/****p* Program/H5match_types * * NAME * Executable: H5match_types * * FILE * fortran/src/H5match_types.c * * PURPOSE * C Program to match C types to Fortran types. * Creates the files H5f90i_gen.h for the C code and * H5fortran_types.f90 for the Fortran code. * * COPYRIGHT * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * Copyright by The HDF Group. * * Copyright by the Board of Trustees of the University of Illinois. * * All rights reserved. * * * * This file is part of HDF5. The full HDF5 copyright notice, including * * terms governing use, modification, and redistribution, is contained in * * the files COPYING and Copyright.html. COPYING can be found at the root * * of the source code distribution tree; Copyright.html can be found at the * * root level of an installed copy of the electronic HDF5 document set and * * is linked from the top-level documents page. It can also be found at * * http://hdfgroup.org/HDF5/doc/Copyright.html. If you do not have * * access to either file, you may request a copy from help@hdfgroup.org. * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * ****** */ #include #include #include "H5public.h" /* Include H5Ipublic.h for hid_t type */ #include "H5Ipublic.h" /* Definitions of which fortran type sizes exist */ #include "H5fort_type_defines.h" /* File pointers for files */ FILE * c_header; FILE * fort_header; #define CFILE "H5f90i_gen.h" #define FFILE "H5fortran_types.f90" /* Prototypes for the write routines */ void writeTypedef(const char* c_typedef, const char* c_type, unsigned int size); void writeTypedefDefault(const char* c_typedef, unsigned int size); void writeToFiles(const char* c_typedef, const char* fortran_type, const char* c_type, int size, unsigned int kind); static void initCfile(void) { fprintf(c_header, "/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\n\ * Copyright by The HDF Group. *\n\ * Copyright by the Board of Trustees of the University of Illinois. *\n\ * All rights reserved. *\n\ * *\n\ * This file is part of HDF5. The full HDF5 copyright notice, including *\n\ * terms governing use, modification, and redistribution, is contained in *\n\ * the files COPYING and Copyright.html. COPYING can be found at the root *\n\ * of the source code distribution tree; Copyright.html can be found at the *\n\ * root level of an installed copy of the electronic HDF5 document set and *\n\ * is linked from the top-level documents page. It can also be found at *\n\ * http://hdfgroup.org/HDF5/doc/Copyright.html. If you do not have *\n\ * access to either file, you may request a copy from help@hdfgroup.org. *\n\ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */\n\ \n\n\ #ifndef _H5f90i_gen_H\n\ #define _H5f90i_gen_H\n\ \n\ /* This file is automatically generated by H5match_types.c at build time. */\n\ \n\ #include \"H5public.h\"\n\n"); } static void initFfile(void) { fprintf(fort_header, "! * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * \n\ ! Copyright by The HDF Group. *\n\ ! Copyright by the Board of Trustees of the University of Illinois. *\n\ ! All rights reserved. *\n\ ! *\n\ ! This file is part of HDF5. The full HDF5 copyright notice, including *\n\ ! terms governing use, modification, and redistribution, is contained in *\n\ ! the files COPYING and Copyright.html. COPYING can be found at the root *\n\ ! of the source code distribution tree; Copyright.html can be found at the *\n\ ! root level of an installed copy of the electronic HDF5 document set and *\n\ ! is linked from the top-level documents page. It can also be found at *\n\ ! http://hdfgroup.org/HDF5/doc/Copyright.html. If you do not have *\n\ ! access to either file, you may request a copy from help@hdfgroup.org. *\n\ ! * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *\n\ !\n!\n\ ! This file is automatically generated and contains HDF5 Fortran90 type definitions.\n!\n\ MODULE H5FORTRAN_TYPES\n\ !\n\ ! HDF5 integers\n\ !\n"); } static void endCfile(void) { fprintf(c_header, "\n#endif /* _H5f90i_gen_H */\n"); } static void endFfile(void) { fprintf(fort_header, "\n INTEGER(SIZE_T), PARAMETER :: OBJECT_NAMELEN_DEFAULT_F = -1\n\n"); fprintf(fort_header, " END MODULE H5FORTRAN_TYPES\n"); } /* Define a c_int_x type in the C header */ void writeTypedef(const char* c_typedef, const char* c_type, unsigned int size) { fprintf(c_header, "#define c_%s_%u %s\n", c_typedef, size, c_type); } /* Call this function if there is no matching C type for sizes > 1 */ void writeTypedefDefault(const char* c_typedef, unsigned int size) { assert(size %2 == 0); fprintf(c_header, "typedef struct {c_%s_%u a; c_%s_%u b;} c_%s_%u\n", c_typedef, size / 2, c_typedef, size / 2, c_typedef, size); } /* Create matching Fortran and C types by writing to both files */ void writeToFiles(const char* c_typedef, const char* fortran_type, const char* c_type, int size, unsigned int kind) { fprintf(fort_header, " INTEGER, PARAMETER :: %s = %u\n", fortran_type, kind); fprintf(c_header, "typedef c_%s_%d %s;\n", c_typedef, size, c_type); } int main(void) { int FoundIntSize[4]; unsigned FoundIntSizeKind[4]; int FoundRealSize[3]; unsigned FoundRealSizeKind[3]; int i,j,flag; char chrA[20],chrB[20]; int H5_C_HAS_REAL_NATIVE_16; /* Open target files */ c_header = fopen(CFILE, "w"); fort_header = fopen(FFILE, "w"); /* Default is C has 16 byte float */ H5_C_HAS_REAL_NATIVE_16 = 1; /* Write copyright, boilerplate to both files */ initCfile(); initFfile(); /* First, define c_int_x */ #if defined H5_FORTRAN_HAS_INTEGER_1_KIND if(sizeof(long long) == 1) writeTypedef("int", "long long", 1); else if(sizeof(long) == 1) writeTypedef("int", "long", 1); else if(sizeof(int) == 1) writeTypedef("int", "int", 1); else if(sizeof(short) == 1) writeTypedef("int", "short", 1); else writeTypedef("int", "char", 1); /* Actually, char is not necessarily one byte. * But if char isn't, then nothing is, so this * is as close as we can get. */ if(sizeof(size_t) == 1) writeTypedef("size_t", "size_t", 1); if(sizeof(hsize_t) == 1) writeTypedef("hsize_t", "hsize_t", 1); #endif /*H5_FORTRAN_HAS_INTEGER_1_KIND*/ #if defined H5_FORTRAN_HAS_INTEGER_2_KIND if(sizeof(long long) == 2) writeTypedef("int", "long long", 2); else if(sizeof(long) == 2) writeTypedef("int", "long", 2); else if(sizeof(int) == 2) writeTypedef("int", "int", 2); else if(sizeof(short) == 2) writeTypedef("int", "short", 2); else writeTypedefDefault("int",2); if(sizeof(size_t) == 2) writeTypedef("size_t", "size_t", 2); if(sizeof(hsize_t) == 2) writeTypedef("hsize_t", "hsize_t", 2); #endif /*H5_FORTRAN_HAS_INTEGER_2_KIND*/ #if defined H5_FORTRAN_HAS_INTEGER_4_KIND if(sizeof(long long) == 4) writeTypedef("int", "long long", 4); else if(sizeof(long) == 4) writeTypedef("int", "long", 4); else if(sizeof(int) == 4) writeTypedef("int", "int", 4); else if(sizeof(short) == 4) writeTypedef("int", "short", 4); else writeTypedefDefault("int",4); if(sizeof(size_t) == 4) writeTypedef("size_t", "size_t", 4); if(sizeof(hsize_t) == 4) writeTypedef("hsize_t", "hsize_t", 4); #endif /*H5_FORTRAN_HAS_INTEGER_4_KIND*/ #if defined H5_FORTRAN_HAS_INTEGER_8_KIND if(sizeof(long long) == 8) writeTypedef("int", "long long", 8); else if(sizeof(long) == 8) writeTypedef("int", "long", 8); else if(sizeof(int) == 8) writeTypedef("int", "int", 8); else if(sizeof(short) == 8) writeTypedef("int", "short", 8); else writeTypedefDefault("int",8); if(sizeof(size_t) == 8) writeTypedef("size_t", "size_t", 8); if(sizeof(hsize_t) == 8) writeTypedef("hsize_t", "hsize_t", 8); #endif /*H5_FORTRAN_HAS_INTEGER_8_KIND*/ /* Define c_float_x */ #if defined H5_FORTRAN_HAS_REAL_NATIVE_4_KIND || defined H5_FORTRAN_HAS_REAL_4_KIND if(sizeof(long double) == 4) writeTypedef("float", "long double", 4); else if(sizeof(double) == 4) writeTypedef("float", "double", 4); else if(sizeof(float) == 4) writeTypedef("float", "float", 4); else { printf("Fortran REAL is 4 bytes, no corresponding C floating type\n"); printf("Quitting....\n"); return -1; } #endif /*H5_FORTRAN_HAS_REAL_NATIVE_4_KIND*/ #if defined H5_FORTRAN_HAS_REAL_NATIVE_8_KIND || defined H5_FORTRAN_HAS_REAL_8_KIND if(sizeof(long double) == 8) writeTypedef("float", "long double", 8); else if(sizeof(double) == 8) writeTypedef("float", "double", 8); else if(sizeof(float) == 8) writeTypedef("float", "float", 8); else { printf("Fortran REAL is 16 bytes, no corresponding C floating type\n"); printf("Quitting....\n"); return -1; } #endif /*H5_FORTRAN_HAS_REAL_NATIVE_8_KIND*/ #if defined H5_FORTRAN_HAS_REAL_NATIVE_16_KIND || defined H5_FORTRAN_HAS_REAL_16_KIND if(sizeof(long double) == 16) writeTypedef("float", "long double", 16); else if(sizeof(double) == 16) writeTypedef("float", "double", 16); else if(sizeof(float) == 16) writeTypedef("float", "float", 16); else /*C has no 16 byte float so disable it in Fortran*/ { printf("warning: Fortran REAL is 16 bytes, no corresponding C floating type\n"); printf(" Disabling Fortran 16 byte REALs\n"); H5_C_HAS_REAL_NATIVE_16 = 0; } #endif /*H5_FORTRAN_HAS_REAL_NATIVE_16_KIND*/ /* Now begin defining fortran types. */ fprintf(c_header, "\n"); /* haddr_t */ #if defined H5_FORTRAN_HAS_INTEGER_8_KIND && H5_SIZEOF_HADDR_T >= 8 writeToFiles("int","HADDR_T", "haddr_t_f", 8, H5_FORTRAN_HAS_INTEGER_8_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_4_KIND && H5_SIZEOF_HADDR_T >= 4 writeToFiles("int","HADDR_T", "haddr_t_f", 4, H5_FORTRAN_HAS_INTEGER_4_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_2_KIND && H5_SIZEOF_HADDR_T >= 2 writeToFiles("int","HADDR_T", "haddr_t_f", 2, H5_FORTRAN_HAS_INTEGER_2_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_1_KIND && H5_SIZEOF_HADDR_T >= 1 writeToFiles("int","HADDR_T", "haddr_t_f", 1, H5_FORTRAN_HAS_INTEGER_1_KIND); #else /* Error: couldn't find a size for haddr_t */ return -1; #endif /* hsize_t */ #if defined H5_FORTRAN_HAS_INTEGER_8_KIND && H5_SIZEOF_HSIZE_T >= 8 writeToFiles("hsize_t","HSIZE_T", "hsize_t_f", 8, H5_FORTRAN_HAS_INTEGER_8_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_4_KIND && H5_SIZEOF_HSIZE_T >= 4 writeToFiles("hsize_t","HSIZE_T", "hsize_t_f", 4, H5_FORTRAN_HAS_INTEGER_4_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_2_KIND && H5_SIZEOF_HSIZE_T >= 2 writeToFiles("hsize_t","HSIZE_T", "hsize_t_f", 2, H5_FORTRAN_HAS_INTEGER_2_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_1_KIND && H5_SIZEOF_HSIZE_T >= 1 writeToFiles("hsize_t","HSIZE_T", "hsize_t_f", 1, H5_FORTRAN_HAS_INTEGER_1_KIND); #else /* Error: couldn't find a size for hsize_t */ return -1; #endif /* hssize_t */ #if defined H5_FORTRAN_HAS_INTEGER_8_KIND && H5_SIZEOF_HSSIZE_T >= 8 writeToFiles("int","HSSIZE_T", "hssize_t_f", 8, H5_FORTRAN_HAS_INTEGER_8_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_4_KIND && H5_SIZEOF_HSSIZE_T >= 4 writeToFiles("int","HSSIZE_T", "hssize_t_f", 4, H5_FORTRAN_HAS_INTEGER_4_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_2_KIND && H5_SIZEOF_HSSIZE_T >= 2 writeToFiles("int","HSSIZE_T", "hssize_t_f", 2, H5_FORTRAN_HAS_INTEGER_2_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_1_KIND && H5_SIZEOF_HSSIZE_T >= 1 writeToFiles("int","HSSIZE_T", "hssize_t_f", 1, H5_FORTRAN_HAS_INTEGER_1_KIND); #else /* Error: couldn't find a size for hssize_t */ return -1; #endif /* off_t */ #if defined H5_FORTRAN_HAS_INTEGER_8_KIND && H5_SIZEOF_OFF_T >= 8 writeToFiles("int","OFF_T", "off_t_f", 8, H5_FORTRAN_HAS_INTEGER_8_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_4_KIND && H5_SIZEOF_OFF_T >= 4 writeToFiles("int","OFF_T", "off_t_f", 4, H5_FORTRAN_HAS_INTEGER_4_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_2_KIND && H5_SIZEOF_OFF_T >= 2 writeToFiles("int","OFF_T", "off_t_f", 2, H5_FORTRAN_HAS_INTEGER_2_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_1_KIND && H5_SIZEOF_OFF_T >= 1 writeToFiles("int","OFF_T", "off_t_f", 1, H5_FORTRAN_HAS_INTEGER_1_KIND); #else /* Error: couldn't find a size for off_t */ return -1; #endif /* size_t */ #if defined H5_FORTRAN_HAS_INTEGER_8_KIND && H5_SIZEOF_SIZE_T >= 8 writeToFiles("size_t","SIZE_T", "size_t_f", 8, H5_FORTRAN_HAS_INTEGER_8_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_4_KIND && H5_SIZEOF_SIZE_T >= 4 writeToFiles("size_t","SIZE_T", "size_t_f", 4, H5_FORTRAN_HAS_INTEGER_4_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_2_KIND && H5_SIZEOF_SIZE_T >= 2 writeToFiles("size_t","SIZE_T", "size_t_f", 2, H5_FORTRAN_HAS_INTEGER_2_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_1_KIND && H5_SIZEOF_SIZE_T >= 1 writeToFiles("size_t","SIZE_T", "size_t_f", 1, H5_FORTRAN_HAS_INTEGER_1_KIND); #else /* Error: couldn't find a size for size_t */ return -1; #endif /* int */ #if defined H5_FORTRAN_HAS_NATIVE_8_KIND writeToFiles("int","Fortran_INTEGER", "int_f", 8, H5_FORTRAN_HAS_NATIVE_8_KIND); #elif defined H5_FORTRAN_HAS_NATIVE_4_KIND writeToFiles("int","Fortran_INTEGER", "int_f", 4, H5_FORTRAN_HAS_NATIVE_4_KIND); #elif defined H5_FORTRAN_HAS_NATIVE_2_KIND writeToFiles("int","Fortran_INTEGER", "int_f", 2, H5_FORTRAN_HAS_NATIVE_2_KIND); #elif defined H5_FORTRAN_HAS_NATIVE_1_KIND writeToFiles("int","Fortran_INTEGER", "int_f", 1, H5_FORTRAN_HAS_NATIVE_1_KIND); #else /* Error: couldn't find a size for int */ return -1; #endif /* int_1, int_2, int_4, int_8 */ /* Defined different KINDs of integers: */ /* if the integer kind is not available then we assign */ /* it a value of the next larger one, but if the next */ /* higher one is not available we assigned it the next lowest */ FoundIntSize[0] = -1; FoundIntSize[1] = -2; FoundIntSize[2] = -4; FoundIntSize[3] = -8; #if defined H5_FORTRAN_HAS_INTEGER_1_KIND FoundIntSize[0] = 1; FoundIntSizeKind[0] = H5_FORTRAN_HAS_INTEGER_1_KIND; #endif #if defined H5_FORTRAN_HAS_INTEGER_2_KIND FoundIntSize[1] = 2; FoundIntSizeKind[1] = H5_FORTRAN_HAS_INTEGER_2_KIND; #endif #if defined H5_FORTRAN_HAS_INTEGER_4_KIND FoundIntSize[2] = 4; FoundIntSizeKind[2] = H5_FORTRAN_HAS_INTEGER_4_KIND; #endif #if defined H5_FORTRAN_HAS_INTEGER_8_KIND FoundIntSize[3] = 8; FoundIntSizeKind[3] = H5_FORTRAN_HAS_INTEGER_8_KIND ; #endif for(i=0;i<4;i++) { if( FoundIntSize[i] > 0) /* Found the integer type */ { sprintf(chrA, "Fortran_INTEGER_%d", FoundIntSize[i]); sprintf(chrB, "int_%d_f", FoundIntSize[i]); writeToFiles("int",chrA, chrB, FoundIntSize[i], FoundIntSizeKind[i]); } else /* Did not find the integer type */ { flag = 0; /* flag indicating if found the next highest */ for(j=i+1;j<4;j++) /* search for next highest */ { if( FoundIntSize[j] > 0) /* Found the next highest */ { sprintf(chrA, "Fortran_INTEGER_%d", (-1)*FoundIntSize[i]); sprintf(chrB, "int_%d_f", (-1)*FoundIntSize[i]); writeToFiles("int",chrA, chrB, FoundIntSize[j], FoundIntSizeKind[j]); flag = 1; break; } } if(flag == 0) /* No higher one found, so find next lowest */ { for(j=2;j>-1;j--) /* Search for next lowest */ { if( FoundIntSize[j] > 0) /* Found the next lowest */ { sprintf(chrA, "Fortran_INTEGER_%d", (-1)*FoundIntSize[i]); sprintf(chrB, "int_%d_f", (-1)*FoundIntSize[i]); writeToFiles("int",chrA, chrB, FoundIntSize[j], FoundIntSizeKind[j]); flag = 1; break; } } } if(flag == 0) /* No higher or lower one found, indicating an error */ return -1; } } /* real_4, real_8, real_16 */ /* Defined different KINDs of reals: */ /* if the REAL kind is not available then we assign */ /* it a value of the next larger one, but if the next */ /* higher one is not available we assigned it the next lowest */ FoundRealSize[0] = -4; FoundRealSize[1] = -8; FoundRealSize[2] = -16; #if defined H5_FORTRAN_HAS_REAL_4_KIND FoundRealSize[0] = 4; FoundRealSizeKind[0] = H5_FORTRAN_HAS_REAL_4_KIND; #endif #if defined H5_FORTRAN_HAS_REAL_8_KIND FoundRealSize[1] = 8; FoundRealSizeKind[1] = H5_FORTRAN_HAS_REAL_8_KIND; #endif #if defined H5_FORTRAN_HAS_REAL_16_KIND if(H5_C_HAS_REAL_NATIVE_16 != 0) { FoundRealSize[2] = 16; FoundRealSizeKind[2] = H5_FORTRAN_HAS_REAL_16_KIND; } #endif for(i=0;i<3;i++) { if( FoundRealSize[i] > 0) /* Found the real type */ { sprintf(chrA, "Fortran_REAL_%d", FoundRealSize[i]); sprintf(chrB, "real_%d_f", FoundRealSize[i]); writeToFiles("float",chrA, chrB, FoundRealSize[i], FoundRealSizeKind[i]); } else /* Did not find the real type */ { flag = 0; /* flag indicating if found the next highest */ for(j=i+1;j<3;j++) /* search for next highest */ { if( FoundRealSize[j] > 0) /* Found the next highest */ { sprintf(chrA, "Fortran_REAL_%d", (-1)*FoundRealSize[i]); sprintf(chrB, "real_%d_f", (-1)*FoundRealSize[i]); if(FoundRealSize[j]>4) { writeToFiles("float",chrA, chrB, FoundRealSize[j], FoundRealSizeKind[j]); flag = 1; } /* else { */ /* writeToFiles("float", chrA, chrB, FoundRealSize[j]); */ /* } */ flag = 1; break; } } if(flag == 0) /* No higher one found, so find next lowest */ { for(j=1;j>-1;j--) /* Search for next lowest */ { if( FoundRealSize[j] > 0) /* Found the next lowest */ { sprintf(chrA, "Fortran_REAL_%d", (-1)*FoundRealSize[i]); sprintf(chrB, "real_%d_f", (-1)*FoundRealSize[i]); if(FoundRealSize[j]>4) writeToFiles("float",chrA, chrB, FoundRealSize[j], FoundRealSizeKind[j]); /* else { */ /* writeToFiles("float", chrA, chrB, FoundRealSize[j]); */ /* } */ flag = 1; break; } } } if(flag == 0) /* No higher or lower one found, indicating an error */ return -1; } } /* hid_t */ #if defined H5_FORTRAN_HAS_INTEGER_8_KIND && H5_SIZEOF_HID_T >= 8 writeToFiles("int","HID_T", "hid_t_f", 8, H5_FORTRAN_HAS_INTEGER_8_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_4_KIND && H5_SIZEOF_HID_T >= 4 writeToFiles("int","HID_T", "hid_t_f", 4, H5_FORTRAN_HAS_INTEGER_4_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_2_KIND && H5_SIZEOF_HID_T >= 2 writeToFiles("int","HID_T", "hid_t_f", 2, H5_FORTRAN_HAS_INTEGER_2_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_1_KIND && H5_SIZEOF_HID_T >= 1 writeToFiles("int","HID_T", "hid_t_f", 1, H5_FORTRAN_HAS_INTEGER_1_KIND); #elif defined H5_FORTRAN_HAS_INTEGER_8_KIND && H5_SIZEOF_HID_T >= 4 writeToFiles("int","HID_T", "hid_t_f", 8, H5_FORTRAN_HAS_INTEGER_8_KIND); #else /* Error: couldn't find a size for hid_t */ return -1; #endif /* real_f */ #if defined H5_FORTRAN_HAS_REAL_NATIVE_16_KIND if(H5_C_HAS_REAL_NATIVE_16 != 0) { writeToFiles("float","Fortran_REAL", "real_f", 16, H5_FORTRAN_HAS_REAL_NATIVE_16_KIND); } #elif defined H5_FORTRAN_HAS_REAL_NATIVE_8_KIND writeToFiles("float", "Fortran_REAL", "real_f", 8, H5_FORTRAN_HAS_REAL_NATIVE_8_KIND); #elif defined H5_FORTRAN_HAS_REAL_NATIVE_4_KIND writeToFiles("float", "Fortran_REAL", "real_f", 4, H5_FORTRAN_HAS_REAL_NATIVE_4_KIND); #else /* Error: couldn't find a size for real_f */ return -1; #endif /* double_f */ #if defined H5_FORTRAN_HAS_DOUBLE_NATIVE_16_KIND if(H5_C_HAS_REAL_NATIVE_16 != 0) { /* Check if C has 16 byte floats */ writeToFiles("float", "Fortran_DOUBLE", "double_f", 16, H5_FORTRAN_HAS_DOUBLE_NATIVE_16_KIND); } else { #if defined H5_FORTRAN_HAS_REAL_NATIVE_8_KIND /* Fall back to 8 byte floats */ writeToFiles("float", "Fortran_DOUBLE", "double_f", 8, H5_FORTRAN_HAS_REAL_NATIVE_8_KIND); } #elif defined H5_FORTRAN_HAS_REAL_NATIVE_4_KIND /* Fall back to 4 byte floats */ writeToFiles("float", "Fortran_DOUBLE", "double_f", 4, H5_FORTRAN_HAS_REAL_NATIVE_4_KIND); } #else /* Error: couldn't find a size for double_f when fortran has 16 byte reals */ return -1; } #endif #elif defined H5_FORTRAN_HAS_DOUBLE_NATIVE_8_KIND writeToFiles("float", "Fortran_DOUBLE", "double_f", 8, H5_FORTRAN_HAS_DOUBLE_NATIVE_8_KIND); #else /* Error: couldn't find a size for real_f */ return -1; #endif /* Need the buffer size for the fortran derive type 'hdset_reg_ref_t_f03' * in order to be interoperable with C's structure, the C buffer size * H5R_DSET_REG_REF_BUF_SIZE is (sizeof(haddr_t)+4) */ fprintf(fort_header, " INTEGER, PARAMETER :: H5R_DSET_REG_REF_BUF_SIZE_F = %u\n", H5_SIZEOF_HADDR_T + 4 ); /* Close files */ endCfile(); endFfile(); fclose(c_header); fclose(fort_header); return 0; }