Mercurial > hg > xemacs-beta
view src/lstream.c @ 70:131b0175ea99 r20-0b30
Import from CVS: tag r20-0b30
| author | cvs |
|---|---|
| date | Mon, 13 Aug 2007 09:02:59 +0200 |
| parents | 441bb1e64a06 |
| children | 54cc21c15cbb |
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/* Generic stream implementation. Copyright (C) 1995 Free Software Foundation, Inc. Copyright (C) 1995 Sun Microsystems, Inc. Copyright (C) 1996 Ben Wing. This file is part of XEmacs. XEmacs is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. XEmacs 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 General Public License for more details. You should have received a copy of the GNU General Public License along with XEmacs; see the file COPYING. If not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /* Synched up with: Not in FSF. */ /* Written by Ben Wing. */ #include <config.h> #include "lisp.h" #include "buffer.h" #include "insdel.h" #include "lstream.h" #include "sysfile.h" #include <errno.h> /* This function provides a generic buffering stream implementation. Conceptually, you send data to the stream or read data from the stream, not caring what's on the other end of the stream. The other end could be another stream, a file descriptor, a stdio stream, a fixed block of memory, a reallocating block of memory, etc. The main purpose of the stream is to provide a standard interface and to do buffering. Macros are defined to read or write characters, so the calling functions do not have to worry about blocking data together in order to achieve efficiency. */ /* Note that this object is called "stream" in Lisp but "lstream" in C. The reason for this is that "stream" is too generic a name for C; too much likelihood of conflict/confusion with C++, etc. */ /* Functions are as follows: Lstream *Lstream_new (Lstream_implementation *imp, CONST char *mode) Allocate and return a new Lstream. This function is not really meant to be called directly; rather, each stream type should provide its own stream creation function, which creates the stream and does any other necessary creation stuff (e.g. opening a file). void Lstream_set_buffering (Lstream *lstr, Lstream_buffering buffering, int buffering_size) Change the buffering of a stream. See lstream.h. By default the buffering is STREAM_BLOCK_BUFFERED. int Lstream_flush (Lstream *lstr) Flush out any pending unwritten data in the stream. Clear any buffered input data. Returns 0 on success, -1 on error. int Lstream_putc (Lstream *stream, int c) Write out one byte to the stream. This is a macro and so it is very efficient. The C argument is only evaluated once but the STREAM argument is evaluated more than once. Returns 0 on success, -1 on error. int Lstream_getc (Lstream *stream) Read one byte from the stream. This is a macro and so it is very efficient. The STREAM argument is evaluated more than once. Return value is -1 for EOF or error. void Lstream_ungetc (Lstream *stream, int c) Push one byte back onto the input queue. This will be the next byte read from the stream. Any number of bytes can be pushed back and will be read in the reverse order they were pushed back -- most recent first. (This is necessary for consistency -- if there are a number of bytes that have been unread and I read and unread a byte, it needs to be the first to be read again.) This is a macro and so it is very efficient. The C argument is only evaluated once but the STREAM argument is evaluated more than once. int Lstream_fputc (Lstream *stream, int c) int Lstream_fgetc (Lstream *stream) void Lstream_fungetc (Lstream *stream, int c) Function equivalents of the above macros. int Lstream_read (Lstream *stream, void *data, int size) Read SIZE bytes of DATA from the stream. Return the number of bytes read. 0 means EOF. -1 means an error occurred and no bytes were read. int Lstream_write (Lstream *stream, void *data, int size) Write SIZE bytes of DATA to the stream. Return the number of bytes written. -1 means an error occurred and no bytes were written. void Lstream_unread (Lstream *stream, void *data, int size) Push back SIZE bytes of DATA onto the input queue. The next call to Lstream_read() with the same size will read the same bytes back. Note that this will be the case even if there is other pending unread data. int Lstream_close (Lstream *stream) Close the stream. All data will be flushed out. void Lstream_reopen (Lstream *stream) Reopen a closed stream. This enables I/O on it again. This is not meant to be called except from a wrapper routine that reinitializes variables and such -- the close routine may well have freed some necessary storage structures, for example. void Lstream_rewind (Lstream *stream) Rewind the stream to the beginning. */ #ifdef MULE MAC_DEFINE (Emchar, MTlstream_emchar) MAC_DEFINE (int, MTlstream_emcint) #endif MAC_DEFINE (struct lstream *, MTlstream_data) static Lisp_Object mark_lstream (Lisp_Object, void (*) (Lisp_Object)); static void print_lstream (Lisp_Object obj, Lisp_Object printcharfun, int escapeflag); static void finalize_lstream (void *header, int for_disksave); static unsigned int sizeof_lstream (CONST void *header); DEFINE_LRECORD_SEQUENCE_IMPLEMENTATION ("stream", lstream, mark_lstream, print_lstream, finalize_lstream, 0, 0, sizeof_lstream, Lstream); #define DEFAULT_BLOCK_BUFFERING_SIZE 512 #define MAX_READ_SIZE 512 static Lisp_Object mark_lstream (Lisp_Object obj, void (*markobj) (Lisp_Object)) { Lstream *lstr = XLSTREAM (obj); if (lstr->imp->marker) return (lstr->imp->marker) (obj, markobj); else return Qnil; } static void print_lstream (Lisp_Object obj, Lisp_Object printcharfun, int escapeflag) { Lstream *lstr = XLSTREAM (obj); char buf[200]; sprintf (buf, "#<INTERNAL EMACS BUG (%s lstream) 0x%x>", lstr->imp->name, (EMACS_INT) lstr); write_c_string (buf, printcharfun); } static void finalize_lstream (void *header, int for_disksave) { /* WARNING WARNING WARNING. This function (and all finalize functions) may get called more than once on the same object, and may get called (at dump time) on objects that are not being released. */ Lstream *lstr = (Lstream *) header; #if 0 /* this may cause weird Broken Pipes? */ if (for_disksave) { Lstream_pseudo_close (lstr); return; } #endif if (lstr->flags & LSTREAM_FL_IS_OPEN) Lstream_close (lstr); } static unsigned int sizeof_lstream (CONST void *header) { CONST Lstream *lstr = (CONST Lstream *) header; return sizeof (*lstr) + lstr->imp->size - 1; } void Lstream_set_buffering (Lstream *lstr, Lstream_buffering buffering, int buffering_size) { lstr->buffering = buffering; switch (buffering) { case LSTREAM_UNBUFFERED: lstr->buffering_size = 0; break; case LSTREAM_BLOCK_BUFFERED: lstr->buffering_size = DEFAULT_BLOCK_BUFFERING_SIZE; break; case LSTREAM_BLOCKN_BUFFERED: lstr->buffering_size = buffering_size; break; case LSTREAM_LINE_BUFFERED: case LSTREAM_UNLIMITED: lstr->buffering_size = INT_MAX; break; } } static CONST Lstream_implementation *lstream_types[32]; static Lisp_Object Vlstream_free_list[32]; static int lstream_type_count; Lstream * Lstream_new (CONST Lstream_implementation *imp, CONST char *mode) { Lstream *p; int i; for (i = 0; i < lstream_type_count; i++) { if (lstream_types[i] == imp) break; } if (i == lstream_type_count) { assert (lstream_type_count < countof (lstream_types)); lstream_types[lstream_type_count] = imp; Vlstream_free_list[lstream_type_count] = make_lcrecord_list (sizeof (*p) + imp->size - 1, lrecord_lstream); lstream_type_count++; } p = XLSTREAM (allocate_managed_lcrecord (Vlstream_free_list[i])); /* Zero it out, except the header. */ memset ((char *) p + sizeof (p->header), 0, sizeof (*p) - sizeof (p->header) + imp->size - 1); p->imp = imp; Lstream_set_buffering (p, LSTREAM_BLOCK_BUFFERED, 0); p->flags = LSTREAM_FL_IS_OPEN; /* convert mode (one of "r", "w", "rc", "wc") to p->flags */ assert (mode[0] == 'r' || mode[0] == 'w'); assert (mode[1] == 'c' || mode[1] == '\0'); p->flags |= (mode[0] == 'r' ? LSTREAM_FL_READ : LSTREAM_FL_WRITE); if (mode[1] == 'c') p->flags |= LSTREAM_FL_NO_PARTIAL_CHARS; return p; } void Lstream_set_character_mode (Lstream *lstr) { lstr->flags |= LSTREAM_FL_NO_PARTIAL_CHARS; } void Lstream_delete (Lstream *lstr) { int i; Lisp_Object val = Qnil; XSETLSTREAM (val, lstr); for (i = 0; i < lstream_type_count; i++) { if (lstream_types[i] == lstr->imp) { free_managed_lcrecord (Vlstream_free_list[i], val); return; } } abort (); } static void signal_simple_internal_error (CONST char *reason, Lisp_Object obj) { #ifdef DEBUG_XEMACS abort (); #else signal_simple_error (reason, obj); #endif } void Lstream_reopen (Lstream *lstr) { if (lstr->flags & LSTREAM_FL_IS_OPEN) { Lisp_Object obj = Qnil; XSETLSTREAM (obj, lstr); signal_simple_internal_error ("Internal error: lstream already open", obj); } lstr->flags |= LSTREAM_FL_IS_OPEN; } /* Attempt to flush out all of the buffered data for writing. */ int Lstream_flush_out (Lstream *lstr) { int num_written; while (lstr->out_buffer_ind > 0) { int size = lstr->out_buffer_ind; if (! (lstr->flags & LSTREAM_FL_IS_OPEN)) { Lisp_Object obj = Qnil; XSETLSTREAM (obj, lstr); signal_simple_internal_error ("Internal error: lstream not open", obj); } if (! (lstr->flags & LSTREAM_FL_WRITE)) { Lisp_Object obj = Qnil; XSETLSTREAM (obj, lstr); signal_simple_internal_error ("Internal error: lstream not open for writing", obj); } if (!lstr->imp->writer) { Lisp_Object obj = Qnil; XSETLSTREAM (obj, lstr); signal_simple_internal_error ("Internal error: lstream has no writer", obj); } if (lstr->flags & LSTREAM_FL_NO_PARTIAL_CHARS) /* It's quite possible for us to get passed an incomplete character at the end. We need to spit back that incomplete character. */ { CONST unsigned char *data = lstr->out_buffer; CONST unsigned char *dataend = data + size - 1; assert (size > 0); /* safety check ... */ /* Optimize the most common case. */ if (!BYTE_ASCII_P (*dataend)) { /* Go back to the beginning of the last (and possibly partial) character, and bump forward to see if the character is complete. */ VALIDATE_CHARPTR_BACKWARD (dataend); if (dataend + REP_BYTES_BY_FIRST_BYTE (*dataend) != data + size) /* If not, chop the size down to ignore the last char and stash it away for next time. */ size = dataend - data; /* If we don't even have one character to write, then just skip out. */ if (size == 0) break; } } num_written = (lstr->imp->writer) (lstr, lstr->out_buffer, size); if (num_written == 0) /* If nothing got written, then just hold the data. This may occur, for example, if this stream does non-blocking I/O; the attempt to write the data might have resulted in an EWOULDBLOCK error. */ return 0; else if (num_written >= lstr->out_buffer_ind) lstr->out_buffer_ind = 0; else if (num_written > 0) { memmove (lstr->out_buffer, lstr->out_buffer + num_written, lstr->out_buffer_ind - num_written); lstr->out_buffer_ind -= num_written; } else /* If error, just hold the data, for similar reasons as above. */ return -1; } if (lstr->imp->flusher) return (lstr->imp->flusher) (lstr); return 0; } int Lstream_flush (Lstream *lstr) { if (Lstream_flush_out (lstr) < 0) return -1; /* clear out buffered data */ lstr->in_buffer_current = lstr->in_buffer_ind = 0; lstr->unget_buffer_ind = 0; return 0; } /* We want to add NUM characters. This function ensures that the buffer is large enough for this (per the buffering size specified in the stream) and returns the number of characters we can actually write. If FORCE is set, ignore the buffering size and go ahead and make space for all the chars even if it exceeds the buffering size. (This is used to deal with the possibility that the stream writer might refuse to write any bytes now, e.g. if it's getting EWOULDBLOCK errors. We have to keep stocking them up until they can be written, so as to avoid losing data. */ static int Lstream_adding (Lstream *lstr, int num, int force) { /* Compute the size that the outbuffer needs to be after the chars are added. */ int size_needed = max (lstr->out_buffer_size, num + lstr->out_buffer_ind); /* Maybe chop it down so that we don't buffer more characters than our advertised buffering size. */ if (!force) size_needed = min (lstr->buffering_size, size_needed); DO_REALLOC (lstr->out_buffer, lstr->out_buffer_size, size_needed, unsigned char); /* There might be more data buffered than the buffering size, so make sure we don't return a negative number here. */ return max (0, min (num, size_needed - lstr->out_buffer_ind)); } /* Like Lstream_write(), but does not handle line-buffering correctly. */ static int Lstream_write_1 (Lstream *lstr, CONST void *data, int size) { CONST unsigned char *p = data; int off = 0; if (! (lstr->flags & LSTREAM_FL_IS_OPEN)) { Lisp_Object obj = Qnil; XSETLSTREAM (obj, lstr); signal_simple_internal_error ("Internal error: lstream not open", obj); } if (! (lstr->flags & LSTREAM_FL_WRITE)) { Lisp_Object obj = Qnil; XSETLSTREAM (obj, lstr); signal_simple_internal_error ("Internal error: lstream not open for writing", obj); } { int couldnt_write_last_time = 0; while (1) { /* Figure out how much we can add to the buffer */ int chunk = Lstream_adding (lstr, size, 0); if (chunk == 0) { if (couldnt_write_last_time) /* Ung, we ran out of space and tried to flush the buffer, but it didn't work because the stream writer is refusing to accept any data. So we just have to squirrel away all the rest of the stuff. */ chunk = Lstream_adding (lstr, size, 1); else couldnt_write_last_time = 1; } /* Do it. */ if (chunk > 0) { memcpy (lstr->out_buffer + lstr->out_buffer_ind, p + off, chunk); lstr->out_buffer_ind += chunk; lstr->byte_count += chunk; size -= chunk; off += chunk; } /* If the buffer is full and we have more to add, flush it out. */ if (size > 0) { if (Lstream_flush_out (lstr) < 0) { if (off == 0) return -1; else return off; } } else break; } } return off; } /* If the stream is not line-buffered, then we can just call Lstream_write_1(), which writes in chunks. Otherwise, we repeatedly call Lstream_putc(), which knows how to handle line buffering. */ int Lstream_write (Lstream *lstr, CONST void *data, int size) { int i; CONST unsigned char *p = data; assert (size >= 0); if (size == 0) return size; if (lstr->buffering != LSTREAM_LINE_BUFFERED) return Lstream_write_1 (lstr, data, size); for (i = 0; i < size; i++) { if (Lstream_putc (lstr, p[i]) < 0) break; } return i == 0 ? -1 : 0; } static int Lstream_raw_read (Lstream *lstr, unsigned char *buffer, int size) { if (! (lstr->flags & LSTREAM_FL_IS_OPEN)) { Lisp_Object obj = Qnil; XSETLSTREAM (obj, lstr); signal_simple_internal_error ("Internal error: lstream not open", obj); } if (! (lstr->flags & LSTREAM_FL_READ)) { Lisp_Object obj = Qnil; XSETLSTREAM (obj, lstr); signal_simple_internal_error ("Internal error: lstream not open for reading", obj); } if (!lstr->imp->reader) { Lisp_Object obj = Qnil; XSETLSTREAM (obj, lstr); signal_simple_internal_error ("Internal error: lstream has no reader", obj); } return (lstr->imp->reader) (lstr, buffer, size); } /* Assuming the buffer is empty, fill it up again. */ static int Lstream_read_more (Lstream *lstr) { #if 0 int size_needed = max (1, min (MAX_READ_SIZE, lstr->buffering_size)); #else /* If someone requested a larger buffer size, so be it! */ int size_needed = max (1, lstr->buffering_size); #endif int size_gotten; DO_REALLOC (lstr->in_buffer, lstr->in_buffer_size, size_needed, unsigned char); size_gotten = Lstream_raw_read (lstr, lstr->in_buffer, size_needed); lstr->in_buffer_current = max (0, size_gotten); lstr->in_buffer_ind = 0; return size_gotten < 0 ? -1 : size_gotten; } int Lstream_read (Lstream *lstr, void *data, int size) { unsigned char *p = (unsigned char *) data; int off = 0; int chunk; int error_occurred = 0; assert (size >= 0); if (size == 0) return 0; /* First try to get some data from the unget buffer */ chunk = min (size, lstr->unget_buffer_ind); if (chunk > 0) { /* The bytes come back in reverse order. */ for (; off < chunk; off++) p[off] = lstr->unget_buffer[--lstr->unget_buffer_ind]; lstr->byte_count += chunk; size -= chunk; } while (size > 0) { /* Take whatever we can from the in buffer */ chunk = min (size, lstr->in_buffer_current - lstr->in_buffer_ind); if (chunk > 0) { memcpy (p + off, lstr->in_buffer + lstr->in_buffer_ind, chunk); lstr->in_buffer_ind += chunk; lstr->byte_count += chunk; size -= chunk; off += chunk; } /* If we need some more, try to get some more from the stream's end */ if (size > 0) { int retval = Lstream_read_more (lstr); if (retval < 0) error_occurred = 1; if (retval <= 0) break; } } /* #### Beware of OFF ending up 0. */ if ((lstr->flags & LSTREAM_FL_NO_PARTIAL_CHARS) && off > 0) { /* It's quite possible for us to get passed an incomplete character at the end. We need to spit back that incomplete character. */ CONST unsigned char *dataend = p + off - 1; /* Optimize the most common case. */ if (!BYTE_ASCII_P (*dataend)) { /* Go back to the beginning of the last (and possibly partial) character, and bump forward to see if the character is complete. */ VALIDATE_CHARPTR_BACKWARD (dataend); if (dataend + REP_BYTES_BY_FIRST_BYTE (*dataend) != p + off) { int newoff = dataend - p; /* If not, chop the size down to ignore the last char and stash it away for next time. */ Lstream_unread (lstr, dataend, off - newoff); off = newoff; } } } return ((off == 0 && error_occurred) ? -1 : off); } void Lstream_unread (Lstream *lstr, CONST void *data, int size) { int i; unsigned char *p = (unsigned char *) data; /* Make sure buffer is big enough */ DO_REALLOC (lstr->unget_buffer, lstr->unget_buffer_size, lstr->unget_buffer_ind + size, unsigned char); /* Bytes have to go on in reverse order -- they are reversed again when read back. */ for (i = size - 1; i >= 0; i--) lstr->unget_buffer[lstr->unget_buffer_ind++] = p[i]; lstr->byte_count -= size; } int Lstream_rewind (Lstream *lstr) { if (!lstr->imp->rewinder) { Lisp_Object obj = Qnil; XSETLSTREAM (obj, lstr); signal_simple_internal_error ("Internal error: lstream has no rewinder", obj); } if (Lstream_flush (lstr) < 0) return -1; lstr->byte_count = 0; return (lstr->imp->rewinder) (lstr); } int Lstream_seekable_p (Lstream *lstr) { if (!lstr->imp->rewinder) return 0; if (!lstr->imp->seekable_p) return 1; return (lstr->imp->seekable_p) (lstr); } static int Lstream_pseudo_close (Lstream *lstr) { if (!lstr->flags & LSTREAM_FL_IS_OPEN) { Lisp_Object obj = Qnil; XSETLSTREAM (obj, lstr); signal_simple_internal_error ("Internal error: lstream is not open", obj); } /* don't check errors here -- best not to risk file descriptor loss */ Lstream_flush (lstr); return 0; } int Lstream_close (Lstream *lstr) { if (lstr->flags & LSTREAM_FL_IS_OPEN) { /* don't return here on error, or file descriptor leak will result. */ Lstream_pseudo_close (lstr); if (lstr->imp->closer) { if ((lstr->imp->closer) (lstr) < 0) return -1; } } lstr->flags &= ~LSTREAM_FL_IS_OPEN; lstr->byte_count = 0; /* Note that Lstream_flush() reset all the buffer indices. That way, the next call to Lstream_putc(), Lstream_getc(), or Lstream_ungetc() on a closed stream will call into the function equivalents, which will cause an error. */ /* We set the pointers to 0 so that we don't lose when this function is called more than once on the same object */ if (lstr->out_buffer) { xfree (lstr->out_buffer); lstr->out_buffer = 0; } if (lstr->in_buffer) { xfree (lstr->in_buffer); lstr->in_buffer = 0; } if (lstr->unget_buffer) { xfree (lstr->unget_buffer); lstr->unget_buffer = 0; } return 0; } int Lstream_fputc (Lstream *lstr, int c) { unsigned char ch = (unsigned char) c; int retval = Lstream_write_1 (lstr, &ch, 1); if (retval >= 0 && lstr->buffering == LSTREAM_LINE_BUFFERED && ch == '\n') return Lstream_flush_out (lstr); return retval < 0 ? -1 : 0; } int Lstream_fgetc (Lstream *lstr) { unsigned char ch; if (Lstream_read (lstr, &ch, 1) <= 0) return -1; return ch; } void Lstream_fungetc (Lstream *lstr, int c) { unsigned char ch = (unsigned char) c; Lstream_unread (lstr, &ch, 1); } /************************ some stream implementations *********************/ /*********** a stdio stream ***********/ struct stdio_stream { FILE *file; int closing; }; #define STDIO_STREAM_DATA(stream) LSTREAM_TYPE_DATA (stream, stdio) DEFINE_LSTREAM_IMPLEMENTATION ("stdio", lstream_stdio, sizeof (struct stdio_stream)); static Lisp_Object make_stdio_stream_1 (FILE *stream, int flags, CONST char *mode) { Lisp_Object obj = Qnil; Lstream *lstr = Lstream_new (lstream_stdio, mode); struct stdio_stream *str = STDIO_STREAM_DATA (lstr); str->file = stream; str->closing = flags & LSTR_CLOSING; XSETLSTREAM (obj, lstr); return obj; } Lisp_Object make_stdio_input_stream (FILE *stream, int flags) { return make_stdio_stream_1 (stream, flags, "r"); } Lisp_Object make_stdio_output_stream (FILE *stream, int flags) { return make_stdio_stream_1 (stream, flags, "w"); } static int stdio_reader (Lstream *stream, unsigned char *data, int size) { struct stdio_stream *str = STDIO_STREAM_DATA (stream); size_t val = fread (data, 1, (size_t) size, str->file); if (!val && ferror (str->file)) return -1; return (int) val; } static int stdio_writer (Lstream *stream, CONST unsigned char *data, int size) { struct stdio_stream *str = STDIO_STREAM_DATA (stream); size_t val = fwrite (data, 1, (size_t) size, str->file); if (!val && ferror (str->file)) return -1; return (int) val; } static int stdio_rewinder (Lstream *stream) { rewind (STDIO_STREAM_DATA (stream)->file); return 0; } static int stdio_seekable_p (Lstream *stream) { struct stdio_stream *str = STDIO_STREAM_DATA (stream); { struct stat lestat; if (fstat (fileno (str->file), &lestat) < 0) return 0; return S_ISREG (lestat.st_mode); } } static int stdio_flusher (Lstream *stream) { struct stdio_stream *str = STDIO_STREAM_DATA (stream); if (stream->flags & LSTREAM_FL_WRITE) return fflush (str->file); else /* call fpurge? Only exists on some systems. */ return 0; } static int stdio_closer (Lstream *stream) { struct stdio_stream *str = STDIO_STREAM_DATA (stream); if (str->closing) return fclose (str->file); else if (stream->flags & LSTREAM_FL_WRITE) return fflush (str->file); else /* call fpurge? Only exists on some systems. */ return 0; } /*********** a file descriptor ***********/ struct filedesc_stream { int fd; int pty_max_bytes; Bufbyte eof_char; int starting_pos; int current_pos; int end_pos; int chars_sans_newline; int closing :1; int allow_quit :1; int blocked_ok :1; int pty_flushing :1; int blocking_error_p :1; }; #define FILEDESC_STREAM_DATA(stream) LSTREAM_TYPE_DATA (stream, filedesc) DEFINE_LSTREAM_IMPLEMENTATION ("filedesc", lstream_filedesc, sizeof (struct filedesc_stream)); /* Make a stream that reads from or writes to a file descriptor FILEDESC. OFFSET is the offset from the *current* file pointer that the reading should start at. COUNT is the number of bytes to be read (it is ignored when writing); -1 for unlimited. */ static Lisp_Object make_filedesc_stream_1 (int filedesc, int offset, int count, int flags, CONST char *mode) { Lisp_Object obj = Qnil; Lstream *lstr = Lstream_new (lstream_filedesc, mode); struct filedesc_stream *fstr = FILEDESC_STREAM_DATA (lstr); fstr->fd = filedesc; fstr->closing = !!(flags & LSTR_CLOSING); fstr->allow_quit = !!(flags & LSTR_ALLOW_QUIT); fstr->blocked_ok = !!(flags & LSTR_BLOCKED_OK); fstr->pty_flushing = !!(flags & LSTR_PTY_FLUSHING); fstr->blocking_error_p = 0; fstr->chars_sans_newline = 0; fstr->starting_pos = lseek (filedesc, offset, SEEK_CUR); if (fstr->starting_pos < 0) fstr->current_pos = 0; else fstr->current_pos = fstr->starting_pos; if (count < 0) fstr->end_pos = -1; else fstr->end_pos = fstr->starting_pos + count; XSETLSTREAM (obj, lstr); return obj; } Lisp_Object make_filedesc_input_stream (int filedesc, int offset, int count, int flags) { return make_filedesc_stream_1 (filedesc, offset, count, flags, "r"); } Lisp_Object make_filedesc_output_stream (int filedesc, int offset, int count, int flags) { return make_filedesc_stream_1 (filedesc, offset, count, flags, "w"); } static int filedesc_reader (Lstream *stream, unsigned char *data, int size) { struct filedesc_stream *str = FILEDESC_STREAM_DATA (stream); if (str->end_pos >= 0) size = min (size, str->end_pos - str->current_pos); size = (str->allow_quit ? read_allowing_quit : read) (str->fd, data, size); if (size > 0) str->current_pos += size; return size; } static int errno_would_block_p (int val) { #ifdef EWOULDBLOCK if (val == EWOULDBLOCK) return 1; #endif #ifdef EAGAIN if (val == EAGAIN) return 1; #endif return 0; } static int filedesc_writer (Lstream *stream, CONST unsigned char *data, int size) { struct filedesc_stream *str = FILEDESC_STREAM_DATA (stream); int retval; int need_newline = 0; /* This function would be simple if it were not for the blasted PTY max-bytes stuff. Why the hell can't they just have written the PTY drivers right so this problem doesn't exist? Maybe all the PTY crap here should be moved into another stream that does nothing but periodically insert EOF's as necessary. */ if (str->pty_flushing) { /* To make life easy, only send out one line at the most. */ CONST unsigned char *ptr; ptr = memchr (data, '\n', size); if (ptr) need_newline = 1; else ptr = data + size; if (ptr - data >= str->pty_max_bytes - str->chars_sans_newline) { ptr = data + str->pty_max_bytes - str->chars_sans_newline; need_newline = 0; } size = ptr - data; } /**** start of non-PTY-crap ****/ if (size > 0) retval = ((str->allow_quit ? write_allowing_quit : write) (str->fd, data, size)); else retval = 0; if (retval < 0 && errno_would_block_p (errno) && str->blocked_ok) { str->blocking_error_p = 1; return 0; } str->blocking_error_p = 0; if (retval < 0) return retval; /**** end non-PTY-crap ****/ if (str->pty_flushing) { str->chars_sans_newline += retval; /* Note that a newline was not among the bytes written out. Add to the number of non-newline bytes written out, and flush with an EOF if necessary. Be careful to keep track of write errors as we go along and look out for EWOULDBLOCK. */ if (str->chars_sans_newline >= str->pty_max_bytes) { int retval2 = ((str->allow_quit ? write_allowing_quit : write) (str->fd, &str->eof_char, 1)); if (retval2 > 0) str->chars_sans_newline = 0; else if (retval2 < 0) { /* Error writing the EOF char. If nothing got written, then treat this as an error -- either return an error condition or set the blocking-error flag. */ if (retval == 0) { if (errno_would_block_p (errno) && str->blocked_ok) { str->blocking_error_p = 1; return 0; } else return retval2; } else return retval; } } } /* The need_newline flag is necessary because otherwise when the first byte is a newline, we'd get stuck never writing anything in pty-flushing mode. */ if (need_newline) { Bufbyte nl = '\n'; int retval2 = ((str->allow_quit ? write_allowing_quit : write) (str->fd, &nl, 1)); if (retval2 > 0) { str->chars_sans_newline = 0; retval++; } else if (retval2 < 0) { /* Error writing the newline char. If nothing got written, then treat this as an error -- either return an error condition or set the blocking-error flag. */ if (retval == 0) { if (errno_would_block_p (errno) && str->blocked_ok) { str->blocking_error_p = 1; return 0; } else return retval2; } else return retval; } } return retval; } static int filedesc_rewinder (Lstream *stream) { struct filedesc_stream *str = FILEDESC_STREAM_DATA (stream); if (str->starting_pos < 0 || lseek (FILEDESC_STREAM_DATA (stream)->fd, str->starting_pos, SEEK_SET) == -1) return -1; else { str->current_pos = str->starting_pos; return 0; } } static int filedesc_seekable_p (Lstream *stream) { struct filedesc_stream *str = FILEDESC_STREAM_DATA (stream); if (str->starting_pos < 0) return 0; else { struct stat lestat; if (fstat (str->fd, &lestat) < 0) return 0; return S_ISREG (lestat.st_mode); } } static int filedesc_closer (Lstream *stream) { struct filedesc_stream *str = FILEDESC_STREAM_DATA (stream); if (str->closing) return close (str->fd); else return 0; } void filedesc_stream_set_pty_flushing (Lstream *stream, int pty_max_bytes, Bufbyte eof_char) { struct filedesc_stream *str = FILEDESC_STREAM_DATA (stream); str->pty_max_bytes = pty_max_bytes; str->eof_char = eof_char; } int filedesc_stream_was_blocked (Lstream *stream) { struct filedesc_stream *str = FILEDESC_STREAM_DATA (stream); return str->blocking_error_p; } /*********** read from a Lisp string ***********/ #define LISP_STRING_STREAM_DATA(stream) LSTREAM_TYPE_DATA (stream, lisp_string) struct lisp_string_stream { Lisp_Object obj; Bytecount init_offset; Bytecount offset, end; }; DEFINE_LSTREAM_IMPLEMENTATION ("lisp-string", lstream_lisp_string, sizeof (struct lisp_string_stream)); Lisp_Object make_lisp_string_input_stream (Lisp_Object string, Bytecount offset, Bytecount len) { Lisp_Object obj = Qnil; Lstream *lstr; struct lisp_string_stream *str; CHECK_STRING (string); if (len < 0) len = XSTRING_LENGTH (string) - offset; assert (offset >= 0); assert (len >= 0); assert (offset + len <= XSTRING_LENGTH (string)); lstr = Lstream_new (lstream_lisp_string, "r"); str = LISP_STRING_STREAM_DATA (lstr); str->offset = offset; str->end = offset + len; str->init_offset = offset; str->obj = string; XSETLSTREAM (obj, lstr); return obj; } static int lisp_string_reader (Lstream *stream, unsigned char *data, int size) { struct lisp_string_stream *str = LISP_STRING_STREAM_DATA (stream); /* Don't lose if the string shrank past us ... */ Bytecount offset = min (str->offset, XSTRING_LENGTH (str->obj)); Bufbyte *strstart = XSTRING_DATA (str->obj); Bufbyte *start = strstart + offset; /* ... or if someone changed the string and we ended up in the middle of a character. */ /* Being in the middle of a character is `normal' unless LSTREAM_NO_PARTIAL_CHARS - mrb */ if (stream->flags & LSTREAM_FL_NO_PARTIAL_CHARS) VALIDATE_CHARPTR_BACKWARD (start); offset = start - strstart; size = min (size, str->end - offset); assert (size >= 0); /* paranoia */ memcpy (data, start, size); str->offset = offset + size; return size; } static int lisp_string_rewinder (Lstream *stream) { struct lisp_string_stream *str = LISP_STRING_STREAM_DATA (stream); int pos = str->init_offset; if (pos > str->end) pos = str->end; /* Don't lose if the string shrank past us ... */ pos = min (pos, XSTRING_LENGTH (str->obj)); /* ... or if someone changed the string and we ended up in the middle of a character. */ { Bufbyte *strstart = XSTRING_DATA (str->obj); Bufbyte *start = strstart + pos; VALIDATE_CHARPTR_BACKWARD (start); pos = start - strstart; } str->offset = pos; return 0; } static Lisp_Object lisp_string_marker (Lisp_Object stream, void (*markobj) (Lisp_Object)) { struct lisp_string_stream *str = LISP_STRING_STREAM_DATA (XLSTREAM (stream)); return str->obj; } /*********** a fixed buffer ***********/ #define FIXED_BUFFER_STREAM_DATA(stream) \ LSTREAM_TYPE_DATA (stream, fixed_buffer) struct fixed_buffer_stream { CONST unsigned char *inbuf; unsigned char *outbuf; int size; int offset; }; DEFINE_LSTREAM_IMPLEMENTATION ("fixed-buffer", lstream_fixed_buffer, sizeof (struct fixed_buffer_stream)); Lisp_Object make_fixed_buffer_input_stream (CONST unsigned char *buf, int size) { Lisp_Object obj = Qnil; Lstream *lstr; struct fixed_buffer_stream *str; lstr = Lstream_new (lstream_fixed_buffer, "r"); str = FIXED_BUFFER_STREAM_DATA (lstr); str->inbuf = buf; str->size = size; XSETLSTREAM (obj, lstr); return obj; } Lisp_Object make_fixed_buffer_output_stream (unsigned char *buf, int size) { Lisp_Object obj = Qnil; Lstream *lstr; struct fixed_buffer_stream *str; lstr = Lstream_new (lstream_fixed_buffer, "w"); str = FIXED_BUFFER_STREAM_DATA (lstr); str->outbuf = buf; str->size = size; XSETLSTREAM (obj, lstr); return obj; } static int fixed_buffer_reader (Lstream *stream, unsigned char *data, int size) { struct fixed_buffer_stream *str = FIXED_BUFFER_STREAM_DATA (stream); size = min (size, str->size - str->offset); memcpy (data, str->inbuf + str->offset, size); str->offset += size; return size; } static int fixed_buffer_writer (Lstream *stream, CONST unsigned char *data, int size) { struct fixed_buffer_stream *str = FIXED_BUFFER_STREAM_DATA (stream); if (str->offset == str->size) { /* If we're at the end, just throw away the data and pretend we wrote all of it. If we return 0, then the lstream routines will try again and again to write it out. */ return size; } size = min (size, str->size - str->offset); memcpy (str->outbuf + str->offset, data, size); str->offset += size; return size; } static int fixed_buffer_rewinder (Lstream *stream) { FIXED_BUFFER_STREAM_DATA (stream)->offset = 0; return 0; } CONST unsigned char * fixed_buffer_input_stream_ptr (Lstream *stream) { assert (stream->imp == lstream_fixed_buffer); return FIXED_BUFFER_STREAM_DATA (stream)->inbuf; } unsigned char * fixed_buffer_output_stream_ptr (Lstream *stream) { assert (stream->imp == lstream_fixed_buffer); return FIXED_BUFFER_STREAM_DATA (stream)->outbuf; } /*********** write to a resizing buffer ***********/ #define RESIZING_BUFFER_STREAM_DATA(stream) \ LSTREAM_TYPE_DATA (stream, resizing_buffer) struct resizing_buffer_stream { unsigned char *buf; int allocked; int max_stored; int stored; }; DEFINE_LSTREAM_IMPLEMENTATION ("resizing-buffer", lstream_resizing_buffer, sizeof (struct resizing_buffer_stream)); Lisp_Object make_resizing_buffer_output_stream (void) { Lisp_Object obj = Qnil; XSETLSTREAM (obj, Lstream_new (lstream_resizing_buffer, "w")); return obj; } static int resizing_buffer_writer (Lstream *stream, CONST unsigned char *data, int size) { struct resizing_buffer_stream *str = RESIZING_BUFFER_STREAM_DATA (stream); DO_REALLOC (str->buf, str->allocked, str->stored + size, unsigned char); memcpy (str->buf + str->stored, data, size); str->stored += size; str->max_stored = max (str->max_stored, str->stored); return size; } static int resizing_buffer_rewinder (Lstream *stream) { RESIZING_BUFFER_STREAM_DATA (stream)->stored = 0; return 0; } static int resizing_buffer_closer (Lstream *stream) { struct resizing_buffer_stream *str = RESIZING_BUFFER_STREAM_DATA (stream); if (str->buf) { xfree (str->buf); str->buf = 0; } return 0; } unsigned char * resizing_buffer_stream_ptr (Lstream *stream) { return RESIZING_BUFFER_STREAM_DATA (stream)->buf; } /*********** write to an unsigned-char dynarr ***********/ /* Note: If you have a dynarr whose type is not unsigned_char_dynarr but which is really just an unsigned_char_dynarr (e.g. its type is Bufbyte or Extbyte), just cast to unsigned_char_dynarr. */ #define DYNARR_STREAM_DATA(stream) \ LSTREAM_TYPE_DATA (stream, dynarr) struct dynarr_stream { unsigned_char_dynarr *dyn; }; DEFINE_LSTREAM_IMPLEMENTATION ("dynarr", lstream_dynarr, sizeof (struct dynarr_stream)); Lisp_Object make_dynarr_output_stream (unsigned_char_dynarr *dyn) { Lisp_Object obj = Qnil; XSETLSTREAM (obj, Lstream_new (lstream_dynarr, "w")); DYNARR_STREAM_DATA (XLSTREAM (obj))->dyn = dyn; return obj; } static int dynarr_writer (Lstream *stream, CONST unsigned char *data, int size) { struct dynarr_stream *str = DYNARR_STREAM_DATA (stream); Dynarr_add_many (str->dyn, data, size); return size; } static int dynarr_rewinder (Lstream *stream) { Dynarr_reset (DYNARR_STREAM_DATA (stream)->dyn); return 0; } static int dynarr_closer (Lstream *stream) { return 0; } /************ read from or write to a Lisp buffer ************/ /* Note: Lisp-buffer read streams never return partial characters, and Lisp-buffer write streams expect to never get partial characters. */ #define LISP_BUFFER_STREAM_DATA(stream) \ LSTREAM_TYPE_DATA (stream, lisp_buffer) struct lisp_buffer_stream { Lisp_Object buffer; Lisp_Object orig_start; /* we use markers to properly deal with insertion/deletion */ Lisp_Object start, end; int flags; }; DEFINE_LSTREAM_IMPLEMENTATION ("lisp-buffer", lstream_lisp_buffer, sizeof (struct lisp_buffer_stream)); static Lisp_Object make_lisp_buffer_stream_1 (struct buffer *buf, Bufpos start, Bufpos end, int flags, CONST char *mode) { Lisp_Object obj = Qnil; Lstream *lstr; struct lisp_buffer_stream *str; Bufpos bmin, bmax; int reading = !strcmp (mode, "r"); /* Make sure the luser didn't pass "w" in. */ if (!strcmp (mode, "w")) abort (); if (flags & LSTR_IGNORE_ACCESSIBLE) { bmin = BUF_BEG (buf); bmax = BUF_Z (buf); } else { bmin = BUF_BEGV (buf); bmax = BUF_ZV (buf); } if (start == -1) start = bmin; if (end == -1) end = bmax; assert (bmin <= start); assert (start <= bmax); if (reading) { assert (bmin <= end); assert (end <= bmax); assert (start <= end); } lstr = Lstream_new (lstream_lisp_buffer, mode); str = LISP_BUFFER_STREAM_DATA (lstr); { Lisp_Object marker; Lisp_Object buffer = Qnil; XSETBUFFER (buffer, buf); marker = Fmake_marker (); Fset_marker (marker, make_int (start), buffer); str->start = marker; marker = Fmake_marker (); Fset_marker (marker, make_int (start), buffer); str->orig_start = marker; if (reading) { marker = Fmake_marker (); Fset_marker (marker, make_int (end), buffer); str->end = marker; } else str->end = Qnil; str->buffer = buffer; } str->flags = flags; XSETLSTREAM (obj, lstr); return obj; } Lisp_Object make_lisp_buffer_input_stream (struct buffer *buf, Bufpos start, Bufpos end, int flags) { return make_lisp_buffer_stream_1 (buf, start, end, flags, "r"); } Lisp_Object make_lisp_buffer_output_stream (struct buffer *buf, Bufpos pos, int flags) { Lisp_Object lstr = make_lisp_buffer_stream_1 (buf, pos, 0, flags, "wc"); Lstream_set_character_mode (XLSTREAM (lstr)); return lstr; } static int lisp_buffer_reader (Lstream *stream, unsigned char *data, int size) { struct lisp_buffer_stream *str = LISP_BUFFER_STREAM_DATA (stream); unsigned char *orig_data = data; Bytind start; Bytind end; struct buffer *buf = XBUFFER (str->buffer); if (!BUFFER_LIVE_P (buf)) return 0; /* Fut. */ /* NOTE: We do all our operations in Bytind's. Keep in mind that SIZE is a value in bytes, not chars. */ start = bi_marker_position (str->start); end = bi_marker_position (str->end); if (!(str->flags & LSTR_IGNORE_ACCESSIBLE)) { start = bytind_clip_to_bounds (BI_BUF_BEGV (buf), start, BI_BUF_ZV (buf)); end = bytind_clip_to_bounds (BI_BUF_BEGV (buf), end, BI_BUF_ZV (buf)); } size = min (size, end - start); end = start + size; /* We cannot return a partial character. */ VALIDATE_BYTIND_BACKWARD (buf, end); while (start < end) { Bytind ceil; Bytecount chunk; if (str->flags & LSTR_IGNORE_ACCESSIBLE) ceil = BI_BUF_CEILING_OF_IGNORE_ACCESSIBLE (buf, start); else ceil = BI_BUF_CEILING_OF (buf, start); chunk = min (ceil, end) - start; memcpy (data, BI_BUF_BYTE_ADDRESS (buf, start), chunk); data += chunk; start += chunk; } if (EQ (buf->selective_display, Qt) && str->flags & LSTR_SELECTIVE) { /* What a kludge. What a kludge. What a kludge. */ unsigned char *p; for (p = orig_data; p < data; p++) if (*p == '\r') *p = '\n'; } set_bi_marker_position (str->start, end); return data - orig_data; } static int lisp_buffer_writer (Lstream *stream, CONST unsigned char *data, int size) { struct lisp_buffer_stream *str = LISP_BUFFER_STREAM_DATA (stream); Bufpos pos; struct buffer *buf = XBUFFER (str->buffer); if (!BUFFER_LIVE_P (buf)) return 0; /* Fut. */ pos = marker_position (str->start); pos += buffer_insert_raw_string_1 (buf, pos, data, size, 0); set_marker_position (str->start, pos); return size; } static int lisp_buffer_rewinder (Lstream *stream) { struct lisp_buffer_stream *str = LISP_BUFFER_STREAM_DATA (stream); struct buffer *buf = XBUFFER (str->buffer); long pos = marker_position (str->orig_start); if (!BUFFER_LIVE_P (buf)) return -1; /* Fut. */ if (pos > BUF_ZV (buf)) pos = BUF_ZV (buf); if (pos < marker_position (str->orig_start)) pos = marker_position (str->orig_start); if (MARKERP (str->end) && pos > marker_position (str->end)) pos = marker_position (str->end); set_marker_position (str->start, pos); return 0; } static Lisp_Object lisp_buffer_marker (Lisp_Object stream, void (*markobj) (Lisp_Object)) { struct lisp_buffer_stream *str = LISP_BUFFER_STREAM_DATA (XLSTREAM (stream)); (markobj) (str->start); (markobj) (str->end); return str->buffer; } Bufpos lisp_buffer_stream_startpos (Lstream *stream) { return marker_position (LISP_BUFFER_STREAM_DATA (stream)->start); } /************************************************************************/ /* initialization */ /************************************************************************/ void lstream_type_create (void) { LSTREAM_HAS_METHOD (stdio, reader); LSTREAM_HAS_METHOD (stdio, writer); LSTREAM_HAS_METHOD (stdio, rewinder); LSTREAM_HAS_METHOD (stdio, seekable_p); LSTREAM_HAS_METHOD (stdio, flusher); LSTREAM_HAS_METHOD (stdio, closer); LSTREAM_HAS_METHOD (filedesc, reader); LSTREAM_HAS_METHOD (filedesc, writer); LSTREAM_HAS_METHOD (filedesc, rewinder); LSTREAM_HAS_METHOD (filedesc, seekable_p); LSTREAM_HAS_METHOD (filedesc, closer); LSTREAM_HAS_METHOD (lisp_string, reader); LSTREAM_HAS_METHOD (lisp_string, rewinder); LSTREAM_HAS_METHOD (lisp_string, marker); LSTREAM_HAS_METHOD (fixed_buffer, reader); LSTREAM_HAS_METHOD (fixed_buffer, writer); LSTREAM_HAS_METHOD (fixed_buffer, rewinder); LSTREAM_HAS_METHOD (resizing_buffer, writer); LSTREAM_HAS_METHOD (resizing_buffer, rewinder); LSTREAM_HAS_METHOD (resizing_buffer, closer); LSTREAM_HAS_METHOD (dynarr, writer); LSTREAM_HAS_METHOD (dynarr, rewinder); LSTREAM_HAS_METHOD (dynarr, closer); LSTREAM_HAS_METHOD (lisp_buffer, reader); LSTREAM_HAS_METHOD (lisp_buffer, writer); LSTREAM_HAS_METHOD (lisp_buffer, rewinder); LSTREAM_HAS_METHOD (lisp_buffer, marker); } void vars_of_lstream (void) { int i; for (i = 0; i < countof (Vlstream_free_list); i++) { Vlstream_free_list[i] = Qnil; staticpro (&Vlstream_free_list[i]); } }