/* $OpenBSD: lib_tparm.c,v 1.7 2001/01/22 18:01:54 millert Exp $ */ /**************************************************************************** * Copyright (c) 1998,2000 Free Software Foundation, 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, distribute with modifications, 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 ABOVE COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, * * DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR * * OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR * * THE USE OR OTHER DEALINGS IN THE SOFTWARE. * * * * Except as contained in this notice, the name(s) of the above copyright * * holders shall not be used in advertising or otherwise to promote the * * sale, use or other dealings in this Software without prior written * * authorization. * ****************************************************************************/ /**************************************************************************** * Author: Zeyd M. Ben-Halim 1992,1995 * * and: Eric S. Raymond * ****************************************************************************/ /* * tparm.c * */ #include #include #include #include MODULE_ID("$From: lib_tparm.c,v 1.51 2000/12/10 02:55:08 tom Exp $") /* * char * * tparm(string, ...) * * Substitute the given parameters into the given string by the following * rules (taken from terminfo(5)): * * Cursor addressing and other strings requiring parame- * ters in the terminal are described by a parameterized string * capability, with like escapes %x in it. For example, to * address the cursor, the cup capability is given, using two * parameters: the row and column to address to. (Rows and * columns are numbered from zero and refer to the physical * screen visible to the user, not to any unseen memory.) If * the terminal has memory relative cursor addressing, that can * be indicated by * * The parameter mechanism uses a stack and special % * codes to manipulate it. Typically a sequence will push one * of the parameters onto the stack and then print it in some * format. Often more complex operations are necessary. * * The % encodings have the following meanings: * * %% outputs `%' * %c print pop() like %c in printf() * %s print pop() like %s in printf() * %[[:]flags][width[.precision]][doxXs] * as in printf, flags are [-+#] and space * The ':' is used to avoid making %+ or %- * patterns (see below). * * %p[1-9] push ith parm * %P[a-z] set dynamic variable [a-z] to pop() * %g[a-z] get dynamic variable [a-z] and push it * %P[A-Z] set static variable [A-Z] to pop() * %g[A-Z] get static variable [A-Z] and push it * %l push strlen(pop) * %'c' push char constant c * %{nn} push integer constant nn * * %+ %- %* %/ %m * arithmetic (%m is mod): push(pop() op pop()) * %& %| %^ bit operations: push(pop() op pop()) * %= %> %< logical operations: push(pop() op pop()) * %A %O logical and & or operations for conditionals * %! %~ unary operations push(op pop()) * %i add 1 to first two parms (for ANSI terminals) * * %? expr %t thenpart %e elsepart %; * if-then-else, %e elsepart is optional. * else-if's are possible ala Algol 68: * %? c1 %t b1 %e c2 %t b2 %e c3 %t b3 %e c4 %t b4 %e b5 %; * * For those of the above operators which are binary and not commutative, * the stack works in the usual way, with * %gx %gy %m * resulting in x mod y, not the reverse. */ #define STACKSIZE 20 typedef struct { union { unsigned int num; char *str; } data; bool num_type; } stack_frame; static stack_frame stack[STACKSIZE]; static int stack_ptr; #ifdef TRACE static const char *tname; #endif /* TRACE */ static char *out_buff; static size_t out_size; static size_t out_used; #if NO_LEAKS NCURSES_EXPORT(void) _nc_free_tparm(void) { if (out_buff != 0) { FreeAndNull(out_buff); out_size = 0; out_used = 0; } } #endif static void really_get_space(size_t need) { out_size = need * 2; out_buff = typeRealloc(char, out_size, out_buff); if (out_buff == 0) _nc_err_abort("Out of memory"); } static inline void get_space(size_t need) { need += out_used; if (need > out_size) really_get_space(need); } static inline void save_text(const char *fmt, const char *s, int len) { size_t s_len = strlen(s); if (len > (int) s_len) s_len = len; get_space(s_len + 1); (void) sprintf(out_buff + out_used, fmt, s); out_used += strlen(out_buff + out_used); } static inline void save_number(const char *fmt, int number, int len) { if (len < 30) len = 30; /* actually log10(MAX_INT)+1 */ get_space(len + 1); (void) sprintf(out_buff + out_used, fmt, number); out_used += strlen(out_buff + out_used); } static inline void save_char(int c) { if (c == 0) c = 0200; get_space(1); out_buff[out_used++] = c; } static inline void npush(int x) { if (stack_ptr < STACKSIZE) { stack[stack_ptr].num_type = TRUE; stack[stack_ptr].data.num = x; stack_ptr++; } } static inline int npop(void) { int result = 0; if (stack_ptr > 0) { stack_ptr--; if (stack[stack_ptr].num_type) result = stack[stack_ptr].data.num; } return result; } static inline void spush(char *x) { if (stack_ptr < STACKSIZE) { stack[stack_ptr].num_type = FALSE; stack[stack_ptr].data.str = x; stack_ptr++; } } static inline char * spop(void) { static char dummy[] = ""; /* avoid const-cast */ char *result = dummy; if (stack_ptr > 0) { stack_ptr--; if (!stack[stack_ptr].num_type && stack[stack_ptr].data.str != 0) result = stack[stack_ptr].data.str; } return result; } static inline const char * parse_format(const char *s, char *format, int *len) { bool done = FALSE; bool allowminus = FALSE; bool dot = FALSE; bool err = FALSE; char *fmt = format; int prec = 0; int width = 0; int value = 0; *len = 0; *format++ = '%'; while (*s != '\0' && !done) { switch (*s) { case 'c': /* FALLTHRU */ case 'd': /* FALLTHRU */ case 'o': /* FALLTHRU */ case 'x': /* FALLTHRU */ case 'X': /* FALLTHRU */ case 's': *format++ = *s; done = TRUE; break; case '.': *format++ = *s++; if (dot) { err = TRUE; } else { dot = TRUE; prec = value; } value = 0; break; case '#': *format++ = *s++; break; case ' ': *format++ = *s++; break; case ':': s++; allowminus = TRUE; break; case '-': if (allowminus) { *format++ = *s++; } else { done = TRUE; } break; default: if (isdigit(CharOf(*s))) { value = (value * 10) + (*s - '0'); if (value > 10000) err = TRUE; *format++ = *s++; } else { done = TRUE; } } } /* * If we found an error, ignore (and remove) the flags. */ if (err) { prec = width = value = 0; format = fmt; *format++ = '%'; *format++ = *s; } if (dot) width = value; else prec = value; *format = '\0'; /* return maximum string length in print */ *len = (prec > width) ? prec : width; return s; } #define isUPPER(c) ((c) >= 'A' && (c) <= 'Z') #define isLOWER(c) ((c) >= 'a' && (c) <= 'z') static inline char * tparam_internal(const char *string, va_list ap) { #define NUM_VARS 26 char *p_is_s[9]; int param[9]; int lastpop; int popcount; int number; int len; int level; int x, y; int i; size_t len2; register const char *cp; static size_t len_fmt; static char dummy[] = ""; static char *format; static int dynamic_var[NUM_VARS]; static int static_vars[NUM_VARS]; out_used = 0; if (string == NULL) return NULL; if ((len2 = strlen(string)) > len_fmt) { len_fmt = len2 + len_fmt + 2; if ((format = typeRealloc(char, len_fmt, format)) == 0) return 0; } /* * Find the highest parameter-number referred to in the format string. * Use this value to limit the number of arguments copied from the * variable-length argument list. */ number = 0; lastpop = -1; popcount = 0; memset(p_is_s, 0, sizeof(p_is_s)); /* * Analyze the string to see how many parameters we need from the varargs * list, and what their types are. We will only accept string parameters * if they appear as a %l or %s format following an explicit parameter * reference (e.g., %p2%s). All other parameters are numbers. * * 'number' counts coarsely the number of pop's we see in the string, and * 'popcount' shows the highest parameter number in the string. We would * like to simply use the latter count, but if we are reading termcap * strings, there may be cases that we cannot see the explicit parameter * numbers. */ for (cp = string; (cp - string) < (int) len2;) { if (*cp == '%') { cp++; cp = parse_format(cp, format, &len); switch (*cp) { default: break; case 'd': /* FALLTHRU */ case 'o': /* FALLTHRU */ case 'x': /* FALLTHRU */ case 'X': /* FALLTHRU */ case 'c': /* FALLTHRU */ number++; lastpop = -1; break; case 'l': case 's': if (lastpop > 0) p_is_s[lastpop - 1] = dummy; ++number; break; case 'p': cp++; i = (*cp - '0'); if (i >= 0 && i <= 9) { lastpop = i; if (lastpop > popcount) popcount = lastpop; } break; case 'P': case 'g': cp++; break; case S_QUOTE: cp += 2; lastpop = -1; break; case L_BRACE: cp++; while (*cp >= '0' && *cp <= '9') { cp++; } break; case '+': case '-': case '*': case '/': case 'm': case 'A': case 'O': case '&': case '|': case '^': case '=': case '<': case '>': case '!': case '~': lastpop = -1; number += 2; break; case 'i': lastpop = -1; if (popcount < 2) popcount = 2; break; } } if (*cp != '\0') cp++; } if (number > 9) number = 9; for (i = 0; i < max(popcount, number); i++) { /* * A few caps (such as plab_norm) have string-valued parms. * We'll have to assume that the caller knows the difference, since * a char* and an int may not be the same size on the stack. */ if (p_is_s[i] != 0) { p_is_s[i] = va_arg(ap, char *); } else { param[i] = va_arg(ap, int); } } /* * This is a termcap compatibility hack. If there are no explicit pop * operations in the string, load the stack in such a way that * successive pops will grab successive parameters. That will make * the expansion of (for example) \E[%d;%dH work correctly in termcap * style, which means tparam() will expand termcap strings OK. */ stack_ptr = 0; if (popcount == 0) { popcount = number; for (i = number - 1; i >= 0; i--) npush(param[i]); } #ifdef TRACE if (_nc_tracing & TRACE_CALLS) { for (i = 0; i < popcount; i++) { if (p_is_s[i] != 0) save_text(", %s", _nc_visbuf(p_is_s[i]), 0); else save_number(", %d", param[i], 0); } _tracef(T_CALLED("%s(%s%s)"), tname, _nc_visbuf(string), out_buff); out_used = 0; } #endif /* TRACE */ while (*string) { if (*string != '%') { save_char(*string); } else { string++; string = parse_format(string, format, &len); switch (*string) { default: break; case '%': save_char('%'); break; case 'd': /* FALLTHRU */ case 'o': /* FALLTHRU */ case 'x': /* FALLTHRU */ case 'X': /* FALLTHRU */ case 'c': /* FALLTHRU */ save_number(format, npop(), len); break; case 'l': save_number("%d", strlen(spop()), 0); break; case 's': save_text(format, spop(), len); break; case 'p': string++; i = (*string - '1'); if (i >= 0 && i < 9) { if (p_is_s[i]) spush(p_is_s[i]); else npush(param[i]); } break; case 'P': string++; if (isUPPER(*string)) { i = (*string - 'A'); static_vars[i] = npop(); } else if (isLOWER(*string)) { i = (*string - 'a'); dynamic_var[i] = npop(); } break; case 'g': string++; if (isUPPER(*string)) { i = (*string - 'A'); npush(static_vars[i]); } else if (isLOWER(*string)) { i = (*string - 'a'); npush(dynamic_var[i]); } break; case S_QUOTE: string++; npush(*string); string++; break; case L_BRACE: number = 0; string++; while (*string >= '0' && *string <= '9') { number = number * 10 + *string - '0'; string++; } npush(number); break; case '+': npush(npop() + npop()); break; case '-': y = npop(); x = npop(); npush(x - y); break; case '*': npush(npop() * npop()); break; case '/': y = npop(); x = npop(); npush(y ? (x / y) : 0); break; case 'm': y = npop(); x = npop(); npush(y ? (x % y) : 0); break; case 'A': npush(npop() && npop()); break; case 'O': npush(npop() || npop()); break; case '&': npush(npop() & npop()); break; case '|': npush(npop() | npop()); break; case '^': npush(npop() ^ npop()); break; case '=': y = npop(); x = npop(); npush(x == y); break; case '<': y = npop(); x = npop(); npush(x < y); break; case '>': y = npop(); x = npop(); npush(x > y); break; case '!': npush(!npop()); break; case '~': npush(~npop()); break; case 'i': if (p_is_s[0] == 0) param[0]++; if (p_is_s[1] == 0) param[1]++; break; case '?': break; case 't': x = npop(); if (!x) { /* scan forward for %e or %; at level zero */ string++; level = 0; while (*string) { if (*string == '%') { string++; if (*string == '?') level++; else if (*string == ';') { if (level > 0) level--; else break; } else if (*string == 'e' && level == 0) break; } if (*string) string++; } } break; case 'e': /* scan forward for a %; at level zero */ string++; level = 0; while (*string) { if (*string == '%') { string++; if (*string == '?') level++; else if (*string == ';') { if (level > 0) level--; else break; } } if (*string) string++; } break; case ';': break; } /* endswitch (*string) */ } /* endelse (*string == '%') */ if (*string == '\0') break; string++; } /* endwhile (*string) */ get_space(1); out_buff[out_used] = '\0'; T((T_RETURN("%s"), _nc_visbuf(out_buff))); return (out_buff); } NCURSES_EXPORT(char *) tparm (NCURSES_CONST char *string,...) { va_list ap; char *result; va_start(ap, string); #ifdef TRACE tname = "tparm"; #endif /* TRACE */ result = tparam_internal(string, ap); va_end(ap); return result; }