/* $Id$ Part of SWI-Prolog Author: Jan Wielemaker E-mail: wielemak@science.uva.nl WWW: http://www.swi-prolog.org Copyright (C): 1985-2008, University of Amsterdam This library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this library; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - This module is far too big. It defines a layer around open(), etc. to get opening and closing of files to the symbolic level required for Prolog. It also defines basic I/O predicates, stream based I/O and finally a bundle of operations on files, such as name expansion, renaming, deleting, etc. Most of this module is rather straightforward. If time is there I will have a look at all this to clean it. Notably handling times must be cleaned, but that not only holds for this module. - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ /*#define O_DEBUG 1*/ /*#define O_DEBUG_MT 1*/ #include "pl-incl.h" #include "pl-ctype.h" #include "pl-utf8.h" #include #ifdef HAVE_SYS_SELECT_H #include #endif #ifdef HAVE_SYS_TIME_H #include #endif #ifdef HAVE_SYS_PARAM_H #include #endif #ifdef HAVE_SYS_FILE_H #include #endif #ifdef HAVE_UNISTD_H #include #endif #ifdef HAVE_BSTRING_H #include #endif #ifdef HAVE_SYS_STAT_H #include #endif #define LOCK() PL_LOCK(L_FILE) /* MT locking */ #define UNLOCK() PL_UNLOCK(L_FILE) #undef LD /* fetch LD once per function */ #define LD LOCAL_LD static int bad_encoding(atom_t name); static int noprotocol(void); static int streamStatus(IOSTREAM *s); #if __YAP_PROLOG__ INIT_DEF(atom_t, standardStreams, 6) ADD_STDSTREAM(ATOM_user_input) /* 0 */ ADD_STDSTREAM(ATOM_user_output) /* 1 */ ADD_STDSTREAM(ATOM_user_error) /* 2 */ ADD_STDSTREAM(ATOM_current_input) /* 3 */ ADD_STDSTREAM(ATOM_current_output) /* 4 */ ADD_STDSTREAM(ATOM_protocol) /* 5 */ END_STDSTREAMS(NULL_ATOM) #else #endif static int standardStreamIndexFromName(atom_t name) { const atom_t *ap; for(ap=standardStreams; *ap; ap++) { if ( *ap == name ) return (int)(ap - standardStreams); } return -1; } static int standardStreamIndexFromStream(IOSTREAM *s) { GET_LD IOSTREAM **sp = LD->IO.streams; int i = 0; for( ; i<6; i++, sp++ ) { if ( *sp == s ) return i; } return -1; } /******************************* * BOOKKEEPING * *******************************/ static void aliasStream(IOSTREAM *s, atom_t alias); static void unaliasStream(IOSTREAM *s, atom_t name); static Table streamAliases; /* alias --> stream */ static Table streamContext; /* stream --> extra data */ typedef struct _alias { struct _alias *next; atom_t name; } alias; #define IO_TELL 0x001 /* opened by tell/1 */ #define IO_SEE 0x002 /* opened by see/1 */ typedef struct { alias *alias_head; alias *alias_tail; atom_t filename; /* associated filename */ unsigned flags; } stream_context; static stream_context * getStreamContext(IOSTREAM *s) { Symbol symb; if ( !(symb = lookupHTable(streamContext, s)) ) { GET_LD stream_context *ctx = allocHeap(sizeof(*ctx)); DEBUG(1, Sdprintf("Created ctx=%p for stream %p\n", ctx, s)); ctx->alias_head = ctx->alias_tail = NULL; ctx->filename = NULL_ATOM; ctx->flags = 0; addHTable(streamContext, s, ctx); return ctx; } return symb->value; } void aliasStream(IOSTREAM *s, atom_t name) { GET_LD stream_context *ctx; Symbol symb; alias *a; /* ensure name is free (error?) */ if ( (symb = lookupHTable(streamAliases, (void *)name)) ) unaliasStream(symb->value, name); ctx = getStreamContext(s); addHTable(streamAliases, (void *)name, s); PL_register_atom(name); a = allocHeap(sizeof(*a)); a->next = NULL; a->name = name; if ( ctx->alias_tail ) { ctx->alias_tail->next = a; ctx->alias_tail = a; } else { ctx->alias_head = ctx->alias_tail = a; } } /* MT: Locked by freeStream() */ static void unaliasStream(IOSTREAM *s, atom_t name) { GET_LD Symbol symb; if ( name ) { if ( (symb = lookupHTable(streamAliases, (void *)name)) ) { deleteSymbolHTable(streamAliases, symb); if ( (symb=lookupHTable(streamContext, s)) ) { stream_context *ctx = symb->value; alias **a; for(a = &ctx->alias_head; *a; a = &(*a)->next) { if ( (*a)->name == name ) { alias *tmp = *a; *a = tmp->next; freeHeap(tmp, sizeof(*tmp)); if ( tmp == ctx->alias_tail ) ctx->alias_tail = NULL; break; } } } PL_unregister_atom(name); } } else /* delete them all */ { if ( (symb=lookupHTable(streamContext, s)) ) { stream_context *ctx = symb->value; alias *a, *n; for(a = ctx->alias_head; a; a=n) { Symbol s2; n = a->next; if ( (s2 = lookupHTable(streamAliases, (void *)a->name)) ) { deleteSymbolHTable(streamAliases, s2); PL_unregister_atom(a->name); } freeHeap(a, sizeof(*a)); } ctx->alias_head = ctx->alias_tail = NULL; } } } static void freeStream(IOSTREAM *s) { GET_LD Symbol symb; int i; IOSTREAM **sp; DEBUG(1, Sdprintf("freeStream(%p)\n", s)); LOCK(); unaliasStream(s, NULL_ATOM); if ( (symb=lookupHTable(streamContext, s)) ) { stream_context *ctx = symb->value; if ( ctx->filename == source_file_name ) { source_file_name = NULL_ATOM; /* TBD: pop? */ source_line_no = -1; } freeHeap(ctx, sizeof(*ctx)); deleteSymbolHTable(streamContext, symb); } /* if we are a standard stream */ /* reassociate with standard I/O */ /* NOTE: there may be more! */ for(i=0, sp = LD->IO.streams; i<6; i++, sp++) { if ( *sp == s ) { if ( s->flags & SIO_INPUT ) *sp = Sinput; else if ( sp == &Suser_error ) *sp = Serror; else if ( sp == &Sprotocol ) *sp = NULL; else *sp = Soutput; } } UNLOCK(); } /* MT: locked by caller (openStream()) */ static void setFileNameStream(IOSTREAM *s, atom_t name) { getStreamContext(s)->filename = name; } static atom_t fileNameStream(IOSTREAM *s) { atom_t name; LOCK(); name = getStreamContext(s)->filename; UNLOCK(); return name; } #if __YAP_PROLOG__ static void init_yap_extras(void); #endif void initIO() { GET_LD const atom_t *np; int i; #if __YAP_PROLOG__ init_yap_extras(); #endif streamAliases = newHTable(16); streamContext = newHTable(16); #ifdef __unix__ { int fd; if ( (fd=Sfileno(Sinput)) < 0 || !isatty(fd) || (fd=Sfileno(Soutput)) < 0 || !isatty(fd) ) PL_set_prolog_flag("tty_control", PL_BOOL, FALSE); } #endif ResetTty(); Sclosehook(freeStream); Sinput->position = &Sinput->posbuf; /* position logging */ Soutput->position = &Sinput->posbuf; Serror->position = &Sinput->posbuf; ttymode = TTY_COOKED; PushTty(Sinput, &ttytab, TTY_SAVE); LD->prompt.current = ATOM_prompt; PL_register_atom(ATOM_prompt); Suser_input = Sinput; Suser_output = Soutput; Suser_error = Serror; Scurin = Sinput; /* see/tell */ Scurout = Soutput; Sprotocol = NULL; /* protocolling */ getStreamContext(Sinput); /* add for enumeration */ getStreamContext(Soutput); getStreamContext(Serror); for( i=0, np = standardStreams; *np; np++, i++ ) addHTable(streamAliases, (void *)*np, (void *)(intptr_t)i); GD->io_initialised = TRUE; } /******************************* * GET HANDLES * *******************************/ #ifdef O_PLMT static inline IOSTREAM * getStream(IOSTREAM *s) { if ( s && s->magic == SIO_MAGIC ) /* TBD: ensure visibility? */ { Slock(s); return s; } return NULL; } static inline IOSTREAM * tryGetStream(IOSTREAM *s) { if ( s && s->magic == SIO_MAGIC && StryLock(s) == 0 ) return s; return NULL; } static inline void releaseStream(IOSTREAM *s) { if ( s->magic == SIO_MAGIC ) Sunlock(s); } #else /*O_PLMT*/ #define getStream(s) (s) #define tryGetStream(s) (s) #define releaseStream(s) #endif /*O_PLMT*/ int PL_release_stream(IOSTREAM *s) { if ( Sferror(s) ) return streamStatus(s); releaseStream(s); return TRUE; } #define SH_ERRORS 0x01 /* generate errors */ #define SH_ALIAS 0x02 /* allow alias */ #define SH_UNLOCKED 0x04 /* don't lock the stream */ #define SH_SAFE 0x08 /* Lookup in table */ static int get_stream_handle__LD(term_t t, IOSTREAM **s, int flags ARG_LD) { atom_t alias; if ( PL_is_functor(t, FUNCTOR_dstream1) ) { void *p; term_t a = PL_new_term_ref(); _PL_get_arg(1, t, a); if ( PL_get_pointer(a, &p) ) { if ( flags & SH_SAFE ) { Symbol symb; LOCK(); symb = lookupHTable(streamContext, p); UNLOCK(); if ( !symb ) goto noent; } if ( flags & SH_UNLOCKED ) { if ( ((IOSTREAM *)p)->magic == SIO_MAGIC ) { *s = p; return TRUE; } goto noent; } if ( (*s = getStream(p)) ) return TRUE; goto noent; } } else if ( PL_get_atom(t, &alias) ) { Symbol symb; if ( !(flags & SH_UNLOCKED) ) LOCK(); if ( (symb=lookupHTable(streamAliases, (void *)alias)) ) { IOSTREAM *stream; uintptr_t n = (uintptr_t)symb->value; if ( n < 6 ) /* standard stream! */ { stream = LD->IO.streams[n]; } else stream = symb->value; if ( !(flags & SH_UNLOCKED) ) UNLOCK(); if ( stream ) { if ( (flags & SH_UNLOCKED) ) { if ( stream->magic == SIO_MAGIC ) { *s = stream; return TRUE; } } else if ( (*s = getStream(stream)) ) return TRUE; goto noent; } } if ( !(flags & SH_UNLOCKED) ) UNLOCK(); goto noent; } if ( flags & SH_ERRORS ) return PL_error(NULL, 0, NULL, ERR_DOMAIN, (flags&SH_ALIAS) ? ATOM_stream_or_alias : ATOM_stream, t); return FALSE; noent: if ( flags & SH_ERRORS ) PL_error(NULL, 0, NULL, ERR_EXISTENCE, ATOM_stream, t); return FALSE; } #define get_stream_handle(t, sp, flags) \ get_stream_handle__LD(t, sp, flags PASS_LD) int PL_get_stream_handle(term_t t, IOSTREAM **s) { GET_LD return get_stream_handle(t, s, SH_ERRORS|SH_ALIAS); } int PL_unify_stream_or_alias(term_t t, IOSTREAM *s) { GET_LD int rval; stream_context *ctx; int i; if ( (i=standardStreamIndexFromStream(s)) >= 0 && i < 3 ) return PL_unify_atom(t, standardStreams[i]); LOCK(); ctx = getStreamContext(s); if ( ctx->alias_head ) { rval = PL_unify_atom(t, ctx->alias_head->name); } else { term_t a = PL_new_term_ref(); PL_put_pointer(a, s); PL_cons_functor(a, FUNCTOR_dstream1, a); rval = PL_unify(t, a); } UNLOCK(); return rval; } int PL_unify_stream(term_t t, IOSTREAM *s) { GET_LD stream_context *ctx; term_t a = PL_new_term_ref(); LOCK(); ctx = getStreamContext(s); UNLOCK(); PL_put_pointer(a, s); PL_cons_functor(a, FUNCTOR_dstream1, a); if ( PL_unify(t, a) ) return TRUE; if ( PL_is_functor(t, FUNCTOR_dstream1) ) return FALSE; return PL_error(NULL, 0, NULL, ERR_DOMAIN, ATOM_stream, t); } IOSTREAM ** /* provide access to Suser_input, */ _PL_streams(void) /* Suser_output and Suser_error */ { GET_LD return &Suser_input; } /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - getInputStream(term_t t, IOSTREAM **s) getOutputStream(term_t t, IOSTREAM **s) These functions are the basis used by all Prolog predicates to get a input or output stream handle. If t = 0, current input/output is returned. This allows us to define the standard-stream based version simply by calling the explicit stream-based version with 0 for the stream argument. MT: The returned stream is always locked and should be returned using releaseStream() or streamStatus(). - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ static int getOutputStream(term_t t, IOSTREAM **stream) { GET_LD atom_t a; IOSTREAM *s; if ( t == 0 ) { *stream = getStream(Scurout); return TRUE; } else if ( PL_get_atom(t, &a) && a == ATOM_user ) { *stream = getStream(Suser_output); return TRUE; } else { *stream = NULL; /* make compiler happy */ } if ( !PL_get_stream_handle(t, &s) ) return FALSE; if ( !(s->flags &SIO_OUTPUT) ) { releaseStream(s); return PL_error(NULL, 0, NULL, ERR_PERMISSION, ATOM_output, ATOM_stream, t); } *stream = s; return TRUE; } static int getInputStream__LD(term_t t, IOSTREAM **stream ARG_LD) { atom_t a; IOSTREAM *s; if ( t == 0 ) { *stream = getStream(Scurin); return TRUE; } else if ( PL_get_atom(t, &a) && a == ATOM_user ) { *stream = getStream(Suser_input); return TRUE; } else { *stream = NULL; /* make compiler happy */ } if ( !get_stream_handle(t, &s, SH_ERRORS|SH_ALIAS) ) return FALSE; if ( !(s->flags &SIO_INPUT) ) { releaseStream(s); return PL_error(NULL, 0, NULL, ERR_PERMISSION, ATOM_input, ATOM_stream, t); } *stream = s; return TRUE; } /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - In windows GUI applications, the IO-streams are not bound. We do not wish to generate an error on the stream errors that may be caused by this. It is a bit of a hack, but the alternative is to define a stream that ignores the error. This might get hairy if the user is playing with these streams too. - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ #if defined(__WINDOWS__) || defined(__MINGW32__) static int isConsoleStream(IOSTREAM *s) { int i = standardStreamIndexFromStream(s); return i >= 0 && i < 3; } #else #define isConsoleStream(s) FALSE #endif int reportStreamError(IOSTREAM *s) { if ( GD->cleaning == CLN_NORMAL && !isConsoleStream(s) && (s->flags & (SIO_FERR|SIO_WARN)) ) { GET_LD atom_t op; term_t stream = PL_new_term_ref(); char *msg; PL_unify_stream_or_alias(stream, s); if ( (s->flags & SIO_FERR) ) { if ( s->exception ) { fid_t fid = PL_open_foreign_frame(); term_t ex = PL_new_term_ref(); PL_recorded(s->exception, ex); PL_erase(s->exception); s->exception = NULL; PL_raise_exception(ex); PL_close_foreign_frame(fid); return FALSE; } if ( s->flags & SIO_INPUT ) { if ( Sfpasteof(s) ) { return PL_error(NULL, 0, NULL, ERR_PERMISSION, ATOM_input, ATOM_past_end_of_stream, stream); } else if ( (s->flags & SIO_TIMEOUT) ) { PL_error(NULL, 0, NULL, ERR_TIMEOUT, ATOM_read, stream); Sclearerr(s); return FALSE; } else op = ATOM_read; } else op = ATOM_write; if ( s->message ) { msg = s->message; } else { msg = MSG_ERRNO; if ( s->io_errno ) errno = s->io_errno; } PL_error(NULL, 0, msg, ERR_STREAM_OP, op, stream); if ( (s->flags & SIO_CLEARERR) ) Sseterr(s, SIO_FERR, NULL); return FALSE; } else { printMessage(ATOM_warning, PL_FUNCTOR_CHARS, "io_warning", 2, PL_TERM, stream, PL_CHARS, s->message); Sseterr(s, SIO_WARN, NULL); } } return TRUE; } static int streamStatus(IOSTREAM *s) { if ( (s->flags & (SIO_FERR|SIO_WARN)) ) { releaseStream(s); return reportStreamError(s); } releaseStream(s); return TRUE; } /******************************* * TTY MODES * *******************************/ ttybuf ttytab; /* saved terminal status on entry */ int ttymode; /* Current tty mode */ typedef struct input_context * InputContext; typedef struct output_context * OutputContext; struct input_context { IOSTREAM * stream; /* pushed input */ atom_t term_file; /* old term_position file */ int term_line; /* old term_position line */ InputContext previous; /* previous context */ }; struct output_context { IOSTREAM * stream; /* pushed output */ OutputContext previous; /* previous context */ }; #define input_context_stack (LD->IO.input_stack) #define output_context_stack (LD->IO.output_stack) static IOSTREAM *openStream(term_t file, term_t mode, term_t options); void dieIO() { if ( GD->io_initialised ) { noprotocol(); closeFiles(TRUE); PopTty(Sinput, &ttytab); } } /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - closeStream() performs Prolog-level closing. Most important right now is to to avoid closing the user-streams. If a stream cannot be flushed (due to a write-error), an exception is generated. MT: We assume the stream is locked and will unlock it here. - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ static int closeStream(IOSTREAM *s) { if ( s == Sinput ) { Sclearerr(s); releaseStream(s); } else if ( s == Soutput || s == Serror ) { if ( Sflush(s) < 0 ) return streamStatus(s); releaseStream(s); } else { if ( !Sferror(s) && Sflush(s) < 0 ) { streamStatus(s); Sclose(s); return FALSE; } if ( Sclose(s) < 0 ) /* will unlock as well */ return FALSE; } return TRUE; } void closeFiles(int all) { GET_LD TableEnum e; Symbol symb; e = newTableEnum(streamContext); while( (symb=advanceTableEnum(e)) ) { IOSTREAM *s = symb->name; if ( all || !(s->flags & SIO_NOCLOSE) ) { IOSTREAM *s2 = tryGetStream(s); if ( s2 ) { if ( !all ) { term_t t = PL_new_term_ref(); PL_unify_stream_or_alias(t, s2); printMessage(ATOM_informational, PL_FUNCTOR, FUNCTOR_close_on_abort1, PL_TERM, t); PL_reset_term_refs(t); } closeStream(s2); } } } freeTableEnum(e); } /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - PL_cleanup_fork() must be called between fork() and exec() to remove traces of Prolog that are not supposed to leak into the new process. Note that we must be careful here. Notably, the code cannot lock or unlock any mutex as the behaviour of mutexes is undefined over fork(). Earlier versions used the file-table to close file descriptors that are in use by Prolog. This can't work as the table is guarded by a mutex. Now we use the FD_CLOEXEC flag in Snew(); - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ void PL_cleanup_fork(void) { stopItimer(); } void protocol(const char *str, size_t n) { GET_LD IOSTREAM *s; if ( LD && (s = getStream(Sprotocol)) ) { while( n-- > 0 ) Sputcode(*str++&0xff, s); Sflush(s); releaseStream(s); /* we don not check errors */ } } /******************************* * TEMPORARY I/O * *******************************/ static int push_input_context(void) { GET_LD InputContext c = allocHeap(sizeof(struct input_context)); c->stream = Scurin; c->term_file = source_file_name; c->term_line = source_line_no; c->previous = input_context_stack; input_context_stack = c; return TRUE; } static int pop_input_context(void) { GET_LD InputContext c = input_context_stack; if ( c ) { Scurin = c->stream; source_file_name = c->term_file; source_line_no = c->term_line; input_context_stack = c->previous; freeHeap(c, sizeof(struct input_context)); return TRUE; } else { Scurin = Sinput; return FALSE; } } static PRED_IMPL("$push_input_context", 0, push_input_context, 0) { return push_input_context(); } static PRED_IMPL("$pop_input_context", 0, pop_input_context, 0) { return pop_input_context(); } static void pushOutputContext(void) { GET_LD OutputContext c = allocHeap(sizeof(struct output_context)); c->stream = Scurout; c->previous = output_context_stack; output_context_stack = c; } static void popOutputContext(void) { GET_LD OutputContext c = output_context_stack; if ( c ) { if ( c->stream->magic == SIO_MAGIC ) Scurout = c->stream; else { Sdprintf("Oops, current stream closed?"); Scurout = Soutput; } output_context_stack = c->previous; freeHeap(c, sizeof(struct output_context)); } else Scurout = Soutput; } int setupOutputRedirect(term_t to, redir_context *ctx, int redir) { GET_LD atom_t a; ctx->term = to; ctx->redirected = redir; if ( to == 0 ) { ctx->stream = getStream(Scurout); ctx->is_stream = TRUE; } else if ( PL_get_atom(to, &a) && a == ATOM_user ) { ctx->stream = getStream(Suser_output); ctx->is_stream = TRUE; } else if ( get_stream_handle(to, &ctx->stream, SH_SAFE) ) { if ( !(ctx->stream->flags &SIO_OUTPUT) ) { releaseStream(ctx->stream); return PL_error(NULL, 0, NULL, ERR_PERMISSION, ATOM_output, ATOM_stream, to); } ctx->is_stream = TRUE; } else { if ( PL_is_functor(to, FUNCTOR_codes2) ) { ctx->out_format = PL_CODE_LIST; ctx->out_arity = 2; } else if ( PL_is_functor(to, FUNCTOR_codes1) ) { ctx->out_format = PL_CODE_LIST; ctx->out_arity = 1; } else if ( PL_is_functor(to, FUNCTOR_chars2) ) { ctx->out_format = PL_CHAR_LIST; ctx->out_arity = 2; } else if ( PL_is_functor(to, FUNCTOR_chars1) ) { ctx->out_format = PL_CHAR_LIST; ctx->out_arity = 1; } else if ( PL_is_functor(to, FUNCTOR_string1) ) { ctx->out_format = PL_STRING; ctx->out_arity = 1; } else if ( PL_is_functor(to, FUNCTOR_atom1) ) { ctx->out_format = PL_ATOM; ctx->out_arity = 1; } else { return PL_error(NULL, 0, NULL, ERR_TYPE, ATOM_output, to); } ctx->is_stream = FALSE; ctx->data = ctx->buffer; ctx->size = sizeof(ctx->buffer); ctx->stream = Sopenmem(&ctx->data, &ctx->size, "w"); ctx->stream->encoding = ENC_WCHAR; } ctx->magic = REDIR_MAGIC; if ( redir ) { pushOutputContext(); Scurout = ctx->stream; } return TRUE; } int closeOutputRedirect(redir_context *ctx) { int rval = TRUE; if ( ctx->magic != REDIR_MAGIC ) return rval; /* already done */ ctx->magic = 0; if ( ctx->redirected ) popOutputContext(); if ( ctx->is_stream ) { rval = streamStatus(ctx->stream); } else { GET_LD term_t out = PL_new_term_ref(); term_t diff, tail; closeStream(ctx->stream); _PL_get_arg(1, ctx->term, out); if ( ctx->out_arity == 2 ) { diff = PL_new_term_ref(); _PL_get_arg(2, ctx->term, diff); tail = PL_new_term_ref(); } else { diff = tail = 0; } rval = PL_unify_wchars_diff(out, tail, ctx->out_format, ctx->size/sizeof(wchar_t), (wchar_t*)ctx->data); if ( tail ) rval = PL_unify(tail, diff); if ( ctx->data != ctx->buffer ) free(ctx->data); } return rval; } void discardOutputRedirect(redir_context *ctx) { if ( ctx->magic != REDIR_MAGIC ) return; /* already done */ ctx->magic = 0; if ( ctx->redirected ) popOutputContext(); if ( ctx->is_stream ) { releaseStream(ctx->stream); } else { closeStream(ctx->stream); if ( ctx->data != ctx->buffer ) free(ctx->data); } } static PRED_IMPL("with_output_to", 2, with_output_to, PL_FA_TRANSPARENT) { redir_context outctx; if ( setupOutputRedirect(A1, &outctx, TRUE) ) { term_t ex = 0; int rval; if ( (rval = callProlog(NULL, A2, PL_Q_CATCH_EXCEPTION, &ex)) ) return closeOutputRedirect(&outctx); discardOutputRedirect(&outctx); if ( ex ) return PL_raise_exception(ex); } return FALSE; } void PL_write_prompt(int dowrite) { GET_LD IOSTREAM *s = getStream(Suser_output); if ( s ) { if ( dowrite ) { atom_t a = PrologPrompt(); if ( a ) writeAtomToStream(s, a); } Sflush(s); releaseStream(s); } LD->prompt.next = FALSE; } /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - Get a single character from Sinput without waiting for a return. The character should not be echoed. If PLFLAG_TTY_CONTROL is false this function will read the first character and then skip all character upto and including the newline. - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ static int Sgetcode_intr(IOSTREAM *s, int signals) { int c; #ifdef __WINDOWS__ int newline = s->newline; s->newline = SIO_NL_POSIX; /* avoid blocking \r */ #endif do { Sclearerr(s); c = Sgetcode(s); } while ( c == -1 && errno == EINTR && (!signals || PL_handle_signals() >= 0) ); #ifdef __WINDOWS__ s->newline = newline; #endif return c; } static int getSingleChar(IOSTREAM *stream, int signals) { GET_LD int c; ttybuf buf; #if __SWI_PROLOG__ debugstatus.suspendTrace++; #endif Slock(stream); Sflush(stream); PushTty(stream, &buf, TTY_RAW); /* just donot prompt */ if ( !truePrologFlag(PLFLAG_TTY_CONTROL) ) { int c2; c2 = Sgetcode_intr(stream, signals); while( c2 == ' ' || c2 == '\t' ) /* skip blanks */ c2 = Sgetcode_intr(stream, signals); c = c2; while( c2 != EOF && c2 != '\n' ) /* read upto newline */ c2 = Sgetcode_intr(stream, signals); } else { if ( stream->position ) { IOPOS oldpos = *stream->position; c = Sgetcode_intr(stream, signals); *stream->position = oldpos; } else c = Sgetcode_intr(stream, signals); } if ( c == 4 || c == 26 ) /* should ask the terminal! */ c = -1; PopTty(stream, &buf); #if __SWI_PROLOG__ debugstatus.suspendTrace--; #endif Sunlock(stream); return c; } /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - readLine() reads a line from the terminal. It is used only by the tracer. - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ #ifndef DEL #define DEL 127 #endif int readLine(IOSTREAM *in, IOSTREAM *out, char *buffer) { GET_LD int c; char *buf = &buffer[strlen(buffer)]; ttybuf tbuf; Slock(in); Slock(out); PushTty(in, &tbuf, TTY_RAW); /* just donot prompt */ for(;;) { Sflush(out); switch( (c=Sgetcode_intr(in, FALSE)) ) { case '\n': case '\r': case EOF: *buf++ = EOS; PopTty(in, &tbuf); Sunlock(in); Sunlock(out); return c == EOF ? FALSE : TRUE; case '\b': case DEL: if ( truePrologFlag(PLFLAG_TTY_CONTROL) && buf > buffer ) { Sfputs("\b \b", out); buf--; continue; } default: if ( truePrologFlag(PLFLAG_TTY_CONTROL) ) Sputcode(c, out); *buf++ = c; } } } IOSTREAM * PL_current_input() { GET_LD return getStream(Scurin); } IOSTREAM * PL_current_output() { GET_LD return getStream(Scurout); } static int openProtocol(term_t f, int appnd) { GET_LD IOSTREAM *s; term_t mode = PL_new_term_ref(); noprotocol(); PL_put_atom(mode, appnd ? ATOM_append : ATOM_write); if ( (s = openStream(f, mode, 0)) ) { s->flags |= SIO_NOCLOSE; /* do not close on abort */ Sprotocol = s; Suser_input->tee = s; Suser_output->tee = s; Suser_error->tee = s; return TRUE; } return FALSE; } static int noprotocol(void) { GET_LD IOSTREAM *s; if ( (s = getStream(Sprotocol)) ) { TableEnum e; Symbol symb; e = newTableEnum(streamContext); while( (symb=advanceTableEnum(e)) ) { IOSTREAM *p = symb->name; if ( p->tee == s ) p->tee = NULL; } freeTableEnum(e); closeStream(s); Sprotocol = NULL; } return TRUE; } static PRED_IMPL("noprotocol", 0, noprotocol, 0) { return noprotocol(); } /******************************* * STREAM ATTRIBUTES * *******************************/ static PRED_IMPL("set_stream", 2, set_stream, 0) { PRED_LD IOSTREAM *s; atom_t aname; int arity; term_t stream = A1; term_t attr = A2; if ( !PL_get_stream_handle(stream, &s) ) return FALSE; if ( PL_get_name_arity(attr, &aname, &arity) ) { if ( arity == 1 ) { term_t a = PL_new_term_ref(); _PL_get_arg(1, attr, a); if ( aname == ATOM_alias ) /* alias(name) */ { atom_t alias; int i; if ( !PL_get_atom_ex(a, &alias) ) goto error; if ( (i=standardStreamIndexFromName(alias)) >= 0 ) { LD->IO.streams[i] = s; if ( i == 0 ) LD->prompt.next = TRUE; /* changed standard input: prompt! */ goto ok; } LOCK(); aliasStream(s, alias); UNLOCK(); goto ok; } else if ( aname == ATOM_buffer ) /* buffer(Buffering) */ { atom_t b; #define SIO_ABUF (SIO_FBUF|SIO_LBUF|SIO_NBUF) if ( !PL_get_atom_ex(a, &b) ) goto error; if ( b == ATOM_full ) { s->flags &= ~SIO_ABUF; s->flags |= SIO_FBUF; } else if ( b == ATOM_line ) { s->flags &= ~SIO_ABUF; s->flags |= SIO_LBUF; } else if ( b == ATOM_false ) { Sflush(s); s->flags &= ~SIO_ABUF; s->flags |= SIO_NBUF; } else { PL_error("set_stream", 2, NULL, ERR_DOMAIN, ATOM_buffer, a); goto error; } goto ok; } else if ( aname == ATOM_buffer_size ) { int size; if ( !PL_get_integer_ex(a, &size) ) goto error; if ( size < 1 ) { PL_error(NULL, 0, NULL, ERR_DOMAIN, ATOM_not_less_than_one, a); goto error; } Ssetbuffer(s, NULL, size); goto ok; } else if ( aname == ATOM_eof_action ) /* eof_action(Action) */ { atom_t action; if ( !PL_get_atom_ex(a, &action) ) return FALSE; if ( action == ATOM_eof_code ) { s->flags &= ~(SIO_NOFEOF|SIO_FEOF2ERR); } else if ( action == ATOM_reset ) { s->flags &= ~SIO_FEOF2ERR; s->flags |= SIO_NOFEOF; } else if ( action == ATOM_error ) { s->flags &= ~SIO_NOFEOF; s->flags |= SIO_FEOF2ERR; } else { PL_error("set_stream", 2, NULL, ERR_DOMAIN, ATOM_eof_action, a); goto error; } goto ok; } else if ( aname == ATOM_close_on_abort ) /* close_on_abort(Bool) */ { int close; if ( !PL_get_bool_ex(a, &close) ) goto error; if ( close ) s->flags &= ~SIO_NOCLOSE; else s->flags |= SIO_NOCLOSE; goto ok; } else if ( aname == ATOM_record_position ) { int rec; if ( !PL_get_bool_ex(a, &rec) ) goto error; if ( rec ) s->position = &s->posbuf; else s->position = NULL; goto ok; } else if ( aname == ATOM_file_name ) /* file_name(Atom) */ { atom_t fn; if ( !PL_get_atom_ex(a, &fn) ) goto error; LOCK(); setFileNameStream(s, fn); UNLOCK(); goto ok; } else if ( aname == ATOM_timeout ) { double f; atom_t v; if ( PL_get_atom(a, &v) && v == ATOM_infinite ) { s->timeout = -1; goto ok; } if ( !PL_get_float_ex(a, &f) ) goto error; s->timeout = (int)(f*1000.0); if ( s->timeout < 0 ) s->timeout = 0; goto ok; } else if ( aname == ATOM_tty ) /* tty(bool) */ { int val; if ( !PL_get_bool_ex(a, &val) ) goto error; if ( val ) set(s, SIO_ISATTY); else clear(s, SIO_ISATTY); goto ok; } else if ( aname == ATOM_encoding ) /* encoding(atom) */ { atom_t val; IOENC enc; if ( !PL_get_atom_ex(a, &val) ) goto error; if ( (enc = atom_to_encoding(val)) == ENC_UNKNOWN ) { bad_encoding(val); goto error; } if ( Ssetenc(s, enc, NULL) == 0 ) goto ok; PL_error(NULL, 0, NULL, ERR_PERMISSION, ATOM_encoding, ATOM_stream, stream); goto error; } else if ( aname == ATOM_representation_errors ) { atom_t val; if ( !PL_get_atom_ex(a, &val) ) goto error; clear(s, SIO_REPXML|SIO_REPPL); if ( val == ATOM_error ) ; else if ( val == ATOM_xml ) set(s, SIO_REPXML); else if ( val == ATOM_prolog ) set(s, SIO_REPPL); else { PL_error(NULL, 0, NULL, ERR_DOMAIN, ATOM_representation_errors, a); goto error; } goto ok; } else if ( aname == ATOM_newline ) { atom_t val; if ( !PL_get_atom_ex(a, &val) ) goto error; if ( val == ATOM_posix ) s->newline = SIO_NL_POSIX; else if ( val == ATOM_dos ) s->newline = SIO_NL_DOS; else if ( val == ATOM_detect ) { if ( false(s, SIO_INPUT) ) { PL_error(NULL, 0, "detect only allowed for input streams", ERR_DOMAIN, ATOM_newline, a); goto error; } s->newline = SIO_NL_DETECT; } else { PL_error(NULL, 0, NULL, ERR_DOMAIN, ATOM_newline, a); goto error; } goto ok; } } } PL_error("set_stream", 2, NULL, ERR_TYPE, PL_new_atom("stream_attribute"), attr); goto error; ok: releaseStream(s); return TRUE; error: releaseStream(s); return FALSE; } /******************************** * STRING I/O * *********************************/ extern IOFUNCTIONS Smemfunctions; int tellString(char **s, size_t *size, IOENC enc) { GET_LD IOSTREAM *stream; stream = Sopenmem(s, size, "w"); stream->encoding = enc; pushOutputContext(); Scurout = stream; return TRUE; } int toldString() { GET_LD IOSTREAM *s = getStream(Scurout); if ( !s ) return TRUE; if ( s->functions == &Smemfunctions ) { closeStream(s); popOutputContext(); } else releaseStream(s); return TRUE; } /******************************** * WAITING FOR INPUT * ********************************/ #ifndef HAVE_SELECT static PRED_IMPL("wait_for_input", 3, wait_for_input, 0) { return notImplemented("wait_for_input", 3); } #else typedef struct fdentry { int fd; term_t stream; struct fdentry *next; } fdentry; static inline term_t findmap(fdentry *map, int fd) { for( ; map; map = map->next ) { if ( map->fd == fd ) return map->stream; } assert(0); return 0; } static PRED_IMPL("wait_for_input", 3, wait_for_input, 0) { PRED_LD fd_set fds; struct timeval t, *to; double time; int n, max = 0, ret, min = 1 << (INTBITSIZE-2); fdentry *map = NULL; term_t head = PL_new_term_ref(); term_t streams = PL_copy_term_ref(A1); term_t available = PL_copy_term_ref(A2); term_t ahead = PL_new_term_ref(); int from_buffer = 0; atom_t a; term_t timeout = A3; FD_ZERO(&fds); while( PL_get_list(streams, head, streams) ) { IOSTREAM *s; int fd; fdentry *e; if ( !PL_get_stream_handle(head, &s) ) return FALSE; if ( (fd=Sfileno(s)) < 0 ) { releaseStream(s); return PL_error("wait_for_input", 3, NULL, ERR_DOMAIN, PL_new_atom("file_stream"), head); } releaseStream(s); /* check for input in buffer */ if ( s->bufp < s->limitp ) { if ( !PL_unify_list(available, ahead, available) || !PL_unify(ahead, head) ) return FALSE; from_buffer++; } e = alloca(sizeof(*e)); e->fd = fd; e->stream = PL_copy_term_ref(head); e->next = map; map = e; #ifdef __WINDOWS__ FD_SET((SOCKET)fd, &fds); #else FD_SET(fd, &fds); #endif if ( fd > max ) max = fd; if( fd < min ) min = fd; } if ( !PL_get_nil(streams) ) return PL_error("wait_for_input", 3, NULL, ERR_TYPE, ATOM_list, A1); if ( from_buffer > 0 ) return PL_unify_nil(available); if ( PL_get_atom(timeout, &a) && a == ATOM_infinite ) { to = NULL; } else if ( PL_is_integer(timeout) ) { long v; PL_get_long(timeout, &v); if ( v > 0L ) { t.tv_sec = v; t.tv_usec = 0; to = &t; } else if ( v == 0 ) { to = NULL; } else { t.tv_sec = 0; t.tv_usec = 0; to = &t; } } else { if ( !PL_get_float(timeout, &time) ) return PL_error("wait_for_input", 3, NULL, ERR_TYPE, ATOM_float, timeout); if ( time >= 0.0 ) { t.tv_sec = (int)time; t.tv_usec = ((int)(time * 1000000) % 1000000); } else { t.tv_sec = 0; t.tv_usec = 0; } to = &t; } while( (ret=select(max+1, &fds, NULL, NULL, to)) == -1 && errno == EINTR ) { fdentry *e; if ( PL_handle_signals() < 0 ) return FALSE; /* exception */ FD_ZERO(&fds); /* EINTR may leave fds undefined */ for(e=map; e; e=e->next) /* so we rebuild it to be safe */ { #ifdef __WINDOWS__ FD_SET((SOCKET)e->fd, &fds); #else FD_SET(e->fd, &fds); #endif } } switch(ret) { case -1: return PL_error("wait_for_input", 3, MSG_ERRNO, ERR_FILE_OPERATION, ATOM_select, ATOM_stream, A1); case 0: /* Timeout */ break; default: /* Something happend -> check fds */ for(n=min; n <= max; n++) { if ( FD_ISSET(n, &fds) ) { if ( !PL_unify_list(available, ahead, available) || !PL_unify(ahead, findmap(map, n)) ) return FALSE; } } break; } return PL_unify_nil(available); } #endif /* HAVE_SELECT */ /******************************** * PROLOG CONNECTION * *********************************/ #define MAX_PENDING SIO_BUFSIZE /* 4096 */ static void re_buffer(IOSTREAM *s, const char *from, size_t len) { if ( s->bufp < s->limitp ) { size_t size = s->limitp - s->bufp; memmove(s->buffer, s->bufp, size); s->bufp = s->buffer; s->limitp = &s->bufp[size]; } else { s->bufp = s->limitp = s->buffer; } memcpy(s->bufp, from, len); s->bufp += len; } #ifndef HAVE_MBSNRTOWCS static size_t mbsnrtowcs(wchar_t *dest, const char **src, size_t nms, size_t len, mbstate_t *ps) { wchar_t c; const char *us = *src; const char *es = us+nms; size_t count = 0; assert(dest == NULL); /* incomplete implementation */ while(usflags&SIO_TEXT ) { switch(s->newline) { case SIO_NL_DETECT: s->newline = SIO_NL_DOS; /*FALLTHROUGH*/ case SIO_NL_DOS: return TRUE; } } return FALSE; } static PRED_IMPL("read_pending_input", 3, read_pending_input, 0) { PRED_LD IOSTREAM *s; if ( getInputStream(A1, &s) ) { char buf[MAX_PENDING]; ssize_t n; int64_t off0 = Stell64(s); IOPOS pos0; list_ctx ctx; if ( Sferror(s) ) return streamStatus(s); n = Sread_pending(s, buf, sizeof(buf), 0); if ( n < 0 ) /* should not happen */ return streamStatus(s); if ( n == 0 ) /* end-of-file */ { S__fcheckpasteeof(s, -1); return PL_unify(A2, A3); } if ( s->position ) { pos0 = *s->position; } else { memset(&pos0, 0, sizeof(pos0)); /* make compiler happy */ } switch(s->encoding) { case ENC_OCTET: case ENC_ISO_LATIN_1: case ENC_ASCII: { ssize_t i; if ( !allocList(n, &ctx) ) return FALSE; for(i=0; iposition ) S__fupdatefilepos_getc(s, c); addSmallIntList(&ctx, c); } if ( s->position ) s->position->byteno = pos0.byteno+n; break; } case ENC_ANSI: { size_t count, i; mbstate_t s0; const char *us = buf; const char *es = buf+n; if ( !s->mbstate ) { if ( !(s->mbstate = malloc(sizeof(*s->mbstate))) ) { PL_error(NULL, 0, NULL, ERR_NOMEM); goto failure; } memset(s->mbstate, 0, sizeof(*s->mbstate)); } s0 = *s->mbstate; count = mbsnrtowcs(NULL, &us, n, 0, &s0); if ( count == (size_t)-1 ) { Sseterr(s, SIO_WARN, "Illegal multibyte Sequence"); goto failure; } DEBUG(2, Sdprintf("Got %ld codes from %d bytes; incomplete: %ld\n", count, n, es-us)); if ( !allocList(count, &ctx) ) return FALSE; for(us=buf,i=0; imbstate); if ( c == '\r' && skip_cr(s) ) continue; if ( s->position ) S__fupdatefilepos_getc(s, c); addSmallIntList(&ctx, c); } if ( s->position ) s->position->byteno = pos0.byteno+us-buf; re_buffer(s, us, es-us); break; } case ENC_UTF8: { const char *us = buf; const char *es = buf+n; size_t count = 0, i; while(usposition ) S__fupdatefilepos_getc(s, c); addSmallIntList(&ctx, c); } if ( s->position ) s->position->byteno = pos0.byteno+us-buf; re_buffer(s, us, es-us); break; } case ENC_UNICODE_BE: case ENC_UNICODE_LE: { size_t count = (size_t)n/2; const char *us = buf; size_t done, i; if ( !allocList(count, &ctx) ) return FALSE; for(i=0; iencoding == ENC_UNICODE_BE ) c = ((us[0]&0xff)<<8)+(us[1]&0xff); else c = ((us[1]&0xff)<<8)+(us[0]&0xff); if ( c == '\r' && skip_cr(s) ) continue; if ( s->position ) S__fupdatefilepos_getc(s, c); addSmallIntList(&ctx, c); } done = count*2; if ( s->position ) s->position->byteno = pos0.byteno+done; re_buffer(s, buf+done, n-done); break; } case ENC_WCHAR: { const pl_wchar_t *ws = (const pl_wchar_t*)buf; size_t count = (size_t)n/sizeof(pl_wchar_t); size_t done, i; if ( !allocList(count, &ctx) ) return FALSE; for(i=0; iposition ) S__fupdatefilepos_getc(s, c); addSmallIntList(&ctx, c); } done = count*sizeof(pl_wchar_t); if ( s->position ) s->position->byteno = pos0.byteno+done; re_buffer(s, buf+done, n-done); break; } case ENC_UNKNOWN: default: assert(0); return FALSE; } if ( !unifyDiffList(A2, A3, &ctx) ) goto failure; releaseStream(s); return TRUE; failure: Sseek64(s, off0, SIO_SEEK_SET); /* TBD: error? */ if ( s->position ) *s->position = pos0; releaseStream(s); return FALSE; } return FALSE; } static foreign_t put_byte(term_t stream, term_t byte ARG_LD) { IOSTREAM *s; int c; if ( !PL_get_integer(byte, &c) || c < 0 || c > 255 ) return PL_error(NULL, 0, NULL, ERR_TYPE, ATOM_byte, byte); if ( !getOutputStream(stream, &s) ) return FALSE; Sputc(c, s); return streamStatus(s); } static PRED_IMPL("put_byte", 2, put_byte2, 0) { PRED_LD return put_byte(A1, A2 PASS_LD); } static PRED_IMPL("put_byte", 1, put_byte1, 0) { PRED_LD return put_byte(0, A1 PASS_LD); } static foreign_t put_code(term_t stream, term_t chr ARG_LD) { IOSTREAM *s; int c = 0; if ( !PL_get_char(chr, &c, FALSE) ) return FALSE; if ( !getOutputStream(stream, &s) ) return FALSE; Sputcode(c, s); return streamStatus(s); } static PRED_IMPL("put_code", 2, put_code2, 0) { PRED_LD return put_code(A1, A2 PASS_LD); } static PRED_IMPL("put_code", 1, put_code1, 0) { PRED_LD return put_code(0, A1 PASS_LD); } static PRED_IMPL("put", 2, put2, 0) { PRED_LD return put_code(A1, A2 PASS_LD); } static PRED_IMPL("put", 1, put1, 0) { PRED_LD return put_code(0, A1 PASS_LD); } static foreign_t get_nonblank(term_t in, term_t chr ARG_LD) { IOSTREAM *s; if ( getInputStream(in, &s) ) { int c; for(;;) { c = Sgetcode(s); if ( c == EOF ) { TRY(PL_unify_integer(chr, -1)); return streamStatus(s); } if ( !isBlankW(c) ) { releaseStream(s); return PL_unify_integer(chr, c); } } } return FALSE; } static PRED_IMPL("get", 1, get1, 0) { PRED_LD return get_nonblank(0, A1 PASS_LD); } static PRED_IMPL("get", 2, get2, 0) { PRED_LD return get_nonblank(A1, A2 PASS_LD); } static foreign_t skip(term_t in, term_t chr ARG_LD) { int c = -1; int r; IOSTREAM *s; if ( !PL_get_char(chr, &c, FALSE) ) return FALSE; if ( !getInputStream(in, &s) ) return FALSE; while((r=Sgetcode(s)) != c && r != EOF ) ; return streamStatus(s); } static PRED_IMPL("skip", 1, skip1, 0) { PRED_LD return skip(0, A1 PASS_LD); } static PRED_IMPL("skip", 2, skip2, 0) { PRED_LD return skip(A1, A2 PASS_LD); } static PRED_IMPL("get_single_char", 1, get_single_char, 0) { GET_LD IOSTREAM *s = getStream(Suser_input); int c = getSingleChar(s, TRUE); if ( c == EOF ) { PL_unify_integer(A1, -1); return streamStatus(s); } releaseStream(s); return PL_unify_integer(A1, c); } static foreign_t get_byte2(term_t in, term_t chr ARG_LD) { IOSTREAM *s; if ( getInputStream(in, &s) ) { int c = Sgetc(s); if ( PL_unify_integer(chr, c) ) return streamStatus(s); if ( Sferror(s) ) return streamStatus(s); PL_get_char(chr, &c, TRUE); /* set type-error */ } return FALSE; } static PRED_IMPL("get_byte", 2, get_byte2, 0) { PRED_LD return get_byte2(A1, A2 PASS_LD); } static PRED_IMPL("get_byte", 1, get_byte1, 0) { PRED_LD return get_byte2(0, A1 PASS_LD); } static foreign_t get_code2(term_t in, term_t chr ARG_LD) { IOSTREAM *s; if ( getInputStream(in, &s) ) { int c = Sgetcode(s); if ( PL_unify_integer(chr, c) ) return streamStatus(s); if ( Sferror(s) ) return streamStatus(s); PL_get_char(chr, &c, TRUE); /* set type-error */ releaseStream(s); } return FALSE; } static PRED_IMPL("get_code", 2, get_code2, 0) { PRED_LD return get_code2(A1, A2 PASS_LD); } static PRED_IMPL("get_code", 1, get_code1, 0) { PRED_LD return get_code2(0, A1 PASS_LD); } static foreign_t get_char2(term_t in, term_t chr ARG_LD) { IOSTREAM *s; if ( getInputStream(in, &s) ) { int c = Sgetcode(s); if ( PL_unify_atom(chr, c == -1 ? ATOM_end_of_file : codeToAtom(c)) ) return streamStatus(s); if ( Sferror(s) ) return streamStatus(s); PL_get_char(chr, &c, TRUE); /* set type-error */ releaseStream(s); } return FALSE; } static PRED_IMPL("get_char", 2, get_char2, 0) { PRED_LD return get_char2(A1, A2 PASS_LD); } static PRED_IMPL("get_char", 1, get_char1, 0) { PRED_LD return get_char2(0, A1 PASS_LD); } static PRED_IMPL("ttyflush", 0, ttyflush, 0) { PRED_LD IOSTREAM *s = getStream(Suser_output); Sflush(s); return streamStatus(s); } static PRED_IMPL("protocol", 1, protocol, 0) { return openProtocol(A1, FALSE); } static PRED_IMPL("protocola", 1, protocola, 0) { return openProtocol(A1, TRUE); } static PRED_IMPL("protocolling", 1, protocolling, 0) { PRED_LD IOSTREAM *s; if ( (s = Sprotocol) ) { atom_t a; if ( (a = fileNameStream(s)) ) return PL_unify_atom(A1, a); else return PL_unify_stream_or_alias(A1, s); } return FALSE; } static PRED_IMPL("prompt", 2, prompt, 0) { PRED_LD atom_t a; term_t old = A1; term_t new = A2; if ( PL_unify_atom(old, LD->prompt.current) && PL_get_atom(new, &a) ) { if ( LD->prompt.current ) PL_unregister_atom(LD->prompt.current); LD->prompt.current = a; PL_register_atom(a); return TRUE; } return FALSE; } static void prompt1(atom_t prompt) { GET_LD if ( LD->prompt.first != prompt ) { if ( LD->prompt.first ) PL_unregister_atom(LD->prompt.first); LD->prompt.first = prompt; PL_register_atom(LD->prompt.first); } LD->prompt.first_used = FALSE; } static PRED_IMPL("prompt1", 1, prompt1, 0) { GET_LD atom_t a; PL_chars_t txt; if ( PL_get_atom(A1, &a) ) { prompt1(a); } else if ( PL_get_text(A1, &txt, CVT_ALL|CVT_EXCEPTION) ) { prompt1(textToAtom(&txt)); } else return FALSE; return TRUE; } atom_t PrologPrompt() { GET_LD if ( !LD->prompt.first_used && LD->prompt.first ) { LD->prompt.first_used = TRUE; return LD->prompt.first; } if ( Sinput->position && Sinput->position->linepos == 0 ) return LD->prompt.current; else return 0; /* "" */ } static int tab(term_t out, term_t spaces) { int64_t count; IOSTREAM *s; if ( !getOutputStream(out, &s) ) return FALSE; if ( !PL_eval_expression_to_int64_ex(spaces, &count) ) return FALSE; while(count-- > 0) { if ( Sputcode(' ', s) < 0 ) break; } return streamStatus(s); } static PRED_IMPL("tab", 2, tab2, 0) { return tab(A1, A2); } static PRED_IMPL("tab", 1, tab1, 0) { return tab(0, A1); } /******************************* * ENCODING * *******************************/ #if __YAP_PROLOG__ typedef struct encname { IOENC code; atom_t name; } encoding_name; INIT_DEF(struct encname, encoding_names, 10) ADD_ENCODING( ENC_UNKNOWN, ATOM_unknown ) ADD_ENCODING( ENC_OCTET, ATOM_octet ) ADD_ENCODING( ENC_ASCII, ATOM_ascii ) ADD_ENCODING( ENC_ISO_LATIN_1, ATOM_iso_latin_1 ) ADD_ENCODING( ENC_ANSI, ATOM_text ) ADD_ENCODING( ENC_UTF8, ATOM_utf8 ) ADD_ENCODING( ENC_UNICODE_BE, ATOM_unicode_be ) ADD_ENCODING( ENC_UNICODE_LE, ATOM_unicode_le ) ADD_ENCODING( ENC_WCHAR, ATOM_wchar_t ) END_ENCODINGS( ENC_UNKNOWN, 0 ) #else static struct encname { IOENC code; atom_t name; } encoding_names[] = { { ENC_UNKNOWN, ATOM_unknown }, { ENC_OCTET, ATOM_octet }, { ENC_ASCII, ATOM_ascii }, { ENC_ISO_LATIN_1, ATOM_iso_latin_1 }, { ENC_ANSI, ATOM_text }, { ENC_UTF8, ATOM_utf8 }, { ENC_UNICODE_BE, ATOM_unicode_be }, { ENC_UNICODE_LE, ATOM_unicode_le }, { ENC_WCHAR, ATOM_wchar_t }, { ENC_UNKNOWN, 0 }, }; #endif IOENC atom_to_encoding(atom_t a) { struct encname *en; for(en=encoding_names; en->name; en++) { if ( en->name == a ) return en->code; } return ENC_UNKNOWN; } static atom_t encoding_to_atom(IOENC enc) { return encoding_names[enc].name; } static int bad_encoding(atom_t name) { GET_LD term_t t = PL_new_term_ref(); PL_put_atom(t, name); return PL_error(NULL, 0, NULL, ERR_DOMAIN, ATOM_encoding, t); } /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - fn_to_atom() translates a 8-bit filename into a unicode atom. The encoding is generic `multibyte' on Unix systems and fixed to UTF-8 on Windows, where the uxnt layer translates the UTF-8 sequences to the Windows *W() functions. - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ static atom_t fn_to_atom(const char *fn) { PL_chars_t text; atom_t a; text.text.t = (char *)fn; text.encoding = ((REP_FN&REP_UTF8) ? ENC_UTF8 : (REP_FN&REP_MB) ? ENC_ANSI : ENC_ISO_LATIN_1); text.storage = PL_CHARS_HEAP; text.length = strlen(fn); text.canonical = FALSE; a = textToAtom(&text); PL_free_text(&text); return a; } /******************************** * STREAM BASED I/O * *********************************/ #if __YAP_PROLOG__ INIT_DEF(opt_spec, open4_options, 10) ADD_OPEN4_OPT( ATOM_type, OPT_ATOM ) ADD_OPEN4_OPT( ATOM_reposition, OPT_BOOL ) ADD_OPEN4_OPT( ATOM_alias, OPT_ATOM ) ADD_OPEN4_OPT( ATOM_eof_action, OPT_ATOM ) ADD_OPEN4_OPT( ATOM_close_on_abort, OPT_BOOL ) ADD_OPEN4_OPT( ATOM_buffer, OPT_ATOM ) ADD_OPEN4_OPT( ATOM_lock, OPT_ATOM ) ADD_OPEN4_OPT( ATOM_encoding, OPT_ATOM ) ADD_OPEN4_OPT( ATOM_bom, OPT_BOOL ) END_OPEN4_DEFS(NULL_ATOM, 0) #else static const opt_spec open4_options[] = { { ATOM_type, OPT_ATOM }, { ATOM_reposition, OPT_BOOL }, { ATOM_alias, OPT_ATOM }, { ATOM_eof_action, OPT_ATOM }, { ATOM_close_on_abort, OPT_BOOL }, { ATOM_buffer, OPT_ATOM }, { ATOM_lock, OPT_ATOM }, { ATOM_encoding, OPT_ATOM }, { ATOM_bom, OPT_BOOL }, { NULL_ATOM, 0 } }; #endif IOSTREAM * openStream(term_t file, term_t mode, term_t options) { GET_LD atom_t mname; atom_t type = ATOM_text; int reposition = TRUE; atom_t alias = NULL_ATOM; atom_t eof_action = ATOM_eof_code; atom_t buffer = ATOM_full; atom_t lock = ATOM_none; atom_t encoding = NULL_ATOM; int close_on_abort = TRUE; int bom = -1; char how[10]; char *h = how; char *path; IOSTREAM *s; IOENC enc; if ( options ) { if ( !scan_options(options, 0, ATOM_stream_option, open4_options, &type, &reposition, &alias, &eof_action, &close_on_abort, &buffer, &lock, &encoding, &bom) ) return FALSE; } /* MODE */ if ( PL_get_atom(mode, &mname) ) { if ( mname == ATOM_write ) { *h++ = 'w'; } else if ( mname == ATOM_append ) { bom = FALSE; *h++ = 'a'; } else if ( mname == ATOM_update ) { bom = FALSE; *h++ = 'u'; } else if ( mname == ATOM_read ) { *h++ = 'r'; } else { PL_error(NULL, 0, NULL, ERR_DOMAIN, ATOM_io_mode, mode); return NULL; } } else { PL_error(NULL, 0, NULL, ERR_TYPE, ATOM_atom, mode); return NULL; } /* ENCODING */ if ( encoding != NULL_ATOM ) { enc = atom_to_encoding(encoding); if ( enc == ENC_UNKNOWN ) { bad_encoding(encoding); return NULL; } } else if ( type == ATOM_binary ) { enc = ENC_OCTET; bom = FALSE; } else { enc = LD->encoding; } if ( bom == -1 ) bom = (mname == ATOM_read ? TRUE : FALSE); if ( type == ATOM_binary ) *h++ = 'b'; /* LOCK */ if ( lock != ATOM_none ) { *h++ = 'l'; if ( lock == ATOM_read || lock == ATOM_shared ) *h++ = 'r'; else if ( lock == ATOM_write || lock == ATOM_exclusive ) *h++ = 'w'; else { term_t l = PL_new_term_ref(); PL_put_atom(l, lock); PL_error(NULL, 0, NULL, ERR_DOMAIN, ATOM_lock, l); return NULL; } } *h = EOS; /* FILE */ if ( PL_get_chars(file, &path, CVT_ATOM|CVT_STRING|CVT_EXCEPTION|REP_FN) ) { if ( !(s = Sopen_file(path, how)) ) { PL_error(NULL, 0, OsError(), ERR_FILE_OPERATION, ATOM_open, ATOM_source_sink, file); return NULL; } setFileNameStream(s, fn_to_atom(path)); } #ifdef HAVE_POPEN else if ( PL_is_functor(file, FUNCTOR_pipe1) ) { term_t a = PL_new_term_ref(); char *cmd; PL_get_arg(1, file, a); if ( !PL_get_chars(a, &cmd, CVT_ATOM|CVT_STRING|REP_FN) ) { PL_error(NULL, 0, NULL, ERR_TYPE, ATOM_atom, a); return NULL; } if ( !(s = Sopen_pipe(cmd, how)) ) { PL_error(NULL, 0, OsError(), ERR_FILE_OPERATION, ATOM_open, ATOM_source_sink, file); return NULL; } } #endif /*HAVE_POPEN*/ else { return NULL; } s->encoding = enc; if ( !close_on_abort ) s->flags |= SIO_NOCLOSE; if ( how[0] == 'r' ) { if ( eof_action != ATOM_eof_code ) { if ( eof_action == ATOM_reset ) s->flags |= SIO_NOFEOF; else if ( eof_action == ATOM_error ) s->flags |= SIO_FEOF2ERR; } } else { if ( buffer != ATOM_full ) { s->flags &= ~SIO_FBUF; if ( buffer == ATOM_line ) s->flags |= SIO_LBUF; if ( buffer == ATOM_false ) s->flags |= SIO_NBUF; } } if ( alias != NULL_ATOM ) aliasStream(s, alias); if ( !reposition ) s->position = NULL; if ( bom ) { if ( mname == ATOM_read ) { if ( ScheckBOM(s) < 0 ) { bom_error: streamStatus(getStream(s)); return NULL; } } else { if ( SwriteBOM(s) < 0 ) goto bom_error; } } return s; } static PRED_IMPL("open", 4, open4, PL_FA_ISO) { IOSTREAM *s = openStream(A1, A2, A4); if ( s ) return PL_unify_stream_or_alias(A3, s); return FALSE; } static PRED_IMPL("open", 3, open3, PL_FA_ISO) { IOSTREAM *s = openStream(A1, A2, 0); if ( s ) return PL_unify_stream_or_alias(A3, s); return FALSE; } /******************************* * EDINBURGH I/O * *******************************/ static IOSTREAM * findStreamFromFile(atom_t name, unsigned int flags) { TableEnum e; Symbol symb; IOSTREAM *s = NULL; e = newTableEnum(streamContext); while( (symb=advanceTableEnum(e)) ) { stream_context *ctx = symb->value; if ( ctx->filename == name && true(ctx, flags) ) { s = symb->name; break; } } freeTableEnum(e); return s; } static int pl_see(term_t f) { GET_LD IOSTREAM *s; atom_t a; term_t mode; LOCK(); if ( get_stream_handle(f, &s, SH_ALIAS|SH_UNLOCKED) ) { Scurin = s; goto ok; } if ( PL_get_atom(f, &a) && a == ATOM_user ) { Scurin = Suser_input; goto ok; } if ( (s = findStreamFromFile(a, IO_SEE)) ) { Scurin = s; goto ok; } mode = PL_new_term_ref(); PL_put_atom(mode, ATOM_read); if ( !(s = openStream(f, mode, 0)) ) { UNLOCK(); return FALSE; } set(getStreamContext(s), IO_SEE); push_input_context(); Scurin = s; ok: UNLOCK(); return TRUE; } static int pl_seen(void) { GET_LD IOSTREAM *s = getStream(Scurin); pop_input_context(); if ( s->flags & SIO_NOFEOF ) return TRUE; return closeStream(s); } static PRED_IMPL("see", 1, see, 0) { return pl_see(A1); } static PRED_IMPL("seen", 0, seen, 0) { return pl_seen(); } static PRED_IMPL("seeing", 1, seeing, 0) { PRED_LD if ( Scurin == Suser_input ) return PL_unify_atom(A1, ATOM_user); return PL_unify_stream(A1, Scurin); } /* MT: Does not create a lock on the stream */ static int do_tell(term_t f, atom_t m) { GET_LD IOSTREAM *s; atom_t a; term_t mode; LOCK(); if ( get_stream_handle(f, &s, SH_UNLOCKED) ) { Scurout = s; goto ok; } if ( PL_get_atom(f, &a) && a == ATOM_user ) { Scurout = Suser_output; goto ok; } if ( (s = findStreamFromFile(a, IO_TELL)) ) { Scurout = s; goto ok; } mode = PL_new_term_ref(); PL_put_atom(mode, m); if ( !(s = openStream(f, mode, 0)) ) { UNLOCK(); return FALSE; } set(getStreamContext(s), IO_TELL); pushOutputContext(); Scurout = s; ok: UNLOCK(); return TRUE; } static PRED_IMPL("tell", 1, tell, 0) { return do_tell(A1, ATOM_write); } static PRED_IMPL("append", 1, append, 0) { return do_tell(A1, ATOM_append); } static PRED_IMPL("telling", 1, telling, 0) { PRED_LD if ( Scurout == Suser_output ) return PL_unify_atom(A1, ATOM_user); return PL_unify_stream(A1, Scurout); } static PRED_IMPL("told", 0, told, 0) { PRED_LD IOSTREAM *s = getStream(Scurout); popOutputContext(); if ( s->flags & SIO_NOFEOF ) return TRUE; return closeStream(s); } /******************************* * NULL-STREAM * *******************************/ static ssize_t Swrite_null(void *handle, char *buf, size_t size) { return size; } static ssize_t Sread_null(void *handle, char *buf, size_t size) { return 0; } static long Sseek_null(void *handle, long offset, int whence) { switch(whence) { case SIO_SEEK_SET: return offset; case SIO_SEEK_CUR: case SIO_SEEK_END: default: return -1; } } static int Sclose_null(void *handle) { return 0; } static const IOFUNCTIONS nullFunctions = { Sread_null, Swrite_null, Sseek_null, Sclose_null }; static PRED_IMPL("open_null_stream", 1, open_null_stream, 0) { int sflags = SIO_NBUF|SIO_RECORDPOS|SIO_OUTPUT; IOSTREAM *s = Snew((void *)NULL, sflags, (IOFUNCTIONS *)&nullFunctions); if ( s ) { s->encoding = ENC_UTF8; return PL_unify_stream_or_alias(A1, s); } return FALSE; } static PRED_IMPL("close", 1, close, PL_FA_ISO) { IOSTREAM *s; if ( PL_get_stream_handle(A1, &s) ) return closeStream(s); return FALSE; } #if __YAP_PROLOG__ INIT_DEF(opt_spec, close2_options, 2) ADD_CLOSE2_OPT( ATOM_force, OPT_BOOL ) END_CLOSE2_DEFS( NULL_ATOM, 0 ) #else static const opt_spec close2_options[] = { { ATOM_force, OPT_BOOL }, { NULL_ATOM, 0 } }; #endif static PRED_IMPL("close", 2, close2, PL_FA_ISO) { IOSTREAM *s; int force = FALSE; if ( !scan_options(A2, 0, ATOM_close_option, close2_options, &force) ) return FALSE; if ( !PL_get_stream_handle(A1, &s) ) return FALSE; if ( !force ) return closeStream(s); if ( s == Sinput ) Sclearerr(s); else if ( s == Soutput || s == Serror ) { Sflush(s); Sclearerr(s); } else { Sflush(s); Sclose(s); } return TRUE; } /******************************* * STREAM-PROPERTY * *******************************/ static int stream_file_name_propery(IOSTREAM *s, term_t prop ARG_LD) { atom_t name; if ( (name = getStreamContext(s)->filename) ) { return PL_unify_atom(prop, name); } return FALSE; } static int stream_mode_property(IOSTREAM *s, term_t prop ARG_LD) { atom_t mode; if ( s->flags & SIO_INPUT ) mode = ATOM_read; else { assert(s->flags & SIO_OUTPUT); if ( s->flags & SIO_APPEND ) mode = ATOM_append; else if ( s->flags & SIO_UPDATE ) mode = ATOM_update; else mode = ATOM_write; } return PL_unify_atom(prop, mode); } static int stream_input_prop(IOSTREAM *s ARG_LD) { return (s->flags & SIO_INPUT) ? TRUE : FALSE; } static int stream_output_prop(IOSTREAM *s ARG_LD) { return (s->flags & SIO_OUTPUT) ? TRUE : FALSE; } /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - Incomplete: should be non-deterministic if the stream has multiple aliases! - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ static int stream_alias_prop(IOSTREAM *s, term_t prop ARG_LD) { atom_t name; stream_context *ctx = getStreamContext(s); int i; if ( PL_get_atom(prop, &name) ) { alias *a; for( a = ctx->alias_head; a; a = a->next ) { if ( a->name == name ) return TRUE; } if ( (i=standardStreamIndexFromName(name)) >= 0 && i < 6 && s == LD->IO.streams[i] ) return TRUE; return FALSE; } if ( (i=standardStreamIndexFromStream(s)) >= 0 && i < 3 ) return PL_unify_atom(prop, standardStreams[i]); if ( ctx->alias_head ) return PL_unify_atom(prop, ctx->alias_head->name); return FALSE; } static int stream_position_prop(IOSTREAM *s, term_t prop ARG_LD) { if ( s->position ) { return PL_unify_term(prop, PL_FUNCTOR, FUNCTOR_stream_position4, PL_INT64, s->position->charno, PL_INT, s->position->lineno, PL_INT, s->position->linepos, PL_INT64, s->position->byteno); } return FALSE; } static int stream_end_of_stream_prop(IOSTREAM *s, term_t prop ARG_LD) { if ( s->flags & SIO_INPUT ) { GET_LD atom_t val; if ( s->flags & SIO_FEOF2 ) val = ATOM_past; else if ( s->flags & SIO_FEOF ) val = ATOM_at; else val = ATOM_not; return PL_unify_atom(prop, val); } return FALSE; } static int stream_eof_action_prop(IOSTREAM *s, term_t prop ARG_LD) { atom_t val; if ( s->flags & SIO_NOFEOF ) val = ATOM_reset; else if ( s->flags & SIO_FEOF2ERR ) val = ATOM_error; else val = ATOM_eof_code; return PL_unify_atom(prop, val); } #ifdef HAVE_FSTAT #include #endif #if !defined(S_ISREG) && defined(S_IFREG) #define S_ISREG(m) ((m&S_IFMT) == S_IFREG) #endif static int stream_reposition_prop(IOSTREAM *s, term_t prop ARG_LD) { atom_t val; if ( s->functions->seek ) { #ifdef HAVE_FSTAT int fd = Sfileno(s); struct stat buf; if ( fstat(fd, &buf) == 0 && S_ISREG(buf.st_mode) ) val = ATOM_true; else val = ATOM_false; #else val = ATOM_true; #endif } else val = ATOM_false; return PL_unify_atom(prop, val); } static int stream_close_on_abort_prop(IOSTREAM *s, term_t prop ARG_LD) { return PL_unify_bool_ex(prop, !(s->flags & SIO_NOCLOSE)); } static int stream_type_prop(IOSTREAM *s, term_t prop ARG_LD) { return PL_unify_atom(prop, s->flags & SIO_TEXT ? ATOM_text : ATOM_binary); } static int stream_file_no_prop(IOSTREAM *s, term_t prop ARG_LD) { int fd; if ( (fd = Sfileno(s)) >= 0 ) return PL_unify_integer(prop, fd); return FALSE; } static int stream_tty_prop(IOSTREAM *s, term_t prop ARG_LD) { if ( (s->flags & SIO_ISATTY) ) return PL_unify_bool_ex(prop, TRUE); return FALSE; } static int stream_bom_prop(IOSTREAM *s, term_t prop ARG_LD) { if ( (s->flags & SIO_BOM) ) return PL_unify_bool_ex(prop, TRUE); return FALSE; } static int stream_newline_prop(IOSTREAM *s, term_t prop ARG_LD) { switch ( s->newline ) { case SIO_NL_POSIX: case SIO_NL_DETECT: return PL_unify_atom(prop, ATOM_posix); case SIO_NL_DOS: return PL_unify_atom(prop, ATOM_dos); } return FALSE; } static int stream_encoding_prop(IOSTREAM *s, term_t prop ARG_LD) { return PL_unify_atom(prop, encoding_to_atom(s->encoding)); } static int stream_reperror_prop(IOSTREAM *s, term_t prop ARG_LD) { atom_t a; if ( (s->flags & SIO_REPXML) ) a = ATOM_xml; else if ( (s->flags & SIO_REPPL) ) a = ATOM_prolog; else a = ATOM_error; return PL_unify_atom(prop, a); } static int stream_buffer_prop(IOSTREAM *s, term_t prop ARG_LD) { atom_t b; if ( s->flags & SIO_FBUF ) b = ATOM_full; else if ( s->flags & SIO_LBUF ) b = ATOM_line; else /*if ( s->flags & SIO_NBUF )*/ b = ATOM_false; return PL_unify_atom(prop, b); } static int stream_buffer_size_prop(IOSTREAM *s, term_t prop ARG_LD) { if ( (s->flags & SIO_NBUF) ) return FALSE; return PL_unify_integer(prop, s->bufsize); } static int stream_timeout_prop(IOSTREAM *s, term_t prop ARG_LD) { if ( s->timeout == -1 ) return PL_unify_atom(prop, ATOM_infinite); return PL_unify_float(prop, (double)s->timeout/1000.0); } static int stream_nlink_prop(IOSTREAM *s, term_t prop ARG_LD) { int fd; if ( (fd = Sfileno(s)) >= 0 ) { struct stat buf; if ( fstat(fd, &buf) == 0 ) { return PL_unify_integer(prop, buf.st_nlink); } } return FALSE; } typedef struct { functor_t functor; /* functor of property */ int (*function)(); /* function to generate */ } sprop; #if __YAP_PROLOG__ INIT_DEF(sprop, sprop_list, 25) ADD_SPROP( FUNCTOR_file_name1, stream_file_name_propery ) ADD_SPROP( FUNCTOR_mode1, stream_mode_property ) ADD_SPROP( FUNCTOR_input0, stream_input_prop ) ADD_SPROP( FUNCTOR_output0, stream_output_prop ) ADD_SPROP( FUNCTOR_alias1, stream_alias_prop ) ADD_SPROP( FUNCTOR_position1, stream_position_prop ) ADD_SPROP( FUNCTOR_end_of_stream1, stream_end_of_stream_prop ) ADD_SPROP( FUNCTOR_eof_action1, stream_eof_action_prop ) ADD_SPROP( FUNCTOR_reposition1, stream_reposition_prop ) ADD_SPROP( FUNCTOR_type1, stream_type_prop ) ADD_SPROP( FUNCTOR_file_no1, stream_file_no_prop ) ADD_SPROP( FUNCTOR_buffer1, stream_buffer_prop ) ADD_SPROP( FUNCTOR_buffer_size1, stream_buffer_size_prop ) ADD_SPROP( FUNCTOR_close_on_abort1,stream_close_on_abort_prop ) ADD_SPROP( FUNCTOR_tty1, stream_tty_prop ) ADD_SPROP( FUNCTOR_encoding1, stream_encoding_prop ) ADD_SPROP( FUNCTOR_bom1, stream_bom_prop ) ADD_SPROP( FUNCTOR_newline1, stream_newline_prop ) ADD_SPROP( FUNCTOR_representation_errors1, stream_reperror_prop ) ADD_SPROP( FUNCTOR_timeout1, stream_timeout_prop ) ADD_SPROP( FUNCTOR_nlink1, stream_nlink_prop ) END_SPROP_DEFS( 0, NULL) #else static const sprop sprop_list [] = { { FUNCTOR_file_name1, stream_file_name_propery }, { FUNCTOR_mode1, stream_mode_property }, { FUNCTOR_input0, stream_input_prop }, { FUNCTOR_output0, stream_output_prop }, { FUNCTOR_alias1, stream_alias_prop }, { FUNCTOR_position1, stream_position_prop }, { FUNCTOR_end_of_stream1, stream_end_of_stream_prop }, { FUNCTOR_eof_action1, stream_eof_action_prop }, { FUNCTOR_reposition1, stream_reposition_prop }, { FUNCTOR_type1, stream_type_prop }, { FUNCTOR_file_no1, stream_file_no_prop }, { FUNCTOR_buffer1, stream_buffer_prop }, { FUNCTOR_buffer_size1, stream_buffer_size_prop }, { FUNCTOR_close_on_abort1,stream_close_on_abort_prop }, { FUNCTOR_tty1, stream_tty_prop }, { FUNCTOR_encoding1, stream_encoding_prop }, { FUNCTOR_bom1, stream_bom_prop }, { FUNCTOR_newline1, stream_newline_prop }, { FUNCTOR_representation_errors1, stream_reperror_prop }, { FUNCTOR_timeout1, stream_timeout_prop }, { FUNCTOR_nlink1, stream_nlink_prop }, { 0, NULL } }; #endif typedef struct { TableEnum e; /* Enumerator on stream-table */ IOSTREAM *s; /* Stream we are enumerating */ const sprop *p; /* Pointer in properties */ int fixed_p; /* Propety is given */ } prop_enum; static PRED_IMPL("stream_property", 2, stream_property, PL_FA_ISO|PL_FA_NONDETERMINISTIC) { PRED_LD IOSTREAM *s; prop_enum *pe; fid_t fid; term_t a1; term_t stream = A1; term_t property = A2; switch( CTX_CNTRL ) { case FRG_FIRST_CALL: a1 = PL_new_term_ref(); if ( PL_is_variable(stream) ) /* generate */ { const sprop *p = sprop_list; int fixed = FALSE; functor_t f; if ( PL_get_functor(property, &f) ) /* test for defined property */ { for( ; p->functor; p++ ) { if ( f == p->functor ) { fixed = TRUE; break; } } if ( !p->functor ) return PL_error(NULL, 0, NULL, ERR_DOMAIN, ATOM_stream_property, property); } pe = allocHeap(sizeof(*pe)); pe->e = newTableEnum(streamContext); pe->s = NULL; pe->p = p; pe->fixed_p = fixed; break; } LOCK(); /* given stream */ if ( get_stream_handle(stream, &s, SH_ERRORS|SH_UNLOCKED) ) { functor_t f; if ( PL_is_variable(property) ) /* generate properties */ { pe = allocHeap(sizeof(*pe)); pe->e = NULL; pe->s = s; pe->p = sprop_list; pe->fixed_p = FALSE; UNLOCK(); break; } if ( PL_get_functor(property, &f) ) { const sprop *p = sprop_list; for( ; p->functor; p++ ) { if ( f == p->functor ) { int rval; switch(arityFunctor(f)) { case 0: rval = (*p->function)(s PASS_LD); break; case 1: { term_t a1 = PL_new_term_ref(); _PL_get_arg(1, property, a1); rval = (*p->function)(s, a1 PASS_LD); break; } default: assert(0); rval = FALSE; } UNLOCK(); return rval; } } } else { UNLOCK(); return PL_error(NULL, 0, NULL, ERR_DOMAIN, ATOM_stream_property, property); } } UNLOCK(); return FALSE; /* bad stream handle */ case FRG_REDO: { pe = CTX_PTR; a1 = PL_new_term_ref(); break; } case FRG_CUTTED: { pe = CTX_PTR; if ( pe ) /* 0 if exception on FRG_FIRST_CALL */ { if ( pe->e ) freeTableEnum(pe->e); freeHeap(pe, sizeof(*pe)); } return TRUE; } default: assert(0); return FALSE; } fid = PL_open_foreign_frame(); for(;;) { if ( pe->s ) /* given stream */ { fid_t fid2; if ( PL_is_variable(stream) ) { if ( !PL_unify_stream(stream, pe->s) ) goto enum_e; } fid2 = PL_open_foreign_frame(); for( ; pe->p->functor ; pe->p++ ) { if ( PL_unify_functor(property, pe->p->functor) ) { int rval; switch(arityFunctor(pe->p->functor)) { case 0: rval = (*pe->p->function)(pe->s PASS_LD); break; case 1: { _PL_get_arg(1, property, a1); rval = (*pe->p->function)(pe->s, a1 PASS_LD); break; } default: assert(0); rval = FALSE; } if ( rval ) { if ( pe->fixed_p ) pe->s = NULL; else pe->p++; ForeignRedoPtr(pe); } } if ( pe->fixed_p ) break; PL_rewind_foreign_frame(fid2); } PL_close_foreign_frame(fid2); pe->s = NULL; } enum_e: if ( pe->e ) { Symbol symb; while ( (symb=advanceTableEnum(pe->e)) ) { PL_rewind_foreign_frame(fid); if ( PL_unify_stream(stream, symb->name) ) { pe->s = symb->name; if ( !pe->fixed_p ) pe->p = sprop_list; break; } } } if ( !pe->s ) { if ( pe->e ) freeTableEnum(pe->e); freeHeap(pe, sizeof(*pe)); return FALSE; } } } static PRED_IMPL("is_stream", 1, is_stream, 0) { GET_LD IOSTREAM *s; if ( get_stream_handle(A1, &s, SH_SAFE) ) { releaseStream(s); return TRUE; } return FALSE; } /******************************* * FLUSH * *******************************/ static int flush_output(term_t out) { IOSTREAM *s; if ( getOutputStream(out, &s) ) { Sflush(s); return streamStatus(s); } return FALSE; } static PRED_IMPL("flush_output", 0, flush_output, PL_FA_ISO) { return flush_output(0); } static PRED_IMPL("flush_output", 1, flush_output1, PL_FA_ISO) { return flush_output(A1); } static int getStreamWithPosition(term_t stream, IOSTREAM **sp) { IOSTREAM *s; if ( PL_get_stream_handle(stream, &s) ) { if ( !s->position ) { PL_error(NULL, 0, NULL, ERR_PERMISSION, /* non-ISO */ ATOM_property, ATOM_position, stream); releaseStream(s); return FALSE; } *sp = s; return TRUE; } return FALSE; } static int getRepositionableStream(term_t stream, IOSTREAM **sp) { GET_LD IOSTREAM *s; if ( get_stream_handle(stream, &s, SH_ERRORS) ) { if ( !s->position || !s->functions || !s->functions->seek ) { PL_error(NULL, 0, NULL, ERR_PERMISSION, ATOM_reposition, ATOM_stream, stream); releaseStream(s); return FALSE; } *sp = s; return TRUE; } return FALSE; } static PRED_IMPL("set_stream_position", 2, set_stream_position, PL_FA_ISO) { PRED_LD IOSTREAM *s; int64_t charno, byteno; long linepos, lineno; term_t a = PL_new_term_ref(); term_t stream = A1; term_t pos = A2; if ( !(getRepositionableStream(stream, &s)) ) return FALSE; if ( !PL_is_functor(pos, FUNCTOR_stream_position4) || !PL_get_arg(1, pos, a) || !PL_get_int64(a, &charno) || !PL_get_arg(2, pos, a) || !PL_get_long(a, &lineno) || !PL_get_arg(3, pos, a) || !PL_get_long(a, &linepos) || !PL_get_arg(4, pos, a) || !PL_get_int64(a, &byteno) ) { releaseStream(s); return PL_error("stream_position", 3, NULL, ERR_DOMAIN, ATOM_stream_position, pos); } if ( Sseek64(s, byteno, SIO_SEEK_SET) != 0 ) return PL_error(NULL, 0, MSG_ERRNO, ERR_FILE_OPERATION, ATOM_reposition, ATOM_stream, stream); s->position->byteno = byteno; s->position->charno = charno; s->position->lineno = (int)lineno; s->position->linepos = (int)linepos; releaseStream(s); return TRUE; } static PRED_IMPL("seek", 4, seek, 0) { PRED_LD atom_t m; int whence = -1; int64_t off, new; IOSTREAM *s; term_t stream = A1; term_t offset = A2; term_t method = A3; term_t newloc = A4; if ( !(PL_get_atom_ex(method, &m)) ) return FALSE; if ( m == ATOM_bof ) whence = SIO_SEEK_SET; else if ( m == ATOM_current ) whence = SIO_SEEK_CUR; else if ( m == ATOM_eof ) whence = SIO_SEEK_END; else return PL_error("seek", 4, NULL, ERR_DOMAIN, ATOM_seek_method, method); if ( !PL_get_int64(offset, &off) ) return PL_error("seek", 4, NULL, ERR_DOMAIN, ATOM_integer, offset); if ( PL_get_stream_handle(stream, &s) ) { int unit = Sunit_size(s); off *= unit; if ( Sseek64(s, off, whence) < 0 ) { if ( errno == EINVAL ) PL_error("seek", 4, "offset out of range", ERR_DOMAIN, ATOM_position, offset); else PL_error("seek", 4, OsError(), ERR_PERMISSION, ATOM_reposition, ATOM_stream, stream); Sclearerr(s); releaseStream(s); return FALSE; } new = Stell64(s); releaseStream(s); new /= unit; return PL_unify_int64(newloc, new); } return FALSE; } static PRED_IMPL("set_input", 1, set_input, PL_FA_ISO) { PRED_LD IOSTREAM *s; if ( getInputStream(A1, &s) ) { Scurin = s; releaseStream(s); return TRUE; } return FALSE; } static PRED_IMPL("set_output", 1, set_output, PL_FA_ISO) { PRED_LD IOSTREAM *s; if ( getOutputStream(A1, &s) ) { Scurout = s; releaseStream(s); return TRUE; } return FALSE; } static PRED_IMPL("current_input", 1, current_input, PL_FA_ISO) { PRED_LD return PL_unify_stream(A1, Scurin); } static PRED_IMPL("current_output", 1, current_output, PL_FA_ISO) { PRED_LD return PL_unify_stream(A1, Scurout); } static PRED_IMPL("byte_count", 2, byte_count, 0) { IOSTREAM *s; if ( getStreamWithPosition(A1, &s) ) { int64_t n = s->position->byteno; releaseStream(s); return PL_unify_int64(A2, n); } return FALSE; } static PRED_IMPL("character_count", 2, character_count, 0) { IOSTREAM *s; if ( getStreamWithPosition(A1, &s) ) { int64_t n = s->position->charno; releaseStream(s); return PL_unify_int64(A2, n); } return FALSE; } static PRED_IMPL("line_count", 2, line_count, 0) { GET_LD IOSTREAM *s; if ( getStreamWithPosition(A1, &s) ) { intptr_t n = s->position->lineno; releaseStream(s); return PL_unify_integer(A2, n); } return FALSE; } static PRED_IMPL("line_position", 2, line_position, 0) { GET_LD IOSTREAM *s; if ( getStreamWithPosition(A1, &s) ) { intptr_t n = s->position->linepos; releaseStream(s); return PL_unify_integer(A2, n); } return FALSE; } static PRED_IMPL("source_location", 2, source_location, 0) { PRED_LD if ( ReadingSource && PL_unify_atom(A1, source_file_name) && PL_unify_integer(A2, source_line_no) ) return TRUE; return FALSE; } static int at_end_of_stream(term_t stream ARG_LD) { IOSTREAM *s; if ( getInputStream(stream, &s) ) { int rval = Sfeof(s); if ( rval < 0 ) { PL_error(NULL, 0, "not-buffered stream", ERR_PERMISSION, ATOM_end_of_stream, ATOM_stream, stream); rval = FALSE; } if ( rval && Sferror(s) ) /* due to error */ return streamStatus(s); else releaseStream(s); return rval; } return FALSE; /* exception */ } static PRED_IMPL("at_end_of_stream", 1, at_end_of_stream, PL_FA_ISO) { PRED_LD return at_end_of_stream(A1 PASS_LD); } static PRED_IMPL("at_end_of_stream", 0, at_end_of_stream0, PL_FA_ISO) { PRED_LD return at_end_of_stream(0 PASS_LD); } static foreign_t peek(term_t stream, term_t chr, int how ARG_LD) { IOSTREAM *s; IOPOS pos; int c; if ( !getInputStream(stream, &s) ) return FALSE; pos = s->posbuf; if ( how == PL_BYTE ) { c = Sgetc(s); if ( c != EOF ) Sungetc(c, s); } else { c = Sgetcode(s); if ( c != EOF ) Sungetcode(c, s); } s->posbuf = pos; if ( Sferror(s) ) return streamStatus(s); releaseStream(s); return PL_unify_char(chr, c, how); } static PRED_IMPL("peek_byte", 2, peek_byte2, 0) { PRED_LD return peek(A1, A2, PL_BYTE PASS_LD); } static PRED_IMPL("peek_byte", 1, peek_byte1, 0) { PRED_LD return peek(0, A1, PL_BYTE PASS_LD); } static PRED_IMPL("peek_code", 2, peek_code2, 0) { PRED_LD return peek(A1, A2, PL_CODE PASS_LD); } static PRED_IMPL("peek_code", 1, peek_code1, 0) { PRED_LD return peek(0, A1, PL_CODE PASS_LD); } static PRED_IMPL("peek_char", 2, peek_char2, 0) { PRED_LD return peek(A1, A2, PL_CHAR PASS_LD); } static PRED_IMPL("peek_char", 1, peek_char1, 0) { PRED_LD return peek(0, A1, PL_CHAR PASS_LD); } /******************************* * INTERACTION * *******************************/ /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - set_prolog_IO(+In, +Out, +Error) - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ typedef struct wrappedIO { void *wrapped_handle; /* original handle */ IOFUNCTIONS *wrapped_functions; /* original functions */ IOSTREAM *wrapped_stream; /* stream we wrapped */ IOFUNCTIONS functions; /* new function block */ } wrappedIO; ssize_t Sread_user(void *handle, char *buf, size_t size) { GET_LD wrappedIO *wio = handle; if ( LD->prompt.next && ttymode != TTY_RAW ) PL_write_prompt(TRUE); else Sflush(Suser_output); size = (*wio->wrapped_functions->read)(wio->wrapped_handle, buf, size); if ( size == 0 ) /* end-of-file */ { Sclearerr(Suser_input); LD->prompt.next = TRUE; } else if ( size > 0 && buf[size-1] == '\n' ) LD->prompt.next = TRUE; return size; } static int closeWrappedIO(void *handle) { wrappedIO *wio = handle; int rval; if ( wio->wrapped_functions->close ) rval = (*wio->wrapped_functions->close)(wio->wrapped_handle); else rval = 0; wio->wrapped_stream->functions = wio->wrapped_functions; wio->wrapped_stream->handle = wio->wrapped_handle; PL_free(wio); return rval; } static void wrapIO(IOSTREAM *s, ssize_t (*read)(void *, char *, size_t), ssize_t (*write)(void *, char *, size_t)) { wrappedIO *wio = PL_malloc(sizeof(*wio)); wio->wrapped_functions = s->functions; wio->wrapped_handle = s->handle; wio->wrapped_stream = s; wio->functions = *s->functions; if ( read ) wio->functions.read = read; if ( write ) wio->functions.write = write; wio->functions.close = closeWrappedIO; s->functions = &wio->functions; s->handle = wio; } static PRED_IMPL("set_prolog_IO", 3, set_prolog_IO, 0) { PRED_LD IOSTREAM *in = NULL, *out = NULL, *error = NULL; int rval = FALSE; if ( !PL_get_stream_handle(A1, &in) || !PL_get_stream_handle(A2, &out) ) goto out; if ( PL_compare(A2, A3) == 0 ) /* == */ { error = getStream(Snew(out->handle, out->flags, out->functions)); error->flags &= ~SIO_ABUF; /* disable buffering */ error->flags |= SIO_NBUF; } else { if ( !PL_get_stream_handle(A3, &error) ) goto out; } LOCK(); out->flags &= ~SIO_ABUF; /* output: line buffered */ out->flags |= SIO_LBUF; LD->IO.streams[0] = in; /* user_input */ LD->IO.streams[1] = out; /* user_output */ LD->IO.streams[2] = error; /* user_error */ LD->IO.streams[3] = in; /* current_input */ LD->IO.streams[4] = out; /* current_output */ wrapIO(in, Sread_user, NULL); LD->prompt.next = TRUE; UNLOCK(); rval = TRUE; out: if ( in ) releaseStream(in); if ( out ) releaseStream(out); if ( error && error != out ) releaseStream(error); return rval; } static PRED_IMPL("$size_stream", 2, size_stream, 0) { GET_LD IOSTREAM *s; int rval; if ( !PL_get_stream_handle(A1, &s) ) return FALSE; rval = PL_unify_integer(A2, Ssize(s)); PL_release_stream(s); return rval; } /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - copy_stream_data(+StreamIn, +StreamOut, [Len]) Copy all data from StreamIn to StreamOut. Should be somewhere else, and maybe we need something else to copy resources. - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ static int copy_stream_data(term_t in, term_t out, term_t len ARG_LD) { IOSTREAM *i, *o; int c; int count = 0; if ( !getInputStream(in, &i) ) return FALSE; if ( !getOutputStream(out, &o) ) { releaseStream(i); return FALSE; } if ( !len ) { while ( (c = Sgetcode(i)) != EOF ) { if ( (++count % 4096) == 0 && PL_handle_signals() < 0 ) { releaseStream(i); releaseStream(o); return FALSE; } if ( Sputcode(c, o) < 0 ) { releaseStream(i); return streamStatus(o); } } } else { int64_t n; if ( !PL_get_int64_ex(len, &n) ) return FALSE; while ( n-- > 0 && (c = Sgetcode(i)) != EOF ) { if ( (++count % 4096) == 0 && PL_handle_signals() < 0 ) { releaseStream(i); releaseStream(o); return FALSE; } if ( Sputcode(c, o) < 0 ) { releaseStream(i); return streamStatus(o); } } } releaseStream(o); return streamStatus(i); } static PRED_IMPL("copy_stream_data", 3, copy_stream_data3, 0) { PRED_LD return copy_stream_data(A1, A2, A3 PASS_LD); } static PRED_IMPL("copy_stream_data", 2, copy_stream_data2, 0) { PRED_LD return copy_stream_data(A1, A2, 0 PASS_LD); } /******************************* * PUBLISH PREDICATES * *******************************/ BeginPredDefs(file) /* ISO IO */ PRED_DEF("swi_open", 4, open4, PL_FA_ISO) PRED_DEF("swi_open", 3, open3, PL_FA_ISO) PRED_DEF("swi_close", 1, close, PL_FA_ISO) PRED_DEF("swi_close", 2, close2, PL_FA_ISO) PRED_DEF("swi_set_input", 1, set_input, PL_FA_ISO) PRED_DEF("swi_set_output", 1, set_output, PL_FA_ISO) PRED_DEF("swi_current_input", 1, current_input, PL_FA_ISO) PRED_DEF("swi_current_output", 1, current_output, PL_FA_ISO) PRED_DEF("swi_get_code", 2, get_code2, PL_FA_ISO) PRED_DEF("swi_get_code", 1, get_code1, PL_FA_ISO) PRED_DEF("swi_get_char", 2, get_char2, PL_FA_ISO) PRED_DEF("swi_get_char", 1, get_char1, PL_FA_ISO) PRED_DEF("swi_get_byte", 2, get_byte2, PL_FA_ISO) PRED_DEF("swi_get_byte", 1, get_byte1, PL_FA_ISO) PRED_DEF("swi_peek_code", 2, peek_code2, PL_FA_ISO) PRED_DEF("swi_peek_code", 1, peek_code1, PL_FA_ISO) PRED_DEF("swi_peek_char", 2, peek_char2, PL_FA_ISO) PRED_DEF("swi_peek_char", 1, peek_char1, PL_FA_ISO) PRED_DEF("swi_peek_byte", 2, peek_byte2, PL_FA_ISO) PRED_DEF("swi_peek_byte", 1, peek_byte1, PL_FA_ISO) PRED_DEF("swi_put_byte", 2, put_byte2, PL_FA_ISO) PRED_DEF("swi_put_byte", 1, put_byte1, PL_FA_ISO) PRED_DEF("swi_put_code", 2, put_code2, PL_FA_ISO) PRED_DEF("swi_put_code", 1, put_code1, PL_FA_ISO) PRED_DEF("swi_put_char", 2, put_code2, PL_FA_ISO) PRED_DEF("swi_put_char", 1, put_code1, PL_FA_ISO) PRED_DEF("swi_flush_output", 0, flush_output, PL_FA_ISO) PRED_DEF("swi_flush_output", 1, flush_output1, PL_FA_ISO) PRED_DEF("swi_at_end_of_stream", 1, at_end_of_stream, PL_FA_ISO) PRED_DEF("swi_at_end_of_stream", 0, at_end_of_stream0, PL_FA_ISO) PRED_DEF("swi_stream_property", 2, stream_property, PL_FA_ISO|PL_FA_NONDETERMINISTIC) PRED_DEF("swi_set_stream_position", 2, set_stream_position, PL_FA_ISO) /* edinburgh IO */ PRED_DEF("swi_see", 1, see, 0) PRED_DEF("swi_seen", 0, seen, 0) PRED_DEF("swi_seeing", 1, seeing, 0) PRED_DEF("swi_tell", 1, tell, 0) PRED_DEF("swi_append", 1, append, 0) PRED_DEF("swi_told", 0, told, 0) PRED_DEF("swi_telling", 1, telling, 0) PRED_DEF("swi_put", 2, put2, 0) PRED_DEF("swi_put", 1, put1, 0) PRED_DEF("swi_skip", 1, skip1, 0) PRED_DEF("swi_skip", 2, skip2, 0) PRED_DEF("swi_get", 1, get1, 0) PRED_DEF("swi_get", 2, get2, 0) PRED_DEF("swi_get0", 2, get_code2, 0) PRED_DEF("swi_get0", 1, get_code1, 0) PRED_DEF("swi_ttyflush", 0, ttyflush, 0) PRED_DEF("swi_prompt", 2, prompt, 0) PRED_DEF("swi_tab", 2, tab2, 0) PRED_DEF("swi_tab", 1, tab1, 0) /* Quintus IO */ PRED_DEF("swi_byte_count", 2, byte_count, 0) PRED_DEF("swi_character_count", 2, character_count, 0) PRED_DEF("swi_line_count", 2, line_count, 0) PRED_DEF("swi_line_position", 2, line_position, 0) PRED_DEF("swi_open_null_stream", 1, open_null_stream, 0) /* SWI specific */ PRED_DEF("swi_is_stream", 1, is_stream, 0) PRED_DEF("swi_set_stream", 2, set_stream, 0) PRED_DEF("swi_with_output_to", 2, with_output_to, PL_FA_TRANSPARENT) PRED_DEF("swi_set_prolog_IO", 3, set_prolog_IO, 0) PRED_DEF("swi_protocol", 1, protocol, 0) PRED_DEF("swi_protocola", 1, protocola, 0) PRED_DEF("swi_noprotocol", 0, noprotocol, 0) PRED_DEF("swi_protocolling", 1, protocolling, 0) PRED_DEF("swi_prompt1", 1, prompt1, 0) PRED_DEF("swi_seek", 4, seek, 0) PRED_DEF("swi_wait_for_input", 3, wait_for_input, 0) PRED_DEF("swi_get_single_char", 1, get_single_char, 0) PRED_DEF("swi_read_pending_input", 3, read_pending_input, 0) PRED_DEF("swi_source_location", 2, source_location, 0) PRED_DEF("swi_copy_stream_data", 3, copy_stream_data3, 0) PRED_DEF("swi_copy_stream_data", 2, copy_stream_data2, 0) /* SWI internal */ PRED_DEF("swi_$push_input_context", 0, push_input_context, 0) PRED_DEF("swi_$pop_input_context", 0, pop_input_context, 0) PRED_DEF("swi_$size_stream", 2, size_stream, 0) EndPredDefs #if __YAP_PROLOG__ static void init_yap_extras() { initCharTypes(); init_standardStreams(); init_encoding_names(); init_open4_options(); init_close2_options(); init_sprop_list(); PL_register_extensions(PL_predicates_from_file); fileerrors = TRUE; SinitStreams(); } #ifdef _WIN32 #include int WINAPI PROTO(win_plstream, (HANDLE, DWORD, LPVOID)); int WINAPI win_plstream(HANDLE hinst, DWORD reason, LPVOID reserved) { switch (reason) { case DLL_PROCESS_ATTACH: break; case DLL_PROCESS_DETACH: break; case DLL_THREAD_ATTACH: break; case DLL_THREAD_DETACH: break; } return 1; } #endif #endif