/* This was modified to try out compiling with Guile. */ /* scmhob.h is a header file for scheme source compiled with hobbit4d Copyright (C) 1992, 1993, 1994, 1995 Tanel Tammet This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 1, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include #include #include "libguile/_scm.h" #define abrt scm_abort #define absval scm_abs #define angle scm_angle #define append scm_append #define assoc scm_assoc #define assq scm_assq #define assv scm_assv #define big2dbl scm_big2dbl #define close_port scm_close_port #define cons scm_cons #define cur_input_port scm_current_input_port #define cur_output_port scm_current_output_port #define difference scm_difference #define display scm_display #define divide scm_divide #define eof_objectp scm_eof_object_p #define eqp scm_eq_p #define equal scm_equal_p #define eqv scm_eqv_p #define evenp scm_even_p #define exactp scm_exact_p #define greaterp scm_gr_p #define greqp scm_geq_p #define imag_part scm_imag_part #define in2ex scm_inexact_to_exact #define inexactp scm_inexact_p #define input_portp scm_input_port_p #define intp scm_int_p #define length scm_length #define leqp scm_leq_p #define lessp scm_less_p #define lgcd scm_gcd #define list_ref scm_list_ref #define list_tail scm_list_tail #define listp scm_list_p #define llcm scm_lcm #define lmax scm_max #define lmin scm_min #define lquotient scm_quotient #define lread(X) scm_read((X), SCM_UNDEFINED) #define lremainder scm_remainder #define lwrite scm_write #define magnitude scm_magnitude #define makcclo scm_makcclo #define makdbl scm_makdbl #define make_string scm_make_string #define make_vector scm_make_vector #define makpolar scm_make_polar #define makrect scm_make_rectangular #define member scm_member #define memq scm_memq #define memv scm_memv #define modulo scm_modulo #define my_time scm_get_internal_run_time #define negativep scm_negative_p #define newline scm_newline #define number2string scm_number_to_string #define oddp scm_odd_p #define open_file scm_open_file #define output_portp scm_output_port_p #define peek_char scm_peek_char #define positivep scm_positive_p #define procedurep scm_procedure_p #define product scm_product #define quit scm_quit #define read_char scm_read_char #define real_part scm_real_part #define realp scm_real_p #define reverse scm_reverse #define set_inp scm_set_current_input_port #define set_outp scm_set_current_output_port #define st_append scm_string_append #define st_equal scm_string_equal_p #define st_leqp scm_string_leq_p #define st_lessp scm_string_less_p #define st_set scm_string_set_x #define stci_equal scm_string_ci_equal_p #define stci_leqp scm_string_ci_leq_p #define stci_lessp scm_string_ci_less_p #define string scm_string #define string2list scm_string_to_list #define string2number scm_string_to_number #define string2symbol scm_string_to_symbol #define string_copy scm_string_copy #define string_fill scm_string_fill_x #define substring scm_substring #define sum scm_sum #define symbol2string scm_symbol_to_string #define vector scm_vector #define vector2list scm_vector_to_list #define vector_ref scm_vector_ref #define vector_set scm_vector_set_x #define write_char scm_write_char #define zerop scm_zero_p #define STBL_VECTOR_SET(v,k,o) (v[((long)SCM_INUM(k))] = o) #define STBL_VECTOR_REF(v,k) (v[((long)SCM_INUM(k))]) #define CHAR_LESSP(x,y) ((SCM_ICHR(x) < SCM_ICHR(y)) ? SCM_BOOL_T : SCM_BOOL_F) #define CHAR_LEQP(x,y) ((SCM_ICHR(x) <= SCM_ICHR(y)) ? SCM_BOOL_T : SCM_BOOL_F) #define CHCI_EQ(x,y) ((upcase[SCM_ICHR(x)]==upcase[SCM_ICHR(y)]) ? SCM_BOOL_T : SCM_BOOL_F) #define CHCI_LESSP(x,y) ((upcase[SCM_ICHR(x)] < upcase[SCM_ICHR(y)]) ? SCM_BOOL_T : SCM_BOOL_F) #define CHCI_LEQP(x,y) ((upcase[SCM_ICHR(x)] <= upcase[SCM_ICHR(y)]) ? SCM_BOOL_T : SCM_BOOL_F) #define CHAR_ALPHAP(chr) ((isascii(SCM_ICHR(chr)) && isalpha(SCM_ICHR(chr))) ? SCM_BOOL_T : SCM_BOOL_F) #define CHAR_SCM_NUMP(chr) ((isascii(SCM_ICHR(chr)) && isdigit(SCM_ICHR(chr))) ? SCM_BOOL_T : SCM_BOOL_F) #define CHAR_WHITEP(chr) ((isascii(SCM_ICHR(chr)) && isspace(SCM_ICHR(chr))) ? SCM_BOOL_T : SCM_BOOL_F) #define CHAR_UPPERP(chr) ((isascii(SCM_ICHR(chr)) && isupper(SCM_ICHR(chr))) ? SCM_BOOL_T : SCM_BOOL_F) #define CHAR_LOWERP(chr) ((isascii(SCM_ICHR(chr)) && islower(SCM_ICHR(chr))) ? SCM_BOOL_T : SCM_BOOL_F) #define CHAR2INT(chr) SCM_MAKINUM(SCM_ICHR(chr)) #define INT2CHAR(n) SCM_MAKICHR(SCM_INUM(n)) #define CHAR_UPCASE(chr) SCM_MAKICHR(upcase[SCM_ICHR(chr)]) #define CHAR_DOWNCASE(chr) SCM_MAKICHR(downcase[SCM_ICHR(chr)]) #define ST_SCM_LENGTH(str) SCM_MAKINUM(SCM_LENGTH(str)) #define ST_REF(str,k) SCM_MAKICHR(SCM_CHARS(str)[SCM_INUM(k)]) #define VECTOR_SCM_LENGTH(v) SCM_MAKINUM(SCM_LENGTH(v)) #ifdef SCM_FLOATS #include #endif #ifdef SCM_BIGDIG #define PRE_TRANSC_FUN(x) (SCM_INUMP(x) ? (double) SCM_INUM(x) : (SCM_REALP(x) ? (double) SCM_REALPART(x) : (double) big2dbl(x))) #else #define PRE_TRANSC_FUN(x) (SCM_INUMP(x) ? (double) SCM_INUM(x) : (double) SCM_REALPART(x)) #endif #define SIN_FUN(x) (makdbl( sin( PRE_TRANSC_FUN(x)), 0.0)) #define COS_FUN(x) (makdbl( cos( PRE_TRANSC_FUN(x)), 0.0)) #define TAN_FUN(x) (makdbl( tan( PRE_TRANSC_FUN(x)), 0.0)) #define ASIN_FUN(x) (makdbl( asin( PRE_TRANSC_FUN(x)), 0.0)) #define ACOS_FUN(x) (makdbl( acos( PRE_TRANSC_FUN(x)), 0.0)) #define ATAN_FUN(x) (makdbl( atan( PRE_TRANSC_FUN(x)), 0.0)) #define SINH_FUN(x) (makdbl( sinh( PRE_TRANSC_FUN(x)), 0.0)) #define COSH_FUN(x) (makdbl( cosh( PRE_TRANSC_FUN(x)), 0.0)) #define TANH_FUN(x) (makdbl( tanh( PRE_TRANSC_FUN(x)), 0.0)) #define ASINH_FUN(x) (makdbl( asinh( PRE_TRANSC_FUN(x)), 0.0)) #define ACOSH_FUN(x) (makdbl( acosh( PRE_TRANSC_FUN(x)), 0.0)) #define ATANH_FUN(x) (makdbl( atanh( PRE_TRANSC_FUN(x)), 0.0)) #define SQRT_FUN(x) (makdbl( sqrt( PRE_TRANSC_FUN(x)), 0.0)) #define EXPT_FUN(x,y) (makdbl( pow(( PRE_TRANSC_FUN(x)), ( PRE_TRANSC_FUN(y))), 0.0)) #define EXP_FUN(x) (makdbl( exp( PRE_TRANSC_FUN(x)), 0.0)) #define LOG_FUN(x) (makdbl( log( PRE_TRANSC_FUN(x)), 0.0)) #define ABS_FUN(x) (makdbl( fabs( PRE_TRANSC_FUN(x)), 0.0)) #define EX2IN_FUN(x) (makdbl( PRE_TRANSC_FUN(x), 0.0)) #define SCM_FLOOR_FUN(x) (makdbl( floor( PRE_TRANSC_FUN(x)), 0.0)) #define CEILING_FUN(x) (makdbl( ceil( PRE_TRANSC_FUN(x)), 0.0)) #define TRUNCATE_FUN(x) (makdbl( ltrunc( PRE_TRANSC_FUN(x)), 0.0)) #define ROUND_FUN(x) (makdbl(round( PRE_TRANSC_FUN(x)), 0.0)) /* the following defs come from the #ifdef HOBBIT part of scm.h */ #define SBOOL(x) ((x) ? SCM_BOOL_T : SCM_BOOL_F) #define BOOLEAN_P(x) ((x)==SCM_BOOL_T || (x)==SCM_BOOL_F) #define CHAR_P SCM_ICHRP #define SYMBOL_P(x) (SCM_ISYMP(x) || (!(SCM_IMP(x)) && SCM_SYMBOLP(x))) #define VECTOR_P(x) (!(SCM_IMP(x)) && SCM_VECTORP(x)) #define PAIR_P(x) (!(SCM_IMP(x)) && SCM_CONSP(x)) #define NUMBER_P SCM_INUMP #define INTEGER_P SCM_INUMP #define STRING_P(x) (!(SCM_IMP(x)) && SCM_STRINGP(x)) #define NULL_P SCM_NULLP #define ZERO_P(x) ((x)==SCM_INUM0) #define POSITIVE_P(x) ((x) > SCM_INUM0) #define NEGATIVE_P(x) ((x) < SCM_INUM0) #define NOT(x) ((x)==SCM_BOOL_F ? SCM_BOOL_T : SCM_BOOL_F) #define SET_CAR(x,y) (CAR(x) = (SCM)(y)) #define SET_CDR(x,y) (CDR(x) = (SCM)(y)) #define VECTOR_SET(v,k,o) (SCM_VELTS(v)[((long)SCM_INUM(k))] = o) #define VECTOR_REF(v,k) (SCM_VELTS(v)[((long)SCM_INUM(k))]) #define CL_VECTOR_SET(v,k,o) (SCM_VELTS(v)[k] = o) #define CL_VECTOR_REF(v,k) (SCM_VELTS(v)[k]) #define GLOBAL(x) (*(x)) #define append2(lst1,lst2) (append(scm_cons2(lst1,lst2,SCM_EOL))) #define procedure_pred_(x) (SCM_BOOL_T==procedurep(x))