/************************************************************************* * * * YAP Prolog * * * * Yap Prolog was developed at NCCUP - Universidade do Porto * * * * Copyright L.Damas, V.S.Costa and Universidade do Porto 1985-1997 * * * ************************************************************************** * * * File: charcodes.c * * Last rev: 5/2/88 * * mods: * * comments: Character codes and character conversion * * * *************************************************************************/ #ifdef SCCS static char SccsId[] = "%W% %G%"; #endif /** * @file charsio.c * @author VITOR SANTOS COSTA * @date Thu Nov 19 11:37:16 2015 * @brief This file includes the definition of character-by-character related *IO. * * */ /* @defgroup CharIO Character-Based Input/Output * @ingroup InputOutput * * YAP implements most of the ISO-Prolog built-ins. Input/Output may be *performed on * the current stream or on a specified stream, and it may involve a: * + byte * + character code * + character atom * * Old-style operations, like get0/2 are still implemented. * * */ #include "Yap.h" #include "Yatom.h" #include "YapHeap.h" #include "YapText.h" #include "yapio.h" #include #if HAVE_UNISTD_H #include #endif #if HAVE_STDARG_H #include #endif #ifdef _WIN32 #if HAVE_IO_H /* Windows */ #include #endif #if HAVE_SOCKET #include #endif #include #ifndef S_ISDIR #define S_ISDIR(x) (((x)&_S_IFDIR) == _S_IFDIR) #endif #endif #include "iopreds.h" static Int get_code(USES_REGS1); static Int get_byte(USES_REGS1); // static Int past_eof( USES_REGS1); static Int put_code(USES_REGS1); static Int put_byte(USES_REGS1); static Int skip(USES_REGS1); static Int flush_output(USES_REGS1); static Int flush_all_streams(USES_REGS1); /** * CharOfAtom: convert an atom into a single character. * * @param at the atom * * @return the char . */ INLINE_ONLY inline EXTERN Int CharOfAtom(Atom at) { if (IsWideAtom(at)) { return at->WStrOfAE[0]; } else { return at->StrOfAE[0]; } } Int Yap_peek(int sno) { CACHE_REGS Int ocharcount, olinecount, olinepos; StreamDesc *s; uint32_t ch; s = GLOBAL_Stream + sno; #if USE_READLINE if (s->status & Readline_Stream_f && trueGlobalPrologFlag(READLINE_FLAG)) { ch = Yap_ReadlinePeekChar(sno); if (ch == EOFCHAR) { s->stream_getc = EOFPeek; s->stream_wgetc = EOFWPeek; s->status |= Push_Eof_Stream_f; } return ch; } #endif /* buffer the character */ if (s->encoding == Yap_SystemEncoding() && 0) { ch = fgetwc(s->file); ungetwc(ch, s->file); return ch; } else { ocharcount = s->charcount; olinecount = s->linecount; olinepos = s->linepos; ch = s->stream_wgetc(sno); if (ch == EOFCHAR) { s->stream_getc = EOFPeek; s->stream_wgetc = EOFWPeek; s->status |= Push_Eof_Stream_f; return ch; } } if (s->encoding == ENC_OCTET || s->encoding == ENC_ISO_LATIN1 || s->encoding == ENC_ISO_ASCII) { ungetc(ch, s->file); } else if (s->encoding == ENC_ISO_UTF8) { unsigned char cs[8]; size_t n = put_utf8(cs, ch); while (n--) { ungetc(cs[n], s->file); } } else if (s->encoding == ENC_UTF16_BE) { /* do the ungetc as if a write .. */ // computations if (ch < 0x10000) { ungetc(ch % 256, s->file); ungetc(ch / 256, s->file); } else { uint16_t lead = LEAD_OFFSET + (ch >> 10); uint16_t trail = 0xDC00 + (ch & 0x3FF); ungetc(lead % 256, s->file); ungetc(lead / 256, s->file); ungetc(trail % 256, s->file); ungetc(trail / 256, s->file); } } else if (s->encoding == ENC_UTF16_LE) { if (ch < 0x10000) { ungetc(ch / 256, s->file); ungetc(ch % 256, s->file); } else { uint16_t lead = LEAD_OFFSET + (ch >> 10); uint16_t trail = 0xDC00 + (ch & 0x3FF); ungetc(trail / 256, s->file); ungetc(trail % 256, s->file); ungetc(lead / 256, s->file); ungetc(lead % 256, s->file); } } else if (s->encoding == ENC_ISO_UTF32_LE) { ungetc((ch >> 24) & 0xff, s->file); ungetc((ch >> 16) & 0xff, s->file); ungetc((ch >> 8) & 0xff, s->file); ungetc(ch & 0xff, s->file); } else if (s->encoding == ENC_ISO_UTF32_BE) { ungetc(ch & 0xff, s->file); ungetc((ch >> 8) & 0xff, s->file); ungetc((ch >> 16) & 0xff, s->file); ungetc((ch >> 24) & 0xff, s->file); } else if (s->encoding == ENC_UCS2_BE) { /* do the ungetc as if a write .. */ // computations ungetc(ch % 256, s->file); ungetc(ch / 256, s->file); } else if (s->encoding == ENC_UCS2_LE) { ungetc(ch / 256, s->file); ungetc(ch % 256, s->file); } s->charcount = ocharcount; s->linecount = olinecount; s->linepos = olinepos; return ch; } static Int dopeek_byte(int sno) { Int ocharcount, olinecount, olinepos; StreamDesc *s; Int ch; s = GLOBAL_Stream + sno; ocharcount = s->charcount; olinecount = s->linecount; olinepos = s->linepos; ch = GLOBAL_Stream[sno].stream_getc(sno); s->charcount = ocharcount; s->linecount = olinecount; s->linepos = olinepos; /* buffer the character */ ungetc(ch, s->file); return ch; } bool store_code(int ch, Term t USES_REGS) { Term t2 = Deref(t); bool rc = Yap_unify_constant(t2, MkIntegerTerm(ch)); if (!rc && !IsVarTerm(t2)) { if (!IsIntegerTerm(t2)) { Yap_Error( TYPE_ERROR_INTEGER, t, "in output argument"); } else if (IntegerOfTerm(t2) < 0){ Yap_Error( REPRESENTATION_ERROR_IN_CHARACTER_CODE, t, "in output argument"); } } return rc; } /** @pred at_end_of_stream(+ _S_) is iso Succeed if the stream _S_ has stream position end-of-stream or past-end-of-stream. Note that _S_ must be a readable stream. */ static Int at_end_of_stream(USES_REGS1) { /* at_end_of_stream */ /* the next character is a EOF */ int sno = Yap_CheckStream(ARG1, Input_Stream_f, NULL); Int out; if (sno < 0) return (FALSE); out = GLOBAL_Stream[sno].status & Eof_Stream_f; if (!out) { if (GLOBAL_Stream[sno].status & Binary_Stream_f) { out = (dopeek_byte(sno) < 0); } else { out = (Yap_peek(sno) < 0); } } UNLOCK(GLOBAL_Stream[sno].streamlock); return out; } /** @pred at_end_of_stream is iso Succeed if the current stream has stream position end-of-stream or past-end-of-stream. */ static Int at_end_of_stream_0(USES_REGS1) { /* at_end_of_stream */ /* the next character is a EOF */ Int out; int sno = LOCAL_c_input_stream; out = GLOBAL_Stream[sno].status & Eof_Stream_f; if (!out) { out = (Yap_peek(sno) < 0); } UNLOCK(GLOBAL_Stream[sno].streamlock); return out; } static int yap_fflush(int sno) { #if USE_READLINE Yap_ReadlineFlush(sno); #endif if ((GLOBAL_Stream[sno].status & Output_Stream_f) && !(GLOBAL_Stream[sno].status & (Null_Stream_f | InMemory_Stream_f | Socket_Stream_f | Pipe_Stream_f | Free_Stream_f))) { return (fflush(GLOBAL_Stream[sno].file)); } else return (0); } /** @pred get(_S_, - _C_) The next non-blank character from the stream _S_ is unified with _C_. Blank characters are the ones whose ASCII codes are not greater than 32. If there are no more non-blank characters in the stream, _C_ is unified with -1. If `end_of_stream` has already been reached in the previous reading, this call will give an error message. */ static Int get(USES_REGS1) { /* '$get'(Stream,-N) */ int sno = Yap_CheckTextStream(ARG1, Input_Stream_f, "get/2"); int ch; // Int status; if (sno < 0) return FALSE; // status = GLOBAL_Stream[sno].status; while ((ch = GLOBAL_Stream[sno].stream_wgetc(sno)) <= 32 && ch >= 0) ; UNLOCK(GLOBAL_Stream[sno].streamlock); return store_code(ch, ARG2 PASS_REGS); } /** @pred get_char(+ _S_,- _C_) is iso If _C_ is unbound, or is an atom representation of a character, and the stream _S_ is a text stream, read the next character from that stream and unify its representation as an atom with _C_. */ static Int get_char(USES_REGS1) { /* '$get'(Stream,-N) */ int sno = Yap_CheckTextStream(ARG1, Input_Stream_f, "get/2"); int ch; // Int status; if (sno < 0) return false; // status = GLOBAL_Stream[sno].status; ch = GLOBAL_Stream[sno].stream_wgetc(sno); UNLOCK(GLOBAL_Stream[sno].streamlock); Term t2 = Deref(ARG2); bool rc = Yap_unify_constant(t2, MkCharTerm(ch)); if (!rc) { if (!IsAtomTerm(t2)) { Yap_Error( TYPE_ERROR_IN_CHARACTER, ARG2, "in input argument"); } } return rc; } /** @pred get_code(+ _S_,- _C_) is iso If _C_ is unbound, or is a character code, and the stream _S_ is a text stream, read the next character from that stream and unify its code with _C_. */ static Int get_code(USES_REGS1) { /* get0(Stream,-N) */ int sno = Yap_CheckTextStream(ARG1, Input_Stream_f, "get0/2"); // Int status; Int out; if (sno < 0) return (FALSE); // status = GLOBAL_Stream[sno].status; out = GLOBAL_Stream[sno].stream_wgetc(sno); UNLOCK(GLOBAL_Stream[sno].streamlock); return store_code(out, ARG2 PASS_REGS); } /** @pred get(- _C_) The next non-blank character from the current input stream is unified with _C_. Blank characters are the ones whose ASCII codes are not greater than 32. If there are no more non-blank characters in the stream, _C_ is unified with -1. If `end_of_stream` has already been reached in the previous reading, this call will give an error message. */ static Int get_1(USES_REGS1) { /* get_code1(Stream,-N) */ int sno = LOCAL_c_input_stream; int ch; // Int status; LOCK(GLOBAL_Stream[sno].streamlock); // status = GLOBAL_Stream[sno].status; if ((GLOBAL_Stream[sno].status & Binary_Stream_f)) { UNLOCK(GLOBAL_Stream[sno].streamlock); PlIOError(PERMISSION_ERROR_INPUT_BINARY_STREAM, TermUserIn, "while getting code"); return false; } while ((ch = GLOBAL_Stream[sno].stream_wgetc(sno)) <= 32 && ch >= 0) ; UNLOCK(GLOBAL_Stream[sno].streamlock); return store_code(ch, ARG1 PASS_REGS); } /** @pred get_code(- _C_) is iso If _C_ is unbound, or is the code for a character, and the current stream is a text stream, read the next character from the current stream and unify its code with _C_. */ static Int getcode_1(USES_REGS1) { /* get0(Stream,-N) */ int sno = LOCAL_c_input_stream; // Int status; Int out; // status = GLOBAL_Stream[sno].status; LOCK(GLOBAL_Stream[sno].streamlock); if ((GLOBAL_Stream[sno].status & Binary_Stream_f)) { UNLOCK(GLOBAL_Stream[sno].streamlock); PlIOError(PERMISSION_ERROR_INPUT_BINARY_STREAM, TermUserIn, "while getting code"); return false; } out = GLOBAL_Stream[sno].stream_wgetc(sno); UNLOCK(GLOBAL_Stream[sno].streamlock); return store_code(out, ARG1 PASS_REGS); } /** @pred get_char(- _C_) is iso If _C_ is unbound, or is an atom representation of a character, and the current stream is a text stream, read the next character from the current stream and unify its atom representation with _C_. */ static Int getchar_1(USES_REGS1) { /* get0(Stream,-N) */ int sno = LOCAL_c_input_stream; // Int status; Int ch; LOCK(GLOBAL_Stream[sno].streamlock); // status = GLOBAL_Stream[sno].status; ch = GLOBAL_Stream[sno].stream_wgetc(sno); if ((GLOBAL_Stream[sno].status & Binary_Stream_f)) { UNLOCK(GLOBAL_Stream[sno].streamlock); PlIOError(PERMISSION_ERROR_INPUT_BINARY_STREAM, TermUserIn, "while getting code"); return false; } UNLOCK(GLOBAL_Stream[sno].streamlock); bool rc = Yap_unify_constant(ARG1, MkCharTerm(ch)); if (!rc) { Term t2 = Deref(ARG1); if (!IsAtomTerm(t2)) { Yap_Error( TYPE_ERROR_IN_CHARACTER, ARG1, "in input argument"); } } return rc; } static Int get0_line_codes(USES_REGS1) { /* '$get0'(Stream,-N) */ int sno = Yap_CheckTextStream(ARG1, Input_Stream_f, "get0/2"); // Int status; Term out; Int ch = '\0'; int rewind; if (sno < 0) return (FALSE); rewind = FALSE; // status = GLOBAL_Stream[sno].status; out = read_line(sno); UNLOCK(GLOBAL_Stream[sno].streamlock); if (rewind) return Yap_unify(MkPairTerm(MkIntegerTerm(ch), out), ARG2); else return Yap_unify(out, ARG2); } /** @pred get_byte(+ _S_,- _C_) is iso If _C_ is unbound, or is a character code, and the stream _S_ is a binary stream, read the next byte from that stream and unify its code with _C_. */ static Int get_byte(USES_REGS1) { /* '$get_byte'(Stream,-N) */ int sno = Yap_CheckStream(ARG1, Input_Stream_f, "get_byte/2"); Int status; Term out; if (sno < 0) return (FALSE); status = GLOBAL_Stream[sno].status; if (!(status & Binary_Stream_f) //&& strictISOFlag() ) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_INPUT_STREAM, ARG1, "get_byte/2"); return (FALSE); } out = MkIntTerm(GLOBAL_Stream[sno].stream_getc(sno)); UNLOCK(GLOBAL_Stream[sno].streamlock); return Yap_unify_constant(ARG2, out); } /** @pred get_byte(- _C_) is iso If _C_ is unbound, or is a character code, and the current stream is a binary stream, read the next byte from the current stream and unify its code with _C_. */ static Int get_byte_1(USES_REGS1) { /* '$get_byte'(Stream,-N) */ int sno = LOCAL_c_input_stream; Int status; Term out; LOCK(GLOBAL_Stream[sno].streamlock); status = GLOBAL_Stream[sno].status; if (!(status & Binary_Stream_f) // &&strictISOFlag() ) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_INPUT_TEXT_STREAM, ARG1, "get_byte/1"); return (FALSE); } out = MkIntTerm(GLOBAL_Stream[sno].stream_getc(sno)); UNLOCK(GLOBAL_Stream[sno].streamlock); return Yap_unify_constant(ARG1, out); } /** @pred put_code(+ _N_) is iso Outputs to the current output stream the character whose ASCII code is _N_. The current output stream must be a text stream. The character _N_ must be a legal ASCII character code, an expression yielding such a code, or a list in which case only the first element is used. */ static Int put_code_1(USES_REGS1) { /* '$put'(,N) */ int sno = LOCAL_c_output_stream, ch; Term t2; if (IsVarTerm(t2 = Deref(ARG1))) { Yap_Error(INSTANTIATION_ERROR, t2, "put_code/1"); return FALSE; } else if (!IsIntegerTerm(t2)) { Yap_Error(TYPE_ERROR_INTEGER, t2, "put_code/1"); return FALSE; } else if ((ch = IntegerOfTerm(t2)) < -1) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, t2, "put_code/1"); return FALSE; } LOCK(GLOBAL_Stream[sno].streamlock); GLOBAL_Stream[sno].stream_wputc(sno, ch); /* * if (!(GLOBAL_Stream[sno].status & Null_Stream_f)) * yap_fflush(GLOBAL_Stream[sno].file); */ UNLOCK(GLOBAL_Stream[sno].streamlock); return (TRUE); } /** @pred put_code(+ _S_,+ _N_) is iso As `put_code(N)`, but to text stream _S_. */ static Int put_code(USES_REGS1) { /* '$put'(Stream,N) */ int ch; Term t2; int sno; if (IsVarTerm(t2 = Deref(ARG2))) { Yap_Error(INSTANTIATION_ERROR, t2, "put_code/1"); return FALSE; } else if (!IsIntegerTerm(t2)) { Yap_Error(TYPE_ERROR_INTEGER, t2, "put_code/1"); return FALSE; } else if ((ch = IntegerOfTerm(t2)) < -1) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, t2, "put_code/1"); return FALSE; } sno = Yap_CheckTextStream(ARG1, Output_Stream_f, "put/2"); if (sno < 0) return (FALSE); if (GLOBAL_Stream[sno].status & Binary_Stream_f) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_OUTPUT_TEXT_STREAM, ARG1, "put/2"); return (FALSE); } GLOBAL_Stream[sno].stream_wputc(sno, ch); /* * if (!(GLOBAL_Stream[sno].status & Null_Stream_f)) * yap_fflush(GLOBAL_Stream[sno].file); */ UNLOCK(GLOBAL_Stream[sno].streamlock); return (TRUE); } /** @pred put_char(+ _N_) is iso Outputs to the current output stream the character who is used to build the representation of atom `A`. The current output stream must be a text stream. */ static Int put_char_1(USES_REGS1) { /* '$put'(,N) */ int sno = LOCAL_c_output_stream; Term t2; int ch; if (IsVarTerm(t2 = Deref(ARG1))) { Yap_Error(INSTANTIATION_ERROR, t2, "put_char/1"); return FALSE; } else if (!IsAtomTerm(t2)) { Yap_Error(TYPE_ERROR_INTEGER, t2, "put_char/1"); return FALSE; } else if ((ch = CharOfAtom(AtomOfTerm(t2))) < -1) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, t2, "put_char/1"); return FALSE; } LOCK(GLOBAL_Stream[sno].streamlock); if (GLOBAL_Stream[sno].status & Binary_Stream_f) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_OUTPUT_TEXT_STREAM, ARG1, "put/2"); return (FALSE); } GLOBAL_Stream[sno].stream_wputc(sno, ch); /* * if (!(GLOBAL_Stream[sno].status & Null_Stream_f)) * yap_fflush(GLOBAL_Stream[sno].file); */ UNLOCK(GLOBAL_Stream[sno].streamlock); return (TRUE); } /** @pred put_char(+ _S_,+ _A_) is iso As `put_char(A)`, but to text stream _S_. */ static Int put_char(USES_REGS1) { /* '$put'(Stream,N) */ Term t2; int ch; int sno; if (IsVarTerm(t2 = Deref(ARG2))) { Yap_Error(INSTANTIATION_ERROR, t2, "put_char/1"); return FALSE; } else if (!IsAtomTerm(t2)) { Yap_Error(TYPE_ERROR_INTEGER, t2, "put_char/1"); return FALSE; } else if ((ch = CharOfAtom(AtomOfTerm(t2))) < -1) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, t2, "put_char/1"); return FALSE; } sno = Yap_CheckTextStream(ARG1, Output_Stream_f, "put/2"); if (sno < 0) return (FALSE); if (GLOBAL_Stream[sno].status & Binary_Stream_f) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_OUTPUT_TEXT_STREAM, ARG1, "put/2"); return (FALSE); } GLOBAL_Stream[sno].stream_wputc(sno, (int)IntegerOfTerm(Deref(ARG2))); /* * if (!(GLOBAL_Stream[sno].status & Null_Stream_f)) * yap_fflush(GLOBAL_Stream[sno].file); */ UNLOCK(GLOBAL_Stream[sno].streamlock); return (TRUE); } /** @pred tab_1(+ _N_) Outputs _N_ spaces to the current output stream. */ static Int tab_1(USES_REGS1) { /* nl */ int sno = LOCAL_c_output_stream; Term t2; Int tabs, i; if (IsVarTerm(t2 = Deref(ARG2))) { Yap_Error(INSTANTIATION_ERROR, t2, "put_char/1"); return FALSE; } else if (!IsIntegerTerm(t2)) { Yap_Error(TYPE_ERROR_INTEGER, t2, "put_char/1"); return FALSE; } else if ((tabs = IntegerOfTerm(t2)) < 0) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, t2, "tab/1"); return FALSE; } LOCK(GLOBAL_Stream[sno].streamlock); if (GLOBAL_Stream[sno].status & Binary_Stream_f) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_OUTPUT_TEXT_STREAM, ARG1, "nl/0"); return (FALSE); } for (i = 0; i < tabs; i++) GLOBAL_Stream[sno].stream_wputc(sno, ' '); /* * if (!(GLOBAL_Stream[sno].status & Null_Stream_f)) * yap_fflush(GLOBAL_Stream[sno].file); */ UNLOCK(GLOBAL_Stream[sno].streamlock); return (TRUE); } /** @pred tab(+ _S_,+ _N_) The same as tab/1, but using stream _S_. */ static Int tab(USES_REGS1) { /* nl(Stream) */ int sno; Term t2; Int tabs, i; if (IsVarTerm(t2 = Deref(ARG2))) { Yap_Error(INSTANTIATION_ERROR, t2, "put_char/1"); return FALSE; } else if (!IsIntegerTerm(t2)) { Yap_Error(TYPE_ERROR_INTEGER, t2, "put_char/1"); return FALSE; } else if ((tabs = IntegerOfTerm(t2)) < 0) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, t2, "tab/1"); return FALSE; } sno = Yap_CheckTextStream(ARG1, Output_Stream_f, "nl/1"); if (sno < 0) return (FALSE); if (GLOBAL_Stream[sno].status & Binary_Stream_f) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_OUTPUT_TEXT_STREAM, ARG1, "nl/0"); return (FALSE); } for (i = 0; i < tabs; i++) GLOBAL_Stream[sno].stream_wputc(sno, ' '); /* * if (!(GLOBAL_Stream[sno].status & Null_Stream_f)) * yap_fflush(GLOBAL_Stream[sno].file); */ UNLOCK(GLOBAL_Stream[sno].streamlock); return (TRUE); } /** @pred nl(+ _S_) is iso Outputs a new line to stream _S_. */ static Int nl_1(USES_REGS1) { /* nl */ int sno = LOCAL_c_output_stream; LOCK(GLOBAL_Stream[sno].streamlock); if (GLOBAL_Stream[sno].status & Binary_Stream_f) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_OUTPUT_BINARY_STREAM, ARG1, "nl/0"); return (FALSE); } GLOBAL_Stream[sno].stream_wputc(sno, 10); /* * if (!(GLOBAL_Stream[sno].status & Null_Stream_f)) * yap_fflush(GLOBAL_Stream[sno].file); */ UNLOCK(GLOBAL_Stream[sno].streamlock); return (TRUE); } /** @pred nl is iso Outputs a new line to the current output stream. */ static Int nl(USES_REGS1) { /* nl(Stream) */ int sno = Yap_CheckTextStream(ARG1, Output_Stream_f, "nl/1"); if (sno < 0) return (FALSE); if (GLOBAL_Stream[sno].status & Binary_Stream_f) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_OUTPUT_BINARY_STREAM, ARG1, "put/2"); return (FALSE); } GLOBAL_Stream[sno].stream_wputc(sno, 10); /* * if (!(GLOBAL_Stream[sno].status & Null_Stream_f)) * yap_fflush(GLOBAL_Stream[sno].file); */ UNLOCK(GLOBAL_Stream[sno].streamlock); return (TRUE); } /** @pred put_byte(+ _S_,+ _N_) is iso As `put_byte(N)`, but to binary stream _S_. */ static Int put_byte(USES_REGS1) { /* '$put_byte'(Stream,N) */ Term t2; Int ch; if (IsVarTerm(t2 = Deref(ARG2))) { Yap_Error(INSTANTIATION_ERROR, t2, "put_code/2"); return FALSE; } else if (!IsIntegerTerm(t2)) { Yap_Error(TYPE_ERROR_BYTE, t2, "put_code/2"); return FALSE; } else if ((ch = IntegerOfTerm(t2)) < -1) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, t2, "put_code/1"); return FALSE; } int sno = Yap_CheckStream(ARG1, Output_Stream_f, "put/2"); if (sno < 0) return (FALSE); if (!(GLOBAL_Stream[sno].status & Binary_Stream_f) // && strictISOFlag() ) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_OUTPUT_BINARY_STREAM, ARG1, NULL); return false; } GLOBAL_Stream[sno].stream_putc(sno, ch); /* * if (!(GLOBAL_Stream[sno].status & Null_Stream_f)) * yap_fflush(GLOBAL_Stream[sno].file); */ UNLOCK(GLOBAL_Stream[sno].streamlock); return (TRUE); } /** @pred put_byte(+ _N_) is iso Outputs to the current output stream the character whose code is _N_. The current output stream must be a binary stream. */ static Int put_byte_1(USES_REGS1) { /* '$put_byte'(Stream,N) */ Term t2; Int ch; int sno = LOCAL_c_output_stream; if (IsVarTerm(t2 = Deref(ARG1))) { Yap_Error(INSTANTIATION_ERROR, t2, "put_code/1"); return FALSE; } else if (!IsIntegerTerm(t2)) { Yap_Error(TYPE_ERROR_BYTE, t2, "put_code/1"); return FALSE; } else if ((ch = IntegerOfTerm(t2)) < -1) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, t2, "put_code/1"); return FALSE; } LOCK(GLOBAL_Stream[sno].streamlock); if (!(GLOBAL_Stream[sno].status & Binary_Stream_f) //&& strictISOFlag() ) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_OUTPUT_BINARY_STREAM, ARG1, "get0/2"); return (FALSE); } GLOBAL_Stream[sno].stream_putc(sno, ch); UNLOCK(GLOBAL_Stream[sno].streamlock); return (TRUE); } /** @pred skip(+ _N_) Skips input characters until the next occurrence of the character with ASCII code _N_. The argument to this predicate can take the same forms as those for `put` (see 6.11). */ static Int skip_1(USES_REGS1) { /* 'skip'(N) */ Int n; Term t2; int sno; int ch; if (IsVarTerm(t2 = Deref(ARG2))) { Yap_Error(INSTANTIATION_ERROR, t2, "skip/2"); return FALSE; } else if (!IsIntegerTerm(t2)) { Yap_Error(TYPE_ERROR_INTEGER, t2, "skip/2"); return FALSE; } else if ((n = IntegerOfTerm(t2)) < 0) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, t2, "skip/2"); return FALSE; } sno = Yap_CheckTextStream(ARG1, Input_Stream_f, "skip/2"); if (sno < 0) return (FALSE); while ((ch = GLOBAL_Stream[sno].stream_wgetc(sno)) != n && ch != -1) ; UNLOCK(GLOBAL_Stream[sno].streamlock); return (TRUE); } /** @pred skip(+ _S_,- _C_) Like skip/1, but using stream _S_ instead of the current input stream. */ static Int skip(USES_REGS1) { /* '$skip'(Stream,N) */ Int n; Term t2; int sno = Yap_CheckTextStream(ARG1, Input_Stream_f, "skip/2"); int ch; if (sno < 0) return (FALSE); if (IsVarTerm(t2 = Deref(ARG2))) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(INSTANTIATION_ERROR, t2, "skip/2"); return FALSE; } else if (!IsIntegerTerm(t2)) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(TYPE_ERROR_INTEGER, t2, "skip/2"); return FALSE; } else if ((n = IntegerOfTerm(t2)) < 0) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, t2, "skip/2"); return FALSE; } while ((ch = GLOBAL_Stream[sno].stream_wgetc(sno)) != n && ch != -1) ; UNLOCK(GLOBAL_Stream[sno].streamlock); return (TRUE); } /** * @pred flush_output(+Stream) * * Flush the stream _Stream_, that is, make sure all pending output is committed * before any further execution. * * @param +_Stream_ * */ static Int flush_output(USES_REGS1) { /* flush_output(Stream) */ int sno = Yap_CheckStream(ARG1, Output_Stream_f, "flush_output/1"); if (sno < 0) { UNLOCK(GLOBAL_Stream[sno].streamlock); return (FALSE); } yap_fflush(sno); UNLOCK(GLOBAL_Stream[sno].streamlock); return (TRUE); } /** * @pred flush_output * * Flush the current output stream, that is, make sure all pending output is *committed * before any further execution. By default this is user_output, but it may be * changed by current_output/1. * */ static Int flush_output0(USES_REGS1) { /* flush_output */ yap_fflush(LOCAL_c_output_stream); return (TRUE); } static Int flush_all_streams(USES_REGS1) { /* $flush_all_streams */ #if BROKEN_FFLUSH_NULL int i; for (i = 0; i < MaxStreams; ++i) { LOCK(GLOBAL_Stream[i].streamlock); yap_fflush(i); UNLOCK(GLOBAL_Stream[i].streamlock); } #else fflush(NULL); #endif return TRUE; } /** @pred peek_code(+ _S_, - _C_) is iso If _C_ is unbound, or is the code for a character, and the stream _S_ is a text stream, read the next character from the current stream and unify its code with _C_, while leaving the current stream position unaltered. */ static Int peek_code(USES_REGS1) { /* at_end_of_stream */ /* the next character is a EOF */ int sno = Yap_CheckTextStream(ARG1, Input_Stream_f, "peek/2"); Int ch; if (sno < 0) return FALSE; if (GLOBAL_Stream[sno].status & Binary_Stream_f) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_INPUT_TEXT_STREAM, ARG1, "peek_code/2"); return FALSE; } if ((ch = Yap_peek(sno)) < 0) { #ifdef PEEK_EOF UNLOCK(GLOBAL_Stream[sno].streamlock); return false; #endif } UNLOCK(GLOBAL_Stream[sno].streamlock); return (Yap_unify_constant(ARG2, MkIntTerm(ch))); } /** @pred peek_code( - _C_) is iso If _C_ is unbound, or is the code for a character, and the current input stream is a text stream, read the next character from the current stream and unify its code with _C_, while leaving the current stream position unaltered. */ static Int peek_code_1(USES_REGS1) { /* at_end_of_stream */ /* the next character is a EOF */ int sno = LOCAL_c_input_stream; Int ch; LOCK(GLOBAL_Stream[sno].streamlock); if (GLOBAL_Stream[sno].status & Binary_Stream_f) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_INPUT_TEXT_STREAM, ARG1, "peek_code/2"); return FALSE; } if ((ch = Yap_peek(sno)) < 0) { #ifdef PEEK_EOF UNLOCK(GLOBAL_Stream[sno].streamlock); return false; #endif } UNLOCK(GLOBAL_Stream[sno].streamlock); return (Yap_unify_constant(ARG1, MkIntTerm(ch))); } /** @pred peek_byte(+Stream, - _C_) is iso If _C_ is unbound, or is a character code, and _Stream_ is a binary stream, read the next byte from the current stream and unify its code with _C_, while leaving the current stream position unaltered. */ static Int peek_byte(USES_REGS1) { /* at_end_of_stream */ /* the next character is a EOF */ int sno = Yap_CheckStream(ARG1, Input_Stream_f, "peek_byte/2"); Int ch; if (sno < 0) return (FALSE); if (!(GLOBAL_Stream[sno].status & Binary_Stream_f)) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_INPUT_BINARY_STREAM, ARG1, "peek_byte/2"); return (FALSE); } if ((ch = dopeek_byte(sno)) < 0) { #ifdef PEEK_EOF UNLOCK(GLOBAL_Stream[sno].streamlock); return false; #endif } UNLOCK(GLOBAL_Stream[sno].streamlock); return (Yap_unify_constant(ARG2, MkIntTerm(ch))); } /** @pred peek_byte( - _C_) is iso If _C_ is unbound, or is a character code, and _Stream_ is a binary stream, read the next byte from the current stream and unify its code with _C_, while leaving the current stream position unaltered. */ static Int peek_byte_1(USES_REGS1) { /* at_end_of_stream */ /* the next character is a EOF */ int sno = LOCAL_c_input_stream; Int ch; if (sno < 0) return (FALSE); LOCK(GLOBAL_Stream[sno].streamlock); if (!(GLOBAL_Stream[sno].status & Binary_Stream_f)) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_INPUT_BINARY_STREAM, ARG1, "peek_byte/2"); return (FALSE); } if ((ch = dopeek_byte(sno)) < 0) { #ifdef PEEK_EOF UNLOCK(GLOBAL_Stream[sno].streamlock); return false; #endif } UNLOCK(GLOBAL_Stream[sno].streamlock); return (Yap_unify_constant(ARG2, MkIntTerm(ch))); } /** @pred peek_char(+_S_, - _C_) is iso If _C_ is unbound, or is a character code, and the stream _S_ is a binary stream, read the next byte from the current stream and unify the atom with _C_, while leaving the stream position unaltered. */ static Int peek_char(USES_REGS1) { /* the next character is a EOF */ int sno = Yap_CheckTextStream(ARG1, Input_Stream_f, "peek/2"); wchar_t wsinp[2]; Int ch; if (sno < 0) return false; if ((GLOBAL_Stream[sno].status & Binary_Stream_f)) { UNLOCK(GLOBAL_Stream[sno].streamlock); Yap_Error(PERMISSION_ERROR_INPUT_TEXT_STREAM, ARG1, "peek_byte/2"); return (FALSE); } if ((ch = Yap_peek(sno)) < 0) { UNLOCK(GLOBAL_Stream[sno].streamlock); return Yap_unify_constant(ARG2, MkAtomTerm(AtomEof)); } UNLOCK(GLOBAL_Stream[sno].streamlock); wsinp[1] = '\0'; wsinp[0] = ch; return Yap_unify_constant(ARG2, MkAtomTerm(Yap_LookupMaybeWideAtom(wsinp))); } /** @pred peek_char( - _C_) is iso If _C_ is unbound, or is a character code, and the current input stream is a binary stream, read the next byte from the current stream and unify the atom with _C_, while leaving the stream position unaltered. */ static Int peek_char_1(USES_REGS1) { /* the next character is a EOF */ int sno = LOCAL_c_input_stream; wchar_t wsinp[2]; Int ch; LOCK(GLOBAL_Stream[sno].streamlock); if ((ch = Yap_peek(sno)) < 0) { UNLOCK(GLOBAL_Stream[sno].streamlock); return Yap_unify_constant(ARG2, MkAtomTerm(AtomEof)); // return false; } UNLOCK(GLOBAL_Stream[sno].streamlock); wsinp[1] = '\0'; wsinp[0] = ch; return Yap_unify_constant(ARG2, MkAtomTerm(Yap_LookupMaybeWideAtom(wsinp))); } /** @pred peek(+ _S_, - _C_) is deprecated If _C_ is unbound, or is the code for a character, and the stream _S_ is a text stream, read the next character from the current stream and unify its code with _C_, while leaving the current stream position unaltered. Please use the ISO built-in peek_code/2. */ /** @pred peek( - _C_) is iso If _C_ is unbound, or is the code for a character, and the currrent input stream is a text stream, read the next character from the current stream and unify its code with _C_, while leaving the current stream position unaltered. */ void Yap_flush(void) { CACHE_REGS(void) flush_all_streams(PASS_REGS1); } void Yap_FlushStreams(void) { CACHE_REGS(void) flush_all_streams(PASS_REGS1); } void Yap_InitCharsio(void) { Yap_InitCPred("get", 2, get, SafePredFlag | SyncPredFlag); Yap_InitCPred("get_code", 2, get_code, SafePredFlag | SyncPredFlag); Yap_InitCPred("get_char", 2, get_char, SafePredFlag | SyncPredFlag); Yap_InitCPred("get0", 2, get_code, SafePredFlag | SyncPredFlag); Yap_InitCPred("get", 1, get_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("get_code", 1, getcode_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("get_char", 1, getchar_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("get0", 1, getcode_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("$get0_line_codes", 2, get0_line_codes, SafePredFlag | SyncPredFlag | HiddenPredFlag); Yap_InitCPred("get_byte", 2, get_byte, SafePredFlag | SyncPredFlag); Yap_InitCPred("get_byte", 1, get_byte_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("put", 1, put_code_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("put", 2, put_code, SafePredFlag | SyncPredFlag); Yap_InitCPred("put_code", 1, put_code_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("put_code", 2, put_code, SafePredFlag | SyncPredFlag); Yap_InitCPred("put_char", 1, put_char_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("put_char", 2, put_char, SafePredFlag | SyncPredFlag); Yap_InitCPred("put_byte", 2, put_byte, SafePredFlag | SyncPredFlag); Yap_InitCPred("put_byte", 1, put_byte_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("put_char", 2, put_char, SafePredFlag | SyncPredFlag); Yap_InitCPred("put_char1", 1, put_char_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("tab", 2, tab, SafePredFlag | SyncPredFlag); Yap_InitCPred("tab1", 1, tab_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("nl", 0, nl_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("nl", 1, nl, SafePredFlag | SyncPredFlag); Yap_InitCPred("$flush_all_streams", 0, flush_all_streams, SafePredFlag | SyncPredFlag | HiddenPredFlag); Yap_InitCPred("flush_output", 1, flush_output, SafePredFlag | SyncPredFlag); Yap_InitCPred("flush_output", 0, flush_output0, SafePredFlag | SyncPredFlag); Yap_InitCPred("at_end_of_stream", 1, at_end_of_stream, SafePredFlag | SyncPredFlag); Yap_InitCPred("at_end_of_stream_0", 0, at_end_of_stream_0, SafePredFlag | SyncPredFlag); // Yap_InitCPred ("$past_eof", 1, past_eof, SafePredFlag|SyncPredFlag); Yap_InitCPred("peek", 2, peek_code, SafePredFlag | SyncPredFlag); Yap_InitCPred("peek_code", 2, peek_code, SafePredFlag | SyncPredFlag); Yap_InitCPred("peek_char", 2, peek_char, SafePredFlag | SyncPredFlag); Yap_InitCPred("peek_byte", 2, peek_byte, SafePredFlag | SyncPredFlag); Yap_InitCPred("peek", 1, peek_code_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("peek_code", 1, peek_code_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("peek_char", 1, peek_char_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("peek_byte", 1, peek_byte_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("skip", 2, skip, SafePredFlag | SyncPredFlag); Yap_InitCPred("skip1", 1, skip_1, SafePredFlag | SyncPredFlag); Yap_InitCPred("tab", 2, tab, SafePredFlag | SyncPredFlag); Yap_InitCPred("tab1", 1, tab_1, SafePredFlag | SyncPredFlag); }