/******************************************************************************
* $Id$
*
* Project: Shapelib
* Purpose: Implementation of core Shapefile read/write functions.
* Author: Frank Warmerdam, warmerdam@pobox.com
*
******************************************************************************
* Copyright (c) 1999, 2001, Frank Warmerdam
*
* This software is available under the following "MIT Style" license,
* or at the option of the licensee under the LGPL (see LICENSE.LGPL). This
* option is discussed in more detail in shapelib.html.
*
* --
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included
* in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
* OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
* DEALINGS IN THE SOFTWARE.
******************************************************************************
*
* $Log$
* Revision 1.1 2005/08/14 21:40:30 jswhit
* inclusion of pyshapelib
*
* Revision 1.3 2004/05/17 15:47:57 bh
* Update to newest shapelib and get rid of Thuban specific extensions,
* i.e. use the new DBFUpdateHeader instead of our DBFCommit kludge
*
* * libraries/shapelib/shpopen.c: Update to version from current
* shapelib CVS.
*
* * libraries/shapelib/shapefil.h: Update to version from current
* shapelib CVS.
*
* * libraries/shapelib/dbfopen.c: Update to version from current
* shapelib CVS.
* (DBFCommit): Effectively removed since shapelib itself has
* DBFUpdateHeader now which is better for what DBFCommit wanted to
* achieve.
* We're now using an unmodified version of dbfopen.
*
* * libraries/pyshapelib/dbflib_wrap.c, libraries/pyshapelib/dbflib.py:
* Update from dbflib.i
*
* * libraries/pyshapelib/dbflib.i (DBFInfo_commit): New. Implementation of
* the commit method. This new indirection is necessary because we use the
* DBFUpdateHeader function now which is not available in shapelib <=
* 1.2.10
* (DBFFile::commit): Use DBFInfo_commit as implementation
* (pragma __class__): New. Kludge to remove the commit method when
* the DBFUpdateHeader function isn't available
* (_have_commit): New. Helper for the pragma kludge.
*
* * libraries/pyshapelib/setup.py (dbf_macros): New. Return the
* preprocessor macros needed to compile the dbflib wrapper. Determine
* whether DBFUpdateHeader is available and define the right value of
* HAVE_UPDATE_HEADER
* (extensions): Use dbf_macros for the dbflibc extension
*
* * setup.py (extensions): Add the HAVE_UPDATE_HEADER macro with
* value '1' to the Lib.dbflibc extension. This simply reflects the
* shapelib and pyshapelib updates
*
* Revision 1.44 2003/12/29 00:18:39 fwarmerdam
* added error checking for failed IO and optional CPL error reporting
*
* Revision 1.43 2003/12/01 16:20:08 warmerda
* be careful of zero vertex shapes
*
* Revision 1.42 2003/12/01 14:58:27 warmerda
* added degenerate object check in SHPRewindObject()
*
* Revision 1.41 2003/07/08 15:22:43 warmerda
* avoid warning
*
* Revision 1.40 2003/04/21 18:30:37 warmerda
* added header write/update public methods
*
* Revision 1.39 2002/08/26 06:46:56 warmerda
* avoid c++ comments
*
* Revision 1.38 2002/05/07 16:43:39 warmerda
* Removed debugging printf.
*
* Revision 1.37 2002/04/10 17:35:22 warmerda
* fixed bug in ring reversal code
*
* Revision 1.36 2002/04/10 16:59:54 warmerda
* added SHPRewindObject
*
* Revision 1.35 2001/12/07 15:10:44 warmerda
* fix if .shx fails to open
*
* Revision 1.34 2001/11/01 16:29:55 warmerda
* move pabyRec into SHPInfo for thread safety
*
* Revision 1.33 2001/07/03 12:18:15 warmerda
* Improved cleanup if SHX not found, provied by Riccardo Cohen.
*
* Revision 1.32 2001/06/22 01:58:07 warmerda
* be more careful about establishing initial bounds in face of NULL shapes
*
* Revision 1.31 2001/05/31 19:35:29 warmerda
* added support for writing null shapes
*
* Revision 1.30 2001/05/28 12:46:29 warmerda
* Add some checking on reasonableness of record count when opening.
*
* Revision 1.29 2001/05/23 13:36:52 warmerda
* added use of SHPAPI_CALL
*
* Revision 1.28 2001/02/06 22:25:06 warmerda
* fixed memory leaks when SHPOpen() fails
*
* Revision 1.27 2000/07/18 15:21:33 warmerda
* added better enforcement of -1 for append in SHPWriteObject
*
* Revision 1.26 2000/02/16 16:03:51 warmerda
* added null shape support
*
* Revision 1.25 1999/12/15 13:47:07 warmerda
* Fixed record size settings in .shp file (was 4 words too long)
* Added stdlib.h.
*
* Revision 1.24 1999/11/05 14:12:04 warmerda
* updated license terms
*
* Revision 1.23 1999/07/27 00:53:46 warmerda
* added support for rewriting shapes
*
* Revision 1.22 1999/06/11 19:19:11 warmerda
* Cleanup pabyRec static buffer on SHPClose().
*
* Revision 1.21 1999/06/02 14:57:56 kshih
* Remove unused variables
*
* Revision 1.20 1999/04/19 21:04:17 warmerda
* Fixed syntax error.
*
* Revision 1.19 1999/04/19 21:01:57 warmerda
* Force access string to binary in SHPOpen().
*
* Revision 1.18 1999/04/01 18:48:07 warmerda
* Try upper case extensions if lower case doesn't work.
*
* Revision 1.17 1998/12/31 15:29:39 warmerda
* Disable writing measure values to multipatch objects if
* DISABLE_MULTIPATCH_MEASURE is defined.
*
* Revision 1.16 1998/12/16 05:14:33 warmerda
* Added support to write MULTIPATCH. Fixed reading Z coordinate of
* MULTIPATCH. Fixed record size written for all feature types.
*
* Revision 1.15 1998/12/03 16:35:29 warmerda
* r+b is proper binary access string, not rb+.
*
* Revision 1.14 1998/12/03 15:47:56 warmerda
* Fixed setting of nVertices in SHPCreateObject().
*
* Revision 1.13 1998/12/03 15:33:54 warmerda
* Made SHPCalculateExtents() separately callable.
*
* Revision 1.12 1998/11/11 20:01:50 warmerda
* Fixed bug writing ArcM/Z, and PolygonM/Z for big endian machines.
*
* Revision 1.11 1998/11/09 20:56:44 warmerda
* Fixed up handling of file wide bounds.
*
* Revision 1.10 1998/11/09 20:18:51 warmerda
* Converted to support 3D shapefiles, and use of SHPObject.
*
* Revision 1.9 1998/02/24 15:09:05 warmerda
* Fixed memory leak.
*
* Revision 1.8 1997/12/04 15:40:29 warmerda
* Fixed byte swapping of record number, and record length fields in the
* .shp file.
*
* Revision 1.7 1995/10/21 03:15:58 warmerda
* Added support for binary file access, the magic cookie 9997
* and tried to improve the int32 selection logic for 16bit systems.
*
* Revision 1.6 1995/09/04 04:19:41 warmerda
* Added fix for file bounds.
*
* Revision 1.5 1995/08/25 15:16:44 warmerda
* Fixed a couple of problems with big endian systems ... one with bounds
* and the other with multipart polygons.
*
* Revision 1.4 1995/08/24 18:10:17 warmerda
* Switch to use SfRealloc() to avoid problems with pre-ANSI realloc()
* functions (such as on the Sun).
*
* Revision 1.3 1995/08/23 02:23:15 warmerda
* Added support for reading bounds, and fixed up problems in setting the
* file wide bounds.
*
* Revision 1.2 1995/08/04 03:16:57 warmerda
* Added header.
*
*/
static char rcsid[] =
"$Id$";
#include "shapefil.h"
#include <math.h>
#include <limits.h>
#include <assert.h>
#include <stdlib.h>
#include <string.h>
typedef unsigned char uchar;
#if UINT_MAX == 65535
typedef long int32;
#else
typedef int int32;
#endif
#ifndef FALSE
# define FALSE 0
# define TRUE 1
#endif
#define ByteCopy( a, b, c ) memcpy( b, a, c )
#ifndef MAX
# define MIN(a,b) ((a<b) ? a : b)
# define MAX(a,b) ((a>b) ? a : b)
#endif
static int bBigEndian;
/************************************************************************/
/* SwapWord() */
/* */
/* Swap a 2, 4 or 8 byte word. */
/************************************************************************/
static void SwapWord( int length, void * wordP )
{
int i;
uchar temp;
for( i=0; i < length/2; i++ )
{
temp = ((uchar *) wordP)[i];
((uchar *)wordP)[i] = ((uchar *) wordP)[length-i-1];
((uchar *) wordP)[length-i-1] = temp;
}
}
/************************************************************************/
/* SfRealloc() */
/* */
/* A realloc cover function that will access a NULL pointer as */
/* a valid input. */
/************************************************************************/
static void * SfRealloc( void * pMem, int nNewSize )
{
if( pMem == NULL )
return( (void *) malloc(nNewSize) );
else
return( (void *) realloc(pMem,nNewSize) );
}
/************************************************************************/
/* SHPWriteHeader() */
/* */
/* Write out a header for the .shp and .shx files as well as the */
/* contents of the index (.shx) file. */
/************************************************************************/
void SHPWriteHeader( SHPHandle psSHP )
{
uchar abyHeader[100];
int i;
int32 i32;
double dValue;
int32 *panSHX;
/* -------------------------------------------------------------------- */
/* Prepare header block for .shp file. */
/* -------------------------------------------------------------------- */
for( i = 0; i < 100; i++ )
abyHeader[i] = 0;
abyHeader[2] = 0x27; /* magic cookie */
abyHeader[3] = 0x0a;
i32 = psSHP->nFileSize/2; /* file size */
ByteCopy( &i32, abyHeader+24, 4 );
if( !bBigEndian ) SwapWord( 4, abyHeader+24 );
i32 = 1000; /* version */
ByteCopy( &i32, abyHeader+28, 4 );
if( bBigEndian ) SwapWord( 4, abyHeader+28 );
i32 = psSHP->nShapeType; /* shape type */
ByteCopy( &i32, abyHeader+32, 4 );
if( bBigEndian ) SwapWord( 4, abyHeader+32 );
dValue = psSHP->adBoundsMin[0]; /* set bounds */
ByteCopy( &dValue, abyHeader+36, 8 );
if( bBigEndian ) SwapWord( 8, abyHeader+36 );
dValue = psSHP->adBoundsMin[1];
ByteCopy( &dValue, abyHeader+44, 8 );
if( bBigEndian ) SwapWord( 8, abyHeader+44 );
dValue = psSHP->adBoundsMax[0];
ByteCopy( &dValue, abyHeader+52, 8 );
if( bBigEndian ) SwapWord( 8, abyHeader+52 );
dValue = psSHP->adBoundsMax[1];
ByteCopy( &dValue, abyHeader+60, 8 );
if( bBigEndian ) SwapWord( 8, abyHeader+60 );
dValue = psSHP->adBoundsMin[2]; /* z */
ByteCopy( &dValue, abyHeader+68, 8 );
if( bBigEndian ) SwapWord( 8, abyHeader+68 );
dValue = psSHP->adBoundsMax[2];
ByteCopy( &dValue, abyHeader+76, 8 );
if( bBigEndian ) SwapWord( 8, abyHeader+76 );
dValue = psSHP->adBoundsMin[3]; /* m */
ByteCopy( &dValue, abyHeader+84, 8 );
if( bBigEndian ) SwapWord( 8, abyHeader+84 );
dValue = psSHP->adBoundsMax[3];
ByteCopy( &dValue, abyHeader+92, 8 );
if( bBigEndian ) SwapWord( 8, abyHeader+92 );
/* -------------------------------------------------------------------- */
/* Write .shp file header. */
/* -------------------------------------------------------------------- */
if( fseek( psSHP->fpSHP, 0, 0 ) != 0
|| fwrite( abyHeader, 100, 1, psSHP->fpSHP ) != 1 )
{
#ifdef USE_CPL
CPLError( CE_Failure, CPLE_OpenFailed,
"Failure writing .shp header." );
#endif
return;
}
/* -------------------------------------------------------------------- */
/* Prepare, and write .shx file header. */
/* -------------------------------------------------------------------- */
i32 = (psSHP->nRecords * 2 * sizeof(int32) + 100)/2; /* file size */
ByteCopy( &i32, abyHeader+24, 4 );
if( !bBigEndian ) SwapWord( 4, abyHeader+24 );
if( fseek( psSHP->fpSHX, 0, 0 ) != 0
|| fwrite( abyHeader, 100, 1, psSHP->fpSHX ) != 1 )
{
#ifdef USE_CPL
CPLError( CE_Failure, CPLE_OpenFailed,
"Failure writing .shx header." );
#endif
return;
}
/* -------------------------------------------------------------------- */
/* Write out the .shx contents. */
/* -------------------------------------------------------------------- */
panSHX = (int32 *) malloc(sizeof(int32) * 2 * psSHP->nRecords);
for( i = 0; i < psSHP->nRecords; i++ )
{
panSHX[i*2 ] = psSHP->panRecOffset[i]/2;
panSHX[i*2+1] = psSHP->panRecSize[i]/2;
if( !bBigEndian ) SwapWord( 4, panSHX+i*2 );
if( !bBigEndian ) SwapWord( 4, panSHX+i*2+1 );
}
if( fwrite( panSHX, sizeof(int32) * 2, psSHP->nRecords, psSHP->fpSHX )
!= psSHP->nRecords )
{
#ifdef USE_CPL
CPLError( CE_Failure, CPLE_OpenFailed,
"Failure writing .shx contents." );
#endif
}
free( panSHX );
/* -------------------------------------------------------------------- */
/* Flush to disk. */
/* -------------------------------------------------------------------- */
fflush( psSHP->fpSHP );
fflush( psSHP->fpSHX );
}
/************************************************************************/
/* shpopen() */
/* */
/* Open the .shp and .shx files based on the basename of the */
/* files or either file name. */
/************************************************************************/
SHPHandle SHPAPI_CALL
SHPOpen( const char * pszLayer, const char * pszAccess )
{
char *pszFullname, *pszBasename;
SHPHandle psSHP;
uchar *pabyBuf;
int i;
double dValue;
/* -------------------------------------------------------------------- */
/* Ensure the access string is one of the legal ones. We */
/* ensure the result string indicates binary to avoid common */
/* problems on Windows. */
/* -------------------------------------------------------------------- */
if( strcmp(pszAccess,"rb+") == 0 || strcmp(pszAccess,"r+b") == 0
|| strcmp(pszAccess,"r+") == 0 )
pszAccess = "r+b";
else
pszAccess = "rb";
/* -------------------------------------------------------------------- */
/* Establish the byte order on this machine. */
/* -------------------------------------------------------------------- */
i = 1;
if( *((uchar *) &i) == 1 )
bBigEndian = FALSE;
else
bBigEndian = TRUE;
/* -------------------------------------------------------------------- */
/* Initialize the info structure. */
/* -------------------------------------------------------------------- */
psSHP = (SHPHandle) calloc(sizeof(SHPInfo),1);
psSHP->bUpdated = FALSE;
/* -------------------------------------------------------------------- */
/* Compute the base (layer) name. If there is any extension */
/* on the passed in filename we will strip it off. */
/* -------------------------------------------------------------------- */
pszBasename = (char *) malloc(strlen(pszLayer)+5);
strcpy( pszBasename, pszLayer );
for( i = strlen(pszBasename)-1;
i > 0 && pszBasename[i] != '.' && pszBasename[i] != '/'
&& pszBasename[i] != '\\';
i-- ) {}
if( pszBasename[i] == '.' )
pszBasename[i] = '\0';
/* -------------------------------------------------------------------- */
/* Open the .shp and .shx files. Note that files pulled from */
/* a PC to Unix with upper case filenames won't work! */
/* -------------------------------------------------------------------- */
pszFullname = (char *) malloc(strlen(pszBasename) + 5);
sprintf( pszFullname, "%s.shp", pszBasename );
psSHP->fpSHP = fopen(pszFullname, pszAccess );
if( psSHP->fpSHP == NULL )
{
sprintf( pszFullname, "%s.SHP", pszBasename );
psSHP->fpSHP = fopen(pszFullname, pszAccess );
}
if( psSHP->fpSHP == NULL )
{
#ifdef USE_CPL
CPLError( CE_Failure, CPLE_OpenFailed,
"Unable to open %s.shp or %s.SHP.",
pszBasename, pszBasename );
#endif
free( psSHP );
free( pszBasename );
free( pszFullname );
return( NULL );
}
sprintf( pszFullname, "%s.shx", pszBasename );
psSHP->fpSHX = fopen(pszFullname, pszAccess );
if( psSHP->fpSHX == NULL )
{
sprintf( pszFullname, "%s.SHX", pszBasename );
psSHP->fpSHX = fopen(pszFullname, pszAccess );
}
if( psSHP->fpSHX == NULL )
{
#ifdef USE_CPL
CPLError( CE_Failure, CPLE_OpenFailed,
"Unable to open %s.shx or %s.SHX.",
pszBasename, pszBasename );
#endif
fclose( psSHP->fpSHP );
free( psSHP );
free( pszBasename );
free( pszFullname );
return( NULL );
}
free( pszFullname );
free( pszBasename );
/* -------------------------------------------------------------------- */
/* Read the file size from the SHP file. */
/* -------------------------------------------------------------------- */
pabyBuf = (uchar *) malloc(100);
fread( pabyBuf, 100, 1, psSHP->fpSHP );
psSHP->nFileSize = (pabyBuf[24] * 256 * 256 * 256
+ pabyBuf[25] * 256 * 256
+ pabyBuf[26] * 256
+ pabyBuf[27]) * 2;
/* -------------------------------------------------------------------- */
/* Read SHX file Header info */
/* -------------------------------------------------------------------- */
if( fread( pabyBuf, 100, 1, psSHP->fpSHX ) != 1
|| pabyBuf[0] != 0
|| pabyBuf[1] != 0
|| pabyBuf[2] != 0x27
|| (pabyBuf[3] != 0x0a && pabyBuf[3] != 0x0d) )
{
#ifdef USE_CPL
CPLError( CE_Failure, CPLE_AppDefined,
".shx file is unreadable, or corrupt." );
#endif
fclose( psSHP->fpSHP );
fclose( psSHP->fpSHX );
free( psSHP );
return( NULL );
}
psSHP->nRecords = pabyBuf[27] + pabyBuf[26] * 256
+ pabyBuf[25] * 256 * 256 + pabyBuf[24] * 256 * 256 * 256;
psSHP->nRecords = (psSHP->nRecords*2 - 100) / 8;
psSHP->nShapeType = pabyBuf[32];
if( psSHP->nRecords < 0 || psSHP->nRecords > 256000000 )
{
#ifdef USE_CPL
CPLError( CE_Failure, CPLE_AppDefined,
"Record count in .shp header is %d, which seems\n"
"unreasonable. Assuming header is corrupt.",
psSHP->nRecords );
#endif
fclose( psSHP->fpSHP );
fclose( psSHP->fpSHX );
free( psSHP );
return( NULL );
}
/* -------------------------------------------------------------------- */
/* Read the bounds. */
/* -------------------------------------------------------------------- */
if( bBigEndian ) SwapWord( 8, pabyBuf+36 );
memcpy( &dValue, pabyBuf+36, 8 );
psSHP->adBoundsMin[0] = dValue;
if( bBigEndian ) SwapWord( 8, pabyBuf+44 );
memcpy( &dValue, pabyBuf+44, 8 );
psSHP->adBoundsMin[1] = dValue;
if( bBigEndian ) SwapWord( 8, pabyBuf+52 );
memcpy( &dValue, pabyBuf+52, 8 );
psSHP->adBoundsMax[0] = dValue;
if( bBigEndian ) SwapWord( 8, pabyBuf+60 );
memcpy( &dValue, pabyBuf+60, 8 );
psSHP->adBoundsMax[1] = dValue;
if( bBigEndian ) SwapWord( 8, pabyBuf+68 ); /* z */
memcpy( &dValue, pabyBuf+68, 8 );
psSHP->adBoundsMin[2] = dValue;
if( bBigEndian ) SwapWord( 8, pabyBuf+76 );
memcpy( &dValue, pabyBuf+76, 8 );
psSHP->adBoundsMax[2] = dValue;
if( bBigEndian ) SwapWord( 8, pabyBuf+84 ); /* z */
memcpy( &dValue, pabyBuf+84, 8 );
psSHP->adBoundsMin[3] = dValue;
if( bBigEndian ) SwapWord( 8, pabyBuf+92 );
memcpy( &dValue, pabyBuf+92, 8 );
psSHP->adBoundsMax[3] = dValue;
free( pabyBuf );
/* -------------------------------------------------------------------- */
/* Read the .shx file to get the offsets to each record in */
/* the .shp file. */
/* -------------------------------------------------------------------- */
psSHP->nMaxRecords = psSHP->nRecords;
psSHP->panRecOffset =
(int *) malloc(sizeof(int) * MAX(1,psSHP->nMaxRecords) );
psSHP->panRecSize =
(int *) malloc(sizeof(int) * MAX(1,psSHP->nMaxRecords) );
pabyBuf = (uchar *) malloc(8 * MAX(1,psSHP->nRecords) );
if( fread( pabyBuf, 8, psSHP->nRecords, psSHP->fpSHX ) != psSHP->nRecords )
{
#ifdef USE_CPL
CPLError( CE_Failure, CPLE_AppDefined,
"Failed to read all values for %d records in .shx file.",
psSHP->nRecords );
#endif
/* SHX is short or unreadable for some reason. */
fclose( psSHP->fpSHP );
fclose( psSHP->fpSHX );
free( psSHP->panRecOffset );
free( psSHP->panRecSize );
free( psSHP );
return( NULL );
}
for( i = 0; i < psSHP->nRecords; i++ )
{
int32 nOffset, nLength;
memcpy( &nOffset, pabyBuf + i * 8, 4 );
if( !bBigEndian ) SwapWord( 4, &nOffset );
memcpy( &nLength, pabyBuf + i * 8 + 4, 4 );
if( !bBigEndian ) SwapWord( 4, &nLength );
psSHP->panRecOffset[i] = nOffset*2;
psSHP->panRecSize[i] = nLength*2;
}
free( pabyBuf );
return( psSHP );
}
/************************************************************************/
/* SHPClose() */
/* */
/* Close the .shp and .shx files. */
/************************************************************************/
void SHPAPI_CALL
SHPClose(SHPHandle psSHP )
{
if( psSHP == NULL )
return;
/* -------------------------------------------------------------------- */
/* Update the header if we have modified anything. */
/* -------------------------------------------------------------------- */
if( psSHP->bUpdated )
SHPWriteHeader( psSHP );
/* -------------------------------------------------------------------- */
/* Free all resources, and close files. */
/* -------------------------------------------------------------------- */
free( psSHP->panRecOffset );
free( psSHP->panRecSize );
fclose( psSHP->fpSHX );
fclose( psSHP->fpSHP );
if( psSHP->pabyRec != NULL )
{
free( psSHP->pabyRec );
}
free( psSHP );
}
/************************************************************************/
/* SHPGetInfo() */
/* */
/* Fetch general information about the shape file. */
/************************************************************************/
void SHPAPI_CALL
SHPGetInfo(SHPHandle psSHP, int * pnEntities, int * pnShapeType,
double * padfMinBound, double * padfMaxBound )
{
int i;
if( psSHP == NULL )
return;
if( pnEntities != NULL )
*pnEntities = psSHP->nRecords;
if( pnShapeType != NULL )
*pnShapeType = psSHP->nShapeType;
for( i = 0; i < 4; i++ )
{
if( padfMinBound != NULL )
padfMinBound[i] = psSHP->adBoundsMin[i];
if( padfMaxBound != NULL )
padfMaxBound[i] = psSHP->adBoundsMax[i];
}
}
/************************************************************************/
/* SHPCreate() */
/* */
/* Create a new shape file and return a handle to the open */
/* shape file with read/write access. */
/************************************************************************/
SHPHandle SHPAPI_CALL
SHPCreate( const char * pszLayer, int nShapeType )
{
char *pszBasename, *pszFullname;
int i;
FILE *fpSHP, *fpSHX;
uchar abyHeader[100];
int32 i32;
double dValue;
/* -------------------------------------------------------------------- */
/* Establish the byte order on this system. */
/* -------------------------------------------------------------------- */
i = 1;
if( *((uchar *) &i) == 1 )
bBigEndian = FALSE;
else
bBigEndian = TRUE;
/* -------------------------------------------------------------------- */
/* Compute the base (layer) name. If there is any extension */
/* on the passed in filename we will strip it off. */
/* -------------------------------------------------------------------- */
pszBasename = (char *) malloc(strlen(pszLayer)+5);
strcpy( pszBasename, pszLayer );
for( i = strlen(pszBasename)-1;
i > 0 && pszBasename[i] != '.' && pszBasename[i] != '/'
&& pszBasename[i] != '\\';
i-- ) {}
if( pszBasename[i] == '.' )
pszBasename[i] = '\0';
/* -------------------------------------------------------------------- */
/* Open the two files so we can write their headers. */
/* -------------------------------------------------------------------- */
pszFullname = (char *) malloc(strlen(pszBasename) + 5);
sprintf( pszFullname, "%s.shp", pszBasename );
fpSHP = fopen(pszFullname, "wb" );
if( fpSHP == NULL )
{
#ifdef USE_CPL
CPLError( CE_Failure, CPLE_AppDefined,
"Failed to create file %s.",
pszFullname );
#endif
return( NULL );
}
sprintf( pszFullname, "%s.shx", pszBasename );
fpSHX = fopen(pszFullname, "wb" );
if( fpSHX == NULL )
{
#ifdef USE_CPL
CPLError( CE_Failure, CPLE_AppDefined,
"Failed to create file %s.",
pszFullname );
#endif
return( NULL );
}
free( pszFullname );
free( pszBasename );
/* -------------------------------------------------------------------- */
/* Prepare header block for .shp file. */
/* -------------------------------------------------------------------- */
for( i = 0; i < 100; i++ )
abyHeader[i] = 0;
abyHeader[2] = 0x27; /* magic cookie */
abyHeader[3] = 0x0a;
i32 = 50; /* file size */
ByteCopy( &i32, abyHeader+24, 4 );
if( !bBigEndian ) SwapWord( 4, abyHeader+24 );
i32 = 1000; /* version */
ByteCopy( &i32, abyHeader+28, 4 );
if( bBigEndian ) SwapWord( 4, abyHeader+28 );
i32 = nShapeType; /* shape type */
ByteCopy( &i32, abyHeader+32, 4 );
if( bBigEndian ) SwapWord( 4, abyHeader+32 );
dValue = 0.0; /* set bounds */
ByteCopy( &dValue, abyHeader+36, 8 );
ByteCopy( &dValue, abyHeader+44, 8 );
ByteCopy( &dValue, abyHeader+52, 8 );
ByteCopy( &dValue, abyHeader+60, 8 );
/* -------------------------------------------------------------------- */
/* Write .shp file header. */
/* -------------------------------------------------------------------- */
if( fwrite( abyHeader, 100, 1, fpSHP ) != 1 )
{
#ifdef USE_CPL
CPLError( CE_Failure, CPLE_AppDefined,
"Failed to write .shp header." );
#endif
return NULL;
}
/* -------------------------------------------------------------------- */
/* Prepare, and write .shx file header. */
/* -------------------------------------------------------------------- */
i32 = 50; /* file size */
ByteCopy( &i32, abyHeader+24, 4 );
if( !bBigEndian ) SwapWord( 4, abyHeader+24 );
if( fwrite( abyHeader, 100, 1, fpSHX ) != 1 )
{
#ifdef USE_CPL
CPLError( CE_Failure, CPLE_AppDefined,
"Failed to write .shx header." );
#endif
return NULL;
}
/* -------------------------------------------------------------------- */
/* Close the files, and then open them as regular existing files. */
/* -------------------------------------------------------------------- */
fclose( fpSHP );
fclose( fpSHX );
return( SHPOpen( pszLayer, "r+b" ) );
}
/************************************************************************/
/* _SHPSetBounds() */
/* */
/* Compute a bounds rectangle for a shape, and set it into the */
/* indicated location in the record. */
/************************************************************************/
static void _SHPSetBounds( uchar * pabyRec, SHPObject * psShape )
{
ByteCopy( &(psShape->dfXMin), pabyRec + 0, 8 );
ByteCopy( &(psShape->dfYMin), pabyRec + 8, 8 );
ByteCopy( &(psShape->dfXMax), pabyRec + 16, 8 );
ByteCopy( &(psShape->dfYMax), pabyRec + 24, 8 );
if( bBigEndian )
{
SwapWord( 8, pabyRec + 0 );
SwapWord( 8, pabyRec + 8 );
SwapWord( 8, pabyRec + 16 );
SwapWord( 8, pabyRec + 24 );
}
}
/************************************************************************/
/* SHPComputeExtents() */
/* */
/* Recompute the extents of a shape. Automatically done by */
/* SHPCreateObject(). */
/************************************************************************/
void SHPAPI_CALL
SHPComputeExtents( SHPObject * psObject )
{
int i;
/* -------------------------------------------------------------------- */
/* Build extents for this object. */
/* -------------------------------------------------------------------- */
if( psObject->nVertices > 0 )
{
psObject->dfXMin = psObject->dfXMax = psObject->padfX[0];
psObject->dfYMin = psObject->dfYMax = psObject->padfY[0];
psObject->dfZMin = psObject->dfZMax = psObject->padfZ[0];
psObject->dfMMin = psObject->dfMMax = psObject->padfM[0];
}
for( i = 0; i < psObject->nVertices; i++ )
{
psObject->dfXMin = MIN(psObject->dfXMin, psObject->padfX[i]);
psObject->dfYMin = MIN(psObject->dfYMin, psObject->padfY[i]);
psObject->dfZMin = MIN(psObject->dfZMin, psObject->padfZ[i]);
psObject->dfMMin = MIN(psObject->dfMMin, psObject->padfM[i]);
psObject->dfXMax = MAX(psObject->dfXMax, psObject->padfX[i]);
psObject->dfYMax = MAX(psObject->dfYMax, psObject->padfY[i]);
psObject->dfZMax = MAX(psObject->dfZMax, psObject->padfZ[i]);
psObject->dfMMax = MAX(psObject->dfMMax, psObject->padfM[i]);
}
}
/************************************************************************/
/* SHPCreateObject() */
/* */
/* Create a shape object. It should be freed with */
/* SHPDestroyObject(). */
/************************************************************************/
SHPObject SHPAPI_CALL1(*)
SHPCreateObject( int nSHPType, int nShapeId, int nParts,
int * panPartStart, int * panPartType,
int nVertices, double * padfX, double * padfY,
double * padfZ, double * padfM )
{
SHPObject *psObject;
int i, bHasM, bHasZ;
psObject = (SHPObject *) calloc(1,sizeof(SHPObject));
psObject->nSHPType = nSHPType;
psObject->nShapeId = nShapeId;
/* -------------------------------------------------------------------- */
/* Establish whether this shape type has M, and Z values. */
/* -------------------------------------------------------------------- */
if( nSHPType == SHPT_ARCM
|| nSHPType == SHPT_POINTM
|| nSHPType == SHPT_POLYGONM
|| nSHPType == SHPT_MULTIPOINTM )
{
bHasM = TRUE;
bHasZ = FALSE;
}
else if( nSHPType == SHPT_ARCZ
|| nSHPType == SHPT_POINTZ
|| nSHPType == SHPT_POLYGONZ
|| nSHPType == SHPT_MULTIPOINTZ
|| nSHPType == SHPT_MULTIPATCH )
{
bHasM = TRUE;
bHasZ = TRUE;
}
else
{
bHasM = FALSE;
bHasZ = FALSE;
}
/* -------------------------------------------------------------------- */
/* Capture parts. Note that part type is optional, and */
/* defaults to ring. */
/* -------------------------------------------------------------------- */
if( nSHPType == SHPT_ARC || nSHPType == SHPT_POLYGON
|| nSHPType == SHPT_ARCM || nSHPType == SHPT_POLYGONM
|| nSHPType == SHPT_ARCZ || nSHPType == SHPT_POLYGONZ
|| nSHPType == SHPT_MULTIPATCH )
{
psObject->nParts = MAX(1,nParts);
psObject->panPartStart = (int *)
malloc(sizeof(int) * psObject->nParts);
psObject->panPartType = (int *)
malloc(sizeof(int) * psObject->nParts);
psObject->panPartStart[0] = 0;
psObject->panPartType[0] = SHPP_RING;
for( i = 0; i < nParts; i++ )
{
psObject->panPartStart[i] = panPartStart[i];
if( panPartType != NULL )
psObject->panPartType[i] = panPartType[i];
else
psObject->panPartType[i] = SHPP_RING;
}
}
/* -------------------------------------------------------------------- */
/* Capture vertices. Note that Z and M are optional, but X and */
/* Y are not. */
/* -------------------------------------------------------------------- */
if( nVertices > 0 )
{
psObject->padfX = (double *) calloc(sizeof(double),nVertices);
psObject->padfY = (double *) calloc(sizeof(double),nVertices);
psObject->padfZ = (double *) calloc(sizeof(double),nVertices);
psObject->padfM = (double *) calloc(sizeof(double),nVertices);
assert( padfX != NULL );
assert( padfY != NULL );
for( i = 0; i < nVertices; i++ )
{
psObject->padfX[i] = padfX[i];
psObject->padfY[i] = padfY[i];
if( padfZ != NULL && bHasZ )
psObject->padfZ[i] = padfZ[i];
if( padfM != NULL && bHasM )
psObject->padfM[i] = padfM[i];
}
}
/* -------------------------------------------------------------------- */
/* Compute the extents. */
/* -------------------------------------------------------------------- */
psObject->nVertices = nVertices;
SHPComputeExtents( psObject );
return( psObject );
}
/************************************************************************/
/* SHPCreateSimpleObject() */
/* */
/* Create a simple (common) shape object. Destroy with */
/* SHPDestroyObject(). */
/************************************************************************/
SHPObject SHPAPI_CALL1(*)
SHPCreateSimpleObject( int nSHPType, int nVertices,
double * padfX, double * padfY,
double * padfZ )
{
return( SHPCreateObject( nSHPType, -1, 0, NULL, NULL,
nVertices, padfX, padfY, padfZ, NULL ) );
}
/************************************************************************/
/* SHPWriteObject() */
/* */
/* Write out the vertices of a new structure. Note that it is */
/* only possible to write vertices at the end of the file. */
/************************************************************************/
int SHPAPI_CALL
SHPWriteObject(SHPHandle psSHP, int nShapeId, SHPObject * psObject )
{
int nRecordOffset, i, nRecordSize=0;
uchar *pabyRec;
int32 i32;
psSHP->bUpdated = TRUE;
/* -------------------------------------------------------------------- */
/* Ensure that shape object matches the type of the file it is */
/* being written to. */
/* -------------------------------------------------------------------- */
assert( psObject->nSHPType == psSHP->nShapeType
|| psObject->nSHPType == SHPT_NULL );
/* -------------------------------------------------------------------- */
/* Ensure that -1 is used for appends. Either blow an */
/* assertion, or if they are disabled, set the shapeid to -1 */
/* for appends. */
/* -------------------------------------------------------------------- */
assert( nShapeId == -1
|| (nShapeId >= 0 && nShapeId < psSHP->nRecords) );
if( nShapeId != -1 && nShapeId >= psSHP->nRecords )
nShapeId = -1;
/* -------------------------------------------------------------------- */
/* Add the new entity to the in memory index. */
/* -------------------------------------------------------------------- */
if( nShapeId == -1 && psSHP->nRecords+1 > psSHP->nMaxRecords )
{
psSHP->nMaxRecords =(int) ( psSHP->nMaxRecords * 1.3 + 100);
psSHP->panRecOffset = (int *)
SfRealloc(psSHP->panRecOffset,sizeof(int) * psSHP->nMaxRecords );
psSHP->panRecSize = (int *)
SfRealloc(psSHP->panRecSize,sizeof(int) * psSHP->nMaxRecords );
}
/* -------------------------------------------------------------------- */
/* Initialize record. */
/* -------------------------------------------------------------------- */
pabyRec = (uchar *) malloc(psObject->nVertices * 4 * sizeof(double)
+ psObject->nParts * 8 + 128);
/* -------------------------------------------------------------------- */
/* Extract vertices for a Polygon or Arc. */
/* -------------------------------------------------------------------- */
if( psObject->nSHPType == SHPT_POLYGON
|| psObject->nSHPType == SHPT_POLYGONZ
|| psObject->nSHPType == SHPT_POLYGONM
|| psObject->nSHPType == SHPT_ARC
|| psObject->nSHPType == SHPT_ARCZ
|| psObject->nSHPType == SHPT_ARCM
|| psObject->nSHPType == SHPT_MULTIPATCH )
{
int32 nPoints, nParts;
int i;
nPoints = psObject->nVertices;
nParts = psObject->nParts;
_SHPSetBounds( pabyRec + 12, psObject );
if( bBigEndian ) SwapWord( 4, &nPoints );
if( bBigEndian ) SwapWord( 4, &nParts );
ByteCopy( &nPoints, pabyRec + 40 + 8, 4 );
ByteCopy( &nParts, pabyRec + 36 + 8, 4 );
nRecordSize = 52;
/*
* Write part start positions.
*/
ByteCopy( psObject->panPartStart, pabyRec + 44 + 8,
4 * psObject->nParts );
for( i = 0; i < psObject->nParts; i++ )
{
if( bBigEndian ) SwapWord( 4, pabyRec + 44 + 8 + 4*i );
nRecordSize += 4;
}
/*
* Write multipatch part types if needed.
*/
if( psObject->nSHPType == SHPT_MULTIPATCH )
{
memcpy( pabyRec + nRecordSize, psObject->panPartType,
4*psObject->nParts );
for( i = 0; i < psObject->nParts; i++ )
{
if( bBigEndian ) SwapWord( 4, pabyRec + nRecordSize );
nRecordSize += 4;
}
}
/*
* Write the (x,y) vertex values.
*/
for( i = 0; i < psObject->nVertices; i++ )
{
ByteCopy( psObject->padfX + i, pabyRec + nRecordSize, 8 );
ByteCopy( psObject->padfY + i, pabyRec + nRecordSize + 8, 8 );
if( bBigEndian )
SwapWord( 8, pabyRec + nRecordSize );
if( bBigEndian )
SwapWord( 8, pabyRec + nRecordSize + 8 );
nRecordSize += 2 * 8;
}
/*
* Write the Z coordinates (if any).
*/
if( psObject->nSHPType == SHPT_POLYGONZ
|| psObject->nSHPType == SHPT_ARCZ
|| psObject->nSHPType == SHPT_MULTIPATCH )
{
ByteCopy( &(psObject->dfZMin), pabyRec + nRecordSize, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + nRecordSize );
nRecordSize += 8;
ByteCopy( &(psObject->dfZMax), pabyRec + nRecordSize, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + nRecordSize );
nRecordSize += 8;
for( i = 0; i < psObject->nVertices; i++ )
{
ByteCopy( psObject->padfZ + i, pabyRec + nRecordSize, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + nRecordSize );
nRecordSize += 8;
}
}
/*
* Write the M values, if any.
*/
if( psObject->nSHPType == SHPT_POLYGONM
|| psObject->nSHPType == SHPT_ARCM
#ifndef DISABLE_MULTIPATCH_MEASURE
|| psObject->nSHPType == SHPT_MULTIPATCH
#endif
|| psObject->nSHPType == SHPT_POLYGONZ
|| psObject->nSHPType == SHPT_ARCZ )
{
ByteCopy( &(psObject->dfMMin), pabyRec + nRecordSize, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + nRecordSize );
nRecordSize += 8;
ByteCopy( &(psObject->dfMMax), pabyRec + nRecordSize, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + nRecordSize );
nRecordSize += 8;
for( i = 0; i < psObject->nVertices; i++ )
{
ByteCopy( psObject->padfM + i, pabyRec + nRecordSize, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + nRecordSize );
nRecordSize += 8;
}
}
}
/* -------------------------------------------------------------------- */
/* Extract vertices for a MultiPoint. */
/* -------------------------------------------------------------------- */
else if( psObject->nSHPType == SHPT_MULTIPOINT
|| psObject->nSHPType == SHPT_MULTIPOINTZ
|| psObject->nSHPType == SHPT_MULTIPOINTM )
{
int32 nPoints;
int i;
nPoints = psObject->nVertices;
_SHPSetBounds( pabyRec + 12, psObject );
if( bBigEndian ) SwapWord( 4, &nPoints );
ByteCopy( &nPoints, pabyRec + 44, 4 );
for( i = 0; i < psObject->nVertices; i++ )
{
ByteCopy( psObject->padfX + i, pabyRec + 48 + i*16, 8 );
ByteCopy( psObject->padfY + i, pabyRec + 48 + i*16 + 8, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + 48 + i*16 );
if( bBigEndian ) SwapWord( 8, pabyRec + 48 + i*16 + 8 );
}
nRecordSize = 48 + 16 * psObject->nVertices;
if( psObject->nSHPType == SHPT_MULTIPOINTZ )
{
ByteCopy( &(psObject->dfZMin), pabyRec + nRecordSize, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + nRecordSize );
nRecordSize += 8;
ByteCopy( &(psObject->dfZMax), pabyRec + nRecordSize, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + nRecordSize );
nRecordSize += 8;
for( i = 0; i < psObject->nVertices; i++ )
{
ByteCopy( psObject->padfZ + i, pabyRec + nRecordSize, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + nRecordSize );
nRecordSize += 8;
}
}
if( psObject->nSHPType == SHPT_MULTIPOINTZ
|| psObject->nSHPType == SHPT_MULTIPOINTM )
{
ByteCopy( &(psObject->dfMMin), pabyRec + nRecordSize, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + nRecordSize );
nRecordSize += 8;
ByteCopy( &(psObject->dfMMax), pabyRec + nRecordSize, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + nRecordSize );
nRecordSize += 8;
for( i = 0; i < psObject->nVertices; i++ )
{
ByteCopy( psObject->padfM + i, pabyRec + nRecordSize, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + nRecordSize );
nRecordSize += 8;
}
}
}
/* -------------------------------------------------------------------- */
/* Write point. */
/* -------------------------------------------------------------------- */
else if( psObject->nSHPType == SHPT_POINT
|| psObject->nSHPType == SHPT_POINTZ
|| psObject->nSHPType == SHPT_POINTM )
{
ByteCopy( psObject->padfX, pabyRec + 12, 8 );
ByteCopy( psObject->padfY, pabyRec + 20, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + 12 );
if( bBigEndian ) SwapWord( 8, pabyRec + 20 );
nRecordSize = 28;
if( psObject->nSHPType == SHPT_POINTZ )
{
ByteCopy( psObject->padfZ, pabyRec + nRecordSize, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + nRecordSize );
nRecordSize += 8;
}
if( psObject->nSHPType == SHPT_POINTZ
|| psObject->nSHPType == SHPT_POINTM )
{
ByteCopy( psObject->padfM, pabyRec + nRecordSize, 8 );
if( bBigEndian ) SwapWord( 8, pabyRec + nRecordSize );
nRecordSize += 8;
}
}
/* -------------------------------------------------------------------- */
/* Not much to do for null geometries. */
/* -------------------------------------------------------------------- */
else if( psObject->nSHPType == SHPT_NULL )
{
nRecordSize = 12;
}
else
{
/* unknown type */
assert( FALSE );
}
/* -------------------------------------------------------------------- */
/* Establish where we are going to put this record. If we are */
/* rewriting and existing record, and it will fit, then put it */
/* back where the original came from. Otherwise write at the end. */
/* -------------------------------------------------------------------- */
if( nShapeId == -1 || psSHP->panRecSize[nShapeId] < nRecordSize-8 )
{
if( nShapeId == -1 )
nShapeId = psSHP->nRecords++;
psSHP->panRecOffset[nShapeId] = nRecordOffset = psSHP->nFileSize;
psSHP->panRecSize[nShapeId] = nRecordSize-8;
psSHP->nFileSize += nRecordSize;
}
else
{
nRecordOffset = psSHP->panRecOffset[nShapeId];
}
/* -------------------------------------------------------------------- */
/* Set the shape type, record number, and record size. */
/* -------------------------------------------------------------------- */
i32 = nShapeId+1; /* record # */
if( !bBigEndian ) SwapWord( 4, &i32 );
ByteCopy( &i32, pabyRec, 4 );
i32 = (nRecordSize-8)/2; /* record size */
if( !bBigEndian ) SwapWord( 4, &i32 );
ByteCopy( &i32, pabyRec + 4, 4 );
i32 = psObject->nSHPType; /* shape type */
if( bBigEndian ) SwapWord( 4, &i32 );
ByteCopy( &i32, pabyRec + 8, 4 );
/* -------------------------------------------------------------------- */
/* Write out record. */
/* -------------------------------------------------------------------- */
if( fseek( psSHP->fpSHP, nRecordOffset, 0 ) != 0
|| fwrite( pabyRec, nRecordSize, 1, psSHP->fpSHP ) < 1 )
{
#ifdef USE_CPL
CPLError( CE_Failure, CPLE_FileIO,
"Error in fseek() or fwrite() writing object to .shp file." );
#endif
free( pabyRec );
return -1;
}
free( pabyRec );
/* -------------------------------------------------------------------- */
/* Expand file wide bounds based on this shape. */
/* -------------------------------------------------------------------- */
if( psSHP->adBoundsMin[0] == 0.0
&& psSHP->adBoundsMax[0] == 0.0
&& psSHP->adBoundsMin[1] == 0.0
&& psSHP->adBoundsMax[1] == 0.0 )
{
if( psObject->nSHPType == SHPT_NULL || psObject->nVertices == 0 )
{
psSHP->adBoundsMin[0] = psSHP->adBoundsMax[0] = 0.0;
psSHP->adBoundsMin[1] = psSHP->adBoundsMax[1] = 0.0;
psSHP->adBoundsMin[2] = psSHP->adBoundsMax[2] = 0.0;
psSHP->adBoundsMin[3] = psSHP->adBoundsMax[3] = 0.0;
}
else
{
psSHP->adBoundsMin[0] = psSHP->adBoundsMax[0] = psObject->padfX[0];
psSHP->adBoundsMin[1] = psSHP->adBoundsMax[1] = psObject->padfY[0];
psSHP->adBoundsMin[2] = psSHP->adBoundsMax[2] = psObject->padfZ[0];
psSHP->adBoundsMin[3] = psSHP->adBoundsMax[3] = psObject->padfM[0];
}
}
for( i = 0; i < psObject->nVertices; i++ )
{
psSHP->adBoundsMin[0] = MIN(psSHP->adBoundsMin[0],psObject->padfX[i]);
psSHP->adBoundsMin[1] = MIN(psSHP->adBoundsMin[1],psObject->padfY[i]);
psSHP->adBoundsMin[2] = MIN(psSHP->adBoundsMin[2],psObject->padfZ[i]);
psSHP->adBoundsMin[3] = MIN(psSHP->adBoundsMin[3],psObject->padfM[i]);
psSHP->adBoundsMax[0] = MAX(psSHP->adBoundsMax[0],psObject->padfX[i]);
psSHP->adBoundsMax[1] = MAX(psSHP->adBoundsMax[1],psObject->padfY[i]);
psSHP->adBoundsMax[2] = MAX(psSHP->adBoundsMax[2],psObject->padfZ[i]);
psSHP->adBoundsMax[3] = MAX(psSHP->adBoundsMax[3],psObject->padfM[i]);
}
return( nShapeId );
}
/************************************************************************/
/* SHPReadObject() */
/* */
/* Read the vertices, parts, and other non-attribute information */
/* for one shape. */
/************************************************************************/
SHPObject SHPAPI_CALL1(*)
SHPReadObject( SHPHandle psSHP, int hEntity )
{
SHPObject *psShape;
/* -------------------------------------------------------------------- */
/* Validate the record/entity number. */
/* -------------------------------------------------------------------- */
if( hEntity < 0 || hEntity >= psSHP->nRecords )
return( NULL );
/* -------------------------------------------------------------------- */
/* Ensure our record buffer is large enough. */
/* -------------------------------------------------------------------- */
if( psSHP->panRecSize[hEntity]+8 > psSHP->nBufSize )
{
psSHP->nBufSize = psSHP->panRecSize[hEntity]+8;
psSHP->pabyRec = (uchar *) SfRealloc(psSHP->pabyRec,psSHP->nBufSize);
}
/* -------------------------------------------------------------------- */
/* Read the record. */
/* -------------------------------------------------------------------- */
if( fseek( psSHP->fpSHP, psSHP->panRecOffset[hEntity], 0 ) != 0
|| fread( psSHP->pabyRec, psSHP->panRecSize[hEntity]+8, 1,
psSHP->fpSHP ) != 1 )
{
#ifdef USE_CPL
CPLError( CE_Failure, CPLE_FileIO,
"Error in fseek() or fread() reading object from .shp file." );
#endif
return NULL;
}
/* -------------------------------------------------------------------- */
/* Allocate and minimally initialize the object. */
/* -------------------------------------------------------------------- */
psShape = (SHPObject *) calloc(1,sizeof(SHPObject));
psShape->nShapeId = hEntity;
memcpy( &psShape->nSHPType, psSHP->pabyRec + 8, 4 );
if( bBigEndian ) SwapWord( 4, &(psShape->nSHPType) );
/* ==================================================================== */
/* Extract vertices for a Polygon or Arc. */
/* ==================================================================== */
if( psShape->nSHPType == SHPT_POLYGON || psShape->nSHPType == SHPT_ARC
|| psShape->nSHPType == SHPT_POLYGONZ
|| psShape->nSHPType == SHPT_POLYGONM
|| psShape->nSHPType == SHPT_ARCZ
|| psShape->nSHPType == SHPT_ARCM
|| psShape->nSHPType == SHPT_MULTIPATCH )
{
int32 nPoints, nParts;
int i, nOffset;
/* -------------------------------------------------------------------- */
/* Get the X/Y bounds. */
/* -------------------------------------------------------------------- */
memcpy( &(psShape->dfXMin), psSHP->pabyRec + 8 + 4, 8 );
memcpy( &(psShape->dfYMin), psSHP->pabyRec + 8 + 12, 8 );
memcpy( &(psShape->dfXMax), psSHP->pabyRec + 8 + 20, 8 );
memcpy( &(psShape->dfYMax), psSHP->pabyRec + 8 + 28, 8 );
if( bBigEndian ) SwapWord( 8, &(psShape->dfXMin) );
if( bBigEndian ) SwapWord( 8, &(psShape->dfYMin) );
if( bBigEndian ) SwapWord( 8, &(psShape->dfXMax) );
if( bBigEndian ) SwapWord( 8, &(psShape->dfYMax) );
/* -------------------------------------------------------------------- */
/* Extract part/point count, and build vertex and part arrays */
/* to proper size. */
/* -------------------------------------------------------------------- */
memcpy( &nPoints, psSHP->pabyRec + 40 + 8, 4 );
memcpy( &nParts, psSHP->pabyRec + 36 + 8, 4 );
if( bBigEndian ) SwapWord( 4, &nPoints );
if( bBigEndian ) SwapWord( 4, &nParts );
psShape->nVertices = nPoints;
psShape->padfX = (double *) calloc(nPoints,sizeof(double));
psShape->padfY = (double *) calloc(nPoints,sizeof(double));
psShape->padfZ = (double *) calloc(nPoints,sizeof(double));
psShape->padfM = (double *) calloc(nPoints,sizeof(double));
psShape->nParts = nParts;
psShape->panPartStart = (int *) calloc(nParts,sizeof(int));
psShape->panPartType = (int *) calloc(nParts,sizeof(int));
for( i = 0; i < nParts; i++ )
psShape->panPartType[i] = SHPP_RING;
/* -------------------------------------------------------------------- */
/* Copy out the part array from the record. */
/* -------------------------------------------------------------------- */
memcpy( psShape->panPartStart, psSHP->pabyRec + 44 + 8, 4 * nParts );
for( i = 0; i < nParts; i++ )
{
if( bBigEndian ) SwapWord( 4, psShape->panPartStart+i );
}
nOffset = 44 + 8 + 4*nParts;
/* -------------------------------------------------------------------- */
/* If this is a multipatch, we will also have parts types. */
/* -------------------------------------------------------------------- */
if( psShape->nSHPType == SHPT_MULTIPATCH )
{
memcpy( psShape->panPartType, psSHP->pabyRec + nOffset, 4*nParts );
for( i = 0; i < nParts; i++ )
{
if( bBigEndian ) SwapWord( 4, psShape->panPartType+i );
}
nOffset += 4*nParts;
}
/* -------------------------------------------------------------------- */
/* Copy out the vertices from the record. */
/* -------------------------------------------------------------------- */
for( i = 0; i < nPoints; i++ )
{
memcpy(psShape->padfX + i,
psSHP->pabyRec + nOffset + i * 16,
8 );
memcpy(psShape->padfY + i,
psSHP->pabyRec + nOffset + i * 16 + 8,
8 );
if( bBigEndian ) SwapWord( 8, psShape->padfX + i );
if( bBigEndian ) SwapWord( 8, psShape->padfY + i );
}
nOffset += 16*nPoints;
/* -------------------------------------------------------------------- */
/* If we have a Z coordinate, collect that now. */
/* -------------------------------------------------------------------- */
if( psShape->nSHPType == SHPT_POLYGONZ
|| psShape->nSHPType == SHPT_ARCZ
|| psShape->nSHPType == SHPT_MULTIPATCH )
{
memcpy( &(psShape->dfZMin), psSHP->pabyRec + nOffset, 8 );
memcpy( &(psShape->dfZMax), psSHP->pabyRec + nOffset + 8, 8 );
if( bBigEndian ) SwapWord( 8, &(psShape->dfZMin) );
if( bBigEndian ) SwapWord( 8, &(psShape->dfZMax) );
for( i = 0; i < nPoints; i++ )
{
memcpy( psShape->padfZ + i,
psSHP->pabyRec + nOffset + 16 + i*8, 8 );
if( bBigEndian ) SwapWord( 8, psShape->padfZ + i );
}
nOffset += 16 + 8*nPoints;
}
/* -------------------------------------------------------------------- */
/* If we have a M measure value, then read it now. We assume */
/* that the measure can be present for any shape if the size is */
/* big enough, but really it will only occur for the Z shapes */
/* (options), and the M shapes. */
/* -------------------------------------------------------------------- */
if( psSHP->panRecSize[hEntity]+8 >= nOffset + 16 + 8*nPoints )
{
memcpy( &(psShape->dfMMin), psSHP->pabyRec + nOffset, 8 );
memcpy( &(psShape->dfMMax), psSHP->pabyRec + nOffset + 8, 8 );
if( bBigEndian ) SwapWord( 8, &(psShape->dfMMin) );
if( bBigEndian ) SwapWord( 8, &(psShape->dfMMax) );
for( i = 0; i < nPoints; i++ )
{
memcpy( psShape->padfM + i,
psSHP->pabyRec + nOffset + 16 + i*8, 8 );
if( bBigEndian ) SwapWord( 8, psShape->padfM + i );
}
}
}
/* ==================================================================== */
/* Extract vertices for a MultiPoint. */
/* ==================================================================== */
else if( psShape->nSHPType == SHPT_MULTIPOINT
|| psShape->nSHPType == SHPT_MULTIPOINTM
|| psShape->nSHPType == SHPT_MULTIPOINTZ )
{
int32 nPoints;
int i, nOffset;
memcpy( &nPoints, psSHP->pabyRec + 44, 4 );
if( bBigEndian ) SwapWord( 4, &nPoints );
psShape->nVertices = nPoints;
psShape->padfX = (double *) calloc(nPoints,sizeof(double));
psShape->padfY = (double *) calloc(nPoints,sizeof(double));
psShape->padfZ = (double *) calloc(nPoints,sizeof(double));
psShape->padfM = (double *) calloc(nPoints,sizeof(double));
for( i = 0; i < nPoints; i++ )
{
memcpy(psShape->padfX+i, psSHP->pabyRec + 48 + 16 * i, 8 );
memcpy(psShape->padfY+i, psSHP->pabyRec + 48 + 16 * i + 8, 8 );
if( bBigEndian ) SwapWord( 8, psShape->padfX + i );
if( bBigEndian ) SwapWord( 8, psShape->padfY + i );
}
nOffset = 48 + 16*nPoints;
/* -------------------------------------------------------------------- */
/* Get the X/Y bounds. */
/* -------------------------------------------------------------------- */
memcpy( &(psShape->dfXMin), psSHP->pabyRec + 8 + 4, 8 );
memcpy( &(psShape->dfYMin), psSHP->pabyRec + 8 + 12, 8 );
memcpy( &(psShape->dfXMax), psSHP->pabyRec + 8 + 20, 8 );
memcpy( &(psShape->dfYMax), psSHP->pabyRec + 8 + 28, 8 );
if( bBigEndian ) SwapWord( 8, &(psShape->dfXMin) );
if( bBigEndian ) SwapWord( 8, &(psShape->dfYMin) );
if( bBigEndian ) SwapWord( 8, &(psShape->dfXMax) );
if( bBigEndian ) SwapWord( 8, &(psShape->dfYMax) );
/* -------------------------------------------------------------------- */
/* If we have a Z coordinate, collect that now. */
/* -------------------------------------------------------------------- */
if( psShape->nSHPType == SHPT_MULTIPOINTZ )
{
memcpy( &(psShape->dfZMin), psSHP->pabyRec + nOffset, 8 );
memcpy( &(psShape->dfZMax), psSHP->pabyRec + nOffset + 8, 8 );
if( bBigEndian ) SwapWord( 8, &(psShape->dfZMin) );
if( bBigEndian ) SwapWord( 8, &(psShape->dfZMax) );
for( i = 0; i < nPoints; i++ )
{
memcpy( psShape->padfZ + i,
psSHP->pabyRec + nOffset + 16 + i*8, 8 );
if( bBigEndian ) SwapWord( 8, psShape->padfZ + i );
}
nOffset += 16 + 8*nPoints;
}
/* -------------------------------------------------------------------- */
/* If we have a M measure value, then read it now. We assume */
/* that the measure can be present for any shape if the size is */
/* big enough, but really it will only occur for the Z shapes */
/* (options), and the M shapes. */
/* -------------------------------------------------------------------- */
if( psSHP->panRecSize[hEntity]+8 >= nOffset + 16 + 8*nPoints )
{
memcpy( &(psShape->dfMMin), psSHP->pabyRec + nOffset, 8 );
memcpy( &(psShape->dfMMax), psSHP->pabyRec + nOffset + 8, 8 );
if( bBigEndian ) SwapWord( 8, &(psShape->dfMMin) );
if( bBigEndian ) SwapWord( 8, &(psShape->dfMMax) );
for( i = 0; i < nPoints; i++ )
{
memcpy( psShape->padfM + i,
psSHP->pabyRec + nOffset + 16 + i*8, 8 );
if( bBigEndian ) SwapWord( 8, psShape->padfM + i );
}
}
}
/* ==================================================================== */
/* Extract vertices for a point. */
/* ==================================================================== */
else if( psShape->nSHPType == SHPT_POINT
|| psShape->nSHPType == SHPT_POINTM
|| psShape->nSHPType == SHPT_POINTZ )
{
int nOffset;
psShape->nVertices = 1;
psShape->padfX = (double *) calloc(1,sizeof(double));
psShape->padfY = (double *) calloc(1,sizeof(double));
psShape->padfZ = (double *) calloc(1,sizeof(double));
psShape->padfM = (double *) calloc(1,sizeof(double));
memcpy( psShape->padfX, psSHP->pabyRec + 12, 8 );
memcpy( psShape->padfY, psSHP->pabyRec + 20, 8 );
if( bBigEndian ) SwapWord( 8, psShape->padfX );
if( bBigEndian ) SwapWord( 8, psShape->padfY );
nOffset = 20 + 8;
/* -------------------------------------------------------------------- */
/* If we have a Z coordinate, collect that now. */
/* -------------------------------------------------------------------- */
if( psShape->nSHPType == SHPT_POINTZ )
{
memcpy( psShape->padfZ, psSHP->pabyRec + nOffset, 8 );
if( bBigEndian ) SwapWord( 8, psShape->padfZ );
nOffset += 8;
}
/* -------------------------------------------------------------------- */
/* If we have a M measure value, then read it now. We assume */
/* that the measure can be present for any shape if the size is */
/* big enough, but really it will only occur for the Z shapes */
/* (options), and the M shapes. */
/* -------------------------------------------------------------------- */
if( psSHP->panRecSize[hEntity]+8 >= nOffset + 8 )
{
memcpy( psShape->padfM, psSHP->pabyRec + nOffset, 8 );
if( bBigEndian ) SwapWord( 8, psShape->padfM );
}
/* -------------------------------------------------------------------- */
/* Since no extents are supplied in the record, we will apply */
/* them from the single vertex. */
/* -------------------------------------------------------------------- */
psShape->dfXMin = psShape->dfXMax = psShape->padfX[0];
psShape->dfYMin = psShape->dfYMax = psShape->padfY[0];
psShape->dfZMin = psShape->dfZMax = psShape->padfZ[0];
psShape->dfMMin = psShape->dfMMax = psShape->padfM[0];
}
return( psShape );
}
/************************************************************************/
/* SHPTypeName() */
/************************************************************************/
const char SHPAPI_CALL1(*)
SHPTypeName( int nSHPType )
{
switch( nSHPType )
{
case SHPT_NULL:
return "NullShape";
case SHPT_POINT:
return "Point";
case SHPT_ARC:
return "Arc";
case SHPT_POLYGON:
return "Polygon";
case SHPT_MULTIPOINT:
return "MultiPoint";
case SHPT_POINTZ:
return "PointZ";
case SHPT_ARCZ:
return "ArcZ";
case SHPT_POLYGONZ:
return "PolygonZ";
case SHPT_MULTIPOINTZ:
return "MultiPointZ";
case SHPT_POINTM:
return "PointM";
case SHPT_ARCM:
return "ArcM";
case SHPT_POLYGONM:
return "PolygonM";
case SHPT_MULTIPOINTM:
return "MultiPointM";
case SHPT_MULTIPATCH:
return "MultiPatch";
default:
return "UnknownShapeType";
}
}
/************************************************************************/
/* SHPPartTypeName() */
/************************************************************************/
const char SHPAPI_CALL1(*)
SHPPartTypeName( int nPartType )
{
switch( nPartType )
{
case SHPP_TRISTRIP:
return "TriangleStrip";
case SHPP_TRIFAN:
return "TriangleFan";
case SHPP_OUTERRING:
return "OuterRing";
case SHPP_INNERRING:
return "InnerRing";
case SHPP_FIRSTRING:
return "FirstRing";
case SHPP_RING:
return "Ring";
default:
return "UnknownPartType";
}
}
/************************************************************************/
/* SHPDestroyObject() */
/************************************************************************/
void SHPAPI_CALL
SHPDestroyObject( SHPObject * psShape )
{
if( psShape == NULL )
return;
if( psShape->padfX != NULL )
free( psShape->padfX );
if( psShape->padfY != NULL )
free( psShape->padfY );
if( psShape->padfZ != NULL )
free( psShape->padfZ );
if( psShape->padfM != NULL )
free( psShape->padfM );
if( psShape->panPartStart != NULL )
free( psShape->panPartStart );
if( psShape->panPartType != NULL )
free( psShape->panPartType );
free( psShape );
}
/************************************************************************/
/* SHPRewindObject() */
/* */
/* Reset the winding of polygon objects to adhere to the */
/* specification. */
/************************************************************************/
int SHPAPI_CALL
SHPRewindObject( SHPHandle hSHP, SHPObject * psObject )
{
int iOpRing, bAltered = 0;
/* -------------------------------------------------------------------- */
/* Do nothing if this is not a polygon object. */
/* -------------------------------------------------------------------- */
if( psObject->nSHPType != SHPT_POLYGON
&& psObject->nSHPType != SHPT_POLYGONZ
&& psObject->nSHPType != SHPT_POLYGONM )
return 0;
if( psObject->nVertices == 0 || psObject->nParts == 0 )
return 0;
/* -------------------------------------------------------------------- */
/* Process each of the rings. */
/* -------------------------------------------------------------------- */
for( iOpRing = 0; iOpRing < psObject->nParts; iOpRing++ )
{
int bInner, iVert, nVertCount, nVertStart, iCheckRing;
double dfSum, dfTestX, dfTestY;
/* -------------------------------------------------------------------- */
/* Determine if this ring is an inner ring or an outer ring */
/* relative to all the other rings. For now we assume the */
/* first ring is outer and all others are inner, but eventually */
/* we need to fix this to handle multiple island polygons and */
/* unordered sets of rings. */
/* -------------------------------------------------------------------- */
dfTestX = psObject->padfX[psObject->panPartStart[iOpRing]];
dfTestY = psObject->padfY[psObject->panPartStart[iOpRing]];
bInner = FALSE;
for( iCheckRing = 0; iCheckRing < psObject->nParts; iCheckRing++ )
{
int iEdge;
if( iCheckRing == iOpRing )
continue;
nVertStart = psObject->panPartStart[iCheckRing];
if( iCheckRing == psObject->nParts-1 )
nVertCount = psObject->nVertices
- psObject->panPartStart[iCheckRing];
else
nVertCount = psObject->panPartStart[iCheckRing+1]
- psObject->panPartStart[iCheckRing];
for( iEdge = 0; iEdge < nVertCount; iEdge++ )
{
int iNext;
if( iEdge < nVertCount-1 )
iNext = iEdge+1;
else
iNext = 0;
if( (psObject->padfY[iEdge+nVertStart] < dfTestY
&& psObject->padfY[iNext+nVertStart] >= dfTestY)
|| (psObject->padfY[iNext+nVertStart] < dfTestY
&& psObject->padfY[iEdge+nVertStart] >= dfTestY) )
{
if( psObject->padfX[iEdge+nVertStart]
+ (dfTestY - psObject->padfY[iEdge+nVertStart])
/ (psObject->padfY[iNext+nVertStart]
- psObject->padfY[iEdge+nVertStart])
* (psObject->padfX[iNext+nVertStart]
- psObject->padfX[iEdge+nVertStart]) < dfTestX )
bInner = !bInner;
}
}
}
/* -------------------------------------------------------------------- */
/* Determine the current order of this ring so we will know if */
/* it has to be reversed. */
/* -------------------------------------------------------------------- */
nVertStart = psObject->panPartStart[iOpRing];
if( iOpRing == psObject->nParts-1 )
nVertCount = psObject->nVertices - psObject->panPartStart[iOpRing];
else
nVertCount = psObject->panPartStart[iOpRing+1]
- psObject->panPartStart[iOpRing];
dfSum = 0.0;
for( iVert = nVertStart; iVert < nVertStart+nVertCount-1; iVert++ )
{
dfSum += psObject->padfX[iVert] * psObject->padfY[iVert+1]
- psObject->padfY[iVert] * psObject->padfX[iVert+1];
}
dfSum += psObject->padfX[iVert] * psObject->padfY[nVertStart]
- psObject->padfY[iVert] * psObject->padfX[nVertStart];
/* -------------------------------------------------------------------- */
/* Reverse if necessary. */
/* -------------------------------------------------------------------- */
if( (dfSum < 0.0 && bInner) || (dfSum > 0.0 && !bInner) )
{
int i;
bAltered++;
for( i = 0; i < nVertCount/2; i++ )
{
double dfSaved;
/* Swap X */
dfSaved = psObject->padfX[nVertStart+i];
psObject->padfX[nVertStart+i] =
psObject->padfX[nVertStart+nVertCount-i-1];
psObject->padfX[nVertStart+nVertCount-i-1] = dfSaved;
/* Swap Y */
dfSaved = psObject->padfY[nVertStart+i];
psObject->padfY[nVertStart+i] =
psObject->padfY[nVertStart+nVertCount-i-1];
psObject->padfY[nVertStart+nVertCount-i-1] = dfSaved;
/* Swap Z */
if( psObject->padfZ )
{
dfSaved = psObject->padfZ[nVertStart+i];
psObject->padfZ[nVertStart+i] =
psObject->padfZ[nVertStart+nVertCount-i-1];
psObject->padfZ[nVertStart+nVertCount-i-1] = dfSaved;
}
/* Swap M */
if( psObject->padfM )
{
dfSaved = psObject->padfM[nVertStart+i];
psObject->padfM[nVertStart+i] =
psObject->padfM[nVertStart+nVertCount-i-1];
psObject->padfM[nVertStart+nVertCount-i-1] = dfSaved;
}
}
}
}
return bAltered;
}
