/* Extra femtoLisp builtin functions */ #include #include #include #include #include #include #include #include #include #include #include #include "scheme.h" size_t llength(value_t v) { size_t n = 0; while (iscons(v)) { n++; v = cdr_(v); } return n; } static value_t fl_nconc(value_t *args, uint32_t nargs) { value_t lst, first; value_t *pcdr; struct cons *c; uint32_t i; if (nargs == 0) return FL_NIL; first = FL_NIL; pcdr = &first; i = 0; while (1) { lst = args[i++]; if (i >= nargs) break; if (iscons(lst)) { *pcdr = lst; c = (struct cons *)ptr(lst); while (iscons(c->cdr)) c = (struct cons *)ptr(c->cdr); pcdr = &c->cdr; } else if (lst != FL_NIL) { type_error("nconc", "cons", lst); } } *pcdr = lst; return first; } static value_t fl_assq(value_t *args, uint32_t nargs) { value_t item; value_t v; value_t bind; argcount("assq", nargs, 2); item = args[0]; v = args[1]; while (iscons(v)) { bind = car_(v); if (iscons(bind) && car_(bind) == item) return bind; v = cdr_(v); } return FL_F; } static value_t fl_memq(value_t *args, uint32_t nargs) { argcount("memq", nargs, 2); while (iscons(args[1])) { struct cons *c = (struct cons *)ptr(args[1]); if (c->car == args[0]) return args[1]; args[1] = c->cdr; } return FL_F; } static value_t fl_length(value_t *args, uint32_t nargs) { value_t a; struct cvalue *cv; argcount("length", nargs, 1); a = args[0]; if (isvector(a)) { return fixnum(vector_size(a)); } else if (iscprim(a)) { cv = (struct cvalue *)ptr(a); if (cp_class(cv) == bytetype) return fixnum(1); else if (cp_class(cv) == wchartype) return fixnum( u8_charlen(*(uint32_t *)cp_data((struct cprim *)cv))); } else if (iscvalue(a)) { cv = (struct cvalue *)ptr(a); if (cv_class(cv)->eltype != NULL) return size_wrap(cvalue_arraylen(a)); } else if (a == FL_NIL) { return fixnum(0); } else if (iscons(a)) { return fixnum(llength(a)); } type_error("length", "sequence", a); return FL_NIL; // TODO } static value_t fl_f_raise(value_t *args, uint32_t nargs) { argcount("raise", nargs, 1); fl_raise(args[0]); return FL_NIL; // TODO } static value_t fl_exit(value_t *args, uint32_t nargs) { if (nargs > 0) exit(tofixnum(args[0], "exit")); exit(0); return FL_NIL; } static value_t fl_symbol(value_t *args, uint32_t nargs) { argcount("symbol", nargs, 1); if (!fl_isstring(args[0])) type_error("symbol", "string", args[0]); return symbol(cvalue_data(args[0])); } static value_t fl_keywordp(value_t *args, uint32_t nargs) { argcount("keyword?", nargs, 1); return (issymbol(args[0]) && iskeyword((struct symbol *)ptr(args[0]))) ? FL_T : FL_F; } static value_t fl_top_level_value(value_t *args, uint32_t nargs) { struct symbol *sym; argcount("top-level-value", nargs, 1); sym = tosymbol(args[0], "top-level-value"); if (sym->binding == UNBOUND) fl_raise(fl_list2(UnboundError, args[0])); return sym->binding; } static value_t fl_set_top_level_value(value_t *args, uint32_t nargs) { struct symbol *sym; argcount("set-top-level-value!", nargs, 2); sym = tosymbol(args[0], "set-top-level-value!"); if (!isconstant(sym)) sym->binding = args[1]; return args[1]; } static void global_env_list(struct symbol *root, value_t *pv) { while (root != NULL) { if (root->name[0] != ':' && (root->binding != UNBOUND)) { *pv = fl_cons(tagptr(root, TAG_SYM), *pv); } global_env_list(root->left, pv); root = root->right; } } extern struct symbol *symtab; value_t fl_global_env(value_t *args, uint32_t nargs) { value_t lst; (void)args; argcount("environment", nargs, 0); lst = FL_NIL; fl_gc_handle(&lst); global_env_list(symtab, &lst); fl_free_gc_handles(1); return lst; } extern value_t QUOTE; static value_t fl_constantp(value_t *args, uint32_t nargs) { argcount("constant?", nargs, 1); if (issymbol(args[0])) return (isconstant((struct symbol *)ptr(args[0])) ? FL_T : FL_F); if (iscons(args[0])) { if (car_(args[0]) == QUOTE) return FL_T; return FL_F; } return FL_T; } static value_t fl_integer_valuedp(value_t *args, uint32_t nargs) { value_t v; double d; void *data; argcount("integer-valued?", nargs, 1); v = args[0]; if (isfixnum(v)) { return FL_T; } else if (iscprim(v)) { numerictype_t nt = cp_numtype((struct cprim *)ptr(v)); if (nt < T_FLOAT) return FL_T; data = cp_data((struct cprim *)ptr(v)); if (nt == T_FLOAT) { float f = *(float *)data; if (f < 0) f = -f; if (f <= FLT_MAXINT && (float)(int32_t)f == f) return FL_T; } else { assert(nt == T_DOUBLE); d = *(double *)data; if (d < 0) d = -d; if (d <= DBL_MAXINT && (double)(int64_t)d == d) return FL_T; } } return FL_F; } static value_t fl_integerp(value_t *args, uint32_t nargs) { value_t v; argcount("integer?", nargs, 1); v = args[0]; return (isfixnum(v) || (iscprim(v) && cp_numtype((struct cprim *)ptr(v)) < T_FLOAT)) ? FL_T : FL_F; } static value_t fl_fixnum(value_t *args, uint32_t nargs) { argcount("fixnum", nargs, 1); if (isfixnum(args[0])) { return args[0]; } else if (iscprim(args[0])) { struct cprim *cp = (struct cprim *)ptr(args[0]); return fixnum(conv_to_long(cp_data(cp), cp_numtype(cp))); } type_error("fixnum", "number", args[0]); return FL_NIL; // TODO } static value_t fl_truncate(value_t *args, uint32_t nargs) { argcount("truncate", nargs, 1); if (isfixnum(args[0])) return args[0]; if (iscprim(args[0])) { struct cprim *cp = (struct cprim *)ptr(args[0]); void *data = cp_data(cp); numerictype_t nt = cp_numtype(cp); double d; if (nt == T_FLOAT) d = (double)*(float *)data; else if (nt == T_DOUBLE) d = *(double *)data; else return args[0]; if (d > 0) { if (d > (double)U64_MAX) return args[0]; return return_from_uint64((uint64_t)d); } if (d > (double)S64_MAX || d < (double)S64_MIN) return args[0]; return return_from_int64((int64_t)d); } type_error("truncate", "number", args[0]); return FL_NIL; // TODO } static value_t fl_vector_alloc(value_t *args, uint32_t nargs) { fixnum_t i; value_t f, v; int k; if (nargs == 0) lerror(ArgError, "vector.alloc: too few arguments"); i = (fixnum_t)toulong(args[0], "vector.alloc"); if (i < 0) lerror(ArgError, "vector.alloc: invalid size"); v = alloc_vector((unsigned)i, 0); if (nargs == 2) f = args[1]; else f = FL_UNSPECIFIED; for (k = 0; k < i; k++) vector_elt(v, k) = f; return v; } static double todouble(value_t a, char *fname) { if (isfixnum(a)) return (double)numval(a); if (iscprim(a)) { struct cprim *cp = (struct cprim *)ptr(a); numerictype_t nt = cp_numtype(cp); return conv_to_double(cp_data(cp), nt); } type_error(fname, "number", a); return FL_NIL; // TODO } static value_t fl_path_cwd(value_t *args, uint32_t nargs) { char *ptr; if (nargs > 1) argcount("path.cwd", nargs, 1); if (nargs == 0) { char buf[1024]; get_cwd(buf, sizeof(buf)); return string_from_cstr(buf); } ptr = tostring(args[0], "path.cwd"); if (set_cwd(ptr)) lerrorf(IOError, "path.cwd: could not cd to %s", ptr); return FL_T; } static value_t fl_path_exists(value_t *args, uint32_t nargs) { char *str; argcount("path.exists?", nargs, 1); str = tostring(args[0], "path.exists?"); return os_path_exists(str) ? FL_T : FL_F; } static value_t fl_os_getenv(value_t *args, uint32_t nargs) { char *name; char *val; argcount("os.getenv", nargs, 1); name = tostring(args[0], "os.getenv"); val = getenv(name); if (val == NULL) return FL_F; if (*val == 0) return symbol_value(emptystringsym); return cvalue_static_cstring(val); } static value_t fl_os_setenv(value_t *args, uint32_t nargs) { const char *name; const char *value; argcount("os.setenv", nargs, 2); name = tostring(args[0], "os.setenv"); if (args[1] == FL_F) { value = 0; } else { value = tostring(args[1], "os.setenv"); } os_setenv(name, value); return FL_T; } static value_t fl_rand(value_t *args, uint32_t nargs) { fixnum_t r; (void)args; (void)nargs; #ifdef BITS64 r = ((((uint64_t)random()) << 32) | random()) & 0x1fffffffffffffffLL; #else r = random() & 0x1fffffff; #endif return fixnum(r); } static value_t fl_rand32(value_t *args, uint32_t nargs) { uint32_t r; (void)args; (void)nargs; r = random(); #ifdef BITS64 return fixnum(r); #else return mk_uint32(r); #endif } static value_t fl_rand64(value_t *args, uint32_t nargs) { uint64_t r; (void)args; (void)nargs; r = (((uint64_t)random()) << 32) | random(); return mk_uint64(r); } static value_t fl_randd(value_t *args, uint32_t nargs) { (void)args; (void)nargs; return mk_double(rand_double()); } static value_t fl_randf(value_t *args, uint32_t nargs) { (void)args; (void)nargs; return mk_float(rand_float()); } #define MATH_FUNC_1ARG(name) \ static value_t fl_##name(value_t *args, uint32_t nargs) \ { \ argcount(#name, nargs, 1); \ if (iscprim(args[0])) { \ struct cprim *cp = (struct cprim *)ptr(args[0]); \ numerictype_t nt = cp_numtype(cp); \ if (nt == T_FLOAT) { \ float f = *(float *)cp_data(cp); \ return mk_float(name((double)f)); \ } \ } \ return mk_double(name(todouble(args[0], #name))); \ } MATH_FUNC_1ARG(sqrt) MATH_FUNC_1ARG(exp) MATH_FUNC_1ARG(log) MATH_FUNC_1ARG(sin) MATH_FUNC_1ARG(cos) MATH_FUNC_1ARG(tan) MATH_FUNC_1ARG(asin) MATH_FUNC_1ARG(acos) MATH_FUNC_1ARG(atan) extern void stringfuncs_init(void); extern void table_init(void); extern void iostream_init(void); extern void print_init(void); static struct builtinspec builtin_info[] = { { "environment", fl_global_env }, { "constant?", fl_constantp }, { "top-level-value", fl_top_level_value }, { "set-top-level-value!", fl_set_top_level_value }, { "raise", fl_f_raise }, { "exit", fl_exit }, { "symbol", fl_symbol }, { "keyword?", fl_keywordp }, { "fixnum", fl_fixnum }, { "truncate", fl_truncate }, { "integer?", fl_integerp }, { "integer-valued?", fl_integer_valuedp }, { "nconc", fl_nconc }, { "append!", fl_nconc }, { "assq", fl_assq }, { "memq", fl_memq }, { "length", fl_length }, { "vector.alloc", fl_vector_alloc }, { "rand", fl_rand }, { "rand.uint32", fl_rand32 }, { "rand.uint64", fl_rand64 }, { "rand.double", fl_randd }, { "rand.float", fl_randf }, { "sqrt", fl_sqrt }, { "exp", fl_exp }, { "log", fl_log }, { "sin", fl_sin }, { "cos", fl_cos }, { "tan", fl_tan }, { "asin", fl_asin }, { "acos", fl_acos }, { "atan", fl_atan }, { "path.cwd", fl_path_cwd }, { "path.exists?", fl_path_exists }, { "os.getenv", fl_os_getenv }, { "os.setenv", fl_os_setenv }, { "import-procedure", builtin_import }, { NULL, NULL } }; void builtins_init(void) { assign_global_builtins(builtin_info); stringfuncs_init(); table_init(); iostream_init(); print_init(); os_init(); }