/* * perlio.c Copyright (c) 1996-2001, Nick Ing-Simmons You may distribute * under the terms of either the GNU General Public License or the * Artistic License, as specified in the README file. */ /* * If we have ActivePerl-like PERL_IMPLICIT_SYS then we need a dTHX to get * at the dispatch tables, even when we do not need it for other reasons. * Invent a dSYS macro to abstract this out */ #ifdef PERL_IMPLICIT_SYS #define dSYS dTHX #else #define dSYS dNOOP #endif #define VOIDUSED 1 #ifdef PERL_MICRO # include "uconfig.h" #else # include "config.h" #endif #define PERLIO_NOT_STDIO 0 #if !defined(PERLIO_IS_STDIO) && !defined(USE_SFIO) /* * #define PerlIO FILE */ #endif /* * This file provides those parts of PerlIO abstraction * which are not #defined in perlio.h. * Which these are depends on various Configure #ifdef's */ #include "EXTERN.h" #define PERL_IN_PERLIO_C #include "perl.h" #ifdef PERL_IMPLICIT_CONTEXT #undef dSYS #define dSYS dTHX #endif #include "XSUB.h" int perlsio_binmode(FILE *fp, int iotype, int mode) { /* * This used to be contents of do_binmode in doio.c */ #ifdef DOSISH # if defined(atarist) || defined(__MINT__) if (!fflush(fp)) { if (mode & O_BINARY) ((FILE *) fp)->_flag |= _IOBIN; else ((FILE *) fp)->_flag &= ~_IOBIN; return 1; } return 0; # else dTHX; #ifdef NETWARE if (PerlLIO_setmode(fp, mode) != -1) { #else if (PerlLIO_setmode(fileno(fp), mode) != -1) { #endif # if defined(WIN32) && defined(__BORLANDC__) /* * The translation mode of the stream is maintained independent of * the translation mode of the fd in the Borland RTL (heavy * digging through their runtime sources reveal). User has to set * the mode explicitly for the stream (though they don't document * this anywhere). GSAR 97-5-24 */ fseek(fp, 0L, 0); if (mode & O_BINARY) fp->flags |= _F_BIN; else fp->flags &= ~_F_BIN; # endif return 1; } else return 0; # endif #else # if defined(USEMYBINMODE) if (my_binmode(fp, iotype, mode) != FALSE) return 1; else return 0; # else return 1; # endif #endif } #ifndef O_ACCMODE #define O_ACCMODE 3 /* Assume traditional implementation */ #endif int PerlIO_intmode2str(int rawmode, char *mode, int *writing) { int result = rawmode & O_ACCMODE; int ix = 0; int ptype; switch (result) { case O_RDONLY: ptype = IoTYPE_RDONLY; break; case O_WRONLY: ptype = IoTYPE_WRONLY; break; case O_RDWR: default: ptype = IoTYPE_RDWR; break; } if (writing) *writing = (result != O_RDONLY); if (result == O_RDONLY) { mode[ix++] = 'r'; } #ifdef O_APPEND else if (rawmode & O_APPEND) { mode[ix++] = 'a'; if (result != O_WRONLY) mode[ix++] = '+'; } #endif else { if (result == O_WRONLY) mode[ix++] = 'w'; else { mode[ix++] = 'r'; mode[ix++] = '+'; } } if (rawmode & O_BINARY) mode[ix++] = 'b'; mode[ix] = '\0'; return ptype; } #ifndef PERLIO_LAYERS int PerlIO_apply_layers(pTHX_ PerlIO *f, const char *mode, const char *names) { if (!names || !*names || strEQ(names, ":crlf") || strEQ(names, ":raw")) { return 0; } Perl_croak(aTHX_ "Cannot apply \"%s\" in non-PerlIO perl", names); /* * NOTREACHED */ return -1; } void PerlIO_destruct(pTHX) { } int PerlIO_binmode(pTHX_ PerlIO *fp, int iotype, int mode, const char *names) { #ifdef USE_SFIO return 1; #else return perlsio_binmode(fp, iotype, mode); #endif } PerlIO * PerlIO_fdupopen(pTHX_ PerlIO *f, CLONE_PARAMS *param, int flags) { #ifndef PERL_MICRO if (f) { int fd = PerlLIO_dup(PerlIO_fileno(f)); if (fd >= 0) { char mode[8]; int omode = fcntl(fd, F_GETFL); PerlIO_intmode2str(omode,mode,NULL); /* the r+ is a hack */ return PerlIO_fdopen(fd, mode); } return NULL; } else { SETERRNO(EBADF, SS$_IVCHAN); } #endif return NULL; } /* * De-mux PerlIO_openn() into fdopen, freopen and fopen type entries */ PerlIO * PerlIO_openn(pTHX_ const char *layers, const char *mode, int fd, int imode, int perm, PerlIO *old, int narg, SV **args) { if (narg == 1) { if (*args == &PL_sv_undef) return PerlIO_tmpfile(); else { char *name = SvPV_nolen(*args); if (*mode == '#') { fd = PerlLIO_open3(name, imode, perm); if (fd >= 0) return PerlIO_fdopen(fd, (char *) mode + 1); } else if (old) { return PerlIO_reopen(name, mode, old); } else { return PerlIO_open(name, mode); } } } else { return PerlIO_fdopen(fd, (char *) mode); } return NULL; } XS(XS_PerlIO__Layer__find) { dXSARGS; if (items < 2) Perl_croak(aTHX_ "Usage class->find(name[,load])"); else { char *name = SvPV_nolen(ST(1)); ST(0) = (strEQ(name, "crlf") || strEQ(name, "raw")) ? &PL_sv_yes : &PL_sv_undef; XSRETURN(1); } } void Perl_boot_core_PerlIO(pTHX) { newXS("PerlIO::Layer::find", XS_PerlIO__Layer__find, __FILE__); } #endif #ifdef PERLIO_IS_STDIO void PerlIO_init(pTHX) { /* * Does nothing (yet) except force this file to be included in perl * binary. That allows this file to force inclusion of other functions * that may be required by loadable extensions e.g. for * FileHandle::tmpfile */ } #undef PerlIO_tmpfile PerlIO * PerlIO_tmpfile(void) { return tmpfile(); } #else /* PERLIO_IS_STDIO */ #ifdef USE_SFIO #undef HAS_FSETPOS #undef HAS_FGETPOS /* * This section is just to make sure these functions get pulled in from * libsfio.a */ #undef PerlIO_tmpfile PerlIO * PerlIO_tmpfile(void) { return sftmp(0); } void PerlIO_init(pTHX) { /* * Force this file to be included in perl binary. Which allows this * file to force inclusion of other functions that may be required by * loadable extensions e.g. for FileHandle::tmpfile */ /* * Hack sfio does its own 'autoflush' on stdout in common cases. Flush * results in a lot of lseek()s to regular files and lot of small * writes to pipes. */ sfset(sfstdout, SF_SHARE, 0); } PerlIO * PerlIO_importFILE(FILE *stdio, int fl) { int fd = fileno(stdio); PerlIO *r = PerlIO_fdopen(fd, "r+"); return r; } FILE * PerlIO_findFILE(PerlIO *pio) { int fd = PerlIO_fileno(pio); FILE *f = fdopen(fd, "r+"); PerlIO_flush(pio); if (!f && errno == EINVAL) f = fdopen(fd, "w"); if (!f && errno == EINVAL) f = fdopen(fd, "r"); return f; } #else /* USE_SFIO */ /*======================================================================================*/ /* * Implement all the PerlIO interface ourselves. */ #include "perliol.h" /* * We _MUST_ have if we are using lseek() and may have large * files */ #ifdef I_UNISTD #include #endif #ifdef HAS_MMAP #include #endif void PerlIO_debug(const char *fmt, ...) __attribute__ ((format(__printf__, 1, 2))); void PerlIO_debug(const char *fmt, ...) { static int dbg = 0; va_list ap; dSYS; va_start(ap, fmt); if (!dbg) { char *s = PerlEnv_getenv("PERLIO_DEBUG"); if (s && *s) dbg = PerlLIO_open3(s, O_WRONLY | O_CREAT | O_APPEND, 0666); else dbg = -1; } if (dbg > 0) { dTHX; #ifdef USE_ITHREADS /* Use fixed buffer as sv_catpvf etc. needs SVs */ char buffer[1024]; char *s; STRLEN len; s = CopFILE(PL_curcop); if (!s) s = "(none)"; sprintf(buffer, "%s:%" IVdf " ", s, (IV) CopLINE(PL_curcop)); len = strlen(buffer); vsprintf(buffer+len, fmt, ap); PerlLIO_write(dbg, buffer, strlen(buffer)); #else SV *sv = newSVpvn("", 0); char *s; STRLEN len; s = CopFILE(PL_curcop); if (!s) s = "(none)"; Perl_sv_catpvf(aTHX_ sv, "%s:%" IVdf " ", s, (IV) CopLINE(PL_curcop)); Perl_sv_vcatpvf(aTHX_ sv, fmt, &ap); s = SvPV(sv, len); PerlLIO_write(dbg, s, len); SvREFCNT_dec(sv); #endif } va_end(ap); } /*--------------------------------------------------------------------------------------*/ /* * Inner level routines */ /* * Table of pointers to the PerlIO structs (malloc'ed) */ #define PERLIO_TABLE_SIZE 64 PerlIO * PerlIO_allocate(pTHX) { /* * Find a free slot in the table, allocating new table as necessary */ PerlIO **last; PerlIO *f; last = &PL_perlio; while ((f = *last)) { int i; last = (PerlIO **) (f); for (i = 1; i < PERLIO_TABLE_SIZE; i++) { if (!*++f) { return f; } } } Newz('I',f,PERLIO_TABLE_SIZE,PerlIO); if (!f) { return NULL; } *last = f; return f + 1; } #undef PerlIO_fdupopen PerlIO * PerlIO_fdupopen(pTHX_ PerlIO *f, CLONE_PARAMS *param, int flags) { if (f && *f) { PerlIO_funcs *tab = PerlIOBase(f)->tab; PerlIO *new; PerlIO_debug("fdupopen f=%p param=%p\n",f,param); new = (*tab->Dup)(aTHX_ PerlIO_allocate(aTHX),f,param, flags); return new; } else { SETERRNO(EBADF, SS$_IVCHAN); return NULL; } } void PerlIO_cleantable(pTHX_ PerlIO **tablep) { PerlIO *table = *tablep; if (table) { int i; PerlIO_cleantable(aTHX_(PerlIO **) & (table[0])); for (i = PERLIO_TABLE_SIZE - 1; i > 0; i--) { PerlIO *f = table + i; if (*f) { PerlIO_close(f); } } Safefree(table); *tablep = NULL; } } PerlIO_list_t * PerlIO_list_alloc(pTHX) { PerlIO_list_t *list; Newz('L', list, 1, PerlIO_list_t); list->refcnt = 1; return list; } void PerlIO_list_free(pTHX_ PerlIO_list_t *list) { if (list) { if (--list->refcnt == 0) { if (list->array) { IV i; for (i = 0; i < list->cur; i++) { if (list->array[i].arg) SvREFCNT_dec(list->array[i].arg); } Safefree(list->array); } Safefree(list); } } } void PerlIO_list_push(pTHX_ PerlIO_list_t *list, PerlIO_funcs *funcs, SV *arg) { PerlIO_pair_t *p; if (list->cur >= list->len) { list->len += 8; if (list->array) Renew(list->array, list->len, PerlIO_pair_t); else New('l', list->array, list->len, PerlIO_pair_t); } p = &(list->array[list->cur++]); p->funcs = funcs; if ((p->arg = arg)) { SvREFCNT_inc(arg); } } PerlIO_list_t * PerlIO_clone_list(pTHX_ PerlIO_list_t *proto, CLONE_PARAMS *param) { PerlIO_list_t *list = (PerlIO_list_t *) NULL; if (proto) { int i; list = PerlIO_list_alloc(aTHX); for (i=0; i < proto->cur; i++) { SV *arg = Nullsv; if (proto->array[i].arg) arg = PerlIO_sv_dup(aTHX_ proto->array[i].arg,param); PerlIO_list_push(aTHX_ list, proto->array[i].funcs, arg); } } return list; } void PerlIO_clone(pTHX_ PerlInterpreter *proto, CLONE_PARAMS *param) { #ifdef USE_ITHREADS PerlIO **table = &proto->Iperlio; PerlIO *f; PL_perlio = NULL; PL_known_layers = PerlIO_clone_list(aTHX_ proto->Iknown_layers, param); PL_def_layerlist = PerlIO_clone_list(aTHX_ proto->Idef_layerlist, param); PerlIO_allocate(aTHX); /* root slot is never used */ PerlIO_debug("Clone %p from %p\n",aTHX,proto); while ((f = *table)) { int i; table = (PerlIO **) (f++); for (i = 1; i < PERLIO_TABLE_SIZE; i++) { if (*f) { (void) fp_dup(f, 0, param); } f++; } } #endif } void PerlIO_destruct(pTHX) { PerlIO **table = &PL_perlio; PerlIO *f; #ifdef USE_ITHREADS PerlIO_debug("Destruct %p\n",aTHX); #endif while ((f = *table)) { int i; table = (PerlIO **) (f++); for (i = 1; i < PERLIO_TABLE_SIZE; i++) { PerlIO *x = f; PerlIOl *l; while ((l = *x)) { if (l->tab->kind & PERLIO_K_DESTRUCT) { PerlIO_debug("Destruct popping %s\n", l->tab->name); PerlIO_flush(x); PerlIO_pop(aTHX_ x); } else { x = PerlIONext(x); } } f++; } } PerlIO_list_free(aTHX_ PL_known_layers); PL_known_layers = NULL; PerlIO_list_free(aTHX_ PL_def_layerlist); PL_def_layerlist = NULL; } void PerlIO_pop(pTHX_ PerlIO *f) { PerlIOl *l = *f; if (l) { PerlIO_debug("PerlIO_pop f=%p %s\n", f, l->tab->name); if (l->tab->Popped) { /* * If popped returns non-zero do not free its layer structure * it has either done so itself, or it is shared and still in * use */ if ((*l->tab->Popped) (f) != 0) return; } *f = l->next;; Safefree(l); } } /*--------------------------------------------------------------------------------------*/ /* * XS Interface for perl code */ PerlIO_funcs * PerlIO_find_layer(pTHX_ const char *name, STRLEN len, int load) { IV i; if ((SSize_t) len <= 0) len = strlen(name); for (i = 0; i < PL_known_layers->cur; i++) { PerlIO_funcs *f = PL_known_layers->array[i].funcs; if (memEQ(f->name, name, len)) { PerlIO_debug("%.*s => %p\n", (int) len, name, f); return f; } } if (load && PL_subname && PL_def_layerlist && PL_def_layerlist->cur >= 2) { SV *pkgsv = newSVpvn("PerlIO", 6); SV *layer = newSVpvn(name, len); ENTER; /* * The two SVs are magically freed by load_module */ Perl_load_module(aTHX_ 0, pkgsv, Nullsv, layer, Nullsv); LEAVE; return PerlIO_find_layer(aTHX_ name, len, 0); } PerlIO_debug("Cannot find %.*s\n", (int) len, name); return NULL; } #ifdef USE_ATTRIBUTES_FOR_PERLIO static int perlio_mg_set(pTHX_ SV *sv, MAGIC *mg) { if (SvROK(sv)) { IO *io = GvIOn((GV *) SvRV(sv)); PerlIO *ifp = IoIFP(io); PerlIO *ofp = IoOFP(io); Perl_warn(aTHX_ "set %" SVf " %p %p %p", sv, io, ifp, ofp); } return 0; } static int perlio_mg_get(pTHX_ SV *sv, MAGIC *mg) { if (SvROK(sv)) { IO *io = GvIOn((GV *) SvRV(sv)); PerlIO *ifp = IoIFP(io); PerlIO *ofp = IoOFP(io); Perl_warn(aTHX_ "get %" SVf " %p %p %p", sv, io, ifp, ofp); } return 0; } static int perlio_mg_clear(pTHX_ SV *sv, MAGIC *mg) { Perl_warn(aTHX_ "clear %" SVf, sv); return 0; } static int perlio_mg_free(pTHX_ SV *sv, MAGIC *mg) { Perl_warn(aTHX_ "free %" SVf, sv); return 0; } MGVTBL perlio_vtab = { perlio_mg_get, perlio_mg_set, NULL, /* len */ perlio_mg_clear, perlio_mg_free }; XS(XS_io_MODIFY_SCALAR_ATTRIBUTES) { dXSARGS; SV *sv = SvRV(ST(1)); AV *av = newAV(); MAGIC *mg; int count = 0; int i; sv_magic(sv, (SV *) av, PERL_MAGIC_ext, NULL, 0); SvRMAGICAL_off(sv); mg = mg_find(sv, PERL_MAGIC_ext); mg->mg_virtual = &perlio_vtab; mg_magical(sv); Perl_warn(aTHX_ "attrib %" SVf, sv); for (i = 2; i < items; i++) { STRLEN len; const char *name = SvPV(ST(i), len); SV *layer = PerlIO_find_layer(aTHX_ name, len, 1); if (layer) { av_push(av, SvREFCNT_inc(layer)); } else { ST(count) = ST(i); count++; } } SvREFCNT_dec(av); XSRETURN(count); } #endif /* USE_ATTIBUTES_FOR_PERLIO */ SV * PerlIO_tab_sv(pTHX_ PerlIO_funcs *tab) { HV *stash = gv_stashpv("PerlIO::Layer", TRUE); SV *sv = sv_bless(newRV_noinc(newSViv(PTR2IV(tab))), stash); return sv; } XS(XS_PerlIO__Layer__find) { dXSARGS; if (items < 2) Perl_croak(aTHX_ "Usage class->find(name[,load])"); else { STRLEN len = 0; char *name = SvPV(ST(1), len); bool load = (items > 2) ? SvTRUE(ST(2)) : 0; PerlIO_funcs *layer = PerlIO_find_layer(aTHX_ name, len, load); ST(0) = (layer) ? sv_2mortal(PerlIO_tab_sv(aTHX_ layer)) : &PL_sv_undef; XSRETURN(1); } } void PerlIO_define_layer(pTHX_ PerlIO_funcs *tab) { if (!PL_known_layers) PL_known_layers = PerlIO_list_alloc(aTHX); PerlIO_list_push(aTHX_ PL_known_layers, tab, Nullsv); PerlIO_debug("define %s %p\n", tab->name, tab); } int PerlIO_parse_layers(pTHX_ PerlIO_list_t *av, const char *names) { if (names) { const char *s = names; while (*s) { while (isSPACE(*s) || *s == ':') s++; if (*s) { STRLEN llen = 0; const char *e = s; const char *as = Nullch; STRLEN alen = 0; if (!isIDFIRST(*s)) { /* * Message is consistent with how attribute lists are * passed. Even though this means "foo : : bar" is * seen as an invalid separator character. */ char q = ((*s == '\'') ? '"' : '\''); Perl_warn(aTHX_ "perlio: invalid separator character %c%c%c in layer specification list %s", q, *s, q, s); return -1; } do { e++; } while (isALNUM(*e)); llen = e - s; if (*e == '(') { int nesting = 1; as = ++e; while (nesting) { switch (*e++) { case ')': if (--nesting == 0) alen = (e - 1) - as; break; case '(': ++nesting; break; case '\\': /* * It's a nul terminated string, not allowed * to \ the terminating null. Anything other * character is passed over. */ if (*e++) { break; } /* * Drop through */ case '\0': e--; Perl_warn(aTHX_ "perlio: argument list not closed for layer \"%.*s\"", (int) (e - s), s); return -1; default: /* * boring. */ break; } } } if (e > s) { PerlIO_funcs *layer = PerlIO_find_layer(aTHX_ s, llen, 1); if (layer) { PerlIO_list_push(aTHX_ av, layer, (as) ? newSVpvn(as, alen) : &PL_sv_undef); } else { Perl_warn(aTHX_ "perlio: unknown layer \"%.*s\"", (int) llen, s); return -1; } } s = e; } } } return 0; } void PerlIO_default_buffer(pTHX_ PerlIO_list_t *av) { PerlIO_funcs *tab = &PerlIO_perlio; if (O_BINARY != O_TEXT) { tab = &PerlIO_crlf; } else { if (PerlIO_stdio.Set_ptrcnt) { tab = &PerlIO_stdio; } } PerlIO_debug("Pushing %s\n", tab->name); PerlIO_list_push(aTHX_ av, PerlIO_find_layer(aTHX_ tab->name, 0, 0), &PL_sv_undef); } SV * PerlIO_arg_fetch(PerlIO_list_t *av, IV n) { return av->array[n].arg; } PerlIO_funcs * PerlIO_layer_fetch(pTHX_ PerlIO_list_t *av, IV n, PerlIO_funcs *def) { if (n >= 0 && n < av->cur) { PerlIO_debug("Layer %" IVdf " is %s\n", n, av->array[n].funcs->name); return av->array[n].funcs; } if (!def) Perl_croak(aTHX_ "panic: PerlIO layer array corrupt"); return def; } PerlIO_list_t * PerlIO_default_layers(pTHX) { if (!PL_def_layerlist) { const char *s = (PL_tainting) ? Nullch : PerlEnv_getenv("PERLIO"); PerlIO_funcs *osLayer = &PerlIO_unix; PL_def_layerlist = PerlIO_list_alloc(aTHX); PerlIO_define_layer(aTHX_ & PerlIO_unix); #if defined(WIN32) && !defined(UNDER_CE) PerlIO_define_layer(aTHX_ & PerlIO_win32); #if 0 osLayer = &PerlIO_win32; #endif #endif PerlIO_define_layer(aTHX_ & PerlIO_raw); PerlIO_define_layer(aTHX_ & PerlIO_perlio); PerlIO_define_layer(aTHX_ & PerlIO_stdio); PerlIO_define_layer(aTHX_ & PerlIO_crlf); #ifdef HAS_MMAP PerlIO_define_layer(aTHX_ & PerlIO_mmap); #endif PerlIO_define_layer(aTHX_ & PerlIO_utf8); PerlIO_define_layer(aTHX_ & PerlIO_byte); PerlIO_list_push(aTHX_ PL_def_layerlist, PerlIO_find_layer(aTHX_ osLayer->name, 0, 0), &PL_sv_undef); if (s) { PerlIO_parse_layers(aTHX_ PL_def_layerlist, s); } else { PerlIO_default_buffer(aTHX_ PL_def_layerlist); } } if (PL_def_layerlist->cur < 2) { PerlIO_default_buffer(aTHX_ PL_def_layerlist); } return PL_def_layerlist; } void Perl_boot_core_PerlIO(pTHX) { #ifdef USE_ATTRIBUTES_FOR_PERLIO newXS("io::MODIFY_SCALAR_ATTRIBUTES", XS_io_MODIFY_SCALAR_ATTRIBUTES, __FILE__); #endif newXS("PerlIO::Layer::find", XS_PerlIO__Layer__find, __FILE__); } PerlIO_funcs * PerlIO_default_layer(pTHX_ I32 n) { PerlIO_list_t *av = PerlIO_default_layers(aTHX); if (n < 0) n += av->cur; return PerlIO_layer_fetch(aTHX_ av, n, &PerlIO_stdio); } #define PerlIO_default_top() PerlIO_default_layer(aTHX_ -1) #define PerlIO_default_btm() PerlIO_default_layer(aTHX_ 0) void PerlIO_stdstreams(pTHX) { if (!PL_perlio) { PerlIO_allocate(aTHX); PerlIO_fdopen(0, "Ir" PERLIO_STDTEXT); PerlIO_fdopen(1, "Iw" PERLIO_STDTEXT); PerlIO_fdopen(2, "Iw" PERLIO_STDTEXT); } } PerlIO * PerlIO_push(pTHX_ PerlIO *f, PerlIO_funcs *tab, const char *mode, SV *arg) { PerlIOl *l = NULL; Newc('L',l,tab->size,char,PerlIOl); if (l) { Zero(l, tab->size, char); l->next = *f; l->tab = tab; *f = l; PerlIO_debug("PerlIO_push f=%p %s %s %p\n", f, tab->name, (mode) ? mode : "(Null)", arg); if ((*l->tab->Pushed) (f, mode, arg) != 0) { PerlIO_pop(aTHX_ f); return NULL; } } return f; } IV PerlIOPop_pushed(PerlIO *f, const char *mode, SV *arg) { dTHX; PerlIO_pop(aTHX_ f); if (*f) { PerlIO_flush(f); PerlIO_pop(aTHX_ f); return 0; } return -1; } IV PerlIORaw_pushed(PerlIO *f, const char *mode, SV *arg) { /* * Remove the dummy layer */ dTHX; PerlIO_pop(aTHX_ f); /* * Pop back to bottom layer */ if (f && *f) { PerlIO_flush(f); while (!(PerlIOBase(f)->tab->kind & PERLIO_K_RAW)) { if (*PerlIONext(f)) { PerlIO_pop(aTHX_ f); } else { /* * Nothing bellow - push unix on top then remove it */ if (PerlIO_push(aTHX_ f, PerlIO_default_btm(), mode, arg)) { PerlIO_pop(aTHX_ PerlIONext(f)); } break; } } PerlIO_debug(":raw f=%p :%s\n", f, PerlIOBase(f)->tab->name); return 0; } return -1; } int PerlIO_apply_layera(pTHX_ PerlIO *f, const char *mode, PerlIO_list_t *layers, IV n) { IV max = layers->cur; int code = 0; while (n < max) { PerlIO_funcs *tab = PerlIO_layer_fetch(aTHX_ layers, n, NULL); if (tab) { if (!PerlIO_push(aTHX_ f, tab, mode, PerlIOArg)) { code = -1; break; } } n++; } return code; } int PerlIO_apply_layers(pTHX_ PerlIO *f, const char *mode, const char *names) { int code = 0; if (names) { PerlIO_list_t *layers = PerlIO_list_alloc(aTHX); code = PerlIO_parse_layers(aTHX_ layers, names); if (code == 0) { code = PerlIO_apply_layera(aTHX_ f, mode, layers, 0); } PerlIO_list_free(aTHX_ layers); } return code; } /*--------------------------------------------------------------------------------------*/ /* * Given the abstraction above the public API functions */ int PerlIO_binmode(pTHX_ PerlIO *f, int iotype, int mode, const char *names) { PerlIO_debug("PerlIO_binmode f=%p %s %c %x %s\n", f, PerlIOBase(f)->tab->name, iotype, mode, (names) ? names : "(Null)"); /* Can't flush if switching encodings. */ if (!(names && memEQ(names, ":encoding(", 10))) { PerlIO_flush(f); if (!names && (O_TEXT != O_BINARY && (mode & O_BINARY))) { PerlIO *top = f; while (*top) { if (PerlIOBase(top)->tab == &PerlIO_crlf) { PerlIOBase(top)->flags &= ~PERLIO_F_CRLF; break; } top = PerlIONext(top); PerlIO_flush(top); } } } return PerlIO_apply_layers(aTHX_ f, NULL, names) == 0 ? TRUE : FALSE; } #undef PerlIO__close int PerlIO__close(PerlIO *f) { if (f && *f) return (*PerlIOBase(f)->tab->Close) (f); else { SETERRNO(EBADF, SS$_IVCHAN); return -1; } } #undef PerlIO_close int PerlIO_close(PerlIO *f) { dTHX; int code = -1; if (f && *f) { code = (*PerlIOBase(f)->tab->Close) (f); while (*f) { PerlIO_pop(aTHX_ f); } } return code; } #undef PerlIO_fileno int PerlIO_fileno(PerlIO *f) { if (f && *f) return (*PerlIOBase(f)->tab->Fileno) (f); else { SETERRNO(EBADF, SS$_IVCHAN); return -1; } } static const char * PerlIO_context_layers(pTHX_ const char *mode) { const char *type = NULL; /* * Need to supply default layer info from open.pm */ if (PL_curcop) { SV *layers = PL_curcop->cop_io; if (layers) { STRLEN len; type = SvPV(layers, len); if (type && mode[0] != 'r') { /* * Skip to write part */ const char *s = strchr(type, 0); if (s && (s - type) < len) { type = s + 1; } } } } return type; } static PerlIO_funcs * PerlIO_layer_from_ref(pTHX_ SV *sv) { /* * For any scalar type load the handler which is bundled with perl */ if (SvTYPE(sv) < SVt_PVAV) return PerlIO_find_layer(aTHX_ "Scalar", 6, 1); /* * For other types allow if layer is known but don't try and load it */ switch (SvTYPE(sv)) { case SVt_PVAV: return PerlIO_find_layer(aTHX_ "Array", 5, 0); case SVt_PVHV: return PerlIO_find_layer(aTHX_ "Hash", 4, 0); case SVt_PVCV: return PerlIO_find_layer(aTHX_ "Code", 4, 0); case SVt_PVGV: return PerlIO_find_layer(aTHX_ "Glob", 4, 0); } return NULL; } PerlIO_list_t * PerlIO_resolve_layers(pTHX_ const char *layers, const char *mode, int narg, SV **args) { PerlIO_list_t *def = PerlIO_default_layers(aTHX); int incdef = 1; if (!PL_perlio) PerlIO_stdstreams(aTHX); if (narg) { SV *arg = *args; /* * If it is a reference but not an object see if we have a handler * for it */ if (SvROK(arg) && !sv_isobject(arg)) { PerlIO_funcs *handler = PerlIO_layer_from_ref(aTHX_ SvRV(arg)); if (handler) { def = PerlIO_list_alloc(aTHX); PerlIO_list_push(aTHX_ def, handler, &PL_sv_undef); incdef = 0; } /* * Don't fail if handler cannot be found :Via(...) etc. may do * something sensible else we will just stringfy and open * resulting string. */ } } if (!layers) layers = PerlIO_context_layers(aTHX_ mode); if (layers && *layers) { PerlIO_list_t *av; if (incdef) { IV i = def->cur; av = PerlIO_list_alloc(aTHX); for (i = 0; i < def->cur; i++) { PerlIO_list_push(aTHX_ av, def->array[i].funcs, def->array[i].arg); } } else { av = def; } PerlIO_parse_layers(aTHX_ av, layers); return av; } else { if (incdef) def->refcnt++; return def; } } PerlIO * PerlIO_openn(pTHX_ const char *layers, const char *mode, int fd, int imode, int perm, PerlIO *f, int narg, SV **args) { if (!f && narg == 1 && *args == &PL_sv_undef) { if ((f = PerlIO_tmpfile())) { if (!layers) layers = PerlIO_context_layers(aTHX_ mode); if (layers && *layers) PerlIO_apply_layers(aTHX_ f, mode, layers); } } else { PerlIO_list_t *layera = NULL; IV n; PerlIO_funcs *tab = NULL; if (f && *f) { /* * This is "reopen" - it is not tested as perl does not use it * yet */ PerlIOl *l = *f; layera = PerlIO_list_alloc(aTHX); while (l) { SV *arg = (l->tab->Getarg) ? (*l->tab-> Getarg) (aTHX_ &l, NULL, 0) : &PL_sv_undef; PerlIO_list_push(aTHX_ layera, l->tab, arg); l = *PerlIONext(&l); } } else { layera = PerlIO_resolve_layers(aTHX_ layers, mode, narg, args); } /* * Start at "top" of layer stack */ n = layera->cur - 1; while (n >= 0) { PerlIO_funcs *t = PerlIO_layer_fetch(aTHX_ layera, n, NULL); if (t && t->Open) { tab = t; break; } n--; } if (tab) { /* * Found that layer 'n' can do opens - call it */ PerlIO_debug("openn(%s,'%s','%s',%d,%x,%o,%p,%d,%p)\n", tab->name, layers, mode, fd, imode, perm, f, narg, args); f = (*tab->Open) (aTHX_ tab, layera, n, mode, fd, imode, perm, f, narg, args); if (f) { if (n + 1 < layera->cur) { /* * More layers above the one that we used to open - * apply them now */ if (PerlIO_apply_layera(aTHX_ f, mode, layera, n + 1) != 0) { f = NULL; } } } } PerlIO_list_free(aTHX_ layera); } return f; } #undef PerlIO_fdopen PerlIO * PerlIO_fdopen(int fd, const char *mode) { dTHX; return PerlIO_openn(aTHX_ Nullch, mode, fd, 0, 0, NULL, 0, NULL); } #undef PerlIO_open PerlIO * PerlIO_open(const char *path, const char *mode) { dTHX; SV *name = sv_2mortal(newSVpvn(path, strlen(path))); return PerlIO_openn(aTHX_ Nullch, mode, -1, 0, 0, NULL, 1, &name); } #undef PerlIO_reopen PerlIO * PerlIO_reopen(const char *path, const char *mode, PerlIO *f) { dTHX; SV *name = sv_2mortal(newSVpvn(path, strlen(path))); return PerlIO_openn(aTHX_ Nullch, mode, -1, 0, 0, f, 1, &name); } #undef PerlIO_read SSize_t PerlIO_read(PerlIO *f, void *vbuf, Size_t count) { if (f && *f) return (*PerlIOBase(f)->tab->Read) (f, vbuf, count); else { SETERRNO(EBADF, SS$_IVCHAN); return -1; } } #undef PerlIO_unread SSize_t PerlIO_unread(PerlIO *f, const void *vbuf, Size_t count) { if (f && *f) return (*PerlIOBase(f)->tab->Unread) (f, vbuf, count); else { SETERRNO(EBADF, SS$_IVCHAN); return -1; } } #undef PerlIO_write SSize_t PerlIO_write(PerlIO *f, const void *vbuf, Size_t count) { if (f && *f) return (*PerlIOBase(f)->tab->Write) (f, vbuf, count); else { SETERRNO(EBADF, SS$_IVCHAN); return -1; } } #undef PerlIO_seek int PerlIO_seek(PerlIO *f, Off_t offset, int whence) { if (f && *f) return (*PerlIOBase(f)->tab->Seek) (f, offset, whence); else { SETERRNO(EBADF, SS$_IVCHAN); return -1; } } #undef PerlIO_tell Off_t PerlIO_tell(PerlIO *f) { if (f && *f) return (*PerlIOBase(f)->tab->Tell) (f); else { SETERRNO(EBADF, SS$_IVCHAN); return -1; } } #undef PerlIO_flush int PerlIO_flush(PerlIO *f) { if (f) { if (*f) { PerlIO_funcs *tab = PerlIOBase(f)->tab; if (tab && tab->Flush) { return (*tab->Flush) (f); } else { PerlIO_debug("Cannot flush f=%p :%s\n", f, tab->name); SETERRNO(EBADF, SS$_IVCHAN); return -1; } } else { PerlIO_debug("Cannot flush f=%p\n", f); SETERRNO(EBADF, SS$_IVCHAN); return -1; } } else { /* * Is it good API design to do flush-all on NULL, a potentially * errorneous input? Maybe some magical value (PerlIO* * PERLIO_FLUSH_ALL = (PerlIO*)-1;)? Yes, stdio does similar * things on fflush(NULL), but should we be bound by their design * decisions? --jhi */ dTHX; PerlIO **table = &PL_perlio; int code = 0; while ((f = *table)) { int i; table = (PerlIO **) (f++); for (i = 1; i < PERLIO_TABLE_SIZE; i++) { if (*f && PerlIO_flush(f) != 0) code = -1; f++; } } return code; } } void PerlIOBase_flush_linebuf() { dTHX; PerlIO **table = &PL_perlio; PerlIO *f; while ((f = *table)) { int i; table = (PerlIO **) (f++); for (i = 1; i < PERLIO_TABLE_SIZE; i++) { if (*f && (PerlIOBase(f)-> flags & (PERLIO_F_LINEBUF | PERLIO_F_CANWRITE)) == (PERLIO_F_LINEBUF | PERLIO_F_CANWRITE)) PerlIO_flush(f); f++; } } } #undef PerlIO_fill int PerlIO_fill(PerlIO *f) { if (f && *f) return (*PerlIOBase(f)->tab->Fill) (f); else { SETERRNO(EBADF, SS$_IVCHAN); return -1; } } #undef PerlIO_isutf8 int PerlIO_isutf8(PerlIO *f) { if (f && *f) return (PerlIOBase(f)->flags & PERLIO_F_UTF8) != 0; else { SETERRNO(EBADF, SS$_IVCHAN); return -1; } } #undef PerlIO_eof int PerlIO_eof(PerlIO *f) { if (f && *f) return (*PerlIOBase(f)->tab->Eof) (f); else { SETERRNO(EBADF, SS$_IVCHAN); return -1; } } #undef PerlIO_error int PerlIO_error(PerlIO *f) { if (f && *f) return (*PerlIOBase(f)->tab->Error) (f); else { SETERRNO(EBADF, SS$_IVCHAN); return -1; } } #undef PerlIO_clearerr void PerlIO_clearerr(PerlIO *f) { if (f && *f) (*PerlIOBase(f)->tab->Clearerr) (f); else SETERRNO(EBADF, SS$_IVCHAN); } #undef PerlIO_setlinebuf void PerlIO_setlinebuf(PerlIO *f) { if (f && *f) (*PerlIOBase(f)->tab->Setlinebuf) (f); else SETERRNO(EBADF, SS$_IVCHAN); } #undef PerlIO_has_base int PerlIO_has_base(PerlIO *f) { if (f && *f) { return (PerlIOBase(f)->tab->Get_base != NULL); } return 0; } #undef PerlIO_fast_gets int PerlIO_fast_gets(PerlIO *f) { if (f && *f && (PerlIOBase(f)->flags & PERLIO_F_FASTGETS)) { PerlIO_funcs *tab = PerlIOBase(f)->tab; return (tab->Set_ptrcnt != NULL); } return 0; } #undef PerlIO_has_cntptr int PerlIO_has_cntptr(PerlIO *f) { if (f && *f) { PerlIO_funcs *tab = PerlIOBase(f)->tab; return (tab->Get_ptr != NULL && tab->Get_cnt != NULL); } return 0; } #undef PerlIO_canset_cnt int PerlIO_canset_cnt(PerlIO *f) { if (f && *f) { PerlIOl *l = PerlIOBase(f); return (l->tab->Set_ptrcnt != NULL); } return 0; } #undef PerlIO_get_base STDCHAR * PerlIO_get_base(PerlIO *f) { if (f && *f) return (*PerlIOBase(f)->tab->Get_base) (f); return NULL; } #undef PerlIO_get_bufsiz int PerlIO_get_bufsiz(PerlIO *f) { if (f && *f) return (*PerlIOBase(f)->tab->Get_bufsiz) (f); return 0; } #undef PerlIO_get_ptr STDCHAR * PerlIO_get_ptr(PerlIO *f) { PerlIO_funcs *tab = PerlIOBase(f)->tab; if (tab->Get_ptr == NULL) return NULL; return (*tab->Get_ptr) (f); } #undef PerlIO_get_cnt int PerlIO_get_cnt(PerlIO *f) { PerlIO_funcs *tab = PerlIOBase(f)->tab; if (tab->Get_cnt == NULL) return 0; return (*tab->Get_cnt) (f); } #undef PerlIO_set_cnt void PerlIO_set_cnt(PerlIO *f, int cnt) { (*PerlIOBase(f)->tab->Set_ptrcnt) (f, NULL, cnt); } #undef PerlIO_set_ptrcnt void PerlIO_set_ptrcnt(PerlIO *f, STDCHAR * ptr, int cnt) { PerlIO_funcs *tab = PerlIOBase(f)->tab; if (tab->Set_ptrcnt == NULL) { dTHX; Perl_croak(aTHX_ "PerlIO buffer snooping abuse"); } (*PerlIOBase(f)->tab->Set_ptrcnt) (f, ptr, cnt); } /*--------------------------------------------------------------------------------------*/ /* * utf8 and raw dummy layers */ IV PerlIOUtf8_pushed(PerlIO *f, const char *mode, SV *arg) { if (PerlIONext(f)) { dTHX; PerlIO_funcs *tab = PerlIOBase(f)->tab; PerlIO_pop(aTHX_ f); if (tab->kind & PERLIO_K_UTF8) PerlIOBase(f)->flags |= PERLIO_F_UTF8; else PerlIOBase(f)->flags &= ~PERLIO_F_UTF8; return 0; } return -1; } PerlIO_funcs PerlIO_utf8 = { "utf8", sizeof(PerlIOl), PERLIO_K_DUMMY | PERLIO_F_UTF8, PerlIOUtf8_pushed, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, /* flush */ NULL, /* fill */ NULL, NULL, NULL, NULL, NULL, /* get_base */ NULL, /* get_bufsiz */ NULL, /* get_ptr */ NULL, /* get_cnt */ NULL, /* set_ptrcnt */ }; PerlIO_funcs PerlIO_byte = { "bytes", sizeof(PerlIOl), PERLIO_K_DUMMY, PerlIOUtf8_pushed, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, /* flush */ NULL, /* fill */ NULL, NULL, NULL, NULL, NULL, /* get_base */ NULL, /* get_bufsiz */ NULL, /* get_ptr */ NULL, /* get_cnt */ NULL, /* set_ptrcnt */ }; PerlIO * PerlIORaw_open(pTHX_ PerlIO_funcs *self, PerlIO_list_t *layers, IV n, const char *mode, int fd, int imode, int perm, PerlIO *old, int narg, SV **args) { PerlIO_funcs *tab = PerlIO_default_btm(); return (*tab->Open) (aTHX_ tab, layers, n - 1, mode, fd, imode, perm, old, narg, args); } PerlIO_funcs PerlIO_raw = { "raw", sizeof(PerlIOl), PERLIO_K_DUMMY, PerlIORaw_pushed, PerlIOBase_popped, PerlIORaw_open, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, /* flush */ NULL, /* fill */ NULL, NULL, NULL, NULL, NULL, /* get_base */ NULL, /* get_bufsiz */ NULL, /* get_ptr */ NULL, /* get_cnt */ NULL, /* set_ptrcnt */ }; /*--------------------------------------------------------------------------------------*/ /*--------------------------------------------------------------------------------------*/ /* * "Methods" of the "base class" */ IV PerlIOBase_fileno(PerlIO *f) { return PerlIO_fileno(PerlIONext(f)); } char * PerlIO_modestr(PerlIO *f, char *buf) { char *s = buf; IV flags = PerlIOBase(f)->flags; if (flags & PERLIO_F_APPEND) { *s++ = 'a'; if (flags & PERLIO_F_CANREAD) { *s++ = '+'; } } else if (flags & PERLIO_F_CANREAD) { *s++ = 'r'; if (flags & PERLIO_F_CANWRITE) *s++ = '+'; } else if (flags & PERLIO_F_CANWRITE) { *s++ = 'w'; if (flags & PERLIO_F_CANREAD) { *s++ = '+'; } } #if O_TEXT != O_BINARY if (!(flags & PERLIO_F_CRLF)) *s++ = 'b'; #endif *s = '\0'; return buf; } IV PerlIOBase_pushed(PerlIO *f, const char *mode, SV *arg) { PerlIOl *l = PerlIOBase(f); #if 0 const char *omode = mode; char temp[8]; #endif PerlIO_funcs *tab = PerlIOBase(f)->tab; l->flags &= ~(PERLIO_F_CANREAD | PERLIO_F_CANWRITE | PERLIO_F_TRUNCATE | PERLIO_F_APPEND); if (tab->Set_ptrcnt != NULL) l->flags |= PERLIO_F_FASTGETS; if (mode) { if (*mode == '#' || *mode == 'I') mode++; switch (*mode++) { case 'r': l->flags |= PERLIO_F_CANREAD; break; case 'a': l->flags |= PERLIO_F_APPEND | PERLIO_F_CANWRITE; break; case 'w': l->flags |= PERLIO_F_TRUNCATE | PERLIO_F_CANWRITE; break; default: SETERRNO(EINVAL, LIB$_INVARG); return -1; } while (*mode) { switch (*mode++) { case '+': l->flags |= PERLIO_F_CANREAD | PERLIO_F_CANWRITE; break; case 'b': l->flags &= ~PERLIO_F_CRLF; break; case 't': l->flags |= PERLIO_F_CRLF; break; default: SETERRNO(EINVAL, LIB$_INVARG); return -1; } } } else { if (l->next) { l->flags |= l->next->flags & (PERLIO_F_CANREAD | PERLIO_F_CANWRITE | PERLIO_F_TRUNCATE | PERLIO_F_APPEND); } } #if 0 PerlIO_debug("PerlIOBase_pushed f=%p %s %s fl=%08" UVxf " (%s)\n", f, PerlIOBase(f)->tab->name, (omode) ? omode : "(Null)", l->flags, PerlIO_modestr(f, temp)); #endif return 0; } IV PerlIOBase_popped(PerlIO *f) { return 0; } SSize_t PerlIOBase_unread(PerlIO *f, const void *vbuf, Size_t count) { dTHX; /* * Save the position as current head considers it */ Off_t old = PerlIO_tell(f); SSize_t done; PerlIO_push(aTHX_ f, &PerlIO_pending, "r", Nullsv); PerlIOSelf(f, PerlIOBuf)->posn = old; done = PerlIOBuf_unread(f, vbuf, count); return done; } SSize_t PerlIOBase_read(PerlIO *f, void *vbuf, Size_t count) { STDCHAR *buf = (STDCHAR *) vbuf; if (f) { if (!(PerlIOBase(f)->flags & PERLIO_F_CANREAD)) return 0; while (count > 0) { SSize_t avail = PerlIO_get_cnt(f); SSize_t take = 0; if (avail > 0) take = (count < avail) ? count : avail; if (take > 0) { STDCHAR *ptr = PerlIO_get_ptr(f); Copy(ptr, buf, take, STDCHAR); PerlIO_set_ptrcnt(f, ptr + take, (avail -= take)); count -= take; buf += take; } if (count > 0 && avail <= 0) { if (PerlIO_fill(f) != 0) break; } } return (buf - (STDCHAR *) vbuf); } return 0; } IV PerlIOBase_noop_ok(PerlIO *f) { return 0; } IV PerlIOBase_noop_fail(PerlIO *f) { return -1; } IV PerlIOBase_close(PerlIO *f) { IV code = 0; PerlIO *n = PerlIONext(f); if (PerlIO_flush(f) != 0) code = -1; if (n && *n && (*PerlIOBase(n)->tab->Close) (n) != 0) code = -1; PerlIOBase(f)->flags &= ~(PERLIO_F_CANREAD | PERLIO_F_CANWRITE | PERLIO_F_OPEN); return code; } IV PerlIOBase_eof(PerlIO *f) { if (f && *f) { return (PerlIOBase(f)->flags & PERLIO_F_EOF) != 0; } return 1; } IV PerlIOBase_error(PerlIO *f) { if (f && *f) { return (PerlIOBase(f)->flags & PERLIO_F_ERROR) != 0; } return 1; } void PerlIOBase_clearerr(PerlIO *f) { if (f && *f) { PerlIO *n = PerlIONext(f); PerlIOBase(f)->flags &= ~(PERLIO_F_ERROR | PERLIO_F_EOF); if (n) PerlIO_clearerr(n); } } void PerlIOBase_setlinebuf(PerlIO *f) { if (f) { PerlIOBase(f)->flags |= PERLIO_F_LINEBUF; } } SV * PerlIO_sv_dup(pTHX_ SV *arg, CLONE_PARAMS *param) { if (!arg) return Nullsv; #ifdef sv_dup if (param) { return sv_dup(arg, param); } else { return newSVsv(arg); } #else return newSVsv(arg); #endif } PerlIO * PerlIOBase_dup(pTHX_ PerlIO *f, PerlIO *o, CLONE_PARAMS *param, int flags) { PerlIO *nexto = PerlIONext(o); if (*nexto) { PerlIO_funcs *tab = PerlIOBase(nexto)->tab; f = (*tab->Dup)(aTHX_ f, nexto, param, flags); } if (f) { PerlIO_funcs *self = PerlIOBase(o)->tab; SV *arg = Nullsv; char buf[8]; PerlIO_debug("PerlIOBase_dup %s f=%p o=%p param=%p\n",self->name,f,o,param); if (self->Getarg) { arg = (*self->Getarg)(aTHX_ o,param,flags); } f = PerlIO_push(aTHX_ f, self, PerlIO_modestr(o,buf), arg); if (arg) { SvREFCNT_dec(arg); } } return f; } #define PERLIO_MAX_REFCOUNTABLE_FD 2048 #ifdef USE_THREADS perl_mutex PerlIO_mutex; #endif int PerlIO_fd_refcnt[PERLIO_MAX_REFCOUNTABLE_FD]; void PerlIO_init(pTHX) { /* Place holder for stdstreams call ??? */ #ifdef USE_THREADS MUTEX_INIT(&PerlIO_mutex); #endif } void PerlIOUnix_refcnt_inc(int fd) { if (fd >= 0 && fd < PERLIO_MAX_REFCOUNTABLE_FD) { #ifdef USE_THREADS MUTEX_LOCK(&PerlIO_mutex); #endif PerlIO_fd_refcnt[fd]++; PerlIO_debug("fd %d refcnt=%d\n",fd,PerlIO_fd_refcnt[fd]); #ifdef USE_THREADS MUTEX_UNLOCK(&PerlIO_mutex); #endif } } int PerlIOUnix_refcnt_dec(int fd) { int cnt = 0; if (fd >= 0 && fd < PERLIO_MAX_REFCOUNTABLE_FD) { #ifdef USE_THREADS MUTEX_LOCK(&PerlIO_mutex); #endif cnt = --PerlIO_fd_refcnt[fd]; PerlIO_debug("fd %d refcnt=%d\n",fd,cnt); #ifdef USE_THREADS MUTEX_UNLOCK(&PerlIO_mutex); #endif } return cnt; } void PerlIO_cleanup(pTHX) { int i; #ifdef USE_ITHREADS PerlIO_debug("Cleanup %p\n",aTHX); #endif /* Raise STDIN..STDERR refcount so we don't close them */ for (i=0; i < 3; i++) PerlIOUnix_refcnt_inc(i); PerlIO_cleantable(aTHX_ &PL_perlio); /* Restore STDIN..STDERR refcount */ for (i=0; i < 3; i++) PerlIOUnix_refcnt_dec(i); } /*--------------------------------------------------------------------------------------*/ /* * Bottom-most level for UNIX-like case */ typedef struct { struct _PerlIO base; /* The generic part */ int fd; /* UNIX like file descriptor */ int oflags; /* open/fcntl flags */ } PerlIOUnix; int PerlIOUnix_oflags(const char *mode) { int oflags = -1; if (*mode == 'I' || *mode == '#') mode++; switch (*mode) { case 'r': oflags = O_RDONLY; if (*++mode == '+') { oflags = O_RDWR; mode++; } break; case 'w': oflags = O_CREAT | O_TRUNC; if (*++mode == '+') { oflags |= O_RDWR; mode++; } else oflags |= O_WRONLY; break; case 'a': oflags = O_CREAT | O_APPEND; if (*++mode == '+') { oflags |= O_RDWR; mode++; } else oflags |= O_WRONLY; break; } if (*mode == 'b') { oflags |= O_BINARY; oflags &= ~O_TEXT; mode++; } else if (*mode == 't') { oflags |= O_TEXT; oflags &= ~O_BINARY; mode++; } /* * Always open in binary mode */ oflags |= O_BINARY; if (*mode || oflags == -1) { SETERRNO(EINVAL, LIB$_INVARG); oflags = -1; } return oflags; } IV PerlIOUnix_fileno(PerlIO *f) { return PerlIOSelf(f, PerlIOUnix)->fd; } IV PerlIOUnix_pushed(PerlIO *f, const char *mode, SV *arg) { IV code = PerlIOBase_pushed(f, mode, arg); PerlIOUnix *s = PerlIOSelf(f, PerlIOUnix); if (*PerlIONext(f)) { s->fd = PerlIO_fileno(PerlIONext(f)); /* * XXX could (or should) we retrieve the oflags from the open file * handle rather than believing the "mode" we are passed in? XXX * Should the value on NULL mode be 0 or -1? */ s->oflags = mode ? PerlIOUnix_oflags(mode) : -1; } PerlIOBase(f)->flags |= PERLIO_F_OPEN; return code; } PerlIO * PerlIOUnix_open(pTHX_ PerlIO_funcs *self, PerlIO_list_t *layers, IV n, const char *mode, int fd, int imode, int perm, PerlIO *f, int narg, SV **args) { if (f) { if (PerlIOBase(f)->flags & PERLIO_F_OPEN) (*PerlIOBase(f)->tab->Close) (f); } if (narg > 0) { char *path = SvPV_nolen(*args); if (*mode == '#') mode++; else { imode = PerlIOUnix_oflags(mode); perm = 0666; } if (imode != -1) { fd = PerlLIO_open3(path, imode, perm); } } if (fd >= 0) { PerlIOUnix *s; if (*mode == 'I') mode++; if (!f) { f = PerlIO_allocate(aTHX); s = PerlIOSelf(PerlIO_push(aTHX_ f, self, mode, PerlIOArg), PerlIOUnix); } else s = PerlIOSelf(f, PerlIOUnix); s->fd = fd; s->oflags = imode; PerlIOBase(f)->flags |= PERLIO_F_OPEN; PerlIOUnix_refcnt_inc(fd); return f; } else { if (f) { /* * FIXME: pop layers ??? */ } return NULL; } } PerlIO * PerlIOUnix_dup(pTHX_ PerlIO *f, PerlIO *o, CLONE_PARAMS *param, int flags) { PerlIOUnix *os = PerlIOSelf(o, PerlIOUnix); int fd = os->fd; if (flags & PERLIO_DUP_FD) { fd = PerlLIO_dup(fd); } if (fd >= 0 && fd < PERLIO_MAX_REFCOUNTABLE_FD) { f = PerlIOBase_dup(aTHX_ f, o, param, flags); if (f) { /* If all went well overwrite fd in dup'ed lay with the dup()'ed fd */ PerlIOUnix *s = PerlIOSelf(f, PerlIOUnix); s->fd = fd; PerlIOUnix_refcnt_inc(fd); return f; } } return NULL; } SSize_t PerlIOUnix_read(PerlIO *f, void *vbuf, Size_t count) { dTHX; int fd = PerlIOSelf(f, PerlIOUnix)->fd; if (!(PerlIOBase(f)->flags & PERLIO_F_CANREAD)) return 0; while (1) { SSize_t len = PerlLIO_read(fd, vbuf, count); if (len >= 0 || errno != EINTR) { if (len < 0) PerlIOBase(f)->flags |= PERLIO_F_ERROR; else if (len == 0 && count != 0) PerlIOBase(f)->flags |= PERLIO_F_EOF; return len; } PERL_ASYNC_CHECK(); } } SSize_t PerlIOUnix_write(PerlIO *f, const void *vbuf, Size_t count) { dTHX; int fd = PerlIOSelf(f, PerlIOUnix)->fd; while (1) { SSize_t len = PerlLIO_write(fd, vbuf, count); if (len >= 0 || errno != EINTR) { if (len < 0) PerlIOBase(f)->flags |= PERLIO_F_ERROR; return len; } PERL_ASYNC_CHECK(); } } IV PerlIOUnix_seek(PerlIO *f, Off_t offset, int whence) { dSYS; Off_t new = PerlLIO_lseek(PerlIOSelf(f, PerlIOUnix)->fd, offset, whence); PerlIOBase(f)->flags &= ~PERLIO_F_EOF; return (new == (Off_t) - 1) ? -1 : 0; } Off_t PerlIOUnix_tell(PerlIO *f) { dSYS; return PerlLIO_lseek(PerlIOSelf(f, PerlIOUnix)->fd, 0, SEEK_CUR); } IV PerlIOUnix_close(PerlIO *f) { dTHX; int fd = PerlIOSelf(f, PerlIOUnix)->fd; int code = 0; if (PerlIOBase(f)->flags & PERLIO_F_OPEN) { if (PerlIOUnix_refcnt_dec(fd) > 0) { PerlIOBase(f)->flags &= ~PERLIO_F_OPEN; return 0; } } else { SETERRNO(EBADF,SS$_IVCHAN); return -1; } while (PerlLIO_close(fd) != 0) { if (errno != EINTR) { code = -1; break; } PERL_ASYNC_CHECK(); } if (code == 0) { PerlIOBase(f)->flags &= ~PERLIO_F_OPEN; } return code; } PerlIO_funcs PerlIO_unix = { "unix", sizeof(PerlIOUnix), PERLIO_K_RAW, PerlIOUnix_pushed, PerlIOBase_noop_ok, PerlIOUnix_open, NULL, PerlIOUnix_fileno, PerlIOUnix_dup, PerlIOUnix_read, PerlIOBase_unread, PerlIOUnix_write, PerlIOUnix_seek, PerlIOUnix_tell, PerlIOUnix_close, PerlIOBase_noop_ok, /* flush */ PerlIOBase_noop_fail, /* fill */ PerlIOBase_eof, PerlIOBase_error, PerlIOBase_clearerr, PerlIOBase_setlinebuf, NULL, /* get_base */ NULL, /* get_bufsiz */ NULL, /* get_ptr */ NULL, /* get_cnt */ NULL, /* set_ptrcnt */ }; /*--------------------------------------------------------------------------------------*/ /* * stdio as a layer */ typedef struct { struct _PerlIO base; FILE *stdio; /* The stream */ } PerlIOStdio; IV PerlIOStdio_fileno(PerlIO *f) { dSYS; return PerlSIO_fileno(PerlIOSelf(f, PerlIOStdio)->stdio); } char * PerlIOStdio_mode(const char *mode, char *tmode) { char *ret = tmode; while (*mode) { *tmode++ = *mode++; } if (O_BINARY != O_TEXT) { *tmode++ = 'b'; } *tmode = '\0'; return ret; } /* * This isn't used yet ... */ IV PerlIOStdio_pushed(PerlIO *f, const char *mode, SV *arg) { if (*PerlIONext(f)) { dSYS; PerlIOStdio *s = PerlIOSelf(f, PerlIOStdio); char tmode[8]; FILE *stdio = PerlSIO_fdopen(PerlIO_fileno(PerlIONext(f)), mode = PerlIOStdio_mode(mode, tmode)); if (stdio) s->stdio = stdio; else return -1; } return PerlIOBase_pushed(f, mode, arg); } #undef PerlIO_importFILE PerlIO * PerlIO_importFILE(FILE *stdio, int fl) { dTHX; PerlIO *f = NULL; if (stdio) { PerlIOStdio *s = PerlIOSelf(PerlIO_push (aTHX_(f = PerlIO_allocate(aTHX)), &PerlIO_stdio, "r+", Nullsv), PerlIOStdio); s->stdio = stdio; } return f; } PerlIO * PerlIOStdio_open(pTHX_ PerlIO_funcs *self, PerlIO_list_t *layers, IV n, const char *mode, int fd, int imode, int perm, PerlIO *f, int narg, SV **args) { char tmode[8]; if (f) { char *path = SvPV_nolen(*args); PerlIOStdio *s = PerlIOSelf(f, PerlIOStdio); FILE *stdio; PerlIOUnix_refcnt_dec(fileno(s->stdio)); stdio = PerlSIO_freopen(path, (mode = PerlIOStdio_mode(mode, tmode)), s->stdio); if (!s->stdio) return NULL; s->stdio = stdio; PerlIOUnix_refcnt_inc(fileno(s->stdio)); return f; } else { if (narg > 0) { char *path = SvPV_nolen(*args); if (*mode == '#') { mode++; fd = PerlLIO_open3(path, imode, perm); } else { FILE *stdio = PerlSIO_fopen(path, mode); if (stdio) { PerlIOStdio *s = PerlIOSelf(PerlIO_push (aTHX_(f = PerlIO_allocate(aTHX)), self, (mode = PerlIOStdio_mode(mode, tmode)), PerlIOArg), PerlIOStdio); s->stdio = stdio; PerlIOUnix_refcnt_inc(fileno(s->stdio)); } return f; } } if (fd >= 0) { FILE *stdio = NULL; int init = 0; if (*mode == 'I') { init = 1; mode++; } if (init) { switch (fd) { case 0: stdio = PerlSIO_stdin; break; case 1: stdio = PerlSIO_stdout; break; case 2: stdio = PerlSIO_stderr; break; } } else { stdio = PerlSIO_fdopen(fd, mode = PerlIOStdio_mode(mode, tmode)); } if (stdio) { PerlIOStdio *s = PerlIOSelf(PerlIO_push (aTHX_(f = PerlIO_allocate(aTHX)), self, mode, PerlIOArg), PerlIOStdio); s->stdio = stdio; PerlIOUnix_refcnt_inc(fileno(s->stdio)); return f; } } } return NULL; } PerlIO * PerlIOStdio_dup(pTHX_ PerlIO *f, PerlIO *o, CLONE_PARAMS *param, int flags) { /* This assumes no layers underneath - which is what happens, but is not how I remember it. NI-S 2001/10/16 */ if ((f = PerlIOBase_dup(aTHX_ f, o, param, flags))) { FILE *stdio = PerlIOSelf(o, PerlIOStdio)->stdio; if (flags & PERLIO_DUP_FD) { int fd = PerlLIO_dup(fileno(stdio)); if (fd >= 0) { char mode[8]; stdio = fdopen(fd, PerlIO_modestr(o,mode)); } else { /* FIXME: To avoid messy error recovery if dup fails re-use the existing stdio as though flag was not set */ } } PerlIOSelf(f, PerlIOStdio)->stdio = stdio; PerlIOUnix_refcnt_inc(fileno(stdio)); } return f; } IV PerlIOStdio_close(PerlIO *f) { dSYS; #ifdef SOCKS5_VERSION_NAME int optval; Sock_size_t optlen = sizeof(int); #endif FILE *stdio = PerlIOSelf(f, PerlIOStdio)->stdio; if (PerlIOUnix_refcnt_dec(fileno(stdio)) > 0) { /* Do not close it but do flush any buffers */ PerlIO_flush(f); return 0; } return ( #ifdef SOCKS5_VERSION_NAME (getsockopt (PerlIO_fileno(f), SOL_SOCKET, SO_TYPE, (void *) &optval, &optlen) < 0) ? PerlSIO_fclose(stdio) : close(PerlIO_fileno(f)) #else PerlSIO_fclose(stdio) #endif ); } SSize_t PerlIOStdio_read(PerlIO *f, void *vbuf, Size_t count) { dSYS; FILE *s = PerlIOSelf(f, PerlIOStdio)->stdio; SSize_t got = 0; if (count == 1) { STDCHAR *buf = (STDCHAR *) vbuf; /* * Perl is expecting PerlIO_getc() to fill the buffer Linux's * stdio does not do that for fread() */ int ch = PerlSIO_fgetc(s); if (ch != EOF) { *buf = ch; got = 1; } } else got = PerlSIO_fread(vbuf, 1, count, s); return got; } SSize_t PerlIOStdio_unread(PerlIO *f, const void *vbuf, Size_t count) { dSYS; FILE *s = PerlIOSelf(f, PerlIOStdio)->stdio; STDCHAR *buf = ((STDCHAR *) vbuf) + count - 1; SSize_t unread = 0; while (count > 0) { int ch = *buf-- & 0xff; if (PerlSIO_ungetc(ch, s) != ch) break; unread++; count--; } return unread; } SSize_t PerlIOStdio_write(PerlIO *f, const void *vbuf, Size_t count) { dSYS; return PerlSIO_fwrite(vbuf, 1, count, PerlIOSelf(f, PerlIOStdio)->stdio); } IV PerlIOStdio_seek(PerlIO *f, Off_t offset, int whence) { dSYS; FILE *stdio = PerlIOSelf(f, PerlIOStdio)->stdio; return PerlSIO_fseek(stdio, offset, whence); } Off_t PerlIOStdio_tell(PerlIO *f) { dSYS; FILE *stdio = PerlIOSelf(f, PerlIOStdio)->stdio; return PerlSIO_ftell(stdio); } IV PerlIOStdio_flush(PerlIO *f) { dSYS; FILE *stdio = PerlIOSelf(f, PerlIOStdio)->stdio; if (PerlIOBase(f)->flags & PERLIO_F_CANWRITE) { return PerlSIO_fflush(stdio); } else { #if 0 /* * FIXME: This discards ungetc() and pre-read stuff which is not * right if this is just a "sync" from a layer above Suspect right * design is to do _this_ but not have layer above flush this * layer read-to-read */ /* * Not writeable - sync by attempting a seek */ int err = errno; if (PerlSIO_fseek(stdio, (Off_t) 0, SEEK_CUR) != 0) errno = err; #endif } return 0; } IV PerlIOStdio_fill(PerlIO *f) { dSYS; FILE *stdio = PerlIOSelf(f, PerlIOStdio)->stdio; int c; /* * fflush()ing read-only streams can cause trouble on some stdio-s */ if ((PerlIOBase(f)->flags & PERLIO_F_CANWRITE)) { if (PerlSIO_fflush(stdio) != 0) return EOF; } c = PerlSIO_fgetc(stdio); if (c == EOF || PerlSIO_ungetc(c, stdio) != c) return EOF; return 0; } IV PerlIOStdio_eof(PerlIO *f) { dSYS; return PerlSIO_feof(PerlIOSelf(f, PerlIOStdio)->stdio); } IV PerlIOStdio_error(PerlIO *f) { dSYS; return PerlSIO_ferror(PerlIOSelf(f, PerlIOStdio)->stdio); } void PerlIOStdio_clearerr(PerlIO *f) { dSYS; PerlSIO_clearerr(PerlIOSelf(f, PerlIOStdio)->stdio); } void PerlIOStdio_setlinebuf(PerlIO *f) { dSYS; #ifdef HAS_SETLINEBUF PerlSIO_setlinebuf(PerlIOSelf(f, PerlIOStdio)->stdio); #else PerlSIO_setvbuf(PerlIOSelf(f, PerlIOStdio)->stdio, Nullch, _IOLBF, 0); #endif } #ifdef FILE_base STDCHAR * PerlIOStdio_get_base(PerlIO *f) { dSYS; FILE *stdio = PerlIOSelf(f, PerlIOStdio)->stdio; return PerlSIO_get_base(stdio); } Size_t PerlIOStdio_get_bufsiz(PerlIO *f) { dSYS; FILE *stdio = PerlIOSelf(f, PerlIOStdio)->stdio; return PerlSIO_get_bufsiz(stdio); } #endif #ifdef USE_STDIO_PTR STDCHAR * PerlIOStdio_get_ptr(PerlIO *f) { dSYS; FILE *stdio = PerlIOSelf(f, PerlIOStdio)->stdio; return PerlSIO_get_ptr(stdio); } SSize_t PerlIOStdio_get_cnt(PerlIO *f) { dSYS; FILE *stdio = PerlIOSelf(f, PerlIOStdio)->stdio; return PerlSIO_get_cnt(stdio); } void PerlIOStdio_set_ptrcnt(PerlIO *f, STDCHAR * ptr, SSize_t cnt) { FILE *stdio = PerlIOSelf(f, PerlIOStdio)->stdio; dSYS; if (ptr != NULL) { #ifdef STDIO_PTR_LVALUE PerlSIO_set_ptr(stdio, ptr); #ifdef STDIO_PTR_LVAL_SETS_CNT if (PerlSIO_get_cnt(stdio) != (cnt)) { dTHX; assert(PerlSIO_get_cnt(stdio) == (cnt)); } #endif #if (!defined(STDIO_PTR_LVAL_NOCHANGE_CNT)) /* * Setting ptr _does_ change cnt - we are done */ return; #endif #else /* STDIO_PTR_LVALUE */ PerlProc_abort(); #endif /* STDIO_PTR_LVALUE */ } /* * Now (or only) set cnt */ #ifdef STDIO_CNT_LVALUE PerlSIO_set_cnt(stdio, cnt); #else /* STDIO_CNT_LVALUE */ #if (defined(STDIO_PTR_LVALUE) && defined(STDIO_PTR_LVAL_SETS_CNT)) PerlSIO_set_ptr(stdio, PerlSIO_get_ptr(stdio) + (PerlSIO_get_cnt(stdio) - cnt)); #else /* STDIO_PTR_LVAL_SETS_CNT */ PerlProc_abort(); #endif /* STDIO_PTR_LVAL_SETS_CNT */ #endif /* STDIO_CNT_LVALUE */ } #endif PerlIO_funcs PerlIO_stdio = { "stdio", sizeof(PerlIOStdio), PERLIO_K_BUFFERED, PerlIOBase_pushed, PerlIOBase_noop_ok, PerlIOStdio_open, NULL, PerlIOStdio_fileno, PerlIOStdio_dup, PerlIOStdio_read, PerlIOStdio_unread, PerlIOStdio_write, PerlIOStdio_seek, PerlIOStdio_tell, PerlIOStdio_close, PerlIOStdio_flush, PerlIOStdio_fill, PerlIOStdio_eof, PerlIOStdio_error, PerlIOStdio_clearerr, PerlIOStdio_setlinebuf, #ifdef FILE_base PerlIOStdio_get_base, PerlIOStdio_get_bufsiz, #else NULL, NULL, #endif #ifdef USE_STDIO_PTR PerlIOStdio_get_ptr, PerlIOStdio_get_cnt, #if (defined(STDIO_PTR_LVALUE) && (defined(STDIO_CNT_LVALUE) || defined(STDIO_PTR_LVAL_SETS_CNT))) PerlIOStdio_set_ptrcnt #else /* STDIO_PTR_LVALUE */ NULL #endif /* STDIO_PTR_LVALUE */ #else /* USE_STDIO_PTR */ NULL, NULL, NULL #endif /* USE_STDIO_PTR */ }; #undef PerlIO_exportFILE FILE * PerlIO_exportFILE(PerlIO *f, int fl) { FILE *stdio; PerlIO_flush(f); stdio = fdopen(PerlIO_fileno(f), "r+"); if (stdio) { dTHX; PerlIOStdio *s = PerlIOSelf(PerlIO_push(aTHX_ f, &PerlIO_stdio, "r+", Nullsv), PerlIOStdio); s->stdio = stdio; } return stdio; } #undef PerlIO_findFILE FILE * PerlIO_findFILE(PerlIO *f) { PerlIOl *l = *f; while (l) { if (l->tab == &PerlIO_stdio) { PerlIOStdio *s = PerlIOSelf(&l, PerlIOStdio); return s->stdio; } l = *PerlIONext(&l); } return PerlIO_exportFILE(f, 0); } #undef PerlIO_releaseFILE void PerlIO_releaseFILE(PerlIO *p, FILE *f) { } /*--------------------------------------------------------------------------------------*/ /* * perlio buffer layer */ IV PerlIOBuf_pushed(PerlIO *f, const char *mode, SV *arg) { dSYS; PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); int fd = PerlIO_fileno(f); Off_t posn; if (fd >= 0 && PerlLIO_isatty(fd)) { PerlIOBase(f)->flags |= PERLIO_F_LINEBUF | PERLIO_F_TTY; } posn = PerlIO_tell(PerlIONext(f)); if (posn != (Off_t) - 1) { b->posn = posn; } return PerlIOBase_pushed(f, mode, arg); } PerlIO * PerlIOBuf_open(pTHX_ PerlIO_funcs *self, PerlIO_list_t *layers, IV n, const char *mode, int fd, int imode, int perm, PerlIO *f, int narg, SV **args) { if (f) { PerlIO *next = PerlIONext(f); PerlIO_funcs *tab = PerlIO_layer_fetch(aTHX_ layers, n - 1, PerlIOBase(next)->tab); next = (*tab->Open) (aTHX_ tab, layers, n - 1, mode, fd, imode, perm, next, narg, args); if (!next || (*PerlIOBase(f)->tab->Pushed) (f, mode, PerlIOArg) != 0) { return NULL; } } else { PerlIO_funcs *tab = PerlIO_layer_fetch(aTHX_ layers, n - 1, PerlIO_default_btm()); int init = 0; if (*mode == 'I') { init = 1; /* * mode++; */ } f = (*tab->Open) (aTHX_ tab, layers, n - 1, mode, fd, imode, perm, NULL, narg, args); if (f) { if (PerlIO_push(aTHX_ f, self, mode, PerlIOArg) == 0) { /* * if push fails during open, open fails. close will pop us. */ PerlIO_close (f); return NULL; } else { fd = PerlIO_fileno(f); #if (O_BINARY != O_TEXT) && !defined(__BEOS__) /* * do something about failing setmode()? --jhi */ PerlLIO_setmode(fd, O_BINARY); #endif if (init && fd == 2) { /* * Initial stderr is unbuffered */ PerlIOBase(f)->flags |= PERLIO_F_UNBUF; } } } } return f; } /* * This "flush" is akin to sfio's sync in that it handles files in either * read or write state */ IV PerlIOBuf_flush(PerlIO *f) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); int code = 0; if (PerlIOBase(f)->flags & PERLIO_F_WRBUF) { /* * write() the buffer */ STDCHAR *buf = b->buf; STDCHAR *p = buf; PerlIO *n = PerlIONext(f); while (p < b->ptr) { SSize_t count = PerlIO_write(n, p, b->ptr - p); if (count > 0) { p += count; } else if (count < 0 || PerlIO_error(n)) { PerlIOBase(f)->flags |= PERLIO_F_ERROR; code = -1; break; } } b->posn += (p - buf); } else if (PerlIOBase(f)->flags & PERLIO_F_RDBUF) { STDCHAR *buf = PerlIO_get_base(f); /* * Note position change */ b->posn += (b->ptr - buf); if (b->ptr < b->end) { /* * We did not consume all of it */ if (PerlIO_seek(PerlIONext(f), b->posn, SEEK_SET) == 0) { b->posn = PerlIO_tell(PerlIONext(f)); } } } b->ptr = b->end = b->buf; PerlIOBase(f)->flags &= ~(PERLIO_F_RDBUF | PERLIO_F_WRBUF); /* * FIXME: Is this right for read case ? */ if (PerlIO_flush(PerlIONext(f)) != 0) code = -1; return code; } IV PerlIOBuf_fill(PerlIO *f) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); PerlIO *n = PerlIONext(f); SSize_t avail; /* * FIXME: doing the down-stream flush is a bad idea if it causes * pre-read data in stdio buffer to be discarded but this is too * simplistic - as it skips _our_ hosekeeping and breaks tell tests. * if (!(PerlIOBase(f)->flags & PERLIO_F_RDBUF)) { } */ if (PerlIO_flush(f) != 0) return -1; if (PerlIOBase(f)->flags & PERLIO_F_TTY) PerlIOBase_flush_linebuf(); if (!b->buf) PerlIO_get_base(f); /* allocate via vtable */ b->ptr = b->end = b->buf; if (PerlIO_fast_gets(n)) { /* * Layer below is also buffered We do _NOT_ want to call its * ->Read() because that will loop till it gets what we asked for * which may hang on a pipe etc. Instead take anything it has to * hand, or ask it to fill _once_. */ avail = PerlIO_get_cnt(n); if (avail <= 0) { avail = PerlIO_fill(n); if (avail == 0) avail = PerlIO_get_cnt(n); else { if (!PerlIO_error(n) && PerlIO_eof(n)) avail = 0; } } if (avail > 0) { STDCHAR *ptr = PerlIO_get_ptr(n); SSize_t cnt = avail; if (avail > b->bufsiz) avail = b->bufsiz; Copy(ptr, b->buf, avail, STDCHAR); PerlIO_set_ptrcnt(n, ptr + avail, cnt - avail); } } else { avail = PerlIO_read(n, b->ptr, b->bufsiz); } if (avail <= 0) { if (avail == 0) PerlIOBase(f)->flags |= PERLIO_F_EOF; else PerlIOBase(f)->flags |= PERLIO_F_ERROR; return -1; } b->end = b->buf + avail; PerlIOBase(f)->flags |= PERLIO_F_RDBUF; return 0; } SSize_t PerlIOBuf_read(PerlIO *f, void *vbuf, Size_t count) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); if (f) { if (!b->ptr) PerlIO_get_base(f); return PerlIOBase_read(f, vbuf, count); } return 0; } SSize_t PerlIOBuf_unread(PerlIO *f, const void *vbuf, Size_t count) { const STDCHAR *buf = (const STDCHAR *) vbuf + count; PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); SSize_t unread = 0; SSize_t avail; if (PerlIOBase(f)->flags & PERLIO_F_WRBUF) PerlIO_flush(f); if (!b->buf) PerlIO_get_base(f); if (b->buf) { if (PerlIOBase(f)->flags & PERLIO_F_RDBUF) { /* * Buffer is already a read buffer, we can overwrite any chars * which have been read back to buffer start */ avail = (b->ptr - b->buf); } else { /* * Buffer is idle, set it up so whole buffer is available for * unread */ avail = b->bufsiz; b->end = b->buf + avail; b->ptr = b->end; PerlIOBase(f)->flags |= PERLIO_F_RDBUF; /* * Buffer extends _back_ from where we are now */ b->posn -= b->bufsiz; } if (avail > (SSize_t) count) { /* * If we have space for more than count, just move count */ avail = count; } if (avail > 0) { b->ptr -= avail; buf -= avail; /* * In simple stdio-like ungetc() case chars will be already * there */ if (buf != b->ptr) { Copy(buf, b->ptr, avail, STDCHAR); } count -= avail; unread += avail; PerlIOBase(f)->flags &= ~PERLIO_F_EOF; } } return unread; } SSize_t PerlIOBuf_write(PerlIO *f, const void *vbuf, Size_t count) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); const STDCHAR *buf = (const STDCHAR *) vbuf; Size_t written = 0; if (!b->buf) PerlIO_get_base(f); if (!(PerlIOBase(f)->flags & PERLIO_F_CANWRITE)) return 0; while (count > 0) { SSize_t avail = b->bufsiz - (b->ptr - b->buf); if ((SSize_t) count < avail) avail = count; PerlIOBase(f)->flags |= PERLIO_F_WRBUF; if (PerlIOBase(f)->flags & PERLIO_F_LINEBUF) { while (avail > 0) { int ch = *buf++; *(b->ptr)++ = ch; count--; avail--; written++; if (ch == '\n') { PerlIO_flush(f); break; } } } else { if (avail) { Copy(buf, b->ptr, avail, STDCHAR); count -= avail; buf += avail; written += avail; b->ptr += avail; } } if (b->ptr >= (b->buf + b->bufsiz)) PerlIO_flush(f); } if (PerlIOBase(f)->flags & PERLIO_F_UNBUF) PerlIO_flush(f); return written; } IV PerlIOBuf_seek(PerlIO *f, Off_t offset, int whence) { IV code; if ((code = PerlIO_flush(f)) == 0) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); PerlIOBase(f)->flags &= ~PERLIO_F_EOF; code = PerlIO_seek(PerlIONext(f), offset, whence); if (code == 0) { b->posn = PerlIO_tell(PerlIONext(f)); } } return code; } Off_t PerlIOBuf_tell(PerlIO *f) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); /* * b->posn is file position where b->buf was read, or will be written */ Off_t posn = b->posn; if (b->buf) { /* * If buffer is valid adjust position by amount in buffer */ posn += (b->ptr - b->buf); } return posn; } IV PerlIOBuf_close(PerlIO *f) { IV code = PerlIOBase_close(f); PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); if (b->buf && b->buf != (STDCHAR *) & b->oneword) { Safefree(b->buf); } b->buf = NULL; b->ptr = b->end = b->buf; PerlIOBase(f)->flags &= ~(PERLIO_F_RDBUF | PERLIO_F_WRBUF); return code; } STDCHAR * PerlIOBuf_get_ptr(PerlIO *f) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); if (!b->buf) PerlIO_get_base(f); return b->ptr; } SSize_t PerlIOBuf_get_cnt(PerlIO *f) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); if (!b->buf) PerlIO_get_base(f); if (PerlIOBase(f)->flags & PERLIO_F_RDBUF) return (b->end - b->ptr); return 0; } STDCHAR * PerlIOBuf_get_base(PerlIO *f) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); if (!b->buf) { if (!b->bufsiz) b->bufsiz = 4096; b->buf = Newz('B',b->buf,b->bufsiz, STDCHAR); if (!b->buf) { b->buf = (STDCHAR *) & b->oneword; b->bufsiz = sizeof(b->oneword); } b->ptr = b->buf; b->end = b->ptr; } return b->buf; } Size_t PerlIOBuf_bufsiz(PerlIO *f) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); if (!b->buf) PerlIO_get_base(f); return (b->end - b->buf); } void PerlIOBuf_set_ptrcnt(PerlIO *f, STDCHAR * ptr, SSize_t cnt) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); if (!b->buf) PerlIO_get_base(f); b->ptr = ptr; if (PerlIO_get_cnt(f) != cnt || b->ptr < b->buf) { dTHX; assert(PerlIO_get_cnt(f) == cnt); assert(b->ptr >= b->buf); } PerlIOBase(f)->flags |= PERLIO_F_RDBUF; } PerlIO * PerlIOBuf_dup(pTHX_ PerlIO *f, PerlIO *o, CLONE_PARAMS *param, int flags) { return PerlIOBase_dup(aTHX_ f, o, param, flags); } PerlIO_funcs PerlIO_perlio = { "perlio", sizeof(PerlIOBuf), PERLIO_K_BUFFERED, PerlIOBuf_pushed, PerlIOBase_noop_ok, PerlIOBuf_open, NULL, PerlIOBase_fileno, PerlIOBuf_dup, PerlIOBuf_read, PerlIOBuf_unread, PerlIOBuf_write, PerlIOBuf_seek, PerlIOBuf_tell, PerlIOBuf_close, PerlIOBuf_flush, PerlIOBuf_fill, PerlIOBase_eof, PerlIOBase_error, PerlIOBase_clearerr, PerlIOBase_setlinebuf, PerlIOBuf_get_base, PerlIOBuf_bufsiz, PerlIOBuf_get_ptr, PerlIOBuf_get_cnt, PerlIOBuf_set_ptrcnt, }; /*--------------------------------------------------------------------------------------*/ /* * Temp layer to hold unread chars when cannot do it any other way */ IV PerlIOPending_fill(PerlIO *f) { /* * Should never happen */ PerlIO_flush(f); return 0; } IV PerlIOPending_close(PerlIO *f) { /* * A tad tricky - flush pops us, then we close new top */ PerlIO_flush(f); return PerlIO_close(f); } IV PerlIOPending_seek(PerlIO *f, Off_t offset, int whence) { /* * A tad tricky - flush pops us, then we seek new top */ PerlIO_flush(f); return PerlIO_seek(f, offset, whence); } IV PerlIOPending_flush(PerlIO *f) { dTHX; PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); if (b->buf && b->buf != (STDCHAR *) & b->oneword) { Safefree(b->buf); b->buf = NULL; } PerlIO_pop(aTHX_ f); return 0; } void PerlIOPending_set_ptrcnt(PerlIO *f, STDCHAR * ptr, SSize_t cnt) { if (cnt <= 0) { PerlIO_flush(f); } else { PerlIOBuf_set_ptrcnt(f, ptr, cnt); } } IV PerlIOPending_pushed(PerlIO *f, const char *mode, SV *arg) { IV code = PerlIOBase_pushed(f, mode, arg); PerlIOl *l = PerlIOBase(f); /* * Our PerlIO_fast_gets must match what we are pushed on, or sv_gets() * etc. get muddled when it changes mid-string when we auto-pop. */ l->flags = (l->flags & ~(PERLIO_F_FASTGETS | PERLIO_F_UTF8)) | (PerlIOBase(PerlIONext(f))-> flags & (PERLIO_F_FASTGETS | PERLIO_F_UTF8)); return code; } SSize_t PerlIOPending_read(PerlIO *f, void *vbuf, Size_t count) { SSize_t avail = PerlIO_get_cnt(f); SSize_t got = 0; if (count < avail) avail = count; if (avail > 0) got = PerlIOBuf_read(f, vbuf, avail); if (got >= 0 && got < count) { SSize_t more = PerlIO_read(f, ((STDCHAR *) vbuf) + got, count - got); if (more >= 0 || got == 0) got += more; } return got; } PerlIO_funcs PerlIO_pending = { "pending", sizeof(PerlIOBuf), PERLIO_K_BUFFERED, PerlIOPending_pushed, PerlIOBase_noop_ok, NULL, NULL, PerlIOBase_fileno, PerlIOBuf_dup, PerlIOPending_read, PerlIOBuf_unread, PerlIOBuf_write, PerlIOPending_seek, PerlIOBuf_tell, PerlIOPending_close, PerlIOPending_flush, PerlIOPending_fill, PerlIOBase_eof, PerlIOBase_error, PerlIOBase_clearerr, PerlIOBase_setlinebuf, PerlIOBuf_get_base, PerlIOBuf_bufsiz, PerlIOBuf_get_ptr, PerlIOBuf_get_cnt, PerlIOPending_set_ptrcnt, }; /*--------------------------------------------------------------------------------------*/ /* * crlf - translation On read translate CR,LF to "\n" we do this by * overriding ptr/cnt entries to hand back a line at a time and keeping a * record of which nl we "lied" about. On write translate "\n" to CR,LF */ typedef struct { PerlIOBuf base; /* PerlIOBuf stuff */ STDCHAR *nl; /* Position of crlf we "lied" about in the * buffer */ } PerlIOCrlf; IV PerlIOCrlf_pushed(PerlIO *f, const char *mode, SV *arg) { IV code; PerlIOBase(f)->flags |= PERLIO_F_CRLF; code = PerlIOBuf_pushed(f, mode, arg); #if 0 PerlIO_debug("PerlIOCrlf_pushed f=%p %s %s fl=%08" UVxf "\n", f, PerlIOBase(f)->tab->name, (mode) ? mode : "(Null)", PerlIOBase(f)->flags); #endif return code; } SSize_t PerlIOCrlf_unread(PerlIO *f, const void *vbuf, Size_t count) { PerlIOCrlf *c = PerlIOSelf(f, PerlIOCrlf); if (c->nl) { *(c->nl) = 0xd; c->nl = NULL; } if (!(PerlIOBase(f)->flags & PERLIO_F_CRLF)) return PerlIOBuf_unread(f, vbuf, count); else { const STDCHAR *buf = (const STDCHAR *) vbuf + count; PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); SSize_t unread = 0; if (PerlIOBase(f)->flags & PERLIO_F_WRBUF) PerlIO_flush(f); if (!b->buf) PerlIO_get_base(f); if (b->buf) { if (!(PerlIOBase(f)->flags & PERLIO_F_RDBUF)) { b->end = b->ptr = b->buf + b->bufsiz; PerlIOBase(f)->flags |= PERLIO_F_RDBUF; b->posn -= b->bufsiz; } while (count > 0 && b->ptr > b->buf) { int ch = *--buf; if (ch == '\n') { if (b->ptr - 2 >= b->buf) { *--(b->ptr) = 0xa; *--(b->ptr) = 0xd; unread++; count--; } else { buf++; break; } } else { *--(b->ptr) = ch; unread++; count--; } } } return unread; } } SSize_t PerlIOCrlf_get_cnt(PerlIO *f) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); if (!b->buf) PerlIO_get_base(f); if (PerlIOBase(f)->flags & PERLIO_F_RDBUF) { PerlIOCrlf *c = PerlIOSelf(f, PerlIOCrlf); if ((PerlIOBase(f)->flags & PERLIO_F_CRLF) && !c->nl) { STDCHAR *nl = b->ptr; scan: while (nl < b->end && *nl != 0xd) nl++; if (nl < b->end && *nl == 0xd) { test: if (nl + 1 < b->end) { if (nl[1] == 0xa) { *nl = '\n'; c->nl = nl; } else { /* * Not CR,LF but just CR */ nl++; goto scan; } } else { /* * Blast - found CR as last char in buffer */ if (b->ptr < nl) { /* * They may not care, defer work as long as * possible */ return (nl - b->ptr); } else { int code; b->ptr++; /* say we have read it as far as * flush() is concerned */ b->buf++; /* Leave space in front of buffer */ b->bufsiz--; /* Buffer is thus smaller */ code = PerlIO_fill(f); /* Fetch some more */ b->bufsiz++; /* Restore size for next time */ b->buf--; /* Point at space */ b->ptr = nl = b->buf; /* Which is what we hand * off */ b->posn--; /* Buffer starts here */ *nl = 0xd; /* Fill in the CR */ if (code == 0) goto test; /* fill() call worked */ /* * CR at EOF - just fall through */ } } } } return (((c->nl) ? (c->nl + 1) : b->end) - b->ptr); } return 0; } void PerlIOCrlf_set_ptrcnt(PerlIO *f, STDCHAR * ptr, SSize_t cnt) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); PerlIOCrlf *c = PerlIOSelf(f, PerlIOCrlf); IV flags = PerlIOBase(f)->flags; if (!b->buf) PerlIO_get_base(f); if (!ptr) { if (c->nl) ptr = c->nl + 1; else { ptr = b->end; if ((flags & PERLIO_F_CRLF) && ptr > b->buf && ptr[-1] == 0xd) ptr--; } ptr -= cnt; } else { /* * Test code - delete when it works ... */ STDCHAR *chk; if (c->nl) chk = c->nl + 1; else { chk = b->end; if ((flags & PERLIO_F_CRLF) && chk > b->buf && chk[-1] == 0xd) chk--; } chk -= cnt; if (ptr != chk) { dTHX; Perl_croak(aTHX_ "ptr wrong %p != %p fl=%08" UVxf " nl=%p e=%p for %d", ptr, chk, flags, c->nl, b->end, cnt); } } if (c->nl) { if (ptr > c->nl) { /* * They have taken what we lied about */ *(c->nl) = 0xd; c->nl = NULL; ptr++; } } b->ptr = ptr; PerlIOBase(f)->flags |= PERLIO_F_RDBUF; } SSize_t PerlIOCrlf_write(PerlIO *f, const void *vbuf, Size_t count) { if (!(PerlIOBase(f)->flags & PERLIO_F_CRLF)) return PerlIOBuf_write(f, vbuf, count); else { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); const STDCHAR *buf = (const STDCHAR *) vbuf; const STDCHAR *ebuf = buf + count; if (!b->buf) PerlIO_get_base(f); if (!(PerlIOBase(f)->flags & PERLIO_F_CANWRITE)) return 0; while (buf < ebuf) { STDCHAR *eptr = b->buf + b->bufsiz; PerlIOBase(f)->flags |= PERLIO_F_WRBUF; while (buf < ebuf && b->ptr < eptr) { if (*buf == '\n') { if ((b->ptr + 2) > eptr) { /* * Not room for both */ PerlIO_flush(f); break; } else { *(b->ptr)++ = 0xd; /* CR */ *(b->ptr)++ = 0xa; /* LF */ buf++; if (PerlIOBase(f)->flags & PERLIO_F_LINEBUF) { PerlIO_flush(f); break; } } } else { int ch = *buf++; *(b->ptr)++ = ch; } if (b->ptr >= eptr) { PerlIO_flush(f); break; } } } if (PerlIOBase(f)->flags & PERLIO_F_UNBUF) PerlIO_flush(f); return (buf - (STDCHAR *) vbuf); } } IV PerlIOCrlf_flush(PerlIO *f) { PerlIOCrlf *c = PerlIOSelf(f, PerlIOCrlf); if (c->nl) { *(c->nl) = 0xd; c->nl = NULL; } return PerlIOBuf_flush(f); } PerlIO_funcs PerlIO_crlf = { "crlf", sizeof(PerlIOCrlf), PERLIO_K_BUFFERED | PERLIO_K_CANCRLF, PerlIOCrlf_pushed, PerlIOBase_noop_ok, /* popped */ PerlIOBuf_open, NULL, PerlIOBase_fileno, PerlIOBuf_dup, PerlIOBuf_read, /* generic read works with ptr/cnt lies * ... */ PerlIOCrlf_unread, /* Put CR,LF in buffer for each '\n' */ PerlIOCrlf_write, /* Put CR,LF in buffer for each '\n' */ PerlIOBuf_seek, PerlIOBuf_tell, PerlIOBuf_close, PerlIOCrlf_flush, PerlIOBuf_fill, PerlIOBase_eof, PerlIOBase_error, PerlIOBase_clearerr, PerlIOBase_setlinebuf, PerlIOBuf_get_base, PerlIOBuf_bufsiz, PerlIOBuf_get_ptr, PerlIOCrlf_get_cnt, PerlIOCrlf_set_ptrcnt, }; #ifdef HAS_MMAP /*--------------------------------------------------------------------------------------*/ /* * mmap as "buffer" layer */ typedef struct { PerlIOBuf base; /* PerlIOBuf stuff */ Mmap_t mptr; /* Mapped address */ Size_t len; /* mapped length */ STDCHAR *bbuf; /* malloced buffer if map fails */ } PerlIOMmap; static size_t page_size = 0; IV PerlIOMmap_map(PerlIO *f) { dTHX; PerlIOMmap *m = PerlIOSelf(f, PerlIOMmap); IV flags = PerlIOBase(f)->flags; IV code = 0; if (m->len) abort(); if (flags & PERLIO_F_CANREAD) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); int fd = PerlIO_fileno(f); Stat_t st; code = Fstat(fd, &st); if (code == 0 && S_ISREG(st.st_mode)) { SSize_t len = st.st_size - b->posn; if (len > 0) { Off_t posn; if (!page_size) { #if defined(HAS_SYSCONF) && (defined(_SC_PAGESIZE) || defined(_SC_PAGE_SIZE)) { SETERRNO(0, SS$_NORMAL); # ifdef _SC_PAGESIZE page_size = sysconf(_SC_PAGESIZE); # else page_size = sysconf(_SC_PAGE_SIZE); # endif if ((long) page_size < 0) { if (errno) { SV *error = ERRSV; char *msg; STRLEN n_a; (void) SvUPGRADE(error, SVt_PV); msg = SvPVx(error, n_a); Perl_croak(aTHX_ "panic: sysconf: %s", msg); } else Perl_croak(aTHX_ "panic: sysconf: pagesize unknown"); } } #else # ifdef HAS_GETPAGESIZE page_size = getpagesize(); # else # if defined(I_SYS_PARAM) && defined(PAGESIZE) page_size = PAGESIZE; /* compiletime, bad */ # endif # endif #endif if ((IV) page_size <= 0) Perl_croak(aTHX_ "panic: bad pagesize %" IVdf, (IV) page_size); } if (b->posn < 0) { /* * This is a hack - should never happen - open should * have set it ! */ b->posn = PerlIO_tell(PerlIONext(f)); } posn = (b->posn / page_size) * page_size; len = st.st_size - posn; m->mptr = mmap(NULL, len, PROT_READ, MAP_SHARED, fd, posn); if (m->mptr && m->mptr != (Mmap_t) - 1) { #if 0 && defined(HAS_MADVISE) && defined(MADV_SEQUENTIAL) madvise(m->mptr, len, MADV_SEQUENTIAL); #endif #if 0 && defined(HAS_MADVISE) && defined(MADV_WILLNEED) madvise(m->mptr, len, MADV_WILLNEED); #endif PerlIOBase(f)->flags = (flags & ~PERLIO_F_EOF) | PERLIO_F_RDBUF; b->end = ((STDCHAR *) m->mptr) + len; b->buf = ((STDCHAR *) m->mptr) + (b->posn - posn); b->ptr = b->buf; m->len = len; } else { b->buf = NULL; } } else { PerlIOBase(f)->flags = flags | PERLIO_F_EOF | PERLIO_F_RDBUF; b->buf = NULL; b->ptr = b->end = b->ptr; code = -1; } } } return code; } IV PerlIOMmap_unmap(PerlIO *f) { PerlIOMmap *m = PerlIOSelf(f, PerlIOMmap); PerlIOBuf *b = &m->base; IV code = 0; if (m->len) { if (b->buf) { code = munmap(m->mptr, m->len); b->buf = NULL; m->len = 0; m->mptr = NULL; if (PerlIO_seek(PerlIONext(f), b->posn, SEEK_SET) != 0) code = -1; } b->ptr = b->end = b->buf; PerlIOBase(f)->flags &= ~(PERLIO_F_RDBUF | PERLIO_F_WRBUF); } return code; } STDCHAR * PerlIOMmap_get_base(PerlIO *f) { PerlIOMmap *m = PerlIOSelf(f, PerlIOMmap); PerlIOBuf *b = &m->base; if (b->buf && (PerlIOBase(f)->flags & PERLIO_F_RDBUF)) { /* * Already have a readbuffer in progress */ return b->buf; } if (b->buf) { /* * We have a write buffer or flushed PerlIOBuf read buffer */ m->bbuf = b->buf; /* save it in case we need it again */ b->buf = NULL; /* Clear to trigger below */ } if (!b->buf) { PerlIOMmap_map(f); /* Try and map it */ if (!b->buf) { /* * Map did not work - recover PerlIOBuf buffer if we have one */ b->buf = m->bbuf; } } b->ptr = b->end = b->buf; if (b->buf) return b->buf; return PerlIOBuf_get_base(f); } SSize_t PerlIOMmap_unread(PerlIO *f, const void *vbuf, Size_t count) { PerlIOMmap *m = PerlIOSelf(f, PerlIOMmap); PerlIOBuf *b = &m->base; if (PerlIOBase(f)->flags & PERLIO_F_WRBUF) PerlIO_flush(f); if (b->ptr && (b->ptr - count) >= b->buf && memEQ(b->ptr - count, vbuf, count)) { b->ptr -= count; PerlIOBase(f)->flags &= ~PERLIO_F_EOF; return count; } if (m->len) { /* * Loose the unwritable mapped buffer */ PerlIO_flush(f); /* * If flush took the "buffer" see if we have one from before */ if (!b->buf && m->bbuf) b->buf = m->bbuf; if (!b->buf) { PerlIOBuf_get_base(f); m->bbuf = b->buf; } } return PerlIOBuf_unread(f, vbuf, count); } SSize_t PerlIOMmap_write(PerlIO *f, const void *vbuf, Size_t count) { PerlIOMmap *m = PerlIOSelf(f, PerlIOMmap); PerlIOBuf *b = &m->base; if (!b->buf || !(PerlIOBase(f)->flags & PERLIO_F_WRBUF)) { /* * No, or wrong sort of, buffer */ if (m->len) { if (PerlIOMmap_unmap(f) != 0) return 0; } /* * If unmap took the "buffer" see if we have one from before */ if (!b->buf && m->bbuf) b->buf = m->bbuf; if (!b->buf) { PerlIOBuf_get_base(f); m->bbuf = b->buf; } } return PerlIOBuf_write(f, vbuf, count); } IV PerlIOMmap_flush(PerlIO *f) { PerlIOMmap *m = PerlIOSelf(f, PerlIOMmap); PerlIOBuf *b = &m->base; IV code = PerlIOBuf_flush(f); /* * Now we are "synced" at PerlIOBuf level */ if (b->buf) { if (m->len) { /* * Unmap the buffer */ if (PerlIOMmap_unmap(f) != 0) code = -1; } else { /* * We seem to have a PerlIOBuf buffer which was not mapped * remember it in case we need one later */ m->bbuf = b->buf; } } return code; } IV PerlIOMmap_fill(PerlIO *f) { PerlIOBuf *b = PerlIOSelf(f, PerlIOBuf); IV code = PerlIO_flush(f); if (code == 0 && !b->buf) { code = PerlIOMmap_map(f); } if (code == 0 && !(PerlIOBase(f)->flags & PERLIO_F_RDBUF)) { code = PerlIOBuf_fill(f); } return code; } IV PerlIOMmap_close(PerlIO *f) { PerlIOMmap *m = PerlIOSelf(f, PerlIOMmap); PerlIOBuf *b = &m->base; IV code = PerlIO_flush(f); if (m->bbuf) { b->buf = m->bbuf; m->bbuf = NULL; b->ptr = b->end = b->buf; } if (PerlIOBuf_close(f) != 0) code = -1; return code; } PerlIO * PerlIOMmap_dup(pTHX_ PerlIO *f, PerlIO *o, CLONE_PARAMS *param, int flags) { return PerlIOBase_dup(aTHX_ f, o, param, flags); } PerlIO_funcs PerlIO_mmap = { "mmap", sizeof(PerlIOMmap), PERLIO_K_BUFFERED, PerlIOBuf_pushed, PerlIOBase_noop_ok, PerlIOBuf_open, NULL, PerlIOBase_fileno, PerlIOMmap_dup, PerlIOBuf_read, PerlIOMmap_unread, PerlIOMmap_write, PerlIOBuf_seek, PerlIOBuf_tell, PerlIOBuf_close, PerlIOMmap_flush, PerlIOMmap_fill, PerlIOBase_eof, PerlIOBase_error, PerlIOBase_clearerr, PerlIOBase_setlinebuf, PerlIOMmap_get_base, PerlIOBuf_bufsiz, PerlIOBuf_get_ptr, PerlIOBuf_get_cnt, PerlIOBuf_set_ptrcnt, }; #endif /* HAS_MMAP */ #undef PerlIO_stdin PerlIO * PerlIO_stdin(void) { dTHX; if (!PL_perlio) { PerlIO_stdstreams(aTHX); } return &PL_perlio[1]; } #undef PerlIO_stdout PerlIO * PerlIO_stdout(void) { dTHX; if (!PL_perlio) { PerlIO_stdstreams(aTHX); } return &PL_perlio[2]; } #undef PerlIO_stderr PerlIO * PerlIO_stderr(void) { dTHX; if (!PL_perlio) { PerlIO_stdstreams(aTHX); } return &PL_perlio[3]; } /*--------------------------------------------------------------------------------------*/ #undef PerlIO_getname char * PerlIO_getname(PerlIO *f, char *buf) { dTHX; char *name = NULL; #ifdef VMS FILE *stdio = PerlIOSelf(f, PerlIOStdio)->stdio; if (stdio) name = fgetname(stdio, buf); #else Perl_croak(aTHX_ "Don't know how to get file name"); #endif return name; } /*--------------------------------------------------------------------------------------*/ /* * Functions which can be called on any kind of PerlIO implemented in * terms of above */ #undef PerlIO_getc int PerlIO_getc(PerlIO *f) { STDCHAR buf[1]; SSize_t count = PerlIO_read(f, buf, 1); if (count == 1) { return (unsigned char) buf[0]; } return EOF; } #undef PerlIO_ungetc int PerlIO_ungetc(PerlIO *f, int ch) { if (ch != EOF) { STDCHAR buf = ch; if (PerlIO_unread(f, &buf, 1) == 1) return ch; } return EOF; } #undef PerlIO_putc int PerlIO_putc(PerlIO *f, int ch) { STDCHAR buf = ch; return PerlIO_write(f, &buf, 1); } #undef PerlIO_puts int PerlIO_puts(PerlIO *f, const char *s) { STRLEN len = strlen(s); return PerlIO_write(f, s, len); } #undef PerlIO_rewind void PerlIO_rewind(PerlIO *f) { PerlIO_seek(f, (Off_t) 0, SEEK_SET); PerlIO_clearerr(f); } #undef PerlIO_vprintf int PerlIO_vprintf(PerlIO *f, const char *fmt, va_list ap) { dTHX; SV *sv = newSVpvn("", 0); char *s; STRLEN len; SSize_t wrote; #ifdef NEED_VA_COPY va_list apc; Perl_va_copy(ap, apc); sv_vcatpvf(sv, fmt, &apc); #else sv_vcatpvf(sv, fmt, &ap); #endif s = SvPV(sv, len); wrote = PerlIO_write(f, s, len); SvREFCNT_dec(sv); return wrote; } #undef PerlIO_printf int PerlIO_printf(PerlIO *f, const char *fmt, ...) { va_list ap; int result; va_start(ap, fmt); result = PerlIO_vprintf(f, fmt, ap); va_end(ap); return result; } #undef PerlIO_stdoutf int PerlIO_stdoutf(const char *fmt, ...) { va_list ap; int result; va_start(ap, fmt); result = PerlIO_vprintf(PerlIO_stdout(), fmt, ap); va_end(ap); return result; } #undef PerlIO_tmpfile PerlIO * PerlIO_tmpfile(void) { /* * I have no idea how portable mkstemp() is ... */ #if defined(WIN32) || !defined(HAVE_MKSTEMP) dTHX; PerlIO *f = NULL; FILE *stdio = PerlSIO_tmpfile(); if (stdio) { PerlIOStdio *s = PerlIOSelf(PerlIO_push (aTHX_(f = PerlIO_allocate(aTHX)), &PerlIO_stdio, "w+", Nullsv), PerlIOStdio); s->stdio = stdio; } return f; #else dTHX; SV *sv = newSVpv("/tmp/PerlIO_XXXXXX", 0); int fd = mkstemp(SvPVX(sv)); PerlIO *f = NULL; if (fd >= 0) { f = PerlIO_fdopen(fd, "w+"); if (f) { PerlIOBase(f)->flags |= PERLIO_F_TEMP; } PerlLIO_unlink(SvPVX(sv)); SvREFCNT_dec(sv); } return f; #endif } #undef HAS_FSETPOS #undef HAS_FGETPOS #endif /* USE_SFIO */ #endif /* PERLIO_IS_STDIO */ /*======================================================================================*/ /* * Now some functions in terms of above which may be needed even if we are * not in true PerlIO mode */ #ifndef HAS_FSETPOS #undef PerlIO_setpos int PerlIO_setpos(PerlIO *f, SV *pos) { dTHX; if (SvOK(pos)) { STRLEN len; Off_t *posn = (Off_t *) SvPV(pos, len); if (f && len == sizeof(Off_t)) return PerlIO_seek(f, *posn, SEEK_SET); } SETERRNO(EINVAL, SS$_IVCHAN); return -1; } #else #undef PerlIO_setpos int PerlIO_setpos(PerlIO *f, SV *pos) { dTHX; if (SvOK(pos)) { STRLEN len; Fpos_t *fpos = (Fpos_t *) SvPV(pos, len); if (f && len == sizeof(Fpos_t)) { #if defined(USE_64_BIT_STDIO) && defined(USE_FSETPOS64) return fsetpos64(f, fpos); #else return fsetpos(f, fpos); #endif } } SETERRNO(EINVAL, SS$_IVCHAN); return -1; } #endif #ifndef HAS_FGETPOS #undef PerlIO_getpos int PerlIO_getpos(PerlIO *f, SV *pos) { dTHX; Off_t posn = PerlIO_tell(f); sv_setpvn(pos, (char *) &posn, sizeof(posn)); return (posn == (Off_t) - 1) ? -1 : 0; } #else #undef PerlIO_getpos int PerlIO_getpos(PerlIO *f, SV *pos) { dTHX; Fpos_t fpos; int code; #if defined(USE_64_BIT_STDIO) && defined(USE_FSETPOS64) code = fgetpos64(f, &fpos); #else code = fgetpos(f, &fpos); #endif sv_setpvn(pos, (char *) &fpos, sizeof(fpos)); return code; } #endif #if (defined(PERLIO_IS_STDIO) || !defined(USE_SFIO)) && !defined(HAS_VPRINTF) int vprintf(char *pat, char *args) { _doprnt(pat, args, stdout); return 0; /* wrong, but perl doesn't use the return * value */ } int vfprintf(FILE *fd, char *pat, char *args) { _doprnt(pat, args, fd); return 0; /* wrong, but perl doesn't use the return * value */ } #endif #ifndef PerlIO_vsprintf int PerlIO_vsprintf(char *s, int n, const char *fmt, va_list ap) { int val = vsprintf(s, fmt, ap); if (n >= 0) { if (strlen(s) >= (STRLEN) n) { dTHX; (void) PerlIO_puts(Perl_error_log, "panic: sprintf overflow - memory corrupted!\n"); my_exit(1); } } return val; } #endif #ifndef PerlIO_sprintf int PerlIO_sprintf(char *s, int n, const char *fmt, ...) { va_list ap; int result; va_start(ap, fmt); result = PerlIO_vsprintf(s, n, fmt, ap); va_end(ap); return result; } #endif