/* * Copyright (c) 2002 by The XFree86 Project, Inc. * * 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 XFREE86 PROJECT 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. * * Except as contained in this notice, the name of the XFree86 Project shall * not be used in advertising or otherwise to promote the sale, use or other * dealings in this Software without prior written authorization from the * XFree86 Project. * * Author: Paulo César Pereira de Andrade */ /* $XFree86: xc/programs/xedit/lisp/write.c,v 1.31tsi Exp $ */ #include "lisp/write.h" #include "lisp/hash.h" #include #include #define FLOAT_PREC 17 #define UPCASE 0 #define DOWNCASE 1 #define CAPITALIZE 2 #define INCDEPTH() \ if (++info->depth > MAX_STACK_DEPTH / 2) \ LispDestroy("stack overflow") #define DECDEPTH() --info->depth /* * Types */ typedef struct _circle_info { long circle_nth; /* nth circular list */ LispObj *object; /* the circular object */ } circle_info; typedef struct _write_info { long depth; long level; /* current level */ long length; /* current length */ long print_level; /* *print-level* when started printing */ long print_length; /* *print-length* when started printing */ int print_escape; int print_case; long circle_count; /* used while building circle info */ LispObj **objects; long num_objects; /* the circular lists */ circle_info *circles; long num_circles; } write_info; /* * Prototypes */ static void check_stream(LispObj*, LispFile**, LispString**, int); static void parse_double(char*, int*, double, int); static int float_string_inc(char*, int); static void format_integer(char*, long, int); static int LispWriteCPointer(LispObj*, void*); static int LispWriteCString(LispObj*, char*, long, write_info*); static int LispDoFormatExponentialFloat(LispObj*, LispObj*, int, int, int*, int, int, int, int, int, int); static int LispWriteInteger(LispObj*, LispObj*); static int LispWriteCharacter(LispObj*, LispObj*, write_info*); static int LispWriteString(LispObj*, LispObj*, write_info*); static int LispWriteFloat(LispObj*, LispObj*); static int LispWriteAtom(LispObj*, LispObj*, write_info*); static int LispDoWriteAtom(LispObj*, char*, int, int); static int LispWriteList(LispObj*, LispObj*, write_info*, int); static int LispWriteArray(LispObj*, LispObj*, write_info*); static int LispWriteStruct(LispObj*, LispObj*, write_info*); static int LispDoWriteObject(LispObj*, LispObj*, write_info*, int); static void LispBuildCircle(LispObj*, write_info*); static void LispDoBuildCircle(LispObj*, write_info*); static long LispCheckCircle(LispObj*, write_info*); static int LispPrintCircle(LispObj*, LispObj*, long, int*, write_info*); static int LispWriteAlist(LispObj*, LispArgList*, write_info*); /* * Initialization */ LispObj *Oprint_level, *Oprint_length, *Oprint_circle, *Oprint_escape, *Oprint_case; LispObj *Kupcase, *Kdowncase, *Kcapitalize; /* * Implementation */ void LispWriteInit(void) { Oprint_level = STATIC_ATOM("*PRINT-LEVEL*"); LispProclaimSpecial(Oprint_level, NIL, NIL); LispExportSymbol(Oprint_level); Oprint_length = STATIC_ATOM("*PRINT-LENGTH*"); LispProclaimSpecial(Oprint_length, NIL, NIL); LispExportSymbol(Oprint_length); Oprint_circle = STATIC_ATOM("*PRINT-CIRCLE*"); LispProclaimSpecial(Oprint_circle, T, NIL); LispExportSymbol(Oprint_circle); Oprint_escape = STATIC_ATOM("*PRINT-ESCAPE*"); LispProclaimSpecial(Oprint_escape, T, NIL); LispExportSymbol(Oprint_escape); Kupcase = KEYWORD("UPCASE"); Kdowncase = KEYWORD("DOWNCASE"); Kcapitalize = KEYWORD("CAPITALIZE"); Oprint_case = STATIC_ATOM("*PRINT-CASE*"); LispProclaimSpecial(Oprint_case, Kupcase, NIL); LispExportSymbol(Oprint_case); } LispObj * Lisp_FreshLine(LispBuiltin *builtin) /* fresh-line &optional output-stream */ { LispObj *output_stream; output_stream = ARGUMENT(0); if (output_stream == UNSPEC) output_stream = NIL; else if (output_stream != NIL) { CHECK_STREAM(output_stream); } if (LispGetColumn(output_stream)) { LispWriteChar(output_stream, '\n'); if (output_stream == NIL || (output_stream->data.stream.type == LispStreamStandard && output_stream->data.stream.source.file == Stdout)) LispFflush(Stdout); return (T); } return (NIL); } LispObj * Lisp_Prin1(LispBuiltin *builtin) /* prin1 object &optional output-stream */ { LispObj *object, *output_stream; output_stream = ARGUMENT(1); object = ARGUMENT(0); if (output_stream == UNSPEC) output_stream = NIL; LispPrint(object, output_stream, 0); return (object); } LispObj * Lisp_Princ(LispBuiltin *builtin) /* princ object &optional output-stream */ { int head; LispObj *object, *output_stream; output_stream = ARGUMENT(1); object = ARGUMENT(0); if (output_stream == UNSPEC) output_stream = NIL; head = lisp__data.env.length; LispAddVar(Oprint_escape, NIL); ++lisp__data.env.head; LispPrint(object, output_stream, 0); lisp__data.env.head = lisp__data.env.length = head; return (object); } LispObj * Lisp_Print(LispBuiltin *builtin) /* print object &optional output-stream */ { LispObj *object, *output_stream; output_stream = ARGUMENT(1); object = ARGUMENT(0); if (output_stream == UNSPEC) output_stream = NIL; LispWriteChar(output_stream, '\n'); LispPrint(object, output_stream, 0); LispWriteChar(output_stream, ' '); return (object); } LispObj * Lisp_Terpri(LispBuiltin *builtin) /* terpri &optional output-stream */ { LispObj *output_stream; output_stream = ARGUMENT(0); if (output_stream == UNSPEC) output_stream = NIL; else if (output_stream != NIL) { CHECK_STREAM(output_stream); } LispWriteChar(output_stream, '\n'); if (output_stream == NIL || (output_stream->data.stream.type == LispStreamStandard && output_stream->data.stream.source.file == Stdout)) LispFflush(Stdout); return (NIL); } LispObj * Lisp_Write(LispBuiltin *builtin) /* write object &key case circle escape length level lines pretty readably right-margin stream */ { int head = lisp__data.env.length; LispObj *object, *ocase, *circle, *escape, *length, *level, *stream; stream = ARGUMENT(10); level = ARGUMENT(5); length = ARGUMENT(4); escape = ARGUMENT(3); circle = ARGUMENT(2); ocase = ARGUMENT(1); object = ARGUMENT(0); if (stream == UNSPEC) stream = NIL; else if (stream != NIL) { CHECK_STREAM(stream); } /* prepare the printer environment */ if (circle != UNSPEC) LispAddVar(Oprint_circle, circle); if (length != UNSPEC) LispAddVar(Oprint_length, length); if (level != UNSPEC) LispAddVar(Oprint_level, level); if (ocase != UNSPEC) LispAddVar(Oprint_case, ocase); if (escape != UNSPEC) LispAddVar(Oprint_escape, escape); lisp__data.env.head = lisp__data.env.length; (void)LispWriteObject(stream, object); lisp__data.env.head = lisp__data.env.length = head; return (object); } LispObj * Lisp_WriteChar(LispBuiltin *builtin) /* write-char character &optional output-stream */ { int ch; LispObj *character, *output_stream; output_stream = ARGUMENT(1); character = ARGUMENT(0); if (output_stream == UNSPEC) output_stream = NIL; CHECK_SCHAR(character); ch = SCHAR_VALUE(character); LispWriteChar(output_stream, ch); return (character); } LispObj * Lisp_WriteLine(LispBuiltin *builtin) /* write-line string &optional output-stream &key start end */ { return (LispWriteString_(builtin, 1)); } LispObj * Lisp_WriteString(LispBuiltin *builtin) /* write-string string &optional output-stream &key start end */ { return (LispWriteString_(builtin, 0)); } int LispWriteObject(LispObj *stream, LispObj *object) { write_info info; int bytes; LispObj *level, *length, *circle, *oescape, *ocase; /* current state */ info.depth = info.level = info.length = 0; /* maximum level to descend */ level = LispGetVar(Oprint_level); if (level && INDEXP(level)) info.print_level = FIXNUM_VALUE(level); else info.print_level = -1; /* maximum list length */ length = LispGetVar(Oprint_length); if (length && INDEXP(length)) info.print_length = FIXNUM_VALUE(length); else info.print_length = -1; /* detect circular/shared objects? */ circle = LispGetVar(Oprint_circle); info.circle_count = 0; info.objects = NULL; info.num_objects = 0; info.circles = NULL; info.num_circles = 0; if (circle && circle != NIL) { LispBuildCircle(object, &info); /* free this data now */ if (info.num_objects) { LispFree(info.objects); info.num_objects = 0; } } /* escape characters and strings? */ oescape = LispGetVar(Oprint_escape); if (oescape != NULL) info.print_escape = oescape == NIL; else info.print_escape = -1; /* don't use the default case printing? */ ocase = LispGetVar(Oprint_case); if (ocase == Kdowncase) info.print_case = DOWNCASE; else if (ocase == Kcapitalize) info.print_case = CAPITALIZE; else info.print_case = UPCASE; bytes = LispDoWriteObject(stream, object, &info, 1); if (circle && circle != NIL && info.num_circles) LispFree(info.circles); return (bytes); } static void LispBuildCircle(LispObj *object, write_info *info) { LispObj *list; switch (OBJECT_TYPE(object)) { case LispCons_t: LispDoBuildCircle(object, info); break; case LispArray_t: /* Currently arrays are implemented as lists, but only * the elements could/should be circular */ if (LispCheckCircle(object, info) >= 0) return; LispDoBuildCircle(object, info); for (list = object->data.array.list; CONSP(list); list = CDR(list)) LispBuildCircle(CAR(list), info); break; case LispStruct_t: /* Like arrays, structs are currently implemented as lists, * but only the elements could/should be circular */ if (LispCheckCircle(object, info) >= 0) return; LispDoBuildCircle(object, info); for (list = object->data.struc.fields; CONSP(list); list = CDR(list)) LispBuildCircle(CAR(list), info); break; case LispQuote_t: case LispBackquote_t: case LispFunctionQuote_t: LispDoBuildCircle(object, info); LispBuildCircle(object->data.quote, info); break; case LispComma_t: LispDoBuildCircle(object, info); LispBuildCircle(object->data.comma.eval, info); break; case LispLambda_t: /* Circularity in a function body should fail elsewhere... */ if (LispCheckCircle(object, info) >= 0) return; LispDoBuildCircle(object, info); LispBuildCircle(object->data.lambda.code, info); break; default: break; } } static void LispDoBuildCircle(LispObj *object, write_info *info) { long i; if (LispCheckCircle(object, info) >= 0) return; for (i = 0; i < info->num_objects; i++) if (info->objects[i] == object) { /* circularity found */ info->circles = LispRealloc(info->circles, sizeof(circle_info) * (info->num_circles + 1)); info->circles[info->num_circles].circle_nth = 0; info->circles[info->num_circles].object = object; ++info->num_circles; return; } /* object pointer not yet recorded */ if ((i % 16) == 0) info->objects = LispRealloc(info->objects, sizeof(LispObj*) * (info->num_objects + 16)); info->objects[info->num_objects++] = object; if (CONSP(object)) { if (CONSP(CAR(object))) LispDoBuildCircle(CAR(object), info); else LispBuildCircle(CAR(object), info); if (CONSP(CDR(object))) LispDoBuildCircle(CDR(object), info); else LispBuildCircle(CDR(object), info); } } static long LispCheckCircle(LispObj *object, write_info *info) { long i; for (i = 0; i < info->num_circles; i++) if (info->circles[i].object == object) return (i); return (-1); } static int LispPrintCircle(LispObj *stream, LispObj *object, long circle, int *length, write_info *info) { char stk[32]; if (!info->circles[circle].circle_nth) { sprintf(stk, "#%ld=", ++info->circle_count); *length += LispWriteStr(stream, stk, strlen(stk)); info->circles[circle].circle_nth = info->circle_count; return (1); } sprintf(stk, "#%ld#", info->circles[circle].circle_nth); *length += LispWriteStr(stream, stk, strlen(stk)); return (0); } static int LispWriteAlist(LispObj *stream, LispArgList *alist, write_info *info) { char *name; int i, length = 0, need_space = 0; #define WRITE_ATOM(object) \ name = ATOMID(object); \ length += LispDoWriteAtom(stream, name, strlen(name), \ info->print_case) #define WRITE_STRING(string) \ length += LispDoWriteAtom(stream, string, strlen(string), \ info->print_case) #define WRITE_OBJECT(object) \ length += LispDoWriteObject(stream, object, info, 1) #define WRITE_OPAREN() \ length += LispWriteChar(stream, '(') #define WRITE_SPACE() \ length += LispWriteChar(stream, ' ') #define WRITE_CPAREN() \ length += LispWriteChar(stream, ')') WRITE_OPAREN(); for (i = 0; i < alist->normals.num_symbols; i++) { WRITE_ATOM(alist->normals.symbols[i]); if (i + 1 < alist->normals.num_symbols) WRITE_SPACE(); else need_space = 1; } if (alist->optionals.num_symbols) { if (need_space) WRITE_SPACE(); WRITE_STRING(Soptional); WRITE_SPACE(); for (i = 0; i < alist->optionals.num_symbols; i++) { WRITE_OPAREN(); WRITE_ATOM(alist->optionals.symbols[i]); WRITE_SPACE(); WRITE_OBJECT(alist->optionals.defaults[i]); if (alist->optionals.sforms[i]) { WRITE_SPACE(); WRITE_ATOM(alist->optionals.sforms[i]); } WRITE_CPAREN(); if (i + 1 < alist->optionals.num_symbols) WRITE_SPACE(); } need_space = 1; } if (alist->keys.num_symbols) { if (need_space) WRITE_SPACE(); length += LispDoWriteAtom(stream, Skey, 4, info->print_case); WRITE_SPACE(); for (i = 0; i < alist->keys.num_symbols; i++) { WRITE_OPAREN(); if (alist->keys.keys[i]) { WRITE_OPAREN(); WRITE_ATOM(alist->keys.keys[i]); WRITE_SPACE(); } WRITE_ATOM(alist->keys.symbols[i]); if (alist->keys.keys[i]) WRITE_CPAREN(); WRITE_SPACE(); WRITE_OBJECT(alist->keys.defaults[i]); if (alist->keys.sforms[i]) { WRITE_SPACE(); WRITE_ATOM(alist->keys.sforms[i]); } WRITE_CPAREN(); if (i + 1 < alist->keys.num_symbols) WRITE_SPACE(); } need_space = 1; } if (alist->rest) { if (need_space) WRITE_SPACE(); WRITE_STRING(Srest); WRITE_SPACE(); WRITE_ATOM(alist->rest); need_space = 1; } if (alist->auxs.num_symbols) { if (need_space) WRITE_SPACE(); WRITE_STRING(Saux); WRITE_SPACE(); for (i = 0; i < alist->auxs.num_symbols; i++) { WRITE_OPAREN(); WRITE_ATOM(alist->auxs.symbols[i]); WRITE_SPACE(); WRITE_OBJECT(alist->auxs.initials[i]); WRITE_CPAREN(); if (i + 1 < alist->auxs.num_symbols) WRITE_SPACE(); } } WRITE_CPAREN(); #undef WRITE_ATOM #undef WRITE_STRING #undef WRITE_OBJECT #undef WRITE_OPAREN #undef WRITE_SPACE #undef WRITE_CPAREN return (length); } static void check_stream(LispObj *stream, LispFile **file, LispString **string, int check_writable) { /* NIL is UNIX stdout, *STANDARD-OUTPUT* may not be UNIX stdout */ if (stream == NIL) { *file = Stdout; *string = NULL; } else { if (!STREAMP(stream)) LispDestroy("%s is not a stream", STROBJ(stream)); if (check_writable && !stream->data.stream.writable) LispDestroy("%s is not writable", STROBJ(stream)); else if (stream->data.stream.type == LispStreamString) { *string = SSTREAMP(stream); *file = NULL; } else { if (stream->data.stream.type == LispStreamPipe) *file = OPSTREAMP(stream); else *file = stream->data.stream.source.file; *string = NULL; } } } /* Assumes buffer has enough storage, 64 bytes should be more than enough */ static void parse_double(char *buffer, int *exponent, double value, int d) { char stk[64], fmt[32], *ptr, *fract = NULL; int positive = value >= 0.0; parse_double_again: if (d >= 8) { double dcheck; int icheck, count; /* this should to do the correct rounding */ for (count = 2; count >= 0; count--) { icheck = d <= 0 ? 0 : d > FLOAT_PREC ? FLOAT_PREC - count : d - count; sprintf(fmt, "%%.%de", icheck); sprintf(stk, fmt, value); if (count) { /* if the value read back is the same formatted */ sscanf(stk, "%lf", &dcheck); if (dcheck == value) break; } } } else { sprintf(fmt, "%%.%de", d <= 0 ? 0 : d > FLOAT_PREC ? FLOAT_PREC : d); sprintf(stk, fmt, value); } /* this "should" never fail */ ptr = strchr(stk, 'e'); if (ptr) { *ptr++ = '\0'; *exponent = atoi(ptr); } else *exponent = 0; /* find start of number representation */ for (ptr = stk; *ptr && !isdigit(*ptr); ptr++) ; /* check if did not trim any significant digit, * this may happen because '%.e' puts only one digit before the '.' */ if (d > 0 && d < FLOAT_PREC && fabs(value) >= 10.0 && strlen(ptr) - 1 - !positive <= *exponent) { d += *exponent - (strlen(ptr) - 1 - !positive) + 1; goto parse_double_again; } /* this "should" never fail */ fract = strchr(ptr, '.'); if (fract) *fract++ = '\0'; /* store number representation in buffer */ *buffer = positive ? '+' : '-'; strcpy(buffer + 1, ptr); if (fract) strcpy(buffer + strlen(buffer), fract); } static void format_integer(char *buffer, long value, int radix) { if (radix == 10) sprintf(buffer, "%ld", value); else if (radix == 16) sprintf(buffer, "%lx", value); else if (radix == 8) sprintf(buffer, "%lo", value); else { /* use bignum routine to convert number to string */ mpi integer; mpi_init(&integer); mpi_seti(&integer, value); mpi_getstr(buffer, &integer, radix); mpi_clear(&integer); } } static int LispWriteCPointer(LispObj *stream, void *data) { char stk[32]; #ifdef LONG64 sprintf(stk, "0x%016lx", (long)data); #else sprintf(stk, "0x%08lx", (long)data); #endif return (LispWriteStr(stream, stk, strlen(stk))); } static int LispWriteCString(LispObj *stream, char *string, long length, write_info *info) { int result; if (!info->print_escape) { char *base, *ptr, *end; result = LispWriteChar(stream, '"'); for (base = ptr = string, end = string + length; ptr < end; ptr++) { if (*ptr == '\\' || *ptr == '"') { result += LispWriteStr(stream, base, ptr - base); result += LispWriteChar(stream, '\\'); result += LispWriteChar(stream, *ptr); base = ptr + 1; } } result += LispWriteStr(stream, base, end - base); result += LispWriteChar(stream, '"'); } else result = LispWriteStr(stream, string, length); return (result); } static int LispWriteList(LispObj *stream, LispObj *object, write_info *info, int paren) { int length = 0; long circle = 0; INCDEPTH(); if (info->print_level < 0 || info->level <= info->print_level) { LispObj *car, *cdr; long print_length = info->length; if (info->circles && (circle = LispCheckCircle(object, info)) >= 0) { if (!paren) { length += LispWriteStr(stream, ". ", 2); paren = 1; } if (LispPrintCircle(stream, object, circle, &length, info) == 0) { DECDEPTH(); return (length); } } car = CAR(object); cdr = CDR(object); if (cdr == NIL) { if (paren) length += LispWriteChar(stream, '('); if (info->print_length < 0 || info->length < info->print_length) { info->length = 0; length += LispDoWriteObject(stream, car, info, 1); info->length = print_length + 1; } else length += LispWriteStr(stream, "...", 3); if (paren) length += LispWriteChar(stream, ')'); } else { if (paren) length += LispWriteChar(stream, '('); if (info->print_length < 0 || info->length < info->print_length) { info->length = 0; length += LispDoWriteObject(stream, car, info, 1); info->length = print_length + 1; if (!CONSP(cdr)) { length += LispWriteStr(stream, " . ", 3); info->length = 0; length += LispDoWriteObject(stream, cdr, info, 0); } else { length += LispWriteChar(stream, ' '); if (info->print_length < 0 || info->length < info->print_length) length += LispWriteList(stream, cdr, info, 0); else length += LispWriteStr(stream, "...", 3); } } else length += LispWriteStr(stream, "...", 3); if (paren) length += LispWriteChar(stream, ')'); } info->length = print_length; } else length += LispWriteChar(stream, '#'); DECDEPTH(); return (length); } static int LispDoWriteObject(LispObj *stream, LispObj *object, write_info *info, int paren) { long print_level; int length = 0; char stk[64], *string = NULL; write_again: switch (OBJECT_TYPE(object)) { case LispNil_t: if (object == NIL) string = Snil; else if (object == T) string = St; else if (object == DOT) string = "#"; else if (object == UNSPEC) string = "#"; else if (object == UNBOUND) string = "#"; else string = "#"; length += LispDoWriteAtom(stream, string, strlen(string), info->print_case); break; case LispOpaque_t: { char *desc = LispIntToOpaqueType(object->data.opaque.type); length += LispWriteChar(stream, '#'); length += LispWriteCPointer(stream, object->data.opaque.data); length += LispWriteStr(stream, desc, strlen(desc)); } break; case LispAtom_t: length += LispWriteAtom(stream, object, info); break; case LispFunction_t: if (object->data.atom->a_function) { object = object->data.atom->property->fun.function; goto write_lambda; } length += LispWriteStr(stream, "#<", 2); if (object->data.atom->a_compiled) LispDoWriteAtom(stream, "COMPILED", 8, info->print_case); else if (object->data.atom->a_builtin) LispDoWriteAtom(stream, "BUILTIN", 7, info->print_case); /* XXX the function does not exist anymore */ /* FIXME not sure if I want this fixed... */ else LispDoWriteAtom(stream, "UNBOUND", 7, info->print_case); LispDoWriteAtom(stream, "-FUNCTION", 9, info->print_case); length += LispWriteChar(stream, ' '); length += LispWriteAtom(stream, object->data.atom->object, info); length += LispWriteChar(stream, '>'); break; case LispString_t: length += LispWriteString(stream, object, info); break; case LispSChar_t: length += LispWriteCharacter(stream, object, info); break; case LispDFloat_t: length += LispWriteFloat(stream, object); break; case LispFixnum_t: case LispInteger_t: case LispBignum_t: length += LispWriteInteger(stream, object); break; case LispRatio_t: format_integer(stk, object->data.ratio.numerator, 10); length += LispWriteStr(stream, stk, strlen(stk)); length += LispWriteChar(stream, '/'); format_integer(stk, object->data.ratio.denominator, 10); length += LispWriteStr(stream, stk, strlen(stk)); break; case LispBigratio_t: { int sz; char *ptr; sz = mpi_getsize(mpr_num(object->data.mp.ratio), 10) + 1 + mpi_getsize(mpr_den(object->data.mp.ratio), 10) + 1 + (mpi_sgn(mpr_num(object->data.mp.ratio)) < 0); if (sz > sizeof(stk)) ptr = LispMalloc(sz); else ptr = stk; mpr_getstr(ptr, object->data.mp.ratio, 10); length += LispWriteStr(stream, ptr, sz - 1); if (ptr != stk) LispFree(ptr); } break; case LispComplex_t: length += LispWriteStr(stream, "#C(", 3); length += LispDoWriteObject(stream, object->data.complex.real, info, 0); length += LispWriteChar(stream, ' '); length += LispDoWriteObject(stream, object->data.complex.imag, info, 0); length += LispWriteChar(stream, ')'); break; case LispCons_t: print_level = info->level; ++info->level; length += LispWriteList(stream, object, info, paren); info->level = print_level; break; case LispQuote_t: length += LispWriteChar(stream, '\''); paren = 1; object = object->data.quote; goto write_again; case LispBackquote_t: length += LispWriteChar(stream, '`'); paren = 1; object = object->data.quote; goto write_again; case LispComma_t: if (object->data.comma.atlist) length += LispWriteStr(stream, ",@", 2); else length += LispWriteChar(stream, ','); paren = 1; object = object->data.comma.eval; goto write_again; break; case LispFunctionQuote_t: length += LispWriteStr(stream, "#'", 2); paren = 1; object = object->data.quote; goto write_again; case LispArray_t: length += LispWriteArray(stream, object, info); break; case LispStruct_t: length += LispWriteStruct(stream, object, info); break; case LispLambda_t: write_lambda: switch (object->funtype) { case LispLambda: string = "#print_case); if (object->funtype != LispLambda) { length += LispWriteAtom(stream, object->data.lambda.name, info); length += LispWriteChar(stream, ' '); length += LispWriteAlist(stream, object->data.lambda.name ->data.atom->property->alist, info); } else { length += LispDoWriteAtom(stream, Snil, 3, info->print_case); length += LispWriteChar(stream, ' '); length += LispWriteAlist(stream, (LispArgList*)object-> data.lambda.name->data.opaque.data, info); } length += LispWriteChar(stream, ' '); length += LispDoWriteObject(stream, object->data.lambda.code, info, 0); length += LispWriteChar(stream, '>'); break; case LispStream_t: length += LispWriteStr(stream, "#<", 2); if (object->data.stream.type == LispStreamFile) string = "FILE-STREAM "; else if (object->data.stream.type == LispStreamString) string = "STRING-STREAM "; else if (object->data.stream.type == LispStreamStandard) string = "STANDARD-STREAM "; else if (object->data.stream.type == LispStreamPipe) string = "PIPE-STREAM "; length += LispDoWriteAtom(stream, string, strlen(string), info->print_case); if (!object->data.stream.readable && !object->data.stream.writable) length += LispDoWriteAtom(stream, "CLOSED", 6, info->print_case); else { if (object->data.stream.readable) length += LispDoWriteAtom(stream, "READ", 4, info->print_case); if (object->data.stream.writable) { if (object->data.stream.readable) length += LispWriteChar(stream, '-'); length += LispDoWriteAtom(stream, "WRITE", 5, info->print_case); } } if (object->data.stream.type != LispStreamString) { length += LispWriteChar(stream, ' '); length += LispDoWriteObject(stream, object->data.stream.pathname, info, 1); /* same address/size for pipes */ length += LispWriteChar(stream, ' '); length += LispWriteCPointer(stream, object->data.stream.source.file); if (object->data.stream.readable && object->data.stream.type == LispStreamFile && !object->data.stream.source.file->binary) { length += LispWriteStr(stream, " @", 2); format_integer(stk, object->data.stream.source.file->line, 10); length += LispWriteStr(stream, stk, strlen(stk)); } } length += LispWriteChar(stream, '>'); break; case LispPathname_t: length += LispWriteStr(stream, "#P", 2); paren = 1; object = CAR(object->data.quote); goto write_again; case LispPackage_t: length += LispDoWriteAtom(stream, "#print_case); length += LispWriteStr(stream, THESTR(object->data.package.name), STRLEN(object->data.package.name)); length += LispWriteChar(stream, '>'); break; case LispRegex_t: length += LispDoWriteAtom(stream, "#print_case); length += LispDoWriteObject(stream, object->data.regex.pattern, info, 1); if (object->data.regex.options & RE_NOSPEC) length += LispDoWriteAtom(stream, " :NOSPEC", 8, info->print_case); if (object->data.regex.options & RE_ICASE) length += LispDoWriteAtom(stream, " :ICASE", 7, info->print_case); if (object->data.regex.options & RE_NOSUB) length += LispDoWriteAtom(stream, " :NOSUB", 7, info->print_case); if (object->data.regex.options & RE_NEWLINE) length += LispDoWriteAtom(stream, " :NEWLINE", 9, info->print_case); length += LispWriteChar(stream, '>'); break; case LispBytecode_t: length += LispDoWriteAtom(stream, "#print_case); length += LispWriteCPointer(stream, object->data.bytecode.bytecode); length += LispWriteChar(stream, '>'); break; case LispHashTable_t: length += LispDoWriteAtom(stream, "#print_case); length += LispWriteAtom(stream, object->data.hash.test, info); snprintf(stk, sizeof(stk), " %g %g", object->data.hash.table->rehash_size, object->data.hash.table->rehash_threshold); length += LispWriteStr(stream, stk, strlen(stk)); snprintf(stk, sizeof(stk), " %ld/%ld>", object->data.hash.table->count, object->data.hash.table->num_entries); length += LispWriteStr(stream, stk, strlen(stk)); break; } return (length); } /* return current column number in stream */ int LispGetColumn(LispObj *stream) { LispFile *file; LispString *string; check_stream(stream, &file, &string, 0); if (file != NULL) return (file->column); return (string->column); } /* write a character to stream */ int LispWriteChar(LispObj *stream, int character) { LispFile *file; LispString *string; check_stream(stream, &file, &string, 1); if (file != NULL) return (LispFputc(file, character)); return (LispSputc(string, character)); } /* write a character count times to stream */ int LispWriteChars(LispObj *stream, int character, int count) { int length = 0; if (count > 0) { char stk[64]; LispFile *file; LispString *string; check_stream(stream, &file, &string, 1); if (count >= sizeof(stk)) { memset(stk, character, sizeof(stk)); for (; count >= sizeof(stk); count -= sizeof(stk)) { if (file != NULL) length += LispFwrite(file, stk, sizeof(stk)); else length += LispSwrite(string, stk, sizeof(stk)); } } else memset(stk, character, count); if (count) { if (file != NULL) length += LispFwrite(file, stk, count); else length += LispSwrite(string, stk, count); } } return (length); } /* write a string to stream */ int LispWriteStr(LispObj *stream, char *buffer, long length) { LispFile *file; LispString *string; check_stream(stream, &file, &string, 1); if (file != NULL) return (LispFwrite(file, buffer, length)); return (LispSwrite(string, buffer, length)); } static int LispDoWriteAtom(LispObj *stream, char *string, int length, int print_case) { int bytes = 0, cap = 0; char buffer[128], *ptr; switch (print_case) { case DOWNCASE: for (ptr = buffer; length > 0; length--, string++) { if (isupper(*string)) *ptr = tolower(*string); else *ptr = *string; ++ptr; if (ptr - buffer >= sizeof(buffer)) { bytes += LispWriteStr(stream, buffer, ptr - buffer); ptr = buffer; } } if (ptr > buffer) bytes += LispWriteStr(stream, buffer, ptr - buffer); break; case CAPITALIZE: for (ptr = buffer; length > 0; length--, string++) { if (isalnum(*string)) { if (cap && isupper(*string)) *ptr = tolower(*string); else *ptr = *string; cap = 1; } else { *ptr = *string; cap = 0; } ++ptr; if (ptr - buffer >= sizeof(buffer)) { bytes += LispWriteStr(stream, buffer, ptr - buffer); ptr = buffer; } } if (ptr > buffer) bytes += LispWriteStr(stream, buffer, ptr - buffer); break; default: /* Strings are already stored upcase/quoted */ bytes += LispWriteStr(stream, string, length); break; } return (bytes); } static int LispWriteAtom(LispObj *stream, LispObj *object, write_info *info) { int length = 0; LispAtom *atom = object->data.atom; Atom_id id = atom->string; if (atom->package != PACKAGE) { if (atom->package == lisp__data.keyword) length += LispWriteChar(stream, ':'); else if (atom->package == NULL) length += LispWriteStr(stream, "#:", 2); else { /* Check if the symbol is visible */ int i, visible = 0; if (atom->ext) { for (i = lisp__data.pack->use.length - 1; i >= 0; i--) { if (lisp__data.pack->use.pairs[i] == atom->package) { visible = 1; break; } } } if (!visible) { /* XXX this assumes that package names are always "readable" */ length += LispDoWriteAtom(stream, THESTR(atom->package->data.package.name), STRLEN(atom->package->data.package.name), info->print_case); length += LispWriteChar(stream, ':'); if (!atom->ext) length += LispWriteChar(stream, ':'); } } } if (atom->unreadable) length += LispWriteChar(stream, '|'); length += LispDoWriteAtom(stream, id, strlen(id), atom->unreadable ? UPCASE : info->print_case); if (atom->unreadable) length += LispWriteChar(stream, '|'); return (length); } static int LispWriteInteger(LispObj *stream, LispObj *object) { return (LispFormatInteger(stream, object, 10, 0, 0, 0, 0, 0, 0)); } static int LispWriteCharacter(LispObj *stream, LispObj *object, write_info *info) { return (LispFormatCharacter(stream, object, !info->print_escape, 0)); } static int LispWriteString(LispObj *stream, LispObj *object, write_info *info) { return (LispWriteCString(stream, THESTR(object), STRLEN(object), info)); } static int LispWriteFloat(LispObj *stream, LispObj *object) { double value = DFLOAT_VALUE(object); if (value == 0.0 || (fabs(value) < 1.0E7 && fabs(value) > 1.0E-4)) return (LispFormatFixedFloat(stream, object, 0, 0, NULL, 0, 0, 0)); return (LispDoFormatExponentialFloat(stream, object, 0, 0, NULL, 0, 1, 0, ' ', 'E', 0)); } static int LispWriteArray(LispObj *stream, LispObj *object, write_info *info) { int length = 0; long print_level = info->level, circle; if (info->circles && (circle = LispCheckCircle(object, info)) >= 0 && LispPrintCircle(stream, object, circle, &length, info) == 0) return (length); if (object->data.array.rank == 0) { length += LispWriteStr(stream, "#0A", 3); length += LispDoWriteObject(stream, object->data.array.list, info, 1); return (length); } INCDEPTH(); ++info->level; if (info->print_level < 0 || info->level <= info->print_level) { if (object->data.array.rank == 1) length += LispWriteStr(stream, "#(", 2); else { char stk[32]; format_integer(stk, object->data.array.rank, 10); length += LispWriteChar(stream, '#'); length += LispWriteStr(stream, stk, strlen(stk)); length += LispWriteStr(stream, "A(", 2); } if (!object->data.array.zero) { long print_length = info->length, local_length = 0; if (object->data.array.rank == 1) { LispObj *ary; long count; for (ary = object->data.array.dim, count = 1; ary != NIL; ary = CDR(ary)) count *= FIXNUM_VALUE(CAR(ary)); for (ary = object->data.array.list; count > 0; ary = CDR(ary), count--) { if (info->print_length < 0 || ++local_length <= info->print_length) { info->length = 0; length += LispDoWriteObject(stream, CAR(ary), info, 1); } else { length += LispWriteStr(stream, "...", 3); break; } if (count - 1 > 0) length += LispWriteChar(stream, ' '); } } else { LispObj *ary; int i, k, rank, *dims, *loop; rank = object->data.array.rank; dims = LispMalloc(sizeof(int) * rank); loop = LispCalloc(1, sizeof(int) * (rank - 1)); /* fill dim */ for (i = 0, ary = object->data.array.dim; ary != NIL; i++, ary = CDR(ary)) dims[i] = FIXNUM_VALUE(CAR(ary)); i = 0; ary = object->data.array.list; while (loop[0] < dims[0]) { if (info->print_length < 0 || local_length < info->print_length) { for (; i < rank - 1; i++) length += LispWriteChar(stream, '('); --i; for (;;) { ++loop[i]; if (i && loop[i] >= dims[i]) loop[i] = 0; else break; --i; } for (k = 0; k < dims[rank - 1] - 1; k++, ary = CDR(ary)) { if (info->print_length < 0 || k < info->print_length) { ++local_length; info->length = 0; length += LispDoWriteObject(stream, CAR(ary), info, 1); length += LispWriteChar(stream, ' '); } } if (info->print_length < 0 || k < info->print_length) { ++local_length; info->length = 0; length += LispDoWriteObject(stream, CAR(ary), info, 0); } else length += LispWriteStr(stream, "...", 3); for (k = rank - 1; k > i; k--) length += LispWriteChar(stream, ')'); if (loop[0] < dims[0]) length += LispWriteChar(stream, ' '); ary = CDR(ary); } else { ++local_length; length += LispWriteStr(stream, "...)", 4); for (; local_length < dims[0] - 1; local_length++) length += LispWriteStr(stream, " ...)", 5); if (local_length <= dims[0]) length += LispWriteStr(stream, " ...", 4); break; } } LispFree(dims); LispFree(loop); } info->length = print_length; } length += LispWriteChar(stream, ')'); } else length += LispWriteChar(stream, '#'); info->level = print_level; DECDEPTH(); return (length); } static int LispWriteStruct(LispObj *stream, LispObj *object, write_info *info) { int length; long circle; LispObj *symbol; LispObj *def = object->data.struc.def; LispObj *field = object->data.struc.fields; if (info->circles && (circle = LispCheckCircle(object, info)) >= 0 && LispPrintCircle(stream, object, circle, &length, info) == 0) return (length); INCDEPTH(); length = LispWriteStr(stream, "#S(", 3); symbol = SYMBOLP(CAR(def)) ? CAR(def) : CAAR(def); length += LispWriteAtom(stream, symbol, info); def = CDR(def); for (; def != NIL; def = CDR(def), field = CDR(field)) { length += LispWriteChar(stream, ' '); symbol = SYMBOLP(CAR(def)) ? CAR(def) : CAAR(def); length += LispWriteAtom(stream, symbol, info); length += LispWriteChar(stream, ' '); length += LispDoWriteObject(stream, CAR(field), info, 1); } length += LispWriteChar(stream, ')'); DECDEPTH(); return (length); } int LispFormatInteger(LispObj *stream, LispObj *object, int radix, int atsign, int collon, int mincol, int padchar, int commachar, int commainterval) { char stk[128], *str = stk; int i, length, sign, intervals; if (LONGINTP(object)) format_integer(stk, LONGINT_VALUE(object), radix); else { if (mpi_getsize(object->data.mp.integer, radix) >= sizeof(stk)) str = mpi_getstr(NULL, object->data.mp.integer, radix); else mpi_getstr(str, object->data.mp.integer, radix); } sign = *str == '-'; length = strlen(str); /* if collon, update length for the number of commachars to be printed */ if (collon && commainterval > 0 && commachar) { intervals = length / commainterval; length += intervals; } else intervals = 0; /* if sign must be printed, and number is positive */ if (atsign && !sign) ++length; /* if need padding */ if (padchar && mincol > length) LispWriteChars(stream, padchar, mincol - length); /* if need to print number sign */ if (sign || atsign) LispWriteChar(stream, sign ? '-' : '+'); /* if need to print commas to separate groups of numbers */ if (intervals) { int j; char *ptr; i = (length - atsign) - intervals; j = i % commainterval; /* make the loop below easier */ if (j == 0) j = commainterval; i -= j; ptr = str + sign; for (; j > 0; j--, ptr++) LispWriteChar(stream, *ptr); for (; i > 0; i -= commainterval) { LispWriteChar(stream, commachar); for (j = 0; j < commainterval; j++, ptr++) LispWriteChar(stream, *ptr); } } /* else, just print the string */ else LispWriteStr(stream, str + sign, length - sign); /* if number required more than sizeof(stk) bytes */ if (str != stk) LispFree(str); return (length); } int LispFormatRomanInteger(LispObj *stream, long value, int new_roman) { char stk[32]; int length; length = 0; while (value > 1000) { stk[length++] = 'M'; value -= 1000; } if (new_roman) { if (value >= 900) { strcpy(stk + length, "CM"); length += 2, value -= 900; } else if (value < 500 && value >= 400) { strcpy(stk + length, "CD"); length += 2; value -= 400; } } if (value >= 500) { stk[length++] = 'D'; value -= 500; } while (value >= 100) { stk[length++] = 'C'; value -= 100; } if (new_roman) { if (value >= 90) { strcpy(stk + length, "XC"); length += 2, value -= 90; } else if (value < 50 && value >= 40) { strcpy(stk + length, "XL"); length += 2; value -= 40; } } if (value >= 50) { stk[length++] = 'L'; value -= 50; } while (value >= 10) { stk[length++] = 'X'; value -= 10; } if (new_roman) { if (value == 9) { strcpy(stk + length, "IX"); length += 2, value -= 9; } else if (value == 4) { strcpy(stk + length, "IV"); length += 2; value -= 4; } } if (value >= 5) { stk[length++] = 'V'; value -= 5; } while (value) { stk[length++] = 'I'; --value; } stk[length] = '\0'; return (LispWriteStr(stream, stk, length)); } int LispFormatEnglishInteger(LispObj *stream, long number, int ordinal) { static char *ds[] = { "", "one", "two", "three", "four", "five", "six", "seven", "eight", "nine", "ten", "eleven", "twelve", "thirteen", "fourteen", "fifteen", "sixteen", "seventeen", "eighteen", "nineteen" }; static char *dsth[] = { "", "first", "second", "third", "fourth", "fifth", "sixth", "seventh", "eighth", "ninth", "tenth", "eleventh", "twelfth", "thirteenth", "fourteenth", "fifteenth", "sixteenth", "seventeenth", "eighteenth", "nineteenth" }; static char *hs[] = { "", "", "twenty", "thirty", "forty", "fifty", "sixty", "seventy", "eighty", "ninety" }; static char *hsth[] = { "", "", "twentieth", "thirtieth", "fortieth", "fiftieth", "sixtieth", "seventieth", "eightieth", "ninetieth" }; static char *ts[] = { "", "thousand", "million" }; static char *tsth[] = { "", "thousandth", "millionth" }; char stk[256]; int length, sign; sign = number < 0; if (sign) number = -number; length = 0; #define SIGNLEN 6 /* strlen("minus ") */ if (sign) { strcpy(stk, "minus "); length += SIGNLEN; } else if (number == 0) { if (ordinal) { strcpy(stk, "zeroth"); length += 6; /* strlen("zeroth") */ } else { strcpy(stk, "zero"); length += 4; /* strlen("zero") */ } } for (;;) { int count, temp; char *t, *h, *d; long value = number; for (count = 0; value >= 1000; value /= 1000, count++) ; t = ds[value / 100]; if (ordinal && !count && (value % 10) == 0) h = hsth[(value % 100) / 10]; else h = hs[(value % 100) / 10]; if (ordinal && !count) d = *h ? dsth[value % 10] : dsth[value % 20]; else d = *h ? ds[value % 10] : ds[value % 20]; if (((!sign && length) || length > SIGNLEN) && (*t || *h || *d)) { if (!ordinal || count || *h || *t) { strcpy(stk + length, ", "); length += 2; } else { strcpy(stk + length, " "); ++length; } } if (*t) { if (ordinal && !count && (value % 100) == 0) temp = sprintf(stk + length, "%s hundredth", t); else temp = sprintf(stk + length, "%s hundred", t); length += temp; } if (*h) { if (*t) { if (ordinal && !count) { strcpy(stk + length, " "); ++length; } else { strcpy(stk + length, " and "); length += 5; /* strlen(" and ") */ } } strcpy(stk + length, h); length += strlen(h); } if (*d) { if (*h) { strcpy(stk + length, "-"); ++length; } else if (*t) { if (ordinal && !count) { strcpy(stk + length, " "); ++length; } else { strcpy(stk + length, " and "); length += 5; /* strlen(" and ") */ } } strcpy(stk + length, d); length += strlen(d); } if (!count) break; else temp = count; if (count > 1) { value *= 1000; while (--count) value *= 1000; number -= value; } else number %= 1000; if (ordinal && number == 0 && !*t && !*h) temp = sprintf(stk + length, " %s", tsth[temp]); else temp = sprintf(stk + length, " %s", ts[temp]); length += temp; if (!number) break; } return (LispWriteStr(stream, stk, length)); } int LispFormatCharacter(LispObj *stream, LispObj *object, int atsign, int collon) { int length = 0; int ch = SCHAR_VALUE(object); if (atsign && !collon) length += LispWriteStr(stream, "#\\", 2); if ((atsign || collon) && (ch <= ' ' || ch == 0177)) { char *name = LispChars[ch].names[0]; length += LispWriteStr(stream, name, strlen(name)); } else length += LispWriteChar(stream, ch); return (length); } /* returns 1 if string size must grow, done inplace */ static int float_string_inc(char *buffer, int offset) { int i; for (i = offset; i >= 0; i--) { if (buffer[i] == '9') buffer[i] = '0'; else if (buffer[i] != '.') { ++buffer[i]; break; } } if (i < 0) { int length = strlen(buffer); /* string size must change */ memmove(buffer + 1, buffer, length + 1); buffer[0] = '1'; return (1); } return (0); } int LispFormatFixedFloat(LispObj *stream, LispObj *object, int atsign, int w, int *pd, int k, int overflowchar, int padchar) { char buffer[512], stk[64]; int sign, exponent, length, offset, d = pd ? *pd : FLOAT_PREC, again; double value = DFLOAT_VALUE(object); if (value == 0.0) { exponent = k = 0; strcpy(stk, "+0"); } else /* calculate format parameters, adjusting scale factor */ parse_double(stk, &exponent, value, d + 1 + k); /* make sure k won't cause overflow */ if (k > 128) k = 128; else if (k < -128) k = -128; /* make sure d won't cause overflow */ if (d > 128) d = 128; else if (d < -128) d = -128; /* adjust scale factor, exponent is used as an index in stk */ exponent += k + 1; /* how many bytes in float representation */ length = strlen(stk) - 1; /* need to print a sign? */ sign = atsign || (stk[0] == '-'); /* format number, cannot overflow, as control variables were checked */ offset = 0; if (sign) buffer[offset++] = stk[0]; if (exponent > 0) { if (exponent > length) { memcpy(buffer + offset, stk + 1, length); memset(buffer + offset + length, '0', exponent - length); } else memcpy(buffer + offset, stk + 1, exponent); offset += exponent; buffer[offset++] = '.'; if (length > exponent) { memcpy(buffer + offset, stk + 1 + exponent, length - exponent); offset += length - exponent; } else buffer[offset++] = '0'; } else { buffer[offset++] = '0'; buffer[offset++] = '.'; while (exponent < 0) { buffer[offset++] = '0'; exponent++; } memcpy(buffer + offset, stk + 1, length); offset += length; } buffer[offset] = '\0'; again = 0; fixed_float_check_again: /* make sure only d digits are printed after decimal point */ if (d > 0) { char *dptr = strchr(buffer, '.'); length = strlen(dptr) - 1; /* check if need to remove excess digits */ if (length > d) { int digit; offset = (dptr - buffer) + 1 + d; digit = buffer[offset]; /* remove extra digits */ buffer[offset] = '\0'; /* check if need to round */ if (!again && offset > 1 && isdigit(digit) && digit >= '5' && isdigit(buffer[offset - 1]) && float_string_inc(buffer, offset - 1)) ++offset; } /* check if need to add extra zero digits to fill space */ else if (length < d) { offset += d - length; for (++length; length <= d; length++) dptr[length] = '0'; dptr[length] = '\0'; } } else { /* no digits after decimal point */ int digit, inc = 0; char *dptr = strchr(buffer, '.') + 1; digit = *dptr; if (!again && digit >= '5' && dptr >= buffer + 2 && isdigit(dptr[-2])) inc = float_string_inc(buffer, dptr - buffer - 2); offset = (dptr - buffer) + inc; buffer[offset] = '\0'; } /* if d was not specified, remove any extra zeros */ if (pd == NULL) { while (offset > 2 && buffer[offset - 2] != '.' && buffer[offset - 1] == '0') --offset; buffer[offset] = '\0'; } if (w > 0 && offset > w) { /* first check if can remove extra fractional digits */ if (pd == NULL) { char *ptr = strchr(buffer, '.') + 1; if (ptr - buffer < w) { d = w - (ptr - buffer); goto fixed_float_check_again; } } /* remove leading "zero" to save space */ if ((!sign && buffer[0] == '0') || (sign && buffer[1] == '0')) { /* ending nul also copied */ memmove(buffer + sign, buffer + sign + 1, offset); --offset; } /* remove leading '+' to "save" space */ if (offset > w && buffer[0] == '+') { /* ending nul also copied */ memmove(buffer, buffer + 1, offset); --offset; } } /* if cannot represent number in given width */ if (overflowchar && offset > w) { again = 1; goto fixed_float_overflow; } length = 0; /* print padding if required */ if (w > offset) length += LispWriteChars(stream, padchar, w - offset); /* print float number representation */ return (LispWriteStr(stream, buffer, offset) + length); fixed_float_overflow: return (LispWriteChars(stream, overflowchar, w)); } int LispFormatExponentialFloat(LispObj *stream, LispObj *object, int atsign, int w, int *pd, int e, int k, int overflowchar, int padchar, int exponentchar) { return (LispDoFormatExponentialFloat(stream, object, atsign, w, pd, e, k, overflowchar, padchar, exponentchar, 1)); } int LispDoFormatExponentialFloat(LispObj *stream, LispObj *object, int atsign, int w, int *pd, int e, int k, int overflowchar, int padchar, int exponentchar, int format) { char buffer[512], stk[64]; int sign, exponent, length, offset, d = pd ? *pd : FLOAT_PREC; double value = DFLOAT_VALUE(object); if (value == 0.0) { exponent = 0; k = 1; strcpy(stk, "+0"); } else /* calculate format parameters, adjusting scale factor */ parse_double(stk, &exponent, value, d + k - 1); /* set e to a value that won't overflow */ if (e > 16) e = 16; /* set k to a value that won't overflow */ if (k > 128) k = 128; else if (k < -128) k = -128; /* set d to a value that won't overflow */ if (d > 128) d = 128; else if (d < -128) d = -128; /* how many bytes in float representation */ length = strlen(stk) - 1; /* need to print a sign? */ sign = atsign || (stk[0] == '-'); /* adjust number of digits after decimal point */ if (k > 0) d -= k - 1; /* adjust exponent, based on scale factor */ exponent -= k - 1; /* format number, cannot overflow, as control variables were checked */ offset = 0; if (sign) buffer[offset++] = stk[0]; if (k > 0) { if (k > length) { memcpy(buffer + offset, stk + 1, length); offset += length; } else { memcpy(buffer + offset, stk + 1, k); offset += k; } buffer[offset++] = '.'; if (length > k) { memcpy(buffer + offset, stk + 1 + k, length - k); offset += length - k; } else buffer[offset++] = '0'; } else { int tmp = k; buffer[offset++] = '0'; buffer[offset++] = '.'; while (tmp < 0) { buffer[offset++] = '0'; tmp++; } memcpy(buffer + offset, stk + 1, length); offset += length; } /* if format, then always add a sign to exponent */ buffer[offset++] = exponentchar; if (format || exponent < 0) buffer[offset++] = exponent < 0 ? '-' : '+'; /* XXX destroy stk contents */ sprintf(stk, "%%0%dd", e); /* format scale factor*/ length = sprintf(buffer + offset, stk, exponent < 0 ? -exponent : exponent); /* check for overflow in exponent */ if (length > e && overflowchar) goto exponential_float_overflow; offset += length; /* make sure only d digits are printed after decimal point */ if (d > 0) { int currd; char *dptr = strchr(buffer, '.'), *eptr = strchr(dptr, exponentchar); currd = eptr - dptr - 1; length = strlen(eptr); /* check if need to remove excess digits */ if (currd > d) { int digit, dpos; dpos = offset = (dptr - buffer) + 1 + d; digit = buffer[offset]; memmove(buffer + offset, eptr, length + 1); /* also copy ending nul character */ /* adjust offset to length of total string */ offset += length; /* check if need to round */ if (dpos > 1 && isdigit(digit) && digit >= '5' && isdigit(buffer[dpos - 1]) && float_string_inc(buffer, dpos - 1)) ++offset; } /* check if need to add extra zero digits to fill space */ else if (pd && currd < d) { memmove(eptr + d - currd, eptr, length + 1); /* also copy ending nul character */ offset += d - currd; for (++currd; currd <= d; currd++) dptr[currd] = '0'; } /* check if need to remove zeros */ else if (pd == NULL) { int zeros = 1; while (eptr[-zeros] == '0') ++zeros; if (eptr[-zeros] == '.') --zeros; if (zeros > 1) { memmove(eptr - zeros + 1, eptr, length + 1); offset -= zeros - 1; } } } else { /* no digits after decimal point */ int digit, inc = 0; char *dptr = strchr(buffer, '.'), *eptr = strchr(dptr, exponentchar); digit = dptr[1]; offset = (dptr - buffer) + 1; length = strlen(eptr); memmove(buffer + offset, eptr, length + 1); /* also copy ending nul character */ if (digit >= '5' && dptr >= buffer + 2 && isdigit(dptr[-2])) inc = float_string_inc(buffer, dptr - buffer - 2); /* adjust offset to length of total string */ offset += length + inc; } if (w > 0 && offset > w) { /* remove leading "zero" to save space */ if ((!sign && buffer[0] == '0') || (sign && buffer[1] == '0')) { /* ending nul also copied */ memmove(buffer + sign, buffer + sign + 1, offset); --offset; } /* remove leading '+' to "save" space */ if (offset > w && buffer[0] == '+') { /* ending nul also copied */ memmove(buffer, buffer + 1, offset); --offset; } } /* if cannot represent number in given width */ if (overflowchar && offset > w) goto exponential_float_overflow; length = 0; /* print padding if required */ if (w > offset) length += LispWriteChars(stream, padchar, w - offset); /* print float number representation */ return (LispWriteStr(stream, buffer, offset) + length); exponential_float_overflow: return (LispWriteChars(stream, overflowchar, w)); } int LispFormatGeneralFloat(LispObj *stream, LispObj *object, int atsign, int w, int *pd, int e, int k, int overflowchar, int padchar, int exponentchar) { char stk[64]; int length, exponent, n, dd, ee, ww, d = pd ? *pd : FLOAT_PREC; double value = DFLOAT_VALUE(object); if (value == 0.0) { exponent = 0; n = 0; d = 1; strcpy(stk, "+0"); } else { /* calculate format parameters, adjusting scale factor */ parse_double(stk, &exponent, value, d + k - 1); n = exponent + 1; } /* Let ee equal e+2, or 4 if e is omitted. */ if (e) ee = e + 2; else ee = 4; /* Let ww equal w-ee, or nil if w is omitted. */ if (w) ww = w - ee; else ww = 0; dd = d - n; if (d >= dd && dd >= 0) { length = LispFormatFixedFloat(stream, object, atsign, ww, &dd, 0, overflowchar, padchar); /* ~ee@T */ length += LispWriteChars(stream, padchar, ee); } else length = LispFormatExponentialFloat(stream, object, atsign, w, pd, e, k, overflowchar, padchar, exponentchar); return (length); } int LispFormatDollarFloat(LispObj *stream, LispObj *object, int atsign, int collon, int d, int n, int w, int padchar) { char buffer[512], stk[64]; int sign, exponent, length, offset; double value = DFLOAT_VALUE(object); if (value == 0.0) { exponent = 0; strcpy(stk, "+0"); } else /* calculate format parameters, adjusting scale factor */ parse_double(stk, &exponent, value, d == 0 ? FLOAT_PREC : d + 1); /* set d to a "sane" value */ if (d > 128) d = 128; /* set n to a "sane" value */ if (n > 128) n = 128; /* use exponent as index in stk */ ++exponent; /* don't put sign in buffer, * if collon specified, must go before padding */ sign = atsign || (stk[0] == '-'); offset = 0; /* pad with zeros if required */ if (exponent > 0) n -= exponent; while (n > 0) { buffer[offset++] = '0'; n--; } /* how many bytes in float representation */ length = strlen(stk) - 1; if (exponent > 0) { if (exponent > length) { memcpy(buffer + offset, stk + 1, length); memset(buffer + offset + length, '0', exponent - length); } else memcpy(buffer + offset, stk + 1, exponent); offset += exponent; buffer[offset++] = '.'; if (length > exponent) { memcpy(buffer + offset, stk + 1 + exponent, length - exponent); offset += length - exponent; } else buffer[offset++] = '0'; } else { if (n > 0) buffer[offset++] = '0'; buffer[offset++] = '.'; while (exponent < 0) { buffer[offset++] = '0'; exponent++; } memcpy(buffer + offset, stk + 1, length); offset += length; } buffer[offset] = '\0'; /* make sure only d digits are printed after decimal point */ if (d > 0) { char *dptr = strchr(buffer, '.'); length = strlen(dptr) - 1; /* check if need to remove excess digits */ if (length > d) { int digit; offset = (dptr - buffer) + 1 + d; digit = buffer[offset]; /* remove extra digits */ buffer[offset] = '\0'; /* check if need to round */ if (offset > 1 && isdigit(digit) && digit >= '5' && isdigit(buffer[offset - 1]) && float_string_inc(buffer, offset - 1)) ++offset; } /* check if need to add extra zero digits to fill space */ else if (length < d) { offset += d - length; for (++length; length <= d; length++) dptr[length] = '0'; dptr[length] = '\0'; } } else { /* no digits after decimal point */ int digit, inc = 0; char *dptr = strchr(buffer, '.') + 1; digit = *dptr; if (digit >= '5' && dptr >= buffer + 2 && isdigit(dptr[-2])) inc = float_string_inc(buffer, dptr - buffer - 2); offset = (dptr - buffer) + inc; buffer[offset] = '\0'; } length = 0; if (sign) { ++offset; if (atsign && collon) length += LispWriteChar(stream, value >= 0.0 ? '+' : '-'); } /* print padding if required */ if (w > offset) length += LispWriteChars(stream, padchar, w - offset); if (atsign && !collon) length += LispWriteChar(stream, value >= 0.0 ? '+' : '-'); /* print float number representation */ return (LispWriteStr(stream, buffer, offset) + length); }