); /* Saves node results to file */
int linkoutput(EN_Project *pr, int, REAL4 *, double); /* Saves link results to file */
int nodeoutput(EN_Project *pr, int, REAL4 *,
double); /* Saves node results to file */
int linkoutput(EN_Project *pr, int, REAL4 *,
double); /* Saves link results to file */
int savefinaloutput(EN_Project *pr); /* Finishes saving output */
int savetimestat(EN_Project *pr, REAL4 *, HdrType); /* Saves time stats to file */
int savenetreacts(EN_Project *pr, double, double,double, double);
/* Saves react. rates to file */
int savetimestat(EN_Project *pr, REAL4 *,
HdrType); /* Saves time stats to file */
int savenetreacts(EN_Project *pr, double,
double,double, double); /* Saves react. rates to file */
int saveepilog(EN_Project *pr); /* Saves output file epilog */
/* ------------ INPFILE.C --------------*/
int saveinpfile(EN_Project *pr, char *); /* Saves network to text file */
int saveinpfile(EN_Project *pr, char *); /* Saves network to text file */
#endif

1
src/hydraul.c
View File

@@ -680,6 +680,7 @@ void demands(EN_Project *pr)
setlinksetting(pr, i, net->Pattern[j].F[k], &hyd->LinkStatus[i], &hyd->LinkSetting[i]);
}
}
} /* End of demands */

6
src/input1.c
View File

@@ -40,8 +40,7 @@ AUTHOR: L. Rossman
--------------------- Module Global Variables ----------------------
*/
#define MAXITER \
200 /* Default max. # hydraulic iterations */
#define MAXITER 200 /* Default max. # hydraulic iterations */
#define HACC 0.001 /* Default hydraulics convergence ratio */
#define HTOL 0.0005 /* Default hydraulic head tolerance (ft) */
@@ -62,8 +61,7 @@ AUTHOR: L. Rossman
#define RQTOL 1E-7 /* Default low flow resistance tolerance */
#define CHECKFREQ 2 /* Default status check frequency */
#define MAXCHECK 10 /* Default # iterations for status checks */
#define DAMPLIMIT \
0 /* Default damping threshold */
#define DAMPLIMIT 0 /* Default damping threshold */
extern char *Fldname[]; /* Defined in enumstxt.h in EPANET.C */
extern char *RptFlowUnitsTxt[];

3
src/output.c
View File

@@ -70,7 +70,8 @@ int savenetdata(EN_Project *pr)
ibuf[0] = MAGICNUMBER;
/*** CODEVERSION replaces VERSION ***/
ibuf[1] = CODEVERSION;
//ibuf[1] = CODEVERSION;
ibuf[1] = 20012; // keep version at 2.00.12 so that GUI will run
ibuf[2] = net->Nnodes;
ibuf[3] = net->Ntanks;

14
src/quality.c
View File

@@ -161,6 +161,9 @@ void initqual(EN_Project *pr)
net->Node[i].S->Smass = 0.0;
}
qu->QTempVolumes =
calloc(net->Ntanks,
sizeof(double)); // keep track of next tank volumes.
qu->QTankVolumes =
calloc(net->Ntanks,
sizeof(double)); // keep track of previous step's tank volumes.
@@ -287,7 +290,7 @@ int nextqual(EN_Project *pr, long *tstep)
{
long hydstep; /* Hydraulic solution time step */
int errcode = 0;
double *tankVolumes;
//double *tankVolumes = NULL;
int i;
EN_Network *net;
hydraulics_t *hyd;
@@ -315,10 +318,10 @@ int nextqual(EN_Project *pr, long *tstep)
// if we're operating in stepwise mode, capture the tank levels so we can
// restore them later.
if (hyd->OpenHflag) {
tankVolumes = calloc(net->Ntanks, sizeof(double));
//tankVolumes = calloc(net->Ntanks, sizeof(double));
for (i = 1; i <= net->Ntanks; ++i) {
if (net->Tank[i].A != 0) { // skip reservoirs
tankVolumes[i - 1] = net->Tank[i].V;
qu->QTempVolumes[i - 1] = net->Tank[i].V;
}
}
@@ -359,7 +362,7 @@ int nextqual(EN_Project *pr, long *tstep)
for (i = 1; i <= net->Ntanks; i++) {
if (net->Tank[i].A != 0) { // skip reservoirs again
int n = net->Tank[i].Node;
net->Tank[i].V = tankVolumes[i - 1];
net->Tank[i].V = qu->QTempVolumes[i - 1];
hyd->NodeHead[n] = tankgrade(pr, i, net->Tank[i].V);
}
}
@@ -370,7 +373,7 @@ int nextqual(EN_Project *pr, long *tstep)
}
}
free(tankVolumes);
//free(tankVolumes);
}
return (errcode);
@@ -448,6 +451,7 @@ int closequal(EN_Project *pr)
free(qu->MassIn);
free(qu->PipeRateCoeff);
free(qu->TempQual);
free(qu->QTempVolumes);
free(qu->QTankVolumes);
free(qu->QLinkFlow);
return (errcode);

7
src/types.h
View File

@@ -542,6 +542,7 @@ typedef struct {
Climit, /// Limiting potential quality
*NodeQual, /// Node quality state
*TempQual, /// General purpose array for water quality
*QTempVolumes,
*QTankVolumes,
*QLinkFlow,
*PipeRateCoeff;
@@ -551,12 +552,12 @@ typedef struct {
Qtime; /// Current quality time (sec)
char OutOfMemory; /* Out of memory indicator */
alloc_handle_t *SegPool; // Memory pool for water quality segments
alloc_handle_t *SegPool; // Memory pool for water quality segments
Pseg FreeSeg; /* Pointer to unused segment */
Pseg *FirstSeg, /* First (downstream) segment in each pipe */
*LastSeg; /* Last (upstream) segment in each pipe */
FlowDirection *FlowDir; /* Flow direction for each pipe */
*LastSeg; /* Last (upstream) segment in each pipe */
FlowDirection *FlowDir; /* Flow direction for each pipe */
double *VolIn; /* Total volume inflow to node */
double *MassIn; /* Total mass inflow to node */
double Sc; /* Schmidt Number */