#line 2 "op.c" /* op.c * * Copyright (C) 1991, 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, * 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008 by Larry Wall and others * * You may distribute under the terms of either the GNU General Public * License or the Artistic License, as specified in the README file. * */ /* * 'You see: Mr. Drogo, he married poor Miss Primula Brandybuck. She was * our Mr. Bilbo's first cousin on the mother's side (her mother being the * youngest of the Old Took's daughters); and Mr. Drogo was his second * cousin. So Mr. Frodo is his first *and* second cousin, once removed * either way, as the saying is, if you follow me.' --the Gaffer * * [p.23 of _The Lord of the Rings_, I/i: "A Long-Expected Party"] */ /* This file contains the functions that create, manipulate and optimize * the OP structures that hold a compiled perl program. * * A Perl program is compiled into a tree of OPs. Each op contains * structural pointers (eg to its siblings and the next op in the * execution sequence), a pointer to the function that would execute the * op, plus any data specific to that op. For example, an OP_CONST op * points to the pp_const() function and to an SV containing the constant * value. When pp_const() is executed, its job is to push that SV onto the * stack. * * OPs are mainly created by the newFOO() functions, which are mainly * called from the parser (in perly.y) as the code is parsed. For example * the Perl code $a + $b * $c would cause the equivalent of the following * to be called (oversimplifying a bit): * * newBINOP(OP_ADD, flags, * newSVREF($a), * newBINOP(OP_MULTIPLY, flags, newSVREF($b), newSVREF($c)) * ) * * Note that during the build of miniperl, a temporary copy of this file * is made, called opmini.c. */ /* Perl's compiler is essentially a 3-pass compiler with interleaved phases: A bottom-up pass A top-down pass An execution-order pass The bottom-up pass is represented by all the "newOP" routines and the ck_ routines. The bottom-upness is actually driven by yacc. So at the point that a ck_ routine fires, we have no idea what the context is, either upward in the syntax tree, or either forward or backward in the execution order. (The bottom-up parser builds that part of the execution order it knows about, but if you follow the "next" links around, you'll find it's actually a closed loop through the top level node.) Whenever the bottom-up parser gets to a node that supplies context to its components, it invokes that portion of the top-down pass that applies to that part of the subtree (and marks the top node as processed, so if a node further up supplies context, it doesn't have to take the plunge again). As a particular subcase of this, as the new node is built, it takes all the closed execution loops of its subcomponents and links them into a new closed loop for the higher level node. But it's still not the real execution order. The actual execution order is not known till we get a grammar reduction to a top-level unit like a subroutine or file that will be called by "name" rather than via a "next" pointer. At that point, we can call into peep() to do that code's portion of the 3rd pass. It has to be recursive, but it's recursive on basic blocks, not on tree nodes. */ /* To implement user lexical pragmas, there needs to be a way at run time to get the compile time state of %^H for that block. Storing %^H in every block (or even COP) would be very expensive, so a different approach is taken. The (running) state of %^H is serialised into a tree of HE-like structs. Stores into %^H are chained onto the current leaf as a struct refcounted_he * with the key and the value. Deletes from %^H are saved with a value of PL_sv_placeholder. The state of %^H at any point can be turned back into a regular HV by walking back up the tree from that point's leaf, ignoring any key you've already seen (placeholder or not), storing the rest into the HV structure, then removing the placeholders. Hence memory is only used to store the %^H deltas from the enclosing COP, rather than the entire %^H on each COP. To cause actions on %^H to write out the serialisation records, it has magic type 'H'. This magic (itself) does nothing, but its presence causes the values to gain magic type 'h', which has entries for set and clear. C updates C with a store record, with deletes written by C. C saves the current C on the save stack, so that it will be correctly restored when any inner compiling scope is exited. */ #include "EXTERN.h" #define PERL_IN_OP_C #include "perl.h" #include "keywords.h" #include "feature.h" #include "regcomp.h" #define CALL_PEEP(o) PL_peepp(aTHX_ o) #define CALL_RPEEP(o) PL_rpeepp(aTHX_ o) #define CALL_OPFREEHOOK(o) if (PL_opfreehook) PL_opfreehook(aTHX_ o) /* remove any leading "empty" ops from the op_next chain whose first * node's address is stored in op_p. Store the updated address of the * first node in op_p. */ STATIC void S_prune_chain_head(OP** op_p) { while (*op_p && ( (*op_p)->op_type == OP_NULL || (*op_p)->op_type == OP_SCOPE || (*op_p)->op_type == OP_SCALAR || (*op_p)->op_type == OP_LINESEQ) ) *op_p = (*op_p)->op_next; } /* See the explanatory comments above struct opslab in op.h. */ #ifdef PERL_DEBUG_READONLY_OPS # define PERL_SLAB_SIZE 128 # define PERL_MAX_SLAB_SIZE 4096 # include #endif #ifndef PERL_SLAB_SIZE # define PERL_SLAB_SIZE 64 #endif #ifndef PERL_MAX_SLAB_SIZE # define PERL_MAX_SLAB_SIZE 2048 #endif /* rounds up to nearest pointer */ #define SIZE_TO_PSIZE(x) (((x) + sizeof(I32 *) - 1)/sizeof(I32 *)) #define DIFF(o,p) ((size_t)((I32 **)(p) - (I32**)(o))) static OPSLAB * S_new_slab(pTHX_ size_t sz) { #ifdef PERL_DEBUG_READONLY_OPS OPSLAB *slab = (OPSLAB *) mmap(0, sz * sizeof(I32 *), PROT_READ|PROT_WRITE, MAP_ANON|MAP_PRIVATE, -1, 0); DEBUG_m(PerlIO_printf(Perl_debug_log, "mapped %lu at %p\n", (unsigned long) sz, slab)); if (slab == MAP_FAILED) { perror("mmap failed"); abort(); } slab->opslab_size = (U16)sz; #else OPSLAB *slab = (OPSLAB *)PerlMemShared_calloc(sz, sizeof(I32 *)); #endif #ifndef WIN32 /* The context is unused in non-Windows */ PERL_UNUSED_CONTEXT; #endif slab->opslab_first = (OPSLOT *)((I32 **)slab + sz - 1); return slab; } /* requires double parens and aTHX_ */ #define DEBUG_S_warn(args) \ DEBUG_S( \ PerlIO_printf(Perl_debug_log, "%s", SvPVx_nolen(Perl_mess args)) \ ) void * Perl_Slab_Alloc(pTHX_ size_t sz) { OPSLAB *slab; OPSLAB *slab2; OPSLOT *slot; OP *o; size_t opsz, space; /* We only allocate ops from the slab during subroutine compilation. We find the slab via PL_compcv, hence that must be non-NULL. It could also be pointing to a subroutine which is now fully set up (CvROOT() pointing to the top of the optree for that sub), or a subroutine which isn't using the slab allocator. If our sanity checks aren't met, don't use a slab, but allocate the OP directly from the heap. */ if (!PL_compcv || CvROOT(PL_compcv) || (CvSTART(PL_compcv) && !CvSLABBED(PL_compcv))) return PerlMemShared_calloc(1, sz); /* While the subroutine is under construction, the slabs are accessed via CvSTART(), to avoid needing to expand PVCV by one pointer for something unneeded at runtime. Once a subroutine is constructed, the slabs are accessed via CvROOT(). So if CvSTART() is NULL, no slab has been allocated yet. See the commit message for 8be227ab5eaa23f2 for more details. */ if (!CvSTART(PL_compcv)) { CvSTART(PL_compcv) = (OP *)(slab = S_new_slab(aTHX_ PERL_SLAB_SIZE)); CvSLABBED_on(PL_compcv); slab->opslab_refcnt = 2; /* one for the CV; one for the new OP */ } else ++(slab = (OPSLAB *)CvSTART(PL_compcv))->opslab_refcnt; opsz = SIZE_TO_PSIZE(sz); sz = opsz + OPSLOT_HEADER_P; /* The slabs maintain a free list of OPs. In particular, constant folding will free up OPs, so it makes sense to re-use them where possible. A freed up slot is used in preference to a new allocation. */ if (slab->opslab_freed) { OP **too = &slab->opslab_freed; o = *too; DEBUG_S_warn((aTHX_ "found free op at %p, slab %p", (void*)o, (void*)slab)); while (o && DIFF(OpSLOT(o), OpSLOT(o)->opslot_next) < sz) { DEBUG_S_warn((aTHX_ "Alas! too small")); o = *(too = &o->op_next); if (o) { DEBUG_S_warn((aTHX_ "found another free op at %p", (void*)o)); } } if (o) { *too = o->op_next; Zero(o, opsz, I32 *); o->op_slabbed = 1; return (void *)o; } } #define INIT_OPSLOT \ slot->opslot_slab = slab; \ slot->opslot_next = slab2->opslab_first; \ slab2->opslab_first = slot; \ o = &slot->opslot_op; \ o->op_slabbed = 1 /* The partially-filled slab is next in the chain. */ slab2 = slab->opslab_next ? slab->opslab_next : slab; if ((space = DIFF(&slab2->opslab_slots, slab2->opslab_first)) < sz) { /* Remaining space is too small. */ /* If we can fit a BASEOP, add it to the free chain, so as not to waste it. */ if (space >= SIZE_TO_PSIZE(sizeof(OP)) + OPSLOT_HEADER_P) { slot = &slab2->opslab_slots; INIT_OPSLOT; o->op_type = OP_FREED; o->op_next = slab->opslab_freed; slab->opslab_freed = o; } /* Create a new slab. Make this one twice as big. */ slot = slab2->opslab_first; while (slot->opslot_next) slot = slot->opslot_next; slab2 = S_new_slab(aTHX_ (DIFF(slab2, slot)+1)*2 > PERL_MAX_SLAB_SIZE ? PERL_MAX_SLAB_SIZE : (DIFF(slab2, slot)+1)*2); slab2->opslab_next = slab->opslab_next; slab->opslab_next = slab2; } assert(DIFF(&slab2->opslab_slots, slab2->opslab_first) >= sz); /* Create a new op slot */ slot = (OPSLOT *)((I32 **)slab2->opslab_first - sz); assert(slot >= &slab2->opslab_slots); if (DIFF(&slab2->opslab_slots, slot) < SIZE_TO_PSIZE(sizeof(OP)) + OPSLOT_HEADER_P) slot = &slab2->opslab_slots; INIT_OPSLOT; DEBUG_S_warn((aTHX_ "allocating op at %p, slab %p", (void*)o, (void*)slab)); return (void *)o; } #undef INIT_OPSLOT #ifdef PERL_DEBUG_READONLY_OPS void Perl_Slab_to_ro(pTHX_ OPSLAB *slab) { PERL_ARGS_ASSERT_SLAB_TO_RO; if (slab->opslab_readonly) return; slab->opslab_readonly = 1; for (; slab; slab = slab->opslab_next) { /*DEBUG_U(PerlIO_printf(Perl_debug_log,"mprotect ->ro %lu at %p\n", (unsigned long) slab->opslab_size, slab));*/ if (mprotect(slab, slab->opslab_size * sizeof(I32 *), PROT_READ)) Perl_warn(aTHX_ "mprotect for %p %lu failed with %d", slab, (unsigned long)slab->opslab_size, errno); } } void Perl_Slab_to_rw(pTHX_ OPSLAB *const slab) { OPSLAB *slab2; PERL_ARGS_ASSERT_SLAB_TO_RW; if (!slab->opslab_readonly) return; slab2 = slab; for (; slab2; slab2 = slab2->opslab_next) { /*DEBUG_U(PerlIO_printf(Perl_debug_log,"mprotect ->rw %lu at %p\n", (unsigned long) size, slab2));*/ if (mprotect((void *)slab2, slab2->opslab_size * sizeof(I32 *), PROT_READ|PROT_WRITE)) { Perl_warn(aTHX_ "mprotect RW for %p %lu failed with %d", slab, (unsigned long)slab2->opslab_size, errno); } } slab->opslab_readonly = 0; } #else # define Slab_to_rw(op) NOOP #endif /* This cannot possibly be right, but it was copied from the old slab allocator, to which it was originally added, without explanation, in commit 083fcd5. */ #ifdef NETWARE # define PerlMemShared PerlMem #endif void Perl_Slab_Free(pTHX_ void *op) { OP * const o = (OP *)op; OPSLAB *slab; PERL_ARGS_ASSERT_SLAB_FREE; if (!o->op_slabbed) { if (!o->op_static) PerlMemShared_free(op); return; } slab = OpSLAB(o); /* If this op is already freed, our refcount will get screwy. */ assert(o->op_type != OP_FREED); o->op_type = OP_FREED; o->op_next = slab->opslab_freed; slab->opslab_freed = o; DEBUG_S_warn((aTHX_ "free op at %p, recorded in slab %p", (void*)o, (void*)slab)); OpslabREFCNT_dec_padok(slab); } void Perl_opslab_free_nopad(pTHX_ OPSLAB *slab) { const bool havepad = !!PL_comppad; PERL_ARGS_ASSERT_OPSLAB_FREE_NOPAD; if (havepad) { ENTER; PAD_SAVE_SETNULLPAD(); } opslab_free(slab); if (havepad) LEAVE; } void Perl_opslab_free(pTHX_ OPSLAB *slab) { OPSLAB *slab2; PERL_ARGS_ASSERT_OPSLAB_FREE; PERL_UNUSED_CONTEXT; DEBUG_S_warn((aTHX_ "freeing slab %p", (void*)slab)); assert(slab->opslab_refcnt == 1); for (; slab; slab = slab2) { slab2 = slab->opslab_next; #ifdef DEBUGGING slab->opslab_refcnt = ~(size_t)0; #endif #ifdef PERL_DEBUG_READONLY_OPS DEBUG_m(PerlIO_printf(Perl_debug_log, "Deallocate slab at %p\n", (void*)slab)); if (munmap(slab, slab->opslab_size * sizeof(I32 *))) { perror("munmap failed"); abort(); } #else PerlMemShared_free(slab); #endif } } void Perl_opslab_force_free(pTHX_ OPSLAB *slab) { OPSLAB *slab2; OPSLOT *slot; #ifdef DEBUGGING size_t savestack_count = 0; #endif PERL_ARGS_ASSERT_OPSLAB_FORCE_FREE; slab2 = slab; do { for (slot = slab2->opslab_first; slot->opslot_next; slot = slot->opslot_next) { if (slot->opslot_op.op_type != OP_FREED && !(slot->opslot_op.op_savefree #ifdef DEBUGGING && ++savestack_count #endif ) ) { assert(slot->opslot_op.op_slabbed); op_free(&slot->opslot_op); if (slab->opslab_refcnt == 1) goto free; } } } while ((slab2 = slab2->opslab_next)); /* > 1 because the CV still holds a reference count. */ if (slab->opslab_refcnt > 1) { /* still referenced by the savestack */ #ifdef DEBUGGING assert(savestack_count == slab->opslab_refcnt-1); #endif /* Remove the CV’s reference count. */ slab->opslab_refcnt--; return; } free: opslab_free(slab); } #ifdef PERL_DEBUG_READONLY_OPS OP * Perl_op_refcnt_inc(pTHX_ OP *o) { if(o) { OPSLAB *const slab = o->op_slabbed ? OpSLAB(o) : NULL; if (slab && slab->opslab_readonly) { Slab_to_rw(slab); ++o->op_targ; Slab_to_ro(slab); } else { ++o->op_targ; } } return o; } PADOFFSET Perl_op_refcnt_dec(pTHX_ OP *o) { PADOFFSET result; OPSLAB *const slab = o->op_slabbed ? OpSLAB(o) : NULL; PERL_ARGS_ASSERT_OP_REFCNT_DEC; if (slab && slab->opslab_readonly) { Slab_to_rw(slab); result = --o->op_targ; Slab_to_ro(slab); } else { result = --o->op_targ; } return result; } #endif /* * In the following definition, the ", (OP*)0" is just to make the compiler * think the expression is of the right type: croak actually does a Siglongjmp. */ #define CHECKOP(type,o) \ ((PL_op_mask && PL_op_mask[type]) \ ? ( op_free((OP*)o), \ Perl_croak(aTHX_ "'%s' trapped by operation mask", PL_op_desc[type]), \ (OP*)0 ) \ : PL_check[type](aTHX_ (OP*)o)) #define RETURN_UNLIMITED_NUMBER (PERL_INT_MAX / 2) #define CHANGE_TYPE(o,type) \ STMT_START { \ o->op_type = (OPCODE)type; \ o->op_ppaddr = PL_ppaddr[type]; \ } STMT_END STATIC SV* S_gv_ename(pTHX_ GV *gv) { SV* const tmpsv = sv_newmortal(); PERL_ARGS_ASSERT_GV_ENAME; gv_efullname3(tmpsv, gv, NULL); return tmpsv; } STATIC OP * S_no_fh_allowed(pTHX_ OP *o) { PERL_ARGS_ASSERT_NO_FH_ALLOWED; yyerror(Perl_form(aTHX_ "Missing comma after first argument to %s function", OP_DESC(o))); return o; } STATIC OP * S_too_few_arguments_sv(pTHX_ OP *o, SV *namesv, U32 flags) { PERL_ARGS_ASSERT_TOO_FEW_ARGUMENTS_SV; yyerror_pv(Perl_form(aTHX_ "Not enough arguments for %"SVf, SVfARG(namesv)), SvUTF8(namesv) | flags); return o; } STATIC OP * S_too_few_arguments_pv(pTHX_ OP *o, const char* name, U32 flags) { PERL_ARGS_ASSERT_TOO_FEW_ARGUMENTS_PV; yyerror_pv(Perl_form(aTHX_ "Not enough arguments for %s", name), flags); return o; } STATIC OP * S_too_many_arguments_pv(pTHX_ OP *o, const char *name, U32 flags) { PERL_ARGS_ASSERT_TOO_MANY_ARGUMENTS_PV; yyerror_pv(Perl_form(aTHX_ "Too many arguments for %s", name), flags); return o; } STATIC OP * S_too_many_arguments_sv(pTHX_ OP *o, SV *namesv, U32 flags) { PERL_ARGS_ASSERT_TOO_MANY_ARGUMENTS_SV; yyerror_pv(Perl_form(aTHX_ "Too many arguments for %"SVf, SVfARG(namesv)), SvUTF8(namesv) | flags); return o; } STATIC void S_bad_type_pv(pTHX_ I32 n, const char *t, const char *name, U32 flags, const OP *kid) { PERL_ARGS_ASSERT_BAD_TYPE_PV; yyerror_pv(Perl_form(aTHX_ "Type of arg %d to %s must be %s (not %s)", (int)n, name, t, OP_DESC(kid)), flags); } STATIC void S_bad_type_gv(pTHX_ I32 n, const char *t, GV *gv, U32 flags, const OP *kid) { SV * const namesv = gv_ename(gv); PERL_ARGS_ASSERT_BAD_TYPE_GV; yyerror_pv(Perl_form(aTHX_ "Type of arg %d to %"SVf" must be %s (not %s)", (int)n, SVfARG(namesv), t, OP_DESC(kid)), SvUTF8(namesv) | flags); } STATIC void S_no_bareword_allowed(pTHX_ OP *o) { PERL_ARGS_ASSERT_NO_BAREWORD_ALLOWED; qerror(Perl_mess(aTHX_ "Bareword \"%"SVf"\" not allowed while \"strict subs\" in use", SVfARG(cSVOPo_sv))); o->op_private &= ~OPpCONST_STRICT; /* prevent warning twice about the same OP */ } /* "register" allocation */ PADOFFSET Perl_allocmy(pTHX_ const char *const name, const STRLEN len, const U32 flags) { PADOFFSET off; const bool is_our = (PL_parser->in_my == KEY_our); PERL_ARGS_ASSERT_ALLOCMY; if (flags & ~SVf_UTF8) Perl_croak(aTHX_ "panic: allocmy illegal flag bits 0x%" UVxf, (UV)flags); /* Until we're using the length for real, cross check that we're being told the truth. */ assert(strlen(name) == len); /* complain about "my $" etc etc */ if (len && !(is_our || isALPHA(name[1]) || ((flags & SVf_UTF8) && isIDFIRST_utf8((U8 *)name+1)) || (name[1] == '_' && (*name == '$' || len > 2)))) { /* name[2] is true if strlen(name) > 2 */ if (!(flags & SVf_UTF8 && UTF8_IS_START(name[1])) && (!isPRINT(name[1]) || strchr("\t\n\r\f", name[1]))) { yyerror(Perl_form(aTHX_ "Can't use global %c^%c%.*s in \"%s\"", name[0], toCTRL(name[1]), (int)(len - 2), name + 2, PL_parser->in_my == KEY_state ? "state" : "my")); } else { yyerror_pv(Perl_form(aTHX_ "Can't use global %.*s in \"%s\"", (int) len, name, PL_parser->in_my == KEY_state ? "state" : "my"), flags & SVf_UTF8); } } else if (len == 2 && name[1] == '_' && !is_our) /* diag_listed_as: Use of my $_ is experimental */ Perl_ck_warner_d(aTHX_ packWARN(WARN_EXPERIMENTAL__LEXICAL_TOPIC), "Use of %s $_ is experimental", PL_parser->in_my == KEY_state ? "state" : "my"); /* allocate a spare slot and store the name in that slot */ off = pad_add_name_pvn(name, len, (is_our ? padadd_OUR : PL_parser->in_my == KEY_state ? padadd_STATE : 0) | ( flags & SVf_UTF8 ? SVf_UTF8 : 0 ), PL_parser->in_my_stash, (is_our /* $_ is always in main::, even with our */ ? (PL_curstash && !strEQ(name,"$_") ? PL_curstash : PL_defstash) : NULL ) ); /* anon sub prototypes contains state vars should always be cloned, * otherwise the state var would be shared between anon subs */ if (PL_parser->in_my == KEY_state && CvANON(PL_compcv)) CvCLONE_on(PL_compcv); return off; } /* =head1 Optree Manipulation Functions =for apidoc alloccopstash Available only under threaded builds, this function allocates an entry in C for the stash passed to it. =cut */ #ifdef USE_ITHREADS PADOFFSET Perl_alloccopstash(pTHX_ HV *hv) { PADOFFSET off = 0, o = 1; bool found_slot = FALSE; PERL_ARGS_ASSERT_ALLOCCOPSTASH; if (PL_stashpad[PL_stashpadix] == hv) return PL_stashpadix; for (; o < PL_stashpadmax; ++o) { if (PL_stashpad[o] == hv) return PL_stashpadix = o; if (!PL_stashpad[o] || SvTYPE(PL_stashpad[o]) != SVt_PVHV) found_slot = TRUE, off = o; } if (!found_slot) { Renew(PL_stashpad, PL_stashpadmax + 10, HV *); Zero(PL_stashpad + PL_stashpadmax, 10, HV *); off = PL_stashpadmax; PL_stashpadmax += 10; } PL_stashpad[PL_stashpadix = off] = hv; return off; } #endif /* free the body of an op without examining its contents. * Always use this rather than FreeOp directly */ static void S_op_destroy(pTHX_ OP *o) { FreeOp(o); } /* Destructor */ /* =for apidoc Am|void|op_free|OP *o Free an op. Only use this when an op is no longer linked to from any optree. =cut */ void Perl_op_free(pTHX_ OP *o) { #ifdef USE_ITHREADS dVAR; #endif OPCODE type; /* Though ops may be freed twice, freeing the op after its slab is a big no-no. */ assert(!o || !o->op_slabbed || OpSLAB(o)->opslab_refcnt != ~(size_t)0); /* During the forced freeing of ops after compilation failure, kidops may be freed before their parents. */ if (!o || o->op_type == OP_FREED) return; type = o->op_type; if (o->op_private & OPpREFCOUNTED) { switch (type) { case OP_LEAVESUB: case OP_LEAVESUBLV: case OP_LEAVEEVAL: case OP_LEAVE: case OP_SCOPE: case OP_LEAVEWRITE: { PADOFFSET refcnt; OP_REFCNT_LOCK; refcnt = OpREFCNT_dec(o); OP_REFCNT_UNLOCK; if (refcnt) { /* Need to find and remove any pattern match ops from the list we maintain for reset(). */ find_and_forget_pmops(o); return; } } break; default: break; } } /* Call the op_free hook if it has been set. Do it now so that it's called * at the right time for refcounted ops, but still before all of the kids * are freed. */ CALL_OPFREEHOOK(o); if (o->op_flags & OPf_KIDS) { OP *kid, *nextkid; for (kid = cUNOPo->op_first; kid; kid = nextkid) { nextkid = kid->op_sibling; /* Get before next freeing kid */ op_free(kid); } } if (type == OP_NULL) type = (OPCODE)o->op_targ; if (o->op_slabbed) Slab_to_rw(OpSLAB(o)); /* COP* is not cleared by op_clear() so that we may track line * numbers etc even after null() */ if (type == OP_NEXTSTATE || type == OP_DBSTATE) { cop_free((COP*)o); } op_clear(o); FreeOp(o); #ifdef DEBUG_LEAKING_SCALARS if (PL_op == o) PL_op = NULL; #endif } void Perl_op_clear(pTHX_ OP *o) { dVAR; PERL_ARGS_ASSERT_OP_CLEAR; switch (o->op_type) { case OP_NULL: /* Was holding old type, if any. */ /* FALLTHROUGH */ case OP_ENTERTRY: case OP_ENTEREVAL: /* Was holding hints. */ o->op_targ = 0; break; default: if (!(o->op_flags & OPf_REF) || (PL_check[o->op_type] != Perl_ck_ftst)) break; /* FALLTHROUGH */ case OP_GVSV: case OP_GV: case OP_AELEMFAST: { GV *gv = (o->op_type == OP_GV || o->op_type == OP_GVSV) #ifdef USE_ITHREADS && PL_curpad #endif ? cGVOPo_gv : NULL; /* It's possible during global destruction that the GV is freed before the optree. Whilst the SvREFCNT_inc is happy to bump from 0 to 1 on a freed SV, the corresponding SvREFCNT_dec from 1 to 0 will trigger an assertion failure, because the entry to sv_clear checks that the scalar is not already freed. A check of for !SvIS_FREED(gv) turns out to be invalid, because during global destruction the reference count can be forced down to zero (with SVf_BREAK set). In which case raising to 1 and then dropping to 0 triggers cleanup before it should happen. I *think* that this might actually be a general, systematic, weakness of the whole idea of SVf_BREAK, in that code *is* allowed to raise and lower references during global destruction, so any *valid* code that happens to do this during global destruction might well trigger premature cleanup. */ bool still_valid = gv && SvREFCNT(gv); if (still_valid) SvREFCNT_inc_simple_void(gv); #ifdef USE_ITHREADS if (cPADOPo->op_padix > 0) { /* No GvIN_PAD_off(cGVOPo_gv) here, because other references * may still exist on the pad */ pad_swipe(cPADOPo->op_padix, TRUE); cPADOPo->op_padix = 0; } #else SvREFCNT_dec(cSVOPo->op_sv); cSVOPo->op_sv = NULL; #endif if (still_valid) { int try_downgrade = SvREFCNT(gv) == 2; SvREFCNT_dec_NN(gv); if (try_downgrade) gv_try_downgrade(gv); } } break; case OP_METHOD_NAMED: case OP_CONST: case OP_HINTSEVAL: SvREFCNT_dec(cSVOPo->op_sv); cSVOPo->op_sv = NULL; #ifdef USE_ITHREADS /** Bug #15654 Even if op_clear does a pad_free for the target of the op, pad_free doesn't actually remove the sv that exists in the pad; instead it lives on. This results in that it could be reused as a target later on when the pad was reallocated. **/ if(o->op_targ) { pad_swipe(o->op_targ,1); o->op_targ = 0; } #endif break; case OP_DUMP: case OP_GOTO: case OP_NEXT: case OP_LAST: case OP_REDO: if (o->op_flags & (OPf_SPECIAL|OPf_STACKED|OPf_KIDS)) break; /* FALLTHROUGH */ case OP_TRANS: case OP_TRANSR: if (o->op_private & (OPpTRANS_FROM_UTF|OPpTRANS_TO_UTF)) { assert(o->op_type == OP_TRANS || o->op_type == OP_TRANSR); #ifdef USE_ITHREADS if (cPADOPo->op_padix > 0) { pad_swipe(cPADOPo->op_padix, TRUE); cPADOPo->op_padix = 0; } #else SvREFCNT_dec(cSVOPo->op_sv); cSVOPo->op_sv = NULL; #endif } else { PerlMemShared_free(cPVOPo->op_pv); cPVOPo->op_pv = NULL; } break; case OP_SUBST: op_free(cPMOPo->op_pmreplrootu.op_pmreplroot); goto clear_pmop; case OP_PUSHRE: #ifdef USE_ITHREADS if (cPMOPo->op_pmreplrootu.op_pmtargetoff) { /* No GvIN_PAD_off here, because other references may still * exist on the pad */ pad_swipe(cPMOPo->op_pmreplrootu.op_pmtargetoff, TRUE); } #else SvREFCNT_dec(MUTABLE_SV(cPMOPo->op_pmreplrootu.op_pmtargetgv)); #endif /* FALLTHROUGH */ case OP_MATCH: case OP_QR: clear_pmop: if (!(cPMOPo->op_pmflags & PMf_CODELIST_PRIVATE)) op_free(cPMOPo->op_code_list); cPMOPo->op_code_list = NULL; forget_pmop(cPMOPo); cPMOPo->op_pmreplrootu.op_pmreplroot = NULL; /* we use the same protection as the "SAFE" version of the PM_ macros * here since sv_clean_all might release some PMOPs * after PL_regex_padav has been cleared * and the clearing of PL_regex_padav needs to * happen before sv_clean_all */ #ifdef USE_ITHREADS if(PL_regex_pad) { /* We could be in destruction */ const IV offset = (cPMOPo)->op_pmoffset; ReREFCNT_dec(PM_GETRE(cPMOPo)); PL_regex_pad[offset] = &PL_sv_undef; sv_catpvn_nomg(PL_regex_pad[0], (const char *)&offset, sizeof(offset)); } #else ReREFCNT_dec(PM_GETRE(cPMOPo)); PM_SETRE(cPMOPo, NULL); #endif break; } if (o->op_targ > 0) { pad_free(o->op_targ); o->op_targ = 0; } } STATIC void S_cop_free(pTHX_ COP* cop) { PERL_ARGS_ASSERT_COP_FREE; CopFILE_free(cop); if (! specialWARN(cop->cop_warnings)) PerlMemShared_free(cop->cop_warnings); cophh_free(CopHINTHASH_get(cop)); if (PL_curcop == cop) PL_curcop = NULL; } STATIC void S_forget_pmop(pTHX_ PMOP *const o ) { HV * const pmstash = PmopSTASH(o); PERL_ARGS_ASSERT_FORGET_PMOP; if (pmstash && !SvIS_FREED(pmstash) && SvMAGICAL(pmstash)) { MAGIC * const mg = mg_find((const SV *)pmstash, PERL_MAGIC_symtab); if (mg) { PMOP **const array = (PMOP**) mg->mg_ptr; U32 count = mg->mg_len / sizeof(PMOP**); U32 i = count; while (i--) { if (array[i] == o) { /* Found it. Move the entry at the end to overwrite it. */ array[i] = array[--count]; mg->mg_len = count * sizeof(PMOP**); /* Could realloc smaller at this point always, but probably not worth it. Probably worth free()ing if we're the last. */ if(!count) { Safefree(mg->mg_ptr); mg->mg_ptr = NULL; } break; } } } } if (PL_curpm == o) PL_curpm = NULL; } STATIC void S_find_and_forget_pmops(pTHX_ OP *o) { PERL_ARGS_ASSERT_FIND_AND_FORGET_PMOPS; if (o->op_flags & OPf_KIDS) { OP *kid = cUNOPo->op_first; while (kid) { switch (kid->op_type) { case OP_SUBST: case OP_PUSHRE: case OP_MATCH: case OP_QR: forget_pmop((PMOP*)kid); } find_and_forget_pmops(kid); kid = kid->op_sibling; } } } /* =for apidoc Am|void|op_null|OP *o Neutralizes an op when it is no longer needed, but is still linked to from other ops. =cut */ void Perl_op_null(pTHX_ OP *o) { dVAR; PERL_ARGS_ASSERT_OP_NULL; if (o->op_type == OP_NULL) return; op_clear(o); o->op_targ = o->op_type; o->op_type = OP_NULL; o->op_ppaddr = PL_ppaddr[OP_NULL]; } void Perl_op_refcnt_lock(pTHX) { #ifdef USE_ITHREADS dVAR; #endif PERL_UNUSED_CONTEXT; OP_REFCNT_LOCK; } void Perl_op_refcnt_unlock(pTHX) { #ifdef USE_ITHREADS dVAR; #endif PERL_UNUSED_CONTEXT; OP_REFCNT_UNLOCK; } /* Contextualizers */ /* =for apidoc Am|OP *|op_contextualize|OP *o|I32 context Applies a syntactic context to an op tree representing an expression. I is the op tree, and I must be C, C, or C to specify the context to apply. The modified op tree is returned. =cut */ OP * Perl_op_contextualize(pTHX_ OP *o, I32 context) { PERL_ARGS_ASSERT_OP_CONTEXTUALIZE; switch (context) { case G_SCALAR: return scalar(o); case G_ARRAY: return list(o); case G_VOID: return scalarvoid(o); default: Perl_croak(aTHX_ "panic: op_contextualize bad context %ld", (long) context); } } /* =for apidoc Am|OP*|op_linklist|OP *o This function is the implementation of the L macro. It should not be called directly. =cut */ OP * Perl_op_linklist(pTHX_ OP *o) { OP *first; PERL_ARGS_ASSERT_OP_LINKLIST; if (o->op_next) return o->op_next; /* establish postfix order */ first = cUNOPo->op_first; if (first) { OP *kid; o->op_next = LINKLIST(first); kid = first; for (;;) { if (kid->op_sibling) { kid->op_next = LINKLIST(kid->op_sibling); kid = kid->op_sibling; } else { kid->op_next = o; break; } } } else o->op_next = o; return o->op_next; } static OP * S_scalarkids(pTHX_ OP *o) { if (o && o->op_flags & OPf_KIDS) { OP *kid; for (kid = cLISTOPo->op_first; kid; kid = kid->op_sibling) scalar(kid); } return o; } STATIC OP * S_scalarboolean(pTHX_ OP *o) { PERL_ARGS_ASSERT_SCALARBOOLEAN; if (o->op_type == OP_SASSIGN && cBINOPo->op_first->op_type == OP_CONST && !(cBINOPo->op_first->op_flags & OPf_SPECIAL)) { if (ckWARN(WARN_SYNTAX)) { const line_t oldline = CopLINE(PL_curcop); if (PL_parser && PL_parser->copline != NOLINE) { /* This ensures that warnings are reported at the first line of the conditional, not the last. */ CopLINE_set(PL_curcop, PL_parser->copline); } Perl_warner(aTHX_ packWARN(WARN_SYNTAX), "Found = in conditional, should be =="); CopLINE_set(PL_curcop, oldline); } } return scalar(o); } static SV * S_op_varname(pTHX_ const OP *o) { assert(o); assert(o->op_type == OP_PADAV || o->op_type == OP_RV2AV || o->op_type == OP_PADHV || o->op_type == OP_RV2HV); { const char funny = o->op_type == OP_PADAV || o->op_type == OP_RV2AV ? '@' : '%'; if (o->op_type == OP_RV2AV || o->op_type == OP_RV2HV) { GV *gv; if (cUNOPo->op_first->op_type != OP_GV || !(gv = cGVOPx_gv(cUNOPo->op_first))) return NULL; return varname(gv, funny, 0, NULL, 0, 1); } return varname(MUTABLE_GV(PL_compcv), funny, o->op_targ, NULL, 0, 1); } } static void S_op_pretty(pTHX_ const OP *o, SV **retsv, const char **retpv) { /* or not so pretty :-) */ if (o->op_type == OP_CONST) { *retsv = cSVOPo_sv; if (SvPOK(*retsv)) { SV *sv = *retsv; *retsv = sv_newmortal(); pv_pretty(*retsv, SvPVX_const(sv), SvCUR(sv), 32, NULL, NULL, PERL_PV_PRETTY_DUMP |PERL_PV_ESCAPE_UNI_DETECT); } else if (!SvOK(*retsv)) *retpv = "undef"; } else *retpv = "..."; } static void S_scalar_slice_warning(pTHX_ const OP *o) { OP *kid; const char lbrack = o->op_type == OP_HSLICE ? '{' : '['; const char rbrack = o->op_type == OP_HSLICE ? '}' : ']'; SV *name; SV *keysv = NULL; /* just to silence compiler warnings */ const char *key = NULL; if (!(o->op_private & OPpSLICEWARNING)) return; if (PL_parser && PL_parser->error_count) /* This warning can be nonsensical when there is a syntax error. */ return; kid = cLISTOPo->op_first; kid = kid->op_sibling; /* get past pushmark */ /* weed out false positives: any ops that can return lists */ switch (kid->op_type) { case OP_BACKTICK: case OP_GLOB: case OP_READLINE: case OP_MATCH: case OP_RV2AV: case OP_EACH: case OP_VALUES: case OP_KEYS: case OP_SPLIT: case OP_LIST: case OP_SORT: case OP_REVERSE: case OP_ENTERSUB: case OP_CALLER: case OP_LSTAT: case OP_STAT: case OP_READDIR: case OP_SYSTEM: case OP_TMS: case OP_LOCALTIME: case OP_GMTIME: case OP_ENTEREVAL: case OP_REACH: case OP_RKEYS: case OP_RVALUES: return; } /* Don't warn if we have a nulled list either. */ if (kid->op_type == OP_NULL && kid->op_targ == OP_LIST) return; assert(kid->op_sibling); name = S_op_varname(aTHX_ kid->op_sibling); if (!name) /* XS module fiddling with the op tree */ return; S_op_pretty(aTHX_ kid, &keysv, &key); assert(SvPOK(name)); sv_chop(name,SvPVX(name)+1); if (key) /* diag_listed_as: Scalar value @%s[%s] better written as $%s[%s] */ Perl_warner(aTHX_ packWARN(WARN_SYNTAX), "Scalar value @%"SVf"%c%s%c better written as $%"SVf "%c%s%c", SVfARG(name), lbrack, key, rbrack, SVfARG(name), lbrack, key, rbrack); else /* diag_listed_as: Scalar value @%s[%s] better written as $%s[%s] */ Perl_warner(aTHX_ packWARN(WARN_SYNTAX), "Scalar value @%"SVf"%c%"SVf"%c better written as $%" SVf"%c%"SVf"%c", SVfARG(name), lbrack, SVfARG(keysv), rbrack, SVfARG(name), lbrack, SVfARG(keysv), rbrack); } OP * Perl_scalar(pTHX_ OP *o) { OP *kid; /* assumes no premature commitment */ if (!o || (PL_parser && PL_parser->error_count) || (o->op_flags & OPf_WANT) || o->op_type == OP_RETURN) { return o; } o->op_flags = (o->op_flags & ~OPf_WANT) | OPf_WANT_SCALAR; switch (o->op_type) { case OP_REPEAT: scalar(cBINOPo->op_first); break; case OP_OR: case OP_AND: case OP_COND_EXPR: for (kid = cUNOPo->op_first->op_sibling; kid; kid = kid->op_sibling) scalar(kid); break; /* FALLTHROUGH */ case OP_SPLIT: case OP_MATCH: case OP_QR: case OP_SUBST: case OP_NULL: default: if (o->op_flags & OPf_KIDS) { for (kid = cUNOPo->op_first; kid; kid = kid->op_sibling) scalar(kid); } break; case OP_LEAVE: case OP_LEAVETRY: kid = cLISTOPo->op_first; scalar(kid); kid = kid->op_sibling; do_kids: while (kid) { OP *sib = kid->op_sibling; if (sib && kid->op_type != OP_LEAVEWHEN) scalarvoid(kid); else scalar(kid); kid = sib; } PL_curcop = &PL_compiling; break; case OP_SCOPE: case OP_LINESEQ: case OP_LIST: kid = cLISTOPo->op_first; goto do_kids; case OP_SORT: Perl_ck_warner(aTHX_ packWARN(WARN_VOID), "Useless use of sort in scalar context"); break; case OP_KVHSLICE: case OP_KVASLICE: { /* Warn about scalar context */ const char lbrack = o->op_type == OP_KVHSLICE ? '{' : '['; const char rbrack = o->op_type == OP_KVHSLICE ? '}' : ']'; SV *name; SV *keysv; const char *key = NULL; /* This warning can be nonsensical when there is a syntax error. */ if (PL_parser && PL_parser->error_count) break; if (!ckWARN(WARN_SYNTAX)) break; kid = cLISTOPo->op_first; kid = kid->op_sibling; /* get past pushmark */ assert(kid->op_sibling); name = S_op_varname(aTHX_ kid->op_sibling); if (!name) /* XS module fiddling with the op tree */ break; S_op_pretty(aTHX_ kid, &keysv, &key); assert(SvPOK(name)); sv_chop(name,SvPVX(name)+1); if (key) /* diag_listed_as: %%s[%s] in scalar context better written as $%s[%s] */ Perl_warner(aTHX_ packWARN(WARN_SYNTAX), "%%%"SVf"%c%s%c in scalar context better written " "as $%"SVf"%c%s%c", SVfARG(name), lbrack, key, rbrack, SVfARG(name), lbrack, key, rbrack); else /* diag_listed_as: %%s[%s] in scalar context better written as $%s[%s] */ Perl_warner(aTHX_ packWARN(WARN_SYNTAX), "%%%"SVf"%c%"SVf"%c in scalar context better " "written as $%"SVf"%c%"SVf"%c", SVfARG(name), lbrack, SVfARG(keysv), rbrack, SVfARG(name), lbrack, SVfARG(keysv), rbrack); } } return o; } OP * Perl_scalarvoid(pTHX_ OP *o) { dVAR; OP *kid; SV *useless_sv = NULL; const char* useless = NULL; SV* sv; U8 want; PERL_ARGS_ASSERT_SCALARVOID; if (o->op_type == OP_NEXTSTATE || o->op_type == OP_DBSTATE || (o->op_type == OP_NULL && (o->op_targ == OP_NEXTSTATE || o->op_targ == OP_DBSTATE))) PL_curcop = (COP*)o; /* for warning below */ /* assumes no premature commitment */ want = o->op_flags & OPf_WANT; if ((want && want != OPf_WANT_SCALAR) || (PL_parser && PL_parser->error_count) || o->op_type == OP_RETURN || o->op_type == OP_REQUIRE || o->op_type == OP_LEAVEWHEN) { return o; } if ((o->op_private & OPpTARGET_MY) && (PL_opargs[o->op_type] & OA_TARGLEX))/* OPp share the meaning */ { return scalar(o); /* As if inside SASSIGN */ } o->op_flags = (o->op_flags & ~OPf_WANT) | OPf_WANT_VOID; switch (o->op_type) { default: if (!(PL_opargs[o->op_type] & OA_FOLDCONST)) break; /* FALLTHROUGH */ case OP_REPEAT: if (o->op_flags & OPf_STACKED) break; goto func_ops; case OP_SUBSTR: if (o->op_private == 4) break; /* FALLTHROUGH */ case OP_GVSV: case OP_WANTARRAY: case OP_GV: case OP_SMARTMATCH: case OP_PADSV: case OP_PADAV: case OP_PADHV: case OP_PADANY: case OP_AV2ARYLEN: case OP_REF: case OP_REFGEN: case OP_SREFGEN: case OP_DEFINED: case OP_HEX: case OP_OCT: case OP_LENGTH: case OP_VEC: case OP_INDEX: case OP_RINDEX: case OP_SPRINTF: case OP_AELEM: case OP_AELEMFAST: case OP_AELEMFAST_LEX: case OP_ASLICE: case OP_KVASLICE: case OP_HELEM: case OP_HSLICE: case OP_KVHSLICE: case OP_UNPACK: case OP_PACK: case OP_JOIN: case OP_LSLICE: case OP_ANONLIST: case OP_ANONHASH: case OP_SORT: case OP_REVERSE: case OP_RANGE: case OP_FLIP: case OP_FLOP: case OP_CALLER: case OP_FILENO: case OP_EOF: case OP_TELL: case OP_GETSOCKNAME: case OP_GETPEERNAME: case OP_READLINK: case OP_TELLDIR: case OP_GETPPID: case OP_GETPGRP: case OP_GETPRIORITY: case OP_TIME: case OP_TMS: case OP_LOCALTIME: case OP_GMTIME: case OP_GHBYNAME: case OP_GHBYADDR: case OP_GHOSTENT: case OP_GNBYNAME: case OP_GNBYADDR: case OP_GNETENT: case OP_GPBYNAME: case OP_GPBYNUMBER: case OP_GPROTOENT: case OP_GSBYNAME: case OP_GSBYPORT: case OP_GSERVENT: case OP_GPWNAM: case OP_GPWUID: case OP_GGRNAM: case OP_GGRGID: case OP_GETLOGIN: case OP_PROTOTYPE: case OP_RUNCV: func_ops: if (!(o->op_private & (OPpLVAL_INTRO|OPpOUR_INTRO))) /* Otherwise it's "Useless use of grep iterator" */ useless = OP_DESC(o); break; case OP_SPLIT: kid = cLISTOPo->op_first; if (kid && kid->op_type == OP_PUSHRE #ifdef USE_ITHREADS && !((PMOP*)kid)->op_pmreplrootu.op_pmtargetoff) #else && !((PMOP*)kid)->op_pmreplrootu.op_pmtargetgv) #endif useless = OP_DESC(o); break; case OP_NOT: kid = cUNOPo->op_first; if (kid->op_type != OP_MATCH && kid->op_type != OP_SUBST && kid->op_type != OP_TRANS && kid->op_type != OP_TRANSR) { goto func_ops; } useless = "negative pattern binding (!~)"; break; case OP_SUBST: if (cPMOPo->op_pmflags & PMf_NONDESTRUCT) useless = "non-destructive substitution (s///r)"; break; case OP_TRANSR: useless = "non-destructive transliteration (tr///r)"; break; case OP_RV2GV: case OP_RV2SV: case OP_RV2AV: case OP_RV2HV: if (!(o->op_private & (OPpLVAL_INTRO|OPpOUR_INTRO)) && (!o->op_sibling || o->op_sibling->op_type != OP_READLINE)) useless = "a variable"; break; case OP_CONST: sv = cSVOPo_sv; if (cSVOPo->op_private & OPpCONST_STRICT) no_bareword_allowed(o); else { if (ckWARN(WARN_VOID)) { /* don't warn on optimised away booleans, eg * use constant Foo, 5; Foo || print; */ if (cSVOPo->op_private & OPpCONST_SHORTCIRCUIT) useless = NULL; /* the constants 0 and 1 are permitted as they are conventionally used as dummies in constructs like 1 while some_condition_with_side_effects; */ else if (SvNIOK(sv) && (SvNV(sv) == 0.0 || SvNV(sv) == 1.0)) useless = NULL; else if (SvPOK(sv)) { SV * const dsv = newSVpvs(""); useless_sv = Perl_newSVpvf(aTHX_ "a constant (%s)", pv_pretty(dsv, SvPVX_const(sv), SvCUR(sv), 32, NULL, NULL, PERL_PV_PRETTY_DUMP | PERL_PV_ESCAPE_NOCLEAR | PERL_PV_ESCAPE_UNI_DETECT)); SvREFCNT_dec_NN(dsv); } else if (SvOK(sv)) { useless_sv = Perl_newSVpvf(aTHX_ "a constant (%"SVf")", SVfARG(sv)); } else useless = "a constant (undef)"; } } op_null(o); /* don't execute or even remember it */ break; case OP_POSTINC: o->op_type = OP_PREINC; /* pre-increment is faster */ o->op_ppaddr = PL_ppaddr[OP_PREINC]; break; case OP_POSTDEC: o->op_type = OP_PREDEC; /* pre-decrement is faster */ o->op_ppaddr = PL_ppaddr[OP_PREDEC]; break; case OP_I_POSTINC: o->op_type = OP_I_PREINC; /* pre-increment is faster */ o->op_ppaddr = PL_ppaddr[OP_I_PREINC]; break; case OP_I_POSTDEC: o->op_type = OP_I_PREDEC; /* pre-decrement is faster */ o->op_ppaddr = PL_ppaddr[OP_I_PREDEC]; break; case OP_SASSIGN: { OP *rv2gv; UNOP *refgen, *rv2cv; LISTOP *exlist; if ((o->op_private & ~OPpASSIGN_BACKWARDS) != 2) break; rv2gv = ((BINOP *)o)->op_last; if (!rv2gv || rv2gv->op_type != OP_RV2GV) break; refgen = (UNOP *)((BINOP *)o)->op_first; if (!refgen || refgen->op_type != OP_REFGEN) break; exlist = (LISTOP *)refgen->op_first; if (!exlist || exlist->op_type != OP_NULL || exlist->op_targ != OP_LIST) break; if (exlist->op_first->op_type != OP_PUSHMARK) break; rv2cv = (UNOP*)exlist->op_last; if (rv2cv->op_type != OP_RV2CV) break; assert ((rv2gv->op_private & OPpDONT_INIT_GV) == 0); assert ((o->op_private & OPpASSIGN_CV_TO_GV) == 0); assert ((rv2cv->op_private & OPpMAY_RETURN_CONSTANT) == 0); o->op_private |= OPpASSIGN_CV_TO_GV; rv2gv->op_private |= OPpDONT_INIT_GV; rv2cv->op_private |= OPpMAY_RETURN_CONSTANT; break; } case OP_AASSIGN: { inplace_aassign(o); break; } case OP_OR: case OP_AND: kid = cLOGOPo->op_first; if (kid->op_type == OP_NOT && (kid->op_flags & OPf_KIDS)) { if (o->op_type == OP_AND) { o->op_type = OP_OR; o->op_ppaddr = PL_ppaddr[OP_OR]; } else { o->op_type = OP_AND; o->op_ppaddr = PL_ppaddr[OP_AND]; } op_null(kid); } /* FALLTHROUGH */ case OP_DOR: case OP_COND_EXPR: case OP_ENTERGIVEN: case OP_ENTERWHEN: for (kid = cUNOPo->op_first->op_sibling; kid; kid = kid->op_sibling) scalarvoid(kid); break; case OP_NULL: if (o->op_flags & OPf_STACKED) break; /* FALLTHROUGH */ case OP_NEXTSTATE: case OP_DBSTATE: case OP_ENTERTRY: case OP_ENTER: if (!(o->op_flags & OPf_KIDS)) break; /* FALLTHROUGH */ case OP_SCOPE: case OP_LEAVE: case OP_LEAVETRY: case OP_LEAVELOOP: case OP_LINESEQ: case OP_LIST: case OP_LEAVEGIVEN: case OP_LEAVEWHEN: for (kid = cLISTOPo->op_first; kid; kid = kid->op_sibling) scalarvoid(kid); break; case OP_ENTEREVAL: scalarkids(o); break; case OP_SCALAR: return scalar(o); } if (useless_sv) { /* mortalise it, in case warnings are fatal. */ Perl_ck_warner(aTHX_ packWARN(WARN_VOID), "Useless use of %"SVf" in void context", SVfARG(sv_2mortal(useless_sv))); } else if (useless) { Perl_ck_warner(aTHX_ packWARN(WARN_VOID), "Useless use of %s in void context", useless); } return o; } static OP * S_listkids(pTHX_ OP *o) { if (o && o->op_flags & OPf_KIDS) { OP *kid; for (kid = cLISTOPo->op_first; kid; kid = kid->op_sibling) list(kid); } return o; } OP * Perl_list(pTHX_ OP *o) { OP *kid; /* assumes no premature commitment */ if (!o || (o->op_flags & OPf_WANT) || (PL_parser && PL_parser->error_count) || o->op_type == OP_RETURN) { return o; } if ((o->op_private & OPpTARGET_MY) && (PL_opargs[o->op_type] & OA_TARGLEX))/* OPp share the meaning */ { return o; /* As if inside SASSIGN */ } o->op_flags = (o->op_flags & ~OPf_WANT) | OPf_WANT_LIST; switch (o->op_type) { case OP_FLOP: case OP_REPEAT: list(cBINOPo->op_first); break; case OP_OR: case OP_AND: case OP_COND_EXPR: for (kid = cUNOPo->op_first->op_sibling; kid; kid = kid->op_sibling) list(kid); break; default: case OP_MATCH: case OP_QR: case OP_SUBST: case OP_NULL: if (!(o->op_flags & OPf_KIDS)) break; if (!o->op_next && cUNOPo->op_first->op_type == OP_FLOP) { list(cBINOPo->op_first); return gen_constant_list(o); } case OP_LIST: listkids(o); break; case OP_LEAVE: case OP_LEAVETRY: kid = cLISTOPo->op_first; list(kid); kid = kid->op_sibling; do_kids: while (kid) { OP *sib = kid->op_sibling; if (sib && kid->op_type != OP_LEAVEWHEN) scalarvoid(kid); else list(kid); kid = sib; } PL_curcop = &PL_compiling; break; case OP_SCOPE: case OP_LINESEQ: kid = cLISTOPo->op_first; goto do_kids; } return o; } static OP * S_scalarseq(pTHX_ OP *o) { if (o) { const OPCODE type = o->op_type; if (type == OP_LINESEQ || type == OP_SCOPE || type == OP_LEAVE || type == OP_LEAVETRY) { OP *kid; for (kid = cLISTOPo->op_first; kid; kid = kid->op_sibling) { if (kid->op_sibling) { scalarvoid(kid); } } PL_curcop = &PL_compiling; } o->op_flags &= ~OPf_PARENS; if (PL_hints & HINT_BLOCK_SCOPE) o->op_flags |= OPf_PARENS; } else o = newOP(OP_STUB, 0); return o; } STATIC OP * S_modkids(pTHX_ OP *o, I32 type) { if (o && o->op_flags & OPf_KIDS) { OP *kid; for (kid = cLISTOPo->op_first; kid; kid = kid->op_sibling) op_lvalue(kid, type); } return o; } /* =for apidoc finalize_optree This function finalizes the optree. Should be called directly after the complete optree is built. It does some additional checking which can't be done in the normal ck_xxx functions and makes the tree thread-safe. =cut */ void Perl_finalize_optree(pTHX_ OP* o) { PERL_ARGS_ASSERT_FINALIZE_OPTREE; ENTER; SAVEVPTR(PL_curcop); finalize_op(o); LEAVE; } STATIC void S_finalize_op(pTHX_ OP* o) { PERL_ARGS_ASSERT_FINALIZE_OP; switch (o->op_type) { case OP_NEXTSTATE: case OP_DBSTATE: PL_curcop = ((COP*)o); /* for warnings */ break; case OP_EXEC: if ( o->op_sibling && (o->op_sibling->op_type == OP_NEXTSTATE || o->op_sibling->op_type == OP_DBSTATE) && ckWARN(WARN_EXEC)) { if (o->op_sibling->op_sibling) { const OPCODE type = o->op_sibling->op_sibling->op_type; if (type != OP_EXIT && type != OP_WARN && type != OP_DIE) { const line_t oldline = CopLINE(PL_curcop); CopLINE_set(PL_curcop, CopLINE((COP*)o->op_sibling)); Perl_warner(aTHX_ packWARN(WARN_EXEC), "Statement unlikely to be reached"); Perl_warner(aTHX_ packWARN(WARN_EXEC), "\t(Maybe you meant system() when you said exec()?)\n"); CopLINE_set(PL_curcop, oldline); } } } break; case OP_GV: if ((o->op_private & OPpEARLY_CV) && ckWARN(WARN_PROTOTYPE)) { GV * const gv = cGVOPo_gv; if (SvTYPE(gv) == SVt_PVGV && GvCV(gv) && SvPVX_const(GvCV(gv))) { /* XXX could check prototype here instead of just carping */ SV * const sv = sv_newmortal(); gv_efullname3(sv, gv, NULL); Perl_warner(aTHX_ packWARN(WARN_PROTOTYPE), "%"SVf"() called too early to check prototype", SVfARG(sv)); } } break; case OP_CONST: if (cSVOPo->op_private & OPpCONST_STRICT) no_bareword_allowed(o); /* FALLTHROUGH */ #ifdef USE_ITHREADS case OP_HINTSEVAL: case OP_METHOD_NAMED: /* Relocate sv to the pad for thread safety. * Despite being a "constant", the SV is written to, * for reference counts, sv_upgrade() etc. */ if (cSVOPo->op_sv) { const PADOFFSET ix = pad_alloc(OP_CONST, SVf_READONLY); SvREFCNT_dec(PAD_SVl(ix)); PAD_SETSV(ix, cSVOPo->op_sv); /* XXX I don't know how this isn't readonly already. */ if (!SvIsCOW(PAD_SVl(ix))) SvREADONLY_on(PAD_SVl(ix)); cSVOPo->op_sv = NULL; o->op_targ = ix; } #endif break; case OP_HELEM: { UNOP *rop; SV *lexname; GV **fields; SVOP *key_op; OP *kid; bool check_fields; if ((key_op = cSVOPx(((BINOP*)o)->op_last))->op_type != OP_CONST) break; rop = (UNOP*)((BINOP*)o)->op_first; goto check_keys; case OP_HSLICE: S_scalar_slice_warning(aTHX_ o); /* FALLTHROUGH */ case OP_KVHSLICE: kid = cLISTOPo->op_first->op_sibling; if (/* I bet there's always a pushmark... */ OP_TYPE_ISNT_AND_WASNT_NN(kid, OP_LIST) && OP_TYPE_ISNT_NN(kid, OP_CONST)) { break; } key_op = (SVOP*)(kid->op_type == OP_CONST ? kid : kLISTOP->op_first->op_sibling); rop = (UNOP*)((LISTOP*)o)->op_last; check_keys: if (o->op_private & OPpLVAL_INTRO || rop->op_type != OP_RV2HV) rop = NULL; else if (rop->op_first->op_type == OP_PADSV) /* @$hash{qw(keys here)} */ rop = (UNOP*)rop->op_first; else { /* @{$hash}{qw(keys here)} */ if (rop->op_first->op_type == OP_SCOPE && cLISTOPx(rop->op_first)->op_last->op_type == OP_PADSV) { rop = (UNOP*)cLISTOPx(rop->op_first)->op_last; } else rop = NULL; } lexname = NULL; /* just to silence compiler warnings */ fields = NULL; /* just to silence compiler warnings */ check_fields = rop && (lexname = *av_fetch(PL_comppad_name, rop->op_targ, TRUE), SvPAD_TYPED(lexname)) && (fields = (GV**)hv_fetchs(SvSTASH(lexname), "FIELDS", FALSE)) && isGV(*fields) && GvHV(*fields); for (; key_op; key_op = (SVOP*)key_op->op_sibling) { SV **svp, *sv; if (key_op->op_type != OP_CONST) continue; svp = cSVOPx_svp(key_op); /* Make the CONST have a shared SV */ if ((!SvIsCOW_shared_hash(sv = *svp)) && SvTYPE(sv) < SVt_PVMG && SvOK(sv) && !SvROK(sv)) { SSize_t keylen; const char * const key = SvPV_const(sv, *(STRLEN*)&keylen); SV *nsv = newSVpvn_share(key, SvUTF8(sv) ? -keylen : keylen, 0); SvREFCNT_dec_NN(sv); *svp = nsv; } if (check_fields && !hv_fetch_ent(GvHV(*fields), *svp, FALSE, 0)) { Perl_croak(aTHX_ "No such class field \"%"SVf"\" " "in variable %"SVf" of type %"HEKf, SVfARG(*svp), SVfARG(lexname), HEKfARG(HvNAME_HEK(SvSTASH(lexname)))); } } break; } case OP_ASLICE: S_scalar_slice_warning(aTHX_ o); break; case OP_SUBST: { if (cPMOPo->op_pmreplrootu.op_pmreplroot) finalize_op(cPMOPo->op_pmreplrootu.op_pmreplroot); break; } default: break; } if (o->op_flags & OPf_KIDS) { OP *kid; for (kid = cUNOPo->op_first; kid; kid = kid->op_sibling) finalize_op(kid); } } /* =for apidoc Amx|OP *|op_lvalue|OP *o|I32 type Propagate lvalue ("modifiable") context to an op and its children. I represents the context type, roughly based on the type of op that would do the modifying, although C is represented by OP_NULL, because it has no op type of its own (it is signalled by a flag on the lvalue op). This function detects things that can't be modified, such as C<$x+1>, and generates errors for them. For example, C<$x+1 = 2> would cause it to be called with an op of type OP_ADD and a C argument of OP_SASSIGN. It also flags things that need to behave specially in an lvalue context, such as C<$$x = 5> which might have to vivify a reference in C<$x>. =cut */ static bool S_vivifies(const OPCODE type) { switch(type) { case OP_RV2AV: case OP_ASLICE: case OP_RV2HV: case OP_KVASLICE: case OP_RV2SV: case OP_HSLICE: case OP_AELEMFAST: case OP_KVHSLICE: case OP_HELEM: case OP_AELEM: return 1; } return 0; } OP * Perl_op_lvalue_flags(pTHX_ OP *o, I32 type, U32 flags) { dVAR; OP *kid; /* -1 = error on localize, 0 = ignore localize, 1 = ok to localize */ int localize = -1; if (!o || (PL_parser && PL_parser->error_count)) return o; if ((o->op_private & OPpTARGET_MY) && (PL_opargs[o->op_type] & OA_TARGLEX))/* OPp share the meaning */ { return o; } assert( (o->op_flags & OPf_WANT) != OPf_WANT_VOID ); if (type == OP_PRTF || type == OP_SPRINTF) type = OP_ENTERSUB; switch (o->op_type) { case OP_UNDEF: PL_modcount++; return o; case OP_STUB: if ((o->op_flags & OPf_PARENS)) break; goto nomod; case OP_ENTERSUB: if ((type == OP_UNDEF || type == OP_REFGEN || type == OP_LOCK) && !(o->op_flags & OPf_STACKED)) { o->op_type = OP_RV2CV; /* entersub => rv2cv */ /* Both ENTERSUB and RV2CV use this bit, but for different pur- poses, so we need it clear. */ o->op_private &= ~1; o->op_ppaddr = PL_ppaddr[OP_RV2CV]; assert(cUNOPo->op_first->op_type == OP_NULL); op_null(((LISTOP*)cUNOPo->op_first)->op_first);/* disable pushmark */ break; } else { /* lvalue subroutine call */ o->op_private |= OPpLVAL_INTRO |(OPpENTERSUB_INARGS * (type == OP_LEAVESUBLV)); PL_modcount = RETURN_UNLIMITED_NUMBER; if (type == OP_GREPSTART || type == OP_ENTERSUB || type == OP_REFGEN) { /* Potential lvalue context: */ o->op_private |= OPpENTERSUB_INARGS; break; } else { /* Compile-time error message: */ OP *kid = cUNOPo->op_first; CV *cv; if (kid->op_type != OP_PUSHMARK) { if (kid->op_type != OP_NULL || kid->op_targ != OP_LIST) Perl_croak(aTHX_ "panic: unexpected lvalue entersub " "args: type/targ %ld:%"UVuf, (long)kid->op_type, (UV)kid->op_targ); kid = kLISTOP->op_first; } while (kid->op_sibling) kid = kid->op_sibling; if (!(kid->op_type == OP_NULL && kid->op_targ == OP_RV2CV)) { break; /* Postpone until runtime */ } kid = kUNOP->op_first; if (kid->op_type == OP_NULL && kid->op_targ == OP_RV2SV) kid = kUNOP->op_first; if (kid->op_type == OP_NULL) Perl_croak(aTHX_ "Unexpected constant lvalue entersub " "entry via type/targ %ld:%"UVuf, (long)kid->op_type, (UV)kid->op_targ); if (kid->op_type != OP_GV) { break; } cv = GvCV(kGVOP_gv); if (!cv) break; if (CvLVALUE(cv)) break; } } /* FALLTHROUGH */ default: nomod: if (flags & OP_LVALUE_NO_CROAK) return NULL; /* grep, foreach, subcalls, refgen */ if (type == OP_GREPSTART || type == OP_ENTERSUB || type == OP_REFGEN || type == OP_LEAVESUBLV) break; yyerror(Perl_form(aTHX_ "Can't modify %s in %s", (o->op_type == OP_NULL && (o->op_flags & OPf_SPECIAL) ? "do block" : (o->op_type == OP_ENTERSUB ? "non-lvalue subroutine call" : OP_DESC(o))), type ? PL_op_desc[type] : "local")); return o; case OP_PREINC: case OP_PREDEC: case OP_POW: case OP_MULTIPLY: case OP_DIVIDE: case OP_MODULO: case OP_REPEAT: case OP_ADD: case OP_SUBTRACT: case OP_CONCAT: case OP_LEFT_SHIFT: case OP_RIGHT_SHIFT: case OP_BIT_AND: case OP_BIT_XOR: case OP_BIT_OR: case OP_I_MULTIPLY: case OP_I_DIVIDE: case OP_I_MODULO: case OP_I_ADD: case OP_I_SUBTRACT: if (!(o->op_flags & OPf_STACKED)) goto nomod; PL_modcount++; break; case OP_COND_EXPR: localize = 1; for (kid = cUNOPo->op_first->op_sibling; kid; kid = kid->op_sibling) op_lvalue(kid, type); break; case OP_RV2AV: case OP_RV2HV: if (type == OP_REFGEN && o->op_flags & OPf_PARENS) { PL_modcount = RETURN_UNLIMITED_NUMBER; return o; /* Treat \(@foo) like ordinary list. */ } /* FALLTHROUGH */ case OP_RV2GV: if (scalar_mod_type(o, type)) goto nomod; ref(cUNOPo->op_first, o->op_type); /* FALLTHROUGH */ case OP_ASLICE: case OP_HSLICE: localize = 1; /* FALLTHROUGH */ case OP_AASSIGN: /* Do not apply the lvsub flag for rv2[ah]v in scalar context. */ if (type == OP_LEAVESUBLV && ( (o->op_type != OP_RV2AV && o->op_type != OP_RV2HV) || (o->op_flags & OPf_WANT) != OPf_WANT_SCALAR )) o->op_private |= OPpMAYBE_LVSUB; /* FALLTHROUGH */ case OP_NEXTSTATE: case OP_DBSTATE: PL_modcount = RETURN_UNLIMITED_NUMBER; break; case OP_KVHSLICE: case OP_KVASLICE: if (type == OP_LEAVESUBLV) o->op_private |= OPpMAYBE_LVSUB; goto nomod; case OP_AV2ARYLEN: PL_hints |= HINT_BLOCK_SCOPE; if (type == OP_LEAVESUBLV) o->op_private |= OPpMAYBE_LVSUB; PL_modcount++; break; case OP_RV2SV: ref(cUNOPo->op_first, o->op_type); localize = 1; /* FALLTHROUGH */ case OP_GV: PL_hints |= HINT_BLOCK_SCOPE; /* FALLTHROUGH */ case OP_SASSIGN: case OP_ANDASSIGN: case OP_ORASSIGN: case OP_DORASSIGN: PL_modcount++; break; case OP_AELEMFAST: case OP_AELEMFAST_LEX: localize = -1; PL_modcount++; break; case OP_PADAV: case OP_PADHV: PL_modcount = RETURN_UNLIMITED_NUMBER; if (type == OP_REFGEN && o->op_flags & OPf_PARENS) return o; /* Treat \(@foo) like ordinary list. */ if (scalar_mod_type(o, type)) goto nomod; if ((o->op_flags & OPf_WANT) != OPf_WANT_SCALAR && type == OP_LEAVESUBLV) o->op_private |= OPpMAYBE_LVSUB; /* FALLTHROUGH */ case OP_PADSV: PL_modcount++; if (!type) /* local() */ Perl_croak(aTHX_ "Can't localize lexical variable %"SVf, PAD_COMPNAME_SV(o->op_targ)); break; case OP_PUSHMARK: localize = 0; break; case OP_KEYS: case OP_RKEYS: if (type != OP_SASSIGN && type != OP_LEAVESUBLV) goto nomod; goto lvalue_func; case OP_SUBSTR: if (o->op_private == 4) /* don't allow 4 arg substr as lvalue */ goto nomod; /* FALLTHROUGH */ case OP_POS: case OP_VEC: lvalue_func: if (type == OP_LEAVESUBLV) o->op_private |= OPpMAYBE_LVSUB; if (o->op_flags & OPf_KIDS) op_lvalue(cBINOPo->op_first->op_sibling, type); break; case OP_AELEM: case OP_HELEM: ref(cBINOPo->op_first, o->op_type); if (type == OP_ENTERSUB && !(o->op_private & (OPpLVAL_INTRO | OPpDEREF))) o->op_private |= OPpLVAL_DEFER; if (type == OP_LEAVESUBLV) o->op_private |= OPpMAYBE_LVSUB; localize = 1; PL_modcount++; break; case OP_LEAVE: case OP_LEAVELOOP: o->op_private |= OPpLVALUE; /* FALLTHROUGH */ case OP_SCOPE: case OP_ENTER: case OP_LINESEQ: localize = 0; if (o->op_flags & OPf_KIDS) op_lvalue(cLISTOPo->op_last, type); break; case OP_NULL: localize = 0; if (o->op_flags & OPf_SPECIAL) /* do BLOCK */ goto nomod; else if (!(o->op_flags & OPf_KIDS)) break; if (o->op_targ != OP_LIST) { op_lvalue(cBINOPo->op_first, type); break; } /* FALLTHROUGH */ case OP_LIST: localize = 0; for (kid = cLISTOPo->op_first; kid; kid = kid->op_sibling) /* elements might be in void context because the list is in scalar context or because they are attribute sub calls */ if ( (kid->op_flags & OPf_WANT) != OPf_WANT_VOID ) op_lvalue(kid, type); break; case OP_RETURN: if (type != OP_LEAVESUBLV) goto nomod; break; /* op_lvalue()ing was handled by ck_return() */ case OP_COREARGS: return o; case OP_AND: case OP_OR: if (type == OP_LEAVESUBLV || !S_vivifies(cLOGOPo->op_first->op_type)) op_lvalue(cLOGOPo->op_first, type); if (type == OP_LEAVESUBLV || !S_vivifies(cLOGOPo->op_first->op_sibling->op_type)) op_lvalue(cLOGOPo->op_first->op_sibling, type); goto nomod; } /* [20011101.069] File test operators interpret OPf_REF to mean that their argument is a filehandle; thus \stat(".") should not set it. AMS 20011102 */ if (type == OP_REFGEN && PL_check[o->op_type] == Perl_ck_ftst) return o; if (type != OP_LEAVESUBLV) o->op_flags |= OPf_MOD; if (type == OP_AASSIGN || type == OP_SASSIGN) o->op_flags |= OPf_SPECIAL|OPf_REF; else if (!type) { /* local() */ switch (localize) { case 1: o->op_private |= OPpLVAL_INTRO; o->op_flags &= ~OPf_SPECIAL; PL_hints |= HINT_BLOCK_SCOPE; break; case 0: break; case -1: Perl_ck_warner(aTHX_ packWARN(WARN_SYNTAX), "Useless localization of %s", OP_DESC(o)); } } else if (type != OP_GREPSTART && type != OP_ENTERSUB && type != OP_LEAVESUBLV) o->op_flags |= OPf_REF; return o; } STATIC bool S_scalar_mod_type(const OP *o, I32 type) { switch (type) { case OP_POS: case OP_SASSIGN: if (o && o->op_type == OP_RV2GV) return FALSE; /* FALLTHROUGH */ case OP_PREINC: case OP_PREDEC: case OP_POSTINC: case OP_POSTDEC: case OP_I_PREINC: case OP_I_PREDEC: case OP_I_POSTINC: case OP_I_POSTDEC: case OP_POW: case OP_MULTIPLY: case OP_DIVIDE: case OP_MODULO: case OP_REPEAT: case OP_ADD: case OP_SUBTRACT: case OP_I_MULTIPLY: case OP_I_DIVIDE: case OP_I_MODULO: case OP_I_ADD: case OP_I_SUBTRACT: case OP_LEFT_SHIFT: case OP_RIGHT_SHIFT: case OP_BIT_AND: case OP_BIT_XOR: case OP_BIT_OR: case OP_CONCAT: case OP_SUBST: case OP_TRANS: case OP_TRANSR: case OP_READ: case OP_SYSREAD: case OP_RECV: case OP_ANDASSIGN: case OP_ORASSIGN: case OP_DORASSIGN: return TRUE; default: return FALSE; } } STATIC bool S_is_handle_constructor(const OP *o, I32 numargs) { PERL_ARGS_ASSERT_IS_HANDLE_CONSTRUCTOR; switch (o->op_type) { case OP_PIPE_OP: case OP_SOCKPAIR: if (numargs == 2) return TRUE; /* FALLTHROUGH */ case OP_SYSOPEN: case OP_OPEN: case OP_SELECT: /* XXX c.f. SelectSaver.pm */ case OP_SOCKET: case OP_OPEN_DIR: case OP_ACCEPT: if (numargs == 1) return TRUE; /* FALLTHROUGH */ default: return FALSE; } } static OP * S_refkids(pTHX_ OP *o, I32 type) { if (o && o->op_flags & OPf_KIDS) { OP *kid; for (kid = cLISTOPo->op_first; kid; kid = kid->op_sibling) ref(kid, type); } return o; } OP * Perl_doref(pTHX_ OP *o, I32 type, bool set_op_ref) { dVAR; OP *kid; PERL_ARGS_ASSERT_DOREF; if (!o || (PL_parser && PL_parser->error_count)) return o; switch (o->op_type) { case OP_ENTERSUB: if ((type == OP_EXISTS || type == OP_DEFINED) && !(o->op_flags & OPf_STACKED)) { o->op_type = OP_RV2CV; /* entersub => rv2cv */ o->op_ppaddr = PL_ppaddr[OP_RV2CV]; assert(cUNOPo->op_first->op_type == OP_NULL); op_null(((LISTOP*)cUNOPo->op_first)->op_first); /* disable pushmark */ o->op_flags |= OPf_SPECIAL; o->op_private &= ~1; } else if (type == OP_RV2SV || type == OP_RV2AV || type == OP_RV2HV){ o->op_private |= (type == OP_RV2AV ? OPpDEREF_AV : type == OP_RV2HV ? OPpDEREF_HV : OPpDEREF_SV); o->op_flags |= OPf_MOD; } break; case OP_COND_EXPR: for (kid = cUNOPo->op_first->op_sibling; kid; kid = kid->op_sibling) doref(kid, type, set_op_ref); break; case OP_RV2SV: if (type == OP_DEFINED) o->op_flags |= OPf_SPECIAL; /* don't create GV */ doref(cUNOPo->op_first, o->op_type, set_op_ref); /* FALLTHROUGH */ case OP_PADSV: if (type == OP_RV2SV || type == OP_RV2AV || type == OP_RV2HV) { o->op_private |= (type == OP_RV2AV ? OPpDEREF_AV : type == OP_RV2HV ? OPpDEREF_HV : OPpDEREF_SV); o->op_flags |= OPf_MOD; } break; case OP_RV2AV: case OP_RV2HV: if (set_op_ref) o->op_flags |= OPf_REF; /* FALLTHROUGH */ case OP_RV2GV: if (type == OP_DEFINED) o->op_flags |= OPf_SPECIAL; /* don't create GV */ doref(cUNOPo->op_first, o->op_type, set_op_ref); break; case OP_PADAV: case OP_PADHV: if (set_op_ref) o->op_flags |= OPf_REF; break; case OP_SCALAR: case OP_NULL: if (!(o->op_flags & OPf_KIDS) || type == OP_DEFINED) break; doref(cBINOPo->op_first, type, set_op_ref); break; case OP_AELEM: case OP_HELEM: doref(cBINOPo->op_first, o->op_type, set_op_ref); if (type == OP_RV2SV || type == OP_RV2AV || type == OP_RV2HV) { o->op_private |= (type == OP_RV2AV ? OPpDEREF_AV : type == OP_RV2HV ? OPpDEREF_HV : OPpDEREF_SV); o->op_flags |= OPf_MOD; } break; case OP_SCOPE: case OP_LEAVE: set_op_ref = FALSE; /* FALLTHROUGH */ case OP_ENTER: case OP_LIST: if (!(o->op_flags & OPf_KIDS)) break; doref(cLISTOPo->op_last, type, set_op_ref); break; default: break; } return scalar(o); } STATIC OP * S_dup_attrlist(pTHX_ OP *o) { OP *rop; PERL_ARGS_ASSERT_DUP_ATTRLIST; /* An attrlist is either a simple OP_CONST or an OP_LIST with kids, * where the first kid is OP_PUSHMARK and the remaining ones * are OP_CONST. We need to push the OP_CONST values. */ if (o->op_type == OP_CONST) rop = newSVOP(OP_CONST, o->op_flags, SvREFCNT_inc_NN(cSVOPo->op_sv)); else { assert((o->op_type == OP_LIST) && (o->op_flags & OPf_KIDS)); rop = NULL; for (o = cLISTOPo->op_first; o; o=o->op_sibling) { if (o->op_type == OP_CONST) rop = op_append_elem(OP_LIST, rop, newSVOP(OP_CONST, o->op_flags, SvREFCNT_inc_NN(cSVOPo->op_sv))); } } return rop; } STATIC void S_apply_attrs(pTHX_ HV *stash, SV *target, OP *attrs) { SV * const stashsv = stash ? newSVhek(HvNAME_HEK(stash)) : &PL_sv_no; PERL_ARGS_ASSERT_APPLY_ATTRS; /* fake up C */ #define ATTRSMODULE "attributes" #define ATTRSMODULE_PM "attributes.pm" Perl_load_module(aTHX_ PERL_LOADMOD_IMPORT_OPS, newSVpvs(ATTRSMODULE), NULL, op_prepend_elem(OP_LIST, newSVOP(OP_CONST, 0, stashsv), op_prepend_elem(OP_LIST, newSVOP(OP_CONST, 0, newRV(target)), dup_attrlist(attrs)))); } STATIC void S_apply_attrs_my(pTHX_ HV *stash, OP *target, OP *attrs, OP **imopsp) { OP *pack, *imop, *arg; SV *meth, *stashsv, **svp; PERL_ARGS_ASSERT_APPLY_ATTRS_MY; if (!attrs) return; assert(target->op_type == OP_PADSV || target->op_type == OP_PADHV || target->op_type == OP_PADAV); /* Ensure that attributes.pm is loaded. */ /* Don't force the C if we don't need it. */ svp = hv_fetchs(GvHVn(PL_incgv), ATTRSMODULE_PM, FALSE); if (svp && *svp != &PL_sv_undef) NOOP; /* already in %INC */ else Perl_load_module(aTHX_ PERL_LOADMOD_NOIMPORT, newSVpvs(ATTRSMODULE), NULL); /* Need package name for method call. */ pack = newSVOP(OP_CONST, 0, newSVpvs(ATTRSMODULE)); /* Build up the real arg-list. */ stashsv = stash ? newSVhek(HvNAME_HEK(stash)) : &PL_sv_no; arg = newOP(OP_PADSV, 0); arg->op_targ = target->op_targ; arg = op_prepend_elem(OP_LIST, newSVOP(OP_CONST, 0, stashsv), op_prepend_elem(OP_LIST, newUNOP(OP_REFGEN, 0, op_lvalue(arg, OP_REFGEN)), dup_attrlist(attrs))); /* Fake up a method call to import */ meth = newSVpvs_share("import"); imop = convert(OP_ENTERSUB, OPf_STACKED|OPf_SPECIAL|OPf_WANT_VOID, op_append_elem(OP_LIST, op_prepend_elem(OP_LIST, pack, list(arg)), newSVOP(OP_METHOD_NAMED, 0, meth))); /* Combine the ops. */ *imopsp = op_append_elem(OP_LIST, *imopsp, imop); } /* =notfor apidoc apply_attrs_string Attempts to apply a list of attributes specified by the C and C arguments to the subroutine identified by the C argument which is expected to be associated with the package identified by the C argument (see L). It gets this wrong, though, in that it does not correctly identify the boundaries of the individual attribute specifications within C. This is not really intended for the public API, but has to be listed here for systems such as AIX which need an explicit export list for symbols. (It's called from XS code in support of the C keyword from F.) Patches to fix it to respect attribute syntax properly would be welcome. =cut */ void Perl_apply_attrs_string(pTHX_ const char *stashpv, CV *cv, const char *attrstr, STRLEN len) { OP *attrs = NULL; PERL_ARGS_ASSERT_APPLY_ATTRS_STRING; if (!len) { len = strlen(attrstr); } while (len) { for (; isSPACE(*attrstr) && len; --len, ++attrstr) ; if (len) { const char * const sstr = attrstr; for (; !isSPACE(*attrstr) && len; --len, ++attrstr) ; attrs = op_append_elem(OP_LIST, attrs, newSVOP(OP_CONST, 0, newSVpvn(sstr, attrstr-sstr))); } } Perl_load_module(aTHX_ PERL_LOADMOD_IMPORT_OPS, newSVpvs(ATTRSMODULE), NULL, op_prepend_elem(OP_LIST, newSVOP(OP_CONST, 0, newSVpv(stashpv,0)), op_prepend_elem(OP_LIST, newSVOP(OP_CONST, 0, newRV(MUTABLE_SV(cv))), attrs))); } STATIC void S_move_proto_attr(pTHX_ OP **proto, OP **attrs, const GV * name) { OP *new_proto = NULL; STRLEN pvlen; char *pv; OP *o; PERL_ARGS_ASSERT_MOVE_PROTO_ATTR; if (!*attrs) return; o = *attrs; if (o->op_type == OP_CONST) { pv = SvPV(cSVOPo_sv, pvlen); if (pvlen >= 10 && memEQ(pv, "prototype(", 10)) { SV * const tmpsv = newSVpvn_flags(pv + 10, pvlen - 11, SvUTF8(cSVOPo_sv)); SV ** const tmpo = cSVOPx_svp(o); SvREFCNT_dec(cSVOPo_sv); *tmpo = tmpsv; new_proto = o; *attrs = NULL; } } else if (o->op_type == OP_LIST) { OP * lasto = NULL; assert(o->op_flags & OPf_KIDS); assert(cLISTOPo->op_first->op_type == OP_PUSHMARK); /* Counting on the first op to hit the lasto = o line */ for (o = cLISTOPo->op_first; o; o=o->op_sibling) { if (o->op_type == OP_CONST) { pv = SvPV(cSVOPo_sv, pvlen); if (pvlen >= 10 && memEQ(pv, "prototype(", 10)) { SV * const tmpsv = newSVpvn_flags(pv + 10, pvlen - 11, SvUTF8(cSVOPo_sv)); SV ** const tmpo = cSVOPx_svp(o); SvREFCNT_dec(cSVOPo_sv); *tmpo = tmpsv; if (new_proto && ckWARN(WARN_MISC)) { STRLEN new_len; const char * newp = SvPV(cSVOPo_sv, new_len); Perl_warner(aTHX_ packWARN(WARN_MISC), "Attribute prototype(%"UTF8f") discards earlier prototype attribute in same sub", UTF8fARG(SvUTF8(cSVOPo_sv), new_len, newp)); op_free(new_proto); } else if (new_proto) op_free(new_proto); new_proto = o; lasto->op_sibling = o->op_sibling; continue; } } lasto = o; } /* If the list is now just the PUSHMARK, scrap the whole thing; otherwise attributes.xs would get pulled in with no real need */ if (!cLISTOPx(*attrs)->op_first->op_sibling) { op_free(*attrs); *attrs = NULL; } } if (new_proto) { SV *svname; if (isGV(name)) { svname = sv_newmortal(); gv_efullname3(svname, name, NULL); } else if (SvPOK(name) && *SvPVX((SV *)name) == '&') svname = newSVpvn_flags(SvPVX((SV *)name)+1, SvCUR(name)-1, SvUTF8(name)|SVs_TEMP); else svname = (SV *)name; if (ckWARN(WARN_ILLEGALPROTO)) (void)validate_proto(svname, cSVOPx_sv(new_proto), TRUE); if (*proto && ckWARN(WARN_PROTOTYPE)) { STRLEN old_len, new_len; const char * oldp = SvPV(cSVOPx_sv(*proto), old_len); const char * newp = SvPV(cSVOPx_sv(new_proto), new_len); Perl_warner(aTHX_ packWARN(WARN_PROTOTYPE), "Prototype '%"UTF8f"' overridden by attribute 'prototype(%"UTF8f")'" " in %"SVf, UTF8fARG(SvUTF8(cSVOPx_sv(*proto)), old_len, oldp), UTF8fARG(SvUTF8(cSVOPx_sv(new_proto)), new_len, newp), SVfARG(svname)); } if (*proto) op_free(*proto); *proto = new_proto; } } static void S_cant_declare(pTHX_ OP *o) { if (o->op_type == OP_NULL && (o->op_flags & (OPf_SPECIAL|OPf_KIDS)) == OPf_KIDS) o = cUNOPo->op_first; yyerror(Perl_form(aTHX_ "Can't declare %s in \"%s\"", o->op_type == OP_NULL && o->op_flags & OPf_SPECIAL ? "do block" : OP_DESC(o), PL_parser->in_my == KEY_our ? "our" : PL_parser->in_my == KEY_state ? "state" : "my")); } STATIC OP * S_my_kid(pTHX_ OP *o, OP *attrs, OP **imopsp) { I32 type; const bool stately = PL_parser && PL_parser->in_my == KEY_state; PERL_ARGS_ASSERT_MY_KID; if (!o || (PL_parser && PL_parser->error_count)) return o; type = o->op_type; if (type == OP_LIST) { OP *kid; for (kid = cLISTOPo->op_first; kid; kid = kid->op_sibling) my_kid(kid, attrs, imopsp); return o; } else if (type == OP_UNDEF || type == OP_STUB) { return o; } else if (type == OP_RV2SV || /* "our" declaration */ type == OP_RV2AV || type == OP_RV2HV) { /* XXX does this let anything illegal in? */ if (cUNOPo->op_first->op_type != OP_GV) { /* MJD 20011224 */ S_cant_declare(aTHX_ o); } else if (attrs) { GV * const gv = cGVOPx_gv(cUNOPo->op_first); assert(PL_parser); PL_parser->in_my = FALSE; PL_parser->in_my_stash = NULL; apply_attrs(GvSTASH(gv), (type == OP_RV2SV ? GvSV(gv) : type == OP_RV2AV ? MUTABLE_SV(GvAV(gv)) : type == OP_RV2HV ? MUTABLE_SV(GvHV(gv)) : MUTABLE_SV(gv)), attrs); } o->op_private |= OPpOUR_INTRO; return o; } else if (type != OP_PADSV && type != OP_PADAV && type != OP_PADHV && type != OP_PUSHMARK) { S_cant_declare(aTHX_ o); return o; } else if (attrs && type != OP_PUSHMARK) { HV *stash; assert(PL_parser); PL_parser->in_my = FALSE; PL_parser->in_my_stash = NULL; /* check for C when deciding package */ stash = PAD_COMPNAME_TYPE(o->op_targ); if (!stash) stash = PL_curstash; apply_attrs_my(stash, o, attrs, imopsp); } o->op_flags |= OPf_MOD; o->op_private |= OPpLVAL_INTRO; if (stately) o->op_private |= OPpPAD_STATE; return o; } OP * Perl_my_attrs(pTHX_ OP *o, OP *attrs) { OP *rops; int maybe_scalar = 0; PERL_ARGS_ASSERT_MY_ATTRS; /* [perl #17376]: this appears to be premature, and results in code such as C< our(%x); > executing in list mode rather than void mode */ #if 0 if (o->op_flags & OPf_PARENS) list(o); else maybe_scalar = 1; #else maybe_scalar = 1; #endif if (attrs) SAVEFREEOP(attrs); rops = NULL; o = my_kid(o, attrs, &rops); if (rops) { if (maybe_scalar && o->op_type == OP_PADSV) { o = scalar(op_append_list(OP_LIST, rops, o)); o->op_private |= OPpLVAL_INTRO; } else { /* The listop in rops might have a pushmark at the beginning, which will mess up list assignment. */ LISTOP * const lrops = (LISTOP *)rops; /* for brevity */ if (rops->op_type == OP_LIST && lrops->op_first && lrops->op_first->op_type == OP_PUSHMARK) { OP * const pushmark = lrops->op_first; lrops->op_first = pushmark->op_sibling; op_free(pushmark); } o = op_append_list(OP_LIST, o, rops); } } PL_parser->in_my = FALSE; PL_parser->in_my_stash = NULL; return o; } OP * Perl_sawparens(pTHX_ OP *o) { PERL_UNUSED_CONTEXT; if (o) o->op_flags |= OPf_PARENS; return o; } OP * Perl_bind_match(pTHX_ I32 type, OP *left, OP *right) { OP *o; bool ismatchop = 0; const OPCODE ltype = left->op_type; const OPCODE rtype = right->op_type; PERL_ARGS_ASSERT_BIND_MATCH; if ( (ltype == OP_RV2AV || ltype == OP_RV2HV || ltype == OP_PADAV || ltype == OP_PADHV) && ckWARN(WARN_MISC)) { const char * const desc = PL_op_desc[( rtype == OP_SUBST || rtype == OP_TRANS || rtype == OP_TRANSR ) ? (int)rtype : OP_MATCH]; const bool isary = ltype == OP_RV2AV || ltype == OP_PADAV; SV * const name = S_op_varname(aTHX_ left); if (name) Perl_warner(aTHX_ packWARN(WARN_MISC), "Applying %s to %"SVf" will act on scalar(%"SVf")", desc, SVfARG(name), SVfARG(name)); else { const char * const sample = (isary ? "@array" : "%hash"); Perl_warner(aTHX_ packWARN(WARN_MISC), "Applying %s to %s will act on scalar(%s)", desc, sample, sample); } } if (rtype == OP_CONST && cSVOPx(right)->op_private & OPpCONST_BARE && cSVOPx(right)->op_private & OPpCONST_STRICT) { no_bareword_allowed(right); } /* !~ doesn't make sense with /r, so error on it for now */ if (rtype == OP_SUBST && (cPMOPx(right)->op_pmflags & PMf_NONDESTRUCT) && type == OP_NOT) /* diag_listed_as: Using !~ with %s doesn't make sense */ yyerror("Using !~ with s///r doesn't make sense"); if (rtype == OP_TRANSR && type == OP_NOT) /* diag_listed_as: Using !~ with %s doesn't make sense */ yyerror("Using !~ with tr///r doesn't make sense"); ismatchop = (rtype == OP_MATCH || rtype == OP_SUBST || rtype == OP_TRANS || rtype == OP_TRANSR) && !(right->op_flags & OPf_SPECIAL); if (ismatchop && right->op_private & OPpTARGET_MY) { right->op_targ = 0; right->op_private &= ~OPpTARGET_MY; } if (!(right->op_flags & OPf_STACKED) && ismatchop) { OP *newleft; right->op_flags |= OPf_STACKED; if (rtype != OP_MATCH && rtype != OP_TRANSR && ! (rtype == OP_TRANS && right->op_private & OPpTRANS_IDENTICAL) && ! (rtype == OP_SUBST && (cPMOPx(right)->op_pmflags & PMf_NONDESTRUCT))) newleft = op_lvalue(left, rtype); else newleft = left; if (right->op_type == OP_TRANS || right->op_type == OP_TRANSR) o = newBINOP(OP_NULL, OPf_STACKED, scalar(newleft), right); else o = op_prepend_elem(rtype, scalar(newleft), right); if (type == OP_NOT) return newUNOP(OP_NOT, 0, scalar(o)); return o; } else return bind_match(type, left, pmruntime(newPMOP(OP_MATCH, 0), right, 0, 0)); } OP * Perl_invert(pTHX_ OP *o) { if (!o) return NULL; return newUNOP(OP_NOT, OPf_SPECIAL, scalar(o)); } /* =for apidoc Amx|OP *|op_scope|OP *o Wraps up an op tree with some additional ops so that at runtime a dynamic scope will be created. The original ops run in the new dynamic scope, and then, provided that they exit normally, the scope will be unwound. The additional ops used to create and unwind the dynamic scope will normally be an C/C pair, but a C op may be used instead if the ops are simple enough to not need the full dynamic scope structure. =cut */ OP * Perl_op_scope(pTHX_ OP *o) { dVAR; if (o) { if (o->op_flags & OPf_PARENS || PERLDB_NOOPT || TAINTING_get) { o = op_prepend_elem(OP_LINESEQ, newOP(OP_ENTER, 0), o); o->op_type = OP_LEAVE; o->op_ppaddr = PL_ppaddr[OP_LEAVE]; } else if (o->op_type == OP_LINESEQ) { OP *kid; o->op_type = OP_SCOPE; o->op_ppaddr = PL_ppaddr[OP_SCOPE]; kid = ((LISTOP*)o)->op_first; if (kid->op_type == OP_NEXTSTATE || kid->op_type == OP_DBSTATE) { op_null(kid); /* The following deals with things like 'do {1 for 1}' */ kid = kid->op_sibling; if (kid && (kid->op_type == OP_NEXTSTATE || kid->op_type == OP_DBSTATE)) op_null(kid); } } else o = newLISTOP(OP_SCOPE, 0, o, NULL); } return o; } OP * Perl_op_unscope(pTHX_ OP *o) { if (o && o->op_type == OP_LINESEQ) { OP *kid = cLISTOPo->op_first; for(; kid; kid = kid->op_sibling) if (kid->op_type == OP_NEXTSTATE || kid->op_type == OP_DBSTATE) op_null(kid); } return o; } int Perl_block_start(pTHX_ int full) { const int retval = PL_savestack_ix; pad_block_start(full); SAVEHINTS(); PL_hints &= ~HINT_BLOCK_SCOPE; SAVECOMPILEWARNINGS(); PL_compiling.cop_warnings = DUP_WARNINGS(PL_compiling.cop_warnings); CALL_BLOCK_HOOKS(bhk_start, full); return retval; } OP* Perl_block_end(pTHX_ I32 floor, OP *seq) { const int needblockscope = PL_hints & HINT_BLOCK_SCOPE; OP* retval = scalarseq(seq); OP *o; CALL_BLOCK_HOOKS(bhk_pre_end, &retval); LEAVE_SCOPE(floor); if (needblockscope) PL_hints |= HINT_BLOCK_SCOPE; /* propagate out */ o = pad_leavemy(); if (o) { /* pad_leavemy has created a sequence of introcv ops for all my subs declared in the block. We have to replicate that list with clonecv ops, to deal with this situation: sub { my sub s1; my sub s2; sub s1 { state sub foo { \&s2 } } }->() Originally, I was going to have introcv clone the CV and turn off the stale flag. Since &s1 is declared before &s2, the introcv op for &s1 is executed (on sub entry) before the one for &s2. But the &foo sub inside &s1 (which is cloned when &s1 is cloned, since it is a state sub) closes over &s2 and expects to see it in its outer CV’s pad. If the introcv op clones &s1, then &s2 is still marked stale. Since &s1 is not active, and &foo closes over &s1’s implicit entry for &s2, we get a ‘Varia- ble will not stay shared’ warning. Because it is the same stub that will be used when the introcv op for &s2 is executed, clos- ing over it is safe. Hence, we have to turn off the stale flag on all lexical subs in the block before we clone any of them. Hence, having introcv clone the sub cannot work. So we create a list of ops like this: lineseq | +-- introcv | +-- introcv | +-- introcv | . . . | +-- clonecv | +-- clonecv | +-- clonecv | . . . */ OP *kid = o->op_flags & OPf_KIDS ? cLISTOPo->op_first : o; OP * const last = o->op_flags & OPf_KIDS ? cLISTOPo->op_last : o; for (;; kid = kid->op_sibling) { OP *newkid = newOP(OP_CLONECV, 0); newkid->op_targ = kid->op_targ; o = op_append_elem(OP_LINESEQ, o, newkid); if (kid == last) break; } retval = op_prepend_elem(OP_LINESEQ, o, retval); } CALL_BLOCK_HOOKS(bhk_post_end, &retval); return retval; } /* =head1 Compile-time scope hooks =for apidoc Aox||blockhook_register Register a set of hooks to be called when the Perl lexical scope changes at compile time. See L. =cut */ void Perl_blockhook_register(pTHX_ BHK *hk) { PERL_ARGS_ASSERT_BLOCKHOOK_REGISTER; Perl_av_create_and_push(aTHX_ &PL_blockhooks, newSViv(PTR2IV(hk))); } STATIC OP * S_newDEFSVOP(pTHX) { const PADOFFSET offset = pad_findmy_pvs("$_", 0); if (offset == NOT_IN_PAD || PAD_COMPNAME_FLAGS_isOUR(offset)) { return newSVREF(newGVOP(OP_GV, 0, PL_defgv)); } else { OP * const o = newOP(OP_PADSV, 0); o->op_targ = offset; return o; } } void Perl_newPROG(pTHX_ OP *o) { PERL_ARGS_ASSERT_NEWPROG; if (PL_in_eval) { PERL_CONTEXT *cx; I32 i; if (PL_eval_root) return; PL_eval_root = newUNOP(OP_LEAVEEVAL, ((PL_in_eval & EVAL_KEEPERR) ? OPf_SPECIAL : 0), o); cx = &cxstack[cxstack_ix]; assert(CxTYPE(cx) == CXt_EVAL); if ((cx->blk_gimme & G_WANT) == G_VOID) scalarvoid(PL_eval_root); else if ((cx->blk_gimme & G_WANT) == G_ARRAY) list(PL_eval_root); else scalar(PL_eval_root); PL_eval_start = op_linklist(PL_eval_root); PL_eval_root->op_private |= OPpREFCOUNTED; OpREFCNT_set(PL_eval_root, 1); PL_eval_root->op_next = 0; i = PL_savestack_ix; SAVEFREEOP(o); ENTER; CALL_PEEP(PL_eval_start); finalize_optree(PL_eval_root); S_prune_chain_head(&PL_eval_start); LEAVE; PL_savestack_ix = i; } else { if (o->op_type == OP_STUB) { /* This block is entered if nothing is compiled for the main program. This will be the case for an genuinely empty main program, or one which only has BEGIN blocks etc, so already run and freed. Historically (5.000) the guard above was !o. However, commit f8a08f7b8bd67b28 (Jun 2001), integrated to blead as c71fccf11fde0068, changed perly.y so that newPROG() is now called with the output of block_end(), which returns a new OP_STUB for the case of an empty optree. ByteLoader (and maybe other things) also take this path, because they set up PL_main_start and PL_main_root directly, without generating an optree. If the parsing the main program aborts (due to parse errors, or due to BEGIN or similar calling exit), then newPROG() isn't even called, and hence this code path and its cleanups are skipped. This shouldn't make a make a difference: * a non-zero return from perl_parse is a failure, and perl_destruct() should be called immediately. * however, if exit(0) is called during the parse, then perl_parse() returns 0, and perl_run() is called. As PL_main_start will be NULL, perl_run() will return promptly, and the exit code will remain 0. */ PL_comppad_name = 0; PL_compcv = 0; S_op_destroy(aTHX_ o); return; } PL_main_root = op_scope(sawparens(scalarvoid(o))); PL_curcop = &PL_compiling; PL_main_start = LINKLIST(PL_main_root); PL_main_root->op_private |= OPpREFCOUNTED; OpREFCNT_set(PL_main_root, 1); PL_main_root->op_next = 0; CALL_PEEP(PL_main_start); finalize_optree(PL_main_root); S_prune_chain_head(&PL_main_start); cv_forget_slab(PL_compcv); PL_compcv = 0; /* Register with debugger */ if (PERLDB_INTER) { CV * const cv = get_cvs("DB::postponed", 0); if (cv) { dSP; PUSHMARK(SP); XPUSHs(MUTABLE_SV(CopFILEGV(&PL_compiling))); PUTBACK; call_sv(MUTABLE_SV(cv), G_DISCARD); } } } } OP * Perl_localize(pTHX_ OP *o, I32 lex) { PERL_ARGS_ASSERT_LOCALIZE; if (o->op_flags & OPf_PARENS) /* [perl #17376]: this appears to be premature, and results in code such as C< our(%x); > executing in list mode rather than void mode */ #if 0 list(o); #else NOOP; #endif else { if ( PL_parser->bufptr > PL_parser->oldbufptr && PL_parser->bufptr[-1] == ',' && ckWARN(WARN_PARENTHESIS)) { char *s = PL_parser->bufptr; bool sigil = FALSE; /* some heuristics to detect a potential error */ while (*s && (strchr(", \t\n", *s))) s++; while (1) { if (*s && strchr("@$%*", *s) && *++s && (isWORDCHAR(*s) || UTF8_IS_CONTINUED(*s))) { s++; sigil = TRUE; while (*s && (isWORDCHAR(*s) || UTF8_IS_CONTINUED(*s))) s++; while (*s && (strchr(", \t\n", *s))) s++; } else break; } if (sigil && (*s == ';' || *s == '=')) { Perl_warner(aTHX_ packWARN(WARN_PARENTHESIS), "Parentheses missing around \"%s\" list", lex ? (PL_parser->in_my == KEY_our ? "our" : PL_parser->in_my == KEY_state ? "state" : "my") : "local"); } } } if (lex) o = my(o); else o = op_lvalue(o, OP_NULL); /* a bit kludgey */ PL_parser->in_my = FALSE; PL_parser->in_my_stash = NULL; return o; } OP * Perl_jmaybe(pTHX_ OP *o) { PERL_ARGS_ASSERT_JMAYBE; if (o->op_type == OP_LIST) { OP * const o2 = newSVREF(newGVOP(OP_GV, 0, gv_fetchpvs(";", GV_ADD|GV_NOTQUAL, SVt_PV))); o = convert(OP_JOIN, 0, op_prepend_elem(OP_LIST, o2, o)); } return o; } PERL_STATIC_INLINE OP * S_op_std_init(pTHX_ OP *o) { I32 type = o->op_type; PERL_ARGS_ASSERT_OP_STD_INIT; if (PL_opargs[type] & OA_RETSCALAR) scalar(o); if (PL_opargs[type] & OA_TARGET && !o->op_targ) o->op_targ = pad_alloc(type, SVs_PADTMP); return o; } PERL_STATIC_INLINE OP * S_op_integerize(pTHX_ OP *o) { I32 type = o->op_type; PERL_ARGS_ASSERT_OP_INTEGERIZE; /* integerize op. */ if ((PL_opargs[type] & OA_OTHERINT) && (PL_hints & HINT_INTEGER)) { dVAR; o->op_ppaddr = PL_ppaddr[++(o->op_type)]; } if (type == OP_NEGATE) /* XXX might want a ck_negate() for this */ cUNOPo->op_first->op_private &= ~OPpCONST_STRICT; return o; } static OP * S_fold_constants(pTHX_ OP *o) { dVAR; OP * VOL curop; OP *newop; VOL I32 type = o->op_type; SV * VOL sv = NULL; int ret = 0; I32 oldscope; OP *old_next; SV * const oldwarnhook = PL_warnhook; SV * const olddiehook = PL_diehook; COP not_compiling; dJMPENV; PERL_ARGS_ASSERT_FOLD_CONSTANTS; if (!(PL_opargs[type] & OA_FOLDCONST)) goto nope; switch (type) { case OP_UCFIRST: case OP_LCFIRST: case OP_UC: case OP_LC: case OP_FC: #ifdef USE_LOCALE_CTYPE if (IN_LC_COMPILETIME(LC_CTYPE)) goto nope; #endif break; case OP_SLT: case OP_SGT: case OP_SLE: case OP_SGE: case OP_SCMP: #ifdef USE_LOCALE_COLLATE if (IN_LC_COMPILETIME(LC_COLLATE)) goto nope; #endif break; case OP_SPRINTF: /* XXX what about the numeric ops? */ #ifdef USE_LOCALE_NUMERIC if (IN_LC_COMPILETIME(LC_NUMERIC)) goto nope; #endif break; case OP_PACK: if (!cLISTOPo->op_first->op_sibling || cLISTOPo->op_first->op_sibling->op_type != OP_CONST) goto nope; { SV * const sv = cSVOPx_sv(cLISTOPo->op_first->op_sibling); if (!SvPOK(sv) || SvGMAGICAL(sv)) goto nope; { const char *s = SvPVX_const(sv); while (s < SvEND(sv)) { if (*s == 'p' || *s == 'P') goto nope; s++; } } } break; case OP_REPEAT: if (o->op_private & OPpREPEAT_DOLIST) goto nope; break; case OP_SREFGEN: if (cUNOPx(cUNOPo->op_first)->op_first->op_type != OP_CONST || SvPADTMP(cSVOPx_sv(cUNOPx(cUNOPo->op_first)->op_first))) goto nope; } if (PL_parser && PL_parser->error_count) goto nope; /* Don't try to run w/ errors */ for (curop = LINKLIST(o); curop != o; curop = LINKLIST(curop)) { const OPCODE type = curop->op_type; if ((type != OP_CONST || (curop->op_private & OPpCONST_BARE)) && type != OP_LIST && type != OP_SCALAR && type != OP_NULL && type != OP_PUSHMARK) { goto nope; } } curop = LINKLIST(o); old_next = o->op_next; o->op_next = 0; PL_op = curop; oldscope = PL_scopestack_ix; create_eval_scope(G_FAKINGEVAL); /* Verify that we don't need to save it: */ assert(PL_curcop == &PL_compiling); StructCopy(&PL_compiling, ¬_compiling, COP); PL_curcop = ¬_compiling; /* The above ensures that we run with all the correct hints of the currently compiling COP, but that IN_PERL_RUNTIME is not true. */ assert(IN_PERL_RUNTIME); PL_warnhook = PERL_WARNHOOK_FATAL; PL_diehook = NULL; JMPENV_PUSH(ret); switch (ret) { case 0: CALLRUNOPS(aTHX); sv = *(PL_stack_sp--); if (o->op_targ && sv == PAD_SV(o->op_targ)) { /* grab pad temp? */ pad_swipe(o->op_targ, FALSE); } else if (SvTEMP(sv)) { /* grab mortal temp? */ SvREFCNT_inc_simple_void(sv); SvTEMP_off(sv); } else { assert(SvIMMORTAL(sv)); } break; case 3: /* Something tried to die. Abandon constant folding. */ /* Pretend the error never happened. */ CLEAR_ERRSV(); o->op_next = old_next; break; default: JMPENV_POP; /* Don't expect 1 (setjmp failed) or 2 (something called my_exit) */ PL_warnhook = oldwarnhook; PL_diehook = olddiehook; /* XXX note that this croak may fail as we've already blown away * the stack - eg any nested evals */ Perl_croak(aTHX_ "panic: fold_constants JMPENV_PUSH returned %d", ret); } JMPENV_POP; PL_warnhook = oldwarnhook; PL_diehook = olddiehook; PL_curcop = &PL_compiling; if (PL_scopestack_ix > oldscope) delete_eval_scope(); if (ret) goto nope; op_free(o); assert(sv); if (type == OP_STRINGIFY) SvPADTMP_off(sv); else if (!SvIMMORTAL(sv)) { SvPADTMP_on(sv); SvREADONLY_on(sv); } if (type == OP_RV2GV) newop = newGVOP(OP_GV, 0, MUTABLE_GV(sv)); else { newop = newSVOP(OP_CONST, 0, MUTABLE_SV(sv)); if (type != OP_STRINGIFY) newop->op_folded = 1; } return newop; nope: return o; } static OP * S_gen_constant_list(pTHX_ OP *o) { dVAR; OP *curop; const SSize_t oldtmps_floor = PL_tmps_floor; SV **svp; AV *av; list(o); if (PL_parser && PL_parser->error_count) return o; /* Don't attempt to run with errors */ curop = LINKLIST(o); o->op_next = 0; CALL_PEEP(curop); S_prune_chain_head(&curop); PL_op = curop; Perl_pp_pushmark(aTHX); CALLRUNOPS(aTHX); PL_op = curop; assert (!(curop->op_flags & OPf_SPECIAL)); assert(curop->op_type == OP_RANGE); Perl_pp_anonlist(aTHX); PL_tmps_floor = oldtmps_floor; o->op_type = OP_RV2AV; o->op_ppaddr = PL_ppaddr[OP_RV2AV]; o->op_flags &= ~OPf_REF; /* treat \(1..2) like an ordinary list */ o->op_flags |= OPf_PARENS; /* and flatten \(1..2,3) */ o->op_opt = 0; /* needs to be revisited in rpeep() */ curop = ((UNOP*)o)->op_first; av = (AV *)SvREFCNT_inc_NN(*PL_stack_sp--); ((UNOP*)o)->op_first = newSVOP(OP_CONST, 0, (SV *)av); if (AvFILLp(av) != -1) for (svp = AvARRAY(av) + AvFILLp(av); svp >= AvARRAY(av); --svp) { SvPADTMP_on(*svp); SvREADONLY_on(*svp); } op_free(curop); LINKLIST(o); return list(o); } OP * Perl_convert(pTHX_ I32 type, I32 flags, OP *o) { dVAR; if (type < 0) type = -type, flags |= OPf_SPECIAL; if (!o || o->op_type != OP_LIST) o = newLISTOP(OP_LIST, 0, o, NULL); else o->op_flags &= ~OPf_WANT; if (!(PL_opargs[type] & OA_MARK)) op_null(cLISTOPo->op_first); else { OP * const kid2 = cLISTOPo->op_first->op_sibling; if (kid2 && kid2->op_type == OP_COREARGS) { op_null(cLISTOPo->op_first); kid2->op_private |= OPpCOREARGS_PUSHMARK; } } o->op_type = (OPCODE)type; o->op_ppaddr = PL_ppaddr[type]; o->op_flags |= flags; o = CHECKOP(type, o); if (o->op_type != (unsigned)type) return o; return fold_constants(op_integerize(op_std_init(o))); } /* =head1 Optree Manipulation Functions */ /* List constructors */ /* =for apidoc Am|OP *|op_append_elem|I32 optype|OP *first|OP *last Append an item to the list of ops contained directly within a list-type op, returning the lengthened list. I is the list-type op, and I is the op to append to the list. I specifies the intended opcode for the list. If I is not already a list of the right type, it will be upgraded into one. If either I or I is null, the other is returned unchanged. =cut */ OP * Perl_op_append_elem(pTHX_ I32 type, OP *first, OP *last) { if (!first) return last; if (!last) return first; if (first->op_type != (unsigned)type || (type == OP_LIST && (first->op_flags & OPf_PARENS))) { return newLISTOP(type, 0, first, last); } if (first->op_flags & OPf_KIDS) ((LISTOP*)first)->op_last->op_sibling = last; else { first->op_flags |= OPf_KIDS; ((LISTOP*)first)->op_first = last; } ((LISTOP*)first)->op_last = last; return first; } /* =for apidoc Am|OP *|op_append_list|I32 optype|OP *first|OP *last Concatenate the lists of ops contained directly within two list-type ops, returning the combined list. I and I are the list-type ops to concatenate. I specifies the intended opcode for the list. If either I or I is not already a list of the right type, it will be upgraded into one. If either I or I is null, the other is returned unchanged. =cut */ OP * Perl_op_append_list(pTHX_ I32 type, OP *first, OP *last) { if (!first) return last; if (!last) return first; if (first->op_type != (unsigned)type) return op_prepend_elem(type, first, last); if (last->op_type != (unsigned)type) return op_append_elem(type, first, last); ((LISTOP*)first)->op_last->op_sibling = ((LISTOP*)last)->op_first; ((LISTOP*)first)->op_last = ((LISTOP*)last)->op_last; first->op_flags |= (last->op_flags & OPf_KIDS); S_op_destroy(aTHX_ last); return first; } /* =for apidoc Am|OP *|op_prepend_elem|I32 optype|OP *first|OP *last Prepend an item to the list of ops contained directly within a list-type op, returning the lengthened list. I is the op to prepend to the list, and I is the list-type op. I specifies the intended opcode for the list. If I is not already a list of the right type, it will be upgraded into one. If either I or I is null, the other is returned unchanged. =cut */ OP * Perl_op_prepend_elem(pTHX_ I32 type, OP *first, OP *last) { if (!first) return last; if (!last) return first; if (last->op_type == (unsigned)type) { if (type == OP_LIST) { /* already a PUSHMARK there */ first->op_sibling = ((LISTOP*)last)->op_first->op_sibling; ((LISTOP*)last)->op_first->op_sibling = first; if (!(first->op_flags & OPf_PARENS)) last->op_flags &= ~OPf_PARENS; } else { if (!(last->op_flags & OPf_KIDS)) { ((LISTOP*)last)->op_last = first; last->op_flags |= OPf_KIDS; } first->op_sibling = ((LISTOP*)last)->op_first; ((LISTOP*)last)->op_first = first; } last->op_flags |= OPf_KIDS; return last; } return newLISTOP(type, 0, first, last); } /* Constructors */ /* =head1 Optree construction =for apidoc Am|OP *|newNULLLIST Constructs, checks, and returns a new C op, which represents an empty list expression. =cut */ OP * Perl_newNULLLIST(pTHX) { return newOP(OP_STUB, 0); } static OP * S_force_list(pTHX_ OP *o) { if (!o || o->op_type != OP_LIST) o = newLISTOP(OP_LIST, 0, o, NULL); op_null(o); return o; } /* =for apidoc Am|OP *|newLISTOP|I32 type|I32 flags|OP *first|OP *last Constructs, checks, and returns an op of any list type. I is the opcode. I gives the eight bits of C, except that C will be set automatically if required. I and I supply up to two ops to be direct children of the list op; they are consumed by this function and become part of the constructed op tree. =cut */ OP * Perl_newLISTOP(pTHX_ I32 type, I32 flags, OP *first, OP *last) { dVAR; LISTOP *listop; assert((PL_opargs[type] & OA_CLASS_MASK) == OA_LISTOP); NewOp(1101, listop, 1, LISTOP); listop->op_type = (OPCODE)type; listop->op_ppaddr = PL_ppaddr[type]; if (first || last) flags |= OPf_KIDS; listop->op_flags = (U8)flags; if (!last && first) last = first; else if (!first && last) first = last; else if (first) first->op_sibling = last; listop->op_first = first; listop->op_last = last; if (type == OP_LIST) { OP* const pushop = newOP(OP_PUSHMARK, 0); pushop->op_sibling = first; listop->op_first = pushop; listop->op_flags |= OPf_KIDS; if (!last) listop->op_last = pushop; } return CHECKOP(type, listop); } /* =for apidoc Am|OP *|newOP|I32 type|I32 flags Constructs, checks, and returns an op of any base type (any type that has no extra fields). I is the opcode. I gives the eight bits of C, and, shifted up eight bits, the eight bits of C. =cut */ OP * Perl_newOP(pTHX_ I32 type, I32 flags) { dVAR; OP *o; if (type == -OP_ENTEREVAL) { type = OP_ENTEREVAL; flags |= OPpEVAL_BYTES<<8; } assert((PL_opargs[type] & OA_CLASS_MASK) == OA_BASEOP || (PL_opargs[type] & OA_CLASS_MASK) == OA_BASEOP_OR_UNOP || (PL_opargs[type] & OA_CLASS_MASK) == OA_FILESTATOP || (PL_opargs[type] & OA_CLASS_MASK) == OA_LOOPEXOP); NewOp(1101, o, 1, OP); o->op_type = (OPCODE)type; o->op_ppaddr = PL_ppaddr[type]; o->op_flags = (U8)flags; o->op_next = o; o->op_private = (U8)(0 | (flags >> 8)); if (PL_opargs[type] & OA_RETSCALAR) scalar(o); if (PL_opargs[type] & OA_TARGET) o->op_targ = pad_alloc(type, SVs_PADTMP); return CHECKOP(type, o); } /* =for apidoc Am|OP *|newUNOP|I32 type|I32 flags|OP *first Constructs, checks, and returns an op of any unary type. I is the opcode. I gives the eight bits of C, except that C will be set automatically if required, and, shifted up eight bits, the eight bits of C, except that the bit with value 1 is automatically set. I supplies an optional op to be the direct child of the unary op; it is consumed by this function and become part of the constructed op tree. =cut */ OP * Perl_newUNOP(pTHX_ I32 type, I32 flags, OP *first) { dVAR; UNOP *unop; if (type == -OP_ENTEREVAL) { type = OP_ENTEREVAL; flags |= OPpEVAL_BYTES<<8; } assert((PL_opargs[type] & OA_CLASS_MASK) == OA_UNOP || (PL_opargs[type] & OA_CLASS_MASK) == OA_BASEOP_OR_UNOP || (PL_opargs[type] & OA_CLASS_MASK) == OA_FILESTATOP || (PL_opargs[type] & OA_CLASS_MASK) == OA_LOOPEXOP || type == OP_SASSIGN || type == OP_ENTERTRY || type == OP_NULL ); if (!first) first = newOP(OP_STUB, 0); if (PL_opargs[type] & OA_MARK) first = force_list(first); NewOp(1101, unop, 1, UNOP); unop->op_type = (OPCODE)type; unop->op_ppaddr = PL_ppaddr[type]; unop->op_first = first; unop->op_flags = (U8)(flags | OPf_KIDS); unop->op_private = (U8)(1 | (flags >> 8)); unop = (UNOP*) CHECKOP(type, unop); if (unop->op_next) return (OP*)unop; return fold_constants(op_integerize(op_std_init((OP *) unop))); } /* =for apidoc Am|OP *|newBINOP|I32 type|I32 flags|OP *first|OP *last Constructs, checks, and returns an op of any binary type. I is the opcode. I gives the eight bits of C, except that C will be set automatically, and, shifted up eight bits, the eight bits of C, except that the bit with value 1 or 2 is automatically set as required. I and I supply up to two ops to be the direct children of the binary op; they are consumed by this function and become part of the constructed op tree. =cut */ OP * Perl_newBINOP(pTHX_ I32 type, I32 flags, OP *first, OP *last) { dVAR; BINOP *binop; ASSUME((PL_opargs[type] & OA_CLASS_MASK) == OA_BINOP || type == OP_SASSIGN || type == OP_NULL ); NewOp(1101, binop, 1, BINOP); if (!first) first = newOP(OP_NULL, 0); binop->op_type = (OPCODE)type; binop->op_ppaddr = PL_ppaddr[type]; binop->op_first = first; binop->op_flags = (U8)(flags | OPf_KIDS); if (!last) { last = first; binop->op_private = (U8)(1 | (flags >> 8)); } else { binop->op_private = (U8)(2 | (flags >> 8)); first->op_sibling = last; } binop = (BINOP*)CHECKOP(type, binop); if (binop->op_next || binop->op_type != (OPCODE)type) return (OP*)binop; binop->op_last = binop->op_first->op_sibling; return fold_constants(op_integerize(op_std_init((OP *)binop))); } static int uvcompare(const void *a, const void *b) __attribute__nonnull__(1) __attribute__nonnull__(2) __attribute__pure__; static int uvcompare(const void *a, const void *b) { if (*((const UV *)a) < (*(const UV *)b)) return -1; if (*((const UV *)a) > (*(const UV *)b)) return 1; if (*((const UV *)a+1) < (*(const UV *)b+1)) return -1; if (*((const UV *)a+1) > (*(const UV *)b+1)) return 1; return 0; } static OP * S_pmtrans(pTHX_ OP *o, OP *expr, OP *repl) { SV * const tstr = ((SVOP*)expr)->op_sv; SV * const rstr = ((SVOP*)repl)->op_sv; STRLEN tlen; STRLEN rlen; const U8 *t = (U8*)SvPV_const(tstr, tlen); const U8 *r = (U8*)SvPV_const(rstr, rlen); I32 i; I32 j; I32 grows = 0; short *tbl; const I32 complement = o->op_private & OPpTRANS_COMPLEMENT; const I32 squash = o->op_private & OPpTRANS_SQUASH; I32 del = o->op_private & OPpTRANS_DELETE; SV* swash; PERL_ARGS_ASSERT_PMTRANS; PL_hints |= HINT_BLOCK_SCOPE; if (SvUTF8(tstr)) o->op_private |= OPpTRANS_FROM_UTF; if (SvUTF8(rstr)) o->op_private |= OPpTRANS_TO_UTF; if (o->op_private & (OPpTRANS_FROM_UTF|OPpTRANS_TO_UTF)) { SV* const listsv = newSVpvs("# comment\n"); SV* transv = NULL; const U8* tend = t + tlen; const U8* rend = r + rlen; STRLEN ulen; UV tfirst = 1; UV tlast = 0; IV tdiff; UV rfirst = 1; UV rlast = 0; IV rdiff; IV diff; I32 none = 0; U32 max = 0; I32 bits; I32 havefinal = 0; U32 final = 0; const I32 from_utf = o->op_private & OPpTRANS_FROM_UTF; const I32 to_utf = o->op_private & OPpTRANS_TO_UTF; U8* tsave = NULL; U8* rsave = NULL; const U32 flags = UTF8_ALLOW_DEFAULT; if (!from_utf) { STRLEN len = tlen; t = tsave = bytes_to_utf8(t, &len); tend = t + len; } if (!to_utf && rlen) { STRLEN len = rlen; r = rsave = bytes_to_utf8(r, &len); rend = r + len; } /* There is a snag with this code on EBCDIC: scan_const() in toke.c has * encoded chars in native encoding which makes ranges in the EBCDIC 0..255 * odd. */ if (complement) { U8 tmpbuf[UTF8_MAXBYTES+1]; UV *cp; UV nextmin = 0; Newx(cp, 2*tlen, UV); i = 0; transv = newSVpvs(""); while (t < tend) { cp[2*i] = utf8n_to_uvchr(t, tend-t, &ulen, flags); t += ulen; if (t < tend && *t == ILLEGAL_UTF8_BYTE) { t++; cp[2*i+1] = utf8n_to_uvchr(t, tend-t, &ulen, flags); t += ulen; } else { cp[2*i+1] = cp[2*i]; } i++; } qsort(cp, i, 2*sizeof(UV), uvcompare); for (j = 0; j < i; j++) { UV val = cp[2*j]; diff = val - nextmin; if (diff > 0) { t = uvchr_to_utf8(tmpbuf,nextmin); sv_catpvn(transv, (char*)tmpbuf, t - tmpbuf); if (diff > 1) { U8 range_mark = ILLEGAL_UTF8_BYTE; t = uvchr_to_utf8(tmpbuf, val - 1); sv_catpvn(transv, (char *)&range_mark, 1); sv_catpvn(transv, (char*)tmpbuf, t - tmpbuf); } } val = cp[2*j+1]; if (val >= nextmin) nextmin = val + 1; } t = uvchr_to_utf8(tmpbuf,nextmin); sv_catpvn(transv, (char*)tmpbuf, t - tmpbuf); { U8 range_mark = ILLEGAL_UTF8_BYTE; sv_catpvn(transv, (char *)&range_mark, 1); } t = uvchr_to_utf8(tmpbuf, 0x7fffffff); sv_catpvn(transv, (char*)tmpbuf, t - tmpbuf); t = (const U8*)SvPVX_const(transv); tlen = SvCUR(transv); tend = t + tlen; Safefree(cp); } else if (!rlen && !del) { r = t; rlen = tlen; rend = tend; } if (!squash) { if ((!rlen && !del) || t == r || (tlen == rlen && memEQ((char *)t, (char *)r, tlen))) { o->op_private |= OPpTRANS_IDENTICAL; } } while (t < tend || tfirst <= tlast) { /* see if we need more "t" chars */ if (tfirst > tlast) { tfirst = (I32)utf8n_to_uvchr(t, tend - t, &ulen, flags); t += ulen; if (t < tend && *t == ILLEGAL_UTF8_BYTE) { /* illegal utf8 val indicates range */ t++; tlast = (I32)utf8n_to_uvchr(t, tend - t, &ulen, flags); t += ulen; } else tlast = tfirst; } /* now see if we need more "r" chars */ if (rfirst > rlast) { if (r < rend) { rfirst = (I32)utf8n_to_uvchr(r, rend - r, &ulen, flags); r += ulen; if (r < rend && *r == ILLEGAL_UTF8_BYTE) { /* illegal utf8 val indicates range */ r++; rlast = (I32)utf8n_to_uvchr(r, rend - r, &ulen, flags); r += ulen; } else rlast = rfirst; } else { if (!havefinal++) final = rlast; rfirst = rlast = 0xffffffff; } } /* now see which range will peter our first, if either. */ tdiff = tlast - tfirst; rdiff = rlast - rfirst; if (tdiff <= rdiff) diff = tdiff; else diff = rdiff; if (rfirst == 0xffffffff) { diff = tdiff; /* oops, pretend rdiff is infinite */ if (diff > 0) Perl_sv_catpvf(aTHX_ listsv, "%04lx\t%04lx\tXXXX\n", (long)tfirst, (long)tlast); else Perl_sv_catpvf(aTHX_ listsv, "%04lx\t\tXXXX\n", (long)tfirst); } else { if (diff > 0) Perl_sv_catpvf(aTHX_ listsv, "%04lx\t%04lx\t%04lx\n", (long)tfirst, (long)(tfirst + diff), (long)rfirst); else Perl_sv_catpvf(aTHX_ listsv, "%04lx\t\t%04lx\n", (long)tfirst, (long)rfirst); if (rfirst + diff > max) max = rfirst + diff; if (!grows) grows = (tfirst < rfirst && UNISKIP(tfirst) < UNISKIP(rfirst + diff)); rfirst += diff + 1; } tfirst += diff + 1; } none = ++max; if (del) del = ++max; if (max > 0xffff) bits = 32; else if (max > 0xff) bits = 16; else bits = 8; swash = MUTABLE_SV(swash_init("utf8", "", listsv, bits, none)); #ifdef USE_ITHREADS cPADOPo->op_padix = pad_alloc(OP_TRANS, SVf_READONLY); SvREFCNT_dec(PAD_SVl(cPADOPo->op_padix)); PAD_SETSV(cPADOPo->op_padix, swash); SvPADTMP_on(swash); SvREADONLY_on(swash); #else cSVOPo->op_sv = swash; #endif SvREFCNT_dec(listsv); SvREFCNT_dec(transv); if (!del && havefinal && rlen) (void)hv_store(MUTABLE_HV(SvRV(swash)), "FINAL", 5, newSVuv((UV)final), 0); if (grows) o->op_private |= OPpTRANS_GROWS; Safefree(tsave); Safefree(rsave); op_free(expr); op_free(repl); return o; } tbl = (short*)PerlMemShared_calloc( (o->op_private & OPpTRANS_COMPLEMENT) && !(o->op_private & OPpTRANS_DELETE) ? 258 : 256, sizeof(short)); cPVOPo->op_pv = (char*)tbl; if (complement) { for (i = 0; i < (I32)tlen; i++) tbl[t[i]] = -1; for (i = 0, j = 0; i < 256; i++) { if (!tbl[i]) { if (j >= (I32)rlen) { if (del) tbl[i] = -2; else if (rlen) tbl[i] = r[j-1]; else tbl[i] = (short)i; } else { if (i < 128 && r[j] >= 128) grows = 1; tbl[i] = r[j++]; } } } if (!del) { if (!rlen) { j = rlen; if (!squash) o->op_private |= OPpTRANS_IDENTICAL; } else if (j >= (I32)rlen) j = rlen - 1; else { tbl = (short *) PerlMemShared_realloc(tbl, (0x101+rlen-j) * sizeof(short)); cPVOPo->op_pv = (char*)tbl; } tbl[0x100] = (short)(rlen - j); for (i=0; i < (I32)rlen - j; i++) tbl[0x101+i] = r[j+i]; } } else { if (!rlen && !del) { r = t; rlen = tlen; if (!squash) o->op_private |= OPpTRANS_IDENTICAL; } else if (!squash && rlen == tlen && memEQ((char*)t, (char*)r, tlen)) { o->op_private |= OPpTRANS_IDENTICAL; } for (i = 0; i < 256; i++) tbl[i] = -1; for (i = 0, j = 0; i < (I32)tlen; i++,j++) { if (j >= (I32)rlen) { if (del) { if (tbl[t[i]] == -1) tbl[t[i]] = -2; continue; } --j; } if (tbl[t[i]] == -1) { if (t[i] < 128 && r[j] >= 128) grows = 1; tbl[t[i]] = r[j]; } } } if(del && rlen == tlen) { Perl_ck_warner(aTHX_ packWARN(WARN_MISC), "Useless use of /d modifier in transliteration operator"); } else if(rlen > tlen && !complement) { Perl_ck_warner(aTHX_ packWARN(WARN_MISC), "Replacement list is longer than search list"); } if (grows) o->op_private |= OPpTRANS_GROWS; op_free(expr); op_free(repl); return o; } /* =for apidoc Am|OP *|newPMOP|I32 type|I32 flags Constructs, checks, and returns an op of any pattern matching type. I is the opcode. I gives the eight bits of C and, shifted up eight bits, the eight bits of C. =cut */ OP * Perl_newPMOP(pTHX_ I32 type, I32 flags) { dVAR; PMOP *pmop; assert((PL_opargs[type] & OA_CLASS_MASK) == OA_PMOP); NewOp(1101, pmop, 1, PMOP); pmop->op_type = (OPCODE)type; pmop->op_ppaddr = PL_ppaddr[type]; pmop->op_flags = (U8)flags; pmop->op_private = (U8)(0 | (flags >> 8)); if (PL_hints & HINT_RE_TAINT) pmop->op_pmflags |= PMf_RETAINT; #ifdef USE_LOCALE_CTYPE if (IN_LC_COMPILETIME(LC_CTYPE)) { set_regex_charset(&(pmop->op_pmflags), REGEX_LOCALE_CHARSET); } else #endif if (IN_UNI_8_BIT) { set_regex_charset(&(pmop->op_pmflags), REGEX_UNICODE_CHARSET); } if (PL_hints & HINT_RE_FLAGS) { SV *reflags = Perl_refcounted_he_fetch_pvn(aTHX_ PL_compiling.cop_hints_hash, STR_WITH_LEN("reflags"), 0, 0 ); if (reflags && SvOK(reflags)) pmop->op_pmflags |= SvIV(reflags); reflags = Perl_refcounted_he_fetch_pvn(aTHX_ PL_compiling.cop_hints_hash, STR_WITH_LEN("reflags_charset"), 0, 0 ); if (reflags && SvOK(reflags)) { set_regex_charset(&(pmop->op_pmflags), (regex_charset)SvIV(reflags)); } } #ifdef USE_ITHREADS assert(SvPOK(PL_regex_pad[0])); if (SvCUR(PL_regex_pad[0])) { /* Pop off the "packed" IV from the end. */ SV *const repointer_list = PL_regex_pad[0]; const char *p = SvEND(repointer_list) - sizeof(IV); const IV offset = *((IV*)p); assert(SvCUR(repointer_list) % sizeof(IV) == 0); SvEND_set(repointer_list, p); pmop->op_pmoffset = offset; /* This slot should be free, so assert this: */ assert(PL_regex_pad[offset] == &PL_sv_undef); } else { SV * const repointer = &PL_sv_undef; av_push(PL_regex_padav, repointer); pmop->op_pmoffset = av_tindex(PL_regex_padav); PL_regex_pad = AvARRAY(PL_regex_padav); } #endif return CHECKOP(type, pmop); } /* Given some sort of match op o, and an expression expr containing a * pattern, either compile expr into a regex and attach it to o (if it's * constant), or convert expr into a runtime regcomp op sequence (if it's * not) * * isreg indicates that the pattern is part of a regex construct, eg * $x =~ /pattern/ or split /pattern/, as opposed to $x =~ $pattern or * split "pattern", which aren't. In the former case, expr will be a list * if the pattern contains more than one term (eg /a$b/) or if it contains * a replacement, ie s/// or tr///. * * When the pattern has been compiled within a new anon CV (for * qr/(?{...})/ ), then floor indicates the savestack level just before * the new sub was created */ OP * Perl_pmruntime(pTHX_ OP *o, OP *expr, bool isreg, I32 floor) { dVAR; PMOP *pm; LOGOP *rcop; I32 repl_has_vars = 0; OP* repl = NULL; bool is_trans = (o->op_type == OP_TRANS || o->op_type == OP_TRANSR); bool is_compiletime; bool has_code; PERL_ARGS_ASSERT_PMRUNTIME; /* for s/// and tr///, last element in list is the replacement; pop it */ if (is_trans || o->op_type == OP_SUBST) { OP* kid; repl = cLISTOPx(expr)->op_last; kid = cLISTOPx(expr)->op_first; while (kid->op_sibling != repl) kid = kid->op_sibling; kid->op_sibling = NULL; cLISTOPx(expr)->op_last = kid; } /* for TRANS, convert LIST/PUSH/CONST into CONST, and pass to pmtrans() */ if (is_trans) { OP* const oe = expr; assert(expr->op_type == OP_LIST); assert(cLISTOPx(expr)->op_first->op_type == OP_PUSHMARK); assert(cLISTOPx(expr)->op_first->op_sibling == cLISTOPx(expr)->op_last); expr = cLISTOPx(oe)->op_last; cLISTOPx(oe)->op_first->op_sibling = NULL; cLISTOPx(oe)->op_last = NULL; op_free(oe); return pmtrans(o, expr, repl); } /* find whether we have any runtime or code elements; * at the same time, temporarily set the op_next of each DO block; * then when we LINKLIST, this will cause the DO blocks to be excluded * from the op_next chain (and from having LINKLIST recursively * applied to them). We fix up the DOs specially later */ is_compiletime = 1; has_code = 0; if (expr->op_type == OP_LIST) { OP *o; for (o = cLISTOPx(expr)->op_first; o; o = o->op_sibling) { if (o->op_type == OP_NULL && (o->op_flags & OPf_SPECIAL)) { has_code = 1; assert(!o->op_next && o->op_sibling); o->op_next = o->op_sibling; } else if (o->op_type != OP_CONST && o->op_type != OP_PUSHMARK) is_compiletime = 0; } } else if (expr->op_type != OP_CONST) is_compiletime = 0; LINKLIST(expr); /* fix up DO blocks; treat each one as a separate little sub; * also, mark any arrays as LIST/REF */ if (expr->op_type == OP_LIST) { OP *o; for (o = cLISTOPx(expr)->op_first; o; o = o->op_sibling) { if (o->op_type == OP_PADAV || o->op_type == OP_RV2AV) { assert( !(o->op_flags & OPf_WANT)); /* push the array rather than its contents. The regex * engine will retrieve and join the elements later */ o->op_flags |= (OPf_WANT_LIST | OPf_REF); continue; } if (!(o->op_type == OP_NULL && (o->op_flags & OPf_SPECIAL))) continue; o->op_next = NULL; /* undo temporary hack from above */ scalar(o); LINKLIST(o); if (cLISTOPo->op_first->op_type == OP_LEAVE) { LISTOP *leaveop = cLISTOPx(cLISTOPo->op_first); /* skip ENTER */ assert(leaveop->op_first->op_type == OP_ENTER); assert(leaveop->op_first->op_sibling); o->op_next = leaveop->op_first->op_sibling; /* skip leave */ assert(leaveop->op_flags & OPf_KIDS); assert(leaveop->op_last->op_next == (OP*)leaveop); leaveop->op_next = NULL; /* stop on last op */ op_null((OP*)leaveop); } else { /* skip SCOPE */ OP *scope = cLISTOPo->op_first; assert(scope->op_type == OP_SCOPE); assert(scope->op_flags & OPf_KIDS); scope->op_next = NULL; /* stop on last op */ op_null(scope); } /* have to peep the DOs individually as we've removed it from * the op_next chain */ CALL_PEEP(o); S_prune_chain_head(&(o->op_next)); if (is_compiletime) /* runtime finalizes as part of finalizing whole tree */ finalize_optree(o); } } else if (expr->op_type == OP_PADAV || expr->op_type == OP_RV2AV) { assert( !(expr->op_flags & OPf_WANT)); /* push the array rather than its contents. The regex * engine will retrieve and join the elements later */ expr->op_flags |= (OPf_WANT_LIST | OPf_REF); } PL_hints |= HINT_BLOCK_SCOPE; pm = (PMOP*)o; assert(floor==0 || (pm->op_pmflags & PMf_HAS_CV)); if (is_compiletime) { U32 rx_flags = pm->op_pmflags & RXf_PMf_COMPILETIME; regexp_engine const *eng = current_re_engine(); if (o->op_flags & OPf_SPECIAL) rx_flags |= RXf_SPLIT; if (!has_code || !eng->op_comp) { /* compile-time simple constant pattern */ if ((pm->op_pmflags & PMf_HAS_CV) && !has_code) { /* whoops! we guessed that a qr// had a code block, but we * were wrong (e.g. /[(?{}]/ ). Throw away the PL_compcv * that isn't required now. Note that we have to be pretty * confident that nothing used that CV's pad while the * regex was parsed */ assert(AvFILLp(PL_comppad) == 0); /* just @_ */ /* But we know that one op is using this CV's slab. */ cv_forget_slab(PL_compcv); LEAVE_SCOPE(floor); pm->op_pmflags &= ~PMf_HAS_CV; } PM_SETRE(pm, eng->op_comp ? eng->op_comp(aTHX_ NULL, 0, expr, eng, NULL, NULL, rx_flags, pm->op_pmflags) : Perl_re_op_compile(aTHX_ NULL, 0, expr, eng, NULL, NULL, rx_flags, pm->op_pmflags) ); op_free(expr); } else { /* compile-time pattern that includes literal code blocks */ REGEXP* re = eng->op_comp(aTHX_ NULL, 0, expr, eng, NULL, NULL, rx_flags, (pm->op_pmflags | ((PL_hints & HINT_RE_EVAL) ? PMf_USE_RE_EVAL : 0)) ); PM_SETRE(pm, re); if (pm->op_pmflags & PMf_HAS_CV) { CV *cv; /* this QR op (and the anon sub we embed it in) is never * actually executed. It's just a placeholder where we can * squirrel away expr in op_code_list without the peephole * optimiser etc processing it for a second time */ OP *qr = newPMOP(OP_QR, 0); ((PMOP*)qr)->op_code_list = expr; /* handle the implicit sub{} wrapped round the qr/(?{..})/ */ SvREFCNT_inc_simple_void(PL_compcv); cv = newATTRSUB(floor, 0, NULL, NULL, qr); ReANY(re)->qr_anoncv = cv; /* attach the anon CV to the pad so that * pad_fixup_inner_anons() can find it */ (void)pad_add_anon(cv, o->op_type); SvREFCNT_inc_simple_void(cv); } else { pm->op_code_list = expr; } } } else { /* runtime pattern: build chain of regcomp etc ops */ bool reglist; PADOFFSET cv_targ = 0; reglist = isreg && expr->op_type == OP_LIST; if (reglist) op_null(expr); if (has_code) { pm->op_code_list = expr; /* don't free op_code_list; its ops are embedded elsewhere too */ pm->op_pmflags |= PMf_CODELIST_PRIVATE; } if (o->op_flags & OPf_SPECIAL) pm->op_pmflags |= PMf_SPLIT; /* the OP_REGCMAYBE is a placeholder in the non-threaded case * to allow its op_next to be pointed past the regcomp and * preceding stacking ops; * OP_REGCRESET is there to reset taint before executing the * stacking ops */ if (pm->op_pmflags & PMf_KEEP || TAINTING_get) expr = newUNOP((TAINTING_get ? OP_REGCRESET : OP_REGCMAYBE),0,expr); if (pm->op_pmflags & PMf_HAS_CV) { /* we have a runtime qr with literal code. This means * that the qr// has been wrapped in a new CV, which * means that runtime consts, vars etc will have been compiled * against a new pad. So... we need to execute those ops * within the environment of the new CV. So wrap them in a call * to a new anon sub. i.e. for * * qr/a$b(?{...})/, * * we build an anon sub that looks like * * sub { "a", $b, '(?{...})' } * * and call it, passing the returned list to regcomp. * Or to put it another way, the list of ops that get executed * are: * * normal PMf_HAS_CV * ------ ------------------- * pushmark (for regcomp) * pushmark (for entersub) * pushmark (for refgen) * anoncode * refgen * entersub * regcreset regcreset * pushmark pushmark * const("a") const("a") * gvsv(b) gvsv(b) * const("(?{...})") const("(?{...})") * leavesub * regcomp regcomp */ SvREFCNT_inc_simple_void(PL_compcv); /* these lines are just an unrolled newANONATTRSUB */ expr = newSVOP(OP_ANONCODE, 0, MUTABLE_SV(newATTRSUB(floor, 0, NULL, NULL, expr))); cv_targ = expr->op_targ; expr = newUNOP(OP_REFGEN, 0, expr); expr = list(force_list(newUNOP(OP_ENTERSUB, 0, scalar(expr)))); } NewOp(1101, rcop, 1, LOGOP); rcop->op_type = OP_REGCOMP; rcop->op_ppaddr = PL_ppaddr[OP_REGCOMP]; rcop->op_first = scalar(expr); rcop->op_flags |= OPf_KIDS | ((PL_hints & HINT_RE_EVAL) ? OPf_SPECIAL : 0) | (reglist ? OPf_STACKED : 0); rcop->op_private = 0; rcop->op_other = o; rcop->op_targ = cv_targ; /* /$x/ may cause an eval, since $x might be qr/(?{..})/ */ if (PL_hints & HINT_RE_EVAL) PL_cv_has_eval = 1; /* establish postfix order */ if (expr->op_type == OP_REGCRESET || expr->op_type == OP_REGCMAYBE) { LINKLIST(expr); rcop->op_next = expr; ((UNOP*)expr)->op_first->op_next = (OP*)rcop; } else { rcop->op_next = LINKLIST(expr); expr->op_next = (OP*)rcop; } op_prepend_elem(o->op_type, scalar((OP*)rcop), o); } if (repl) { OP *curop = repl; bool konst; /* If we are looking at s//.../e with a single statement, get past the implicit do{}. */ if (curop->op_type == OP_NULL && curop->op_flags & OPf_KIDS && cUNOPx(curop)->op_first->op_type == OP_SCOPE && cUNOPx(curop)->op_first->op_flags & OPf_KIDS) { OP *kid = cUNOPx(cUNOPx(curop)->op_first)->op_first; if (kid->op_type == OP_NULL && kid->op_sibling && !kid->op_sibling->op_sibling) curop = kid->op_sibling; } if (curop->op_type == OP_CONST) konst = TRUE; else if (( (curop->op_type == OP_RV2SV || curop->op_type == OP_RV2AV || curop->op_type == OP_RV2HV || curop->op_type == OP_RV2GV) && cUNOPx(curop)->op_first && cUNOPx(curop)->op_first->op_type == OP_GV ) || curop->op_type == OP_PADSV || curop->op_type == OP_PADAV || curop->op_type == OP_PADHV || curop->op_type == OP_PADANY) { repl_has_vars = 1; konst = TRUE; } else konst = FALSE; if (konst && !(repl_has_vars && (!PM_GETRE(pm) || !RX_PRELEN(PM_GETRE(pm)) || RX_EXTFLAGS(PM_GETRE(pm)) & RXf_EVAL_SEEN))) { pm->op_pmflags |= PMf_CONST; /* const for long enough */ op_prepend_elem(o->op_type, scalar(repl), o); } else { NewOp(1101, rcop, 1, LOGOP); rcop->op_type = OP_SUBSTCONT; rcop->op_ppaddr = PL_ppaddr[OP_SUBSTCONT]; rcop->op_first = scalar(repl); rcop->op_flags |= OPf_KIDS; rcop->op_private = 1; rcop->op_other = o; /* establish postfix order */ rcop->op_next = LINKLIST(repl); repl->op_next = (OP*)rcop; pm->op_pmreplrootu.op_pmreplroot = scalar((OP*)rcop); assert(!(pm->op_pmflags & PMf_ONCE)); pm->op_pmstashstartu.op_pmreplstart = LINKLIST(rcop); rcop->op_next = 0; } } return (OP*)pm; } /* =for apidoc Am|OP *|newSVOP|I32 type|I32 flags|SV *sv Constructs, checks, and returns an op of any type that involves an embedded SV. I is the opcode. I gives the eight bits of C. I gives the SV to embed in the op; this function takes ownership of one reference to it. =cut */ OP * Perl_newSVOP(pTHX_ I32 type, I32 flags, SV *sv) { dVAR; SVOP *svop; PERL_ARGS_ASSERT_NEWSVOP; assert((PL_opargs[type] & OA_CLASS_MASK) == OA_SVOP || (PL_opargs[type] & OA_CLASS_MASK) == OA_PVOP_OR_SVOP || (PL_opargs[type] & OA_CLASS_MASK) == OA_FILESTATOP); NewOp(1101, svop, 1, SVOP); svop->op_type = (OPCODE)type; svop->op_ppaddr = PL_ppaddr[type]; svop->op_sv = sv; svop->op_next = (OP*)svop; svop->op_flags = (U8)flags; svop->op_private = (U8)(0 | (flags >> 8)); if (PL_opargs[type] & OA_RETSCALAR) scalar((OP*)svop); if (PL_opargs[type] & OA_TARGET) svop->op_targ = pad_alloc(type, SVs_PADTMP); return CHECKOP(type, svop); } #ifdef USE_ITHREADS /* =for apidoc Am|OP *|newPADOP|I32 type|I32 flags|SV *sv Constructs, checks, and returns an op of any type that involves a reference to a pad element. I is the opcode. I gives the eight bits of C. A pad slot is automatically allocated, and is populated with I; this function takes ownership of one reference to it. This function only exists if Perl has been compiled to use ithreads. =cut */ OP * Perl_newPADOP(pTHX_ I32 type, I32 flags, SV *sv) { dVAR; PADOP *padop; PERL_ARGS_ASSERT_NEWPADOP; assert((PL_opargs[type] & OA_CLASS_MASK) == OA_SVOP || (PL_opargs[type] & OA_CLASS_MASK) == OA_PVOP_OR_SVOP || (PL_opargs[type] & OA_CLASS_MASK) == OA_FILESTATOP); NewOp(1101, padop, 1, PADOP); padop->op_type = (OPCODE)type; padop->op_ppaddr = PL_ppaddr[type]; padop->op_padix = pad_alloc(type, SVs_PADTMP); SvREFCNT_dec(PAD_SVl(padop->op_padix)); PAD_SETSV(padop->op_padix, sv); assert(sv); padop->op_next = (OP*)padop; padop->op_flags = (U8)flags; if (PL_opargs[type] & OA_RETSCALAR) scalar((OP*)padop); if (PL_opargs[type] & OA_TARGET) padop->op_targ = pad_alloc(type, SVs_PADTMP); return CHECKOP(type, padop); } #endif /* USE_ITHREADS */ /* =for apidoc Am|OP *|newGVOP|I32 type|I32 flags|GV *gv Constructs, checks, and returns an op of any type that involves an embedded reference to a GV. I is the opcode. I gives the eight bits of C. I identifies the GV that the op should reference; calling this function does not transfer ownership of any reference to it. =cut */ OP * Perl_newGVOP(pTHX_ I32 type, I32 flags, GV *gv) { PERL_ARGS_ASSERT_NEWGVOP; #ifdef USE_ITHREADS GvIN_PAD_on(gv); return newPADOP(type, flags, SvREFCNT_inc_simple_NN(gv)); #else return newSVOP(type, flags, SvREFCNT_inc_simple_NN(gv)); #endif } /* =for apidoc Am|OP *|newPVOP|I32 type|I32 flags|char *pv Constructs, checks, and returns an op of any type that involves an embedded C-level pointer (PV). I is the opcode. I gives the eight bits of C. I supplies the C-level pointer, which must have been allocated using C; the memory will be freed when the op is destroyed. =cut */ OP * Perl_newPVOP(pTHX_ I32 type, I32 flags, char *pv) { dVAR; const bool utf8 = cBOOL(flags & SVf_UTF8); PVOP *pvop; flags &= ~SVf_UTF8; assert((PL_opargs[type] & OA_CLASS_MASK) == OA_PVOP_OR_SVOP || type == OP_RUNCV || (PL_opargs[type] & OA_CLASS_MASK) == OA_LOOPEXOP); NewOp(1101, pvop, 1, PVOP); pvop->op_type = (OPCODE)type; pvop->op_ppaddr = PL_ppaddr[type]; pvop->op_pv = pv; pvop->op_next = (OP*)pvop; pvop->op_flags = (U8)flags; pvop->op_private = utf8 ? OPpPV_IS_UTF8 : 0; if (PL_opargs[type] & OA_RETSCALAR) scalar((OP*)pvop); if (PL_opargs[type] & OA_TARGET) pvop->op_targ = pad_alloc(type, SVs_PADTMP); return CHECKOP(type, pvop); } void Perl_package(pTHX_ OP *o) { SV *const sv = cSVOPo->op_sv; PERL_ARGS_ASSERT_PACKAGE; SAVEGENERICSV(PL_curstash); save_item(PL_curstname); PL_curstash = (HV *)SvREFCNT_inc(gv_stashsv(sv, GV_ADD)); sv_setsv(PL_curstname, sv); PL_hints |= HINT_BLOCK_SCOPE; PL_parser->copline = NOLINE; PL_parser->expect = XSTATE; op_free(o); } void Perl_package_version( pTHX_ OP *v ) { U32 savehints = PL_hints; PERL_ARGS_ASSERT_PACKAGE_VERSION; PL_hints &= ~HINT_STRICT_VARS; sv_setsv( GvSV(gv_fetchpvs("VERSION", GV_ADDMULTI, SVt_PV)), cSVOPx(v)->op_sv ); PL_hints = savehints; op_free(v); } void Perl_utilize(pTHX_ int aver, I32 floor, OP *version, OP *idop, OP *arg) { OP *pack; OP *imop; OP *veop; SV *use_version = NULL; PERL_ARGS_ASSERT_UTILIZE; if (idop->op_type != OP_CONST) Perl_croak(aTHX_ "Module name must be constant"); veop = NULL; if (version) { SV * const vesv = ((SVOP*)version)->op_sv; if (!arg && !SvNIOKp(vesv)) { arg = version; } else { OP *pack; SV *meth; if (version->op_type != OP_CONST || !SvNIOKp(vesv)) Perl_croak(aTHX_ "Version number must be a constant number"); /* Make copy of idop so we don't free it twice */ pack = newSVOP(OP_CONST, 0, newSVsv(((SVOP*)idop)->op_sv)); /* Fake up a method call to VERSION */ meth = newSVpvs_share("VERSION"); veop = convert(OP_ENTERSUB, OPf_STACKED|OPf_SPECIAL, op_append_elem(OP_LIST, op_prepend_elem(OP_LIST, pack, list(version)), newSVOP(OP_METHOD_NAMED, 0, meth))); } } /* Fake up an import/unimport */ if (arg && arg->op_type == OP_STUB) { imop = arg; /* no import on explicit () */ } else if (SvNIOKp(((SVOP*)idop)->op_sv)) { imop = NULL; /* use 5.0; */ if (aver) use_version = ((SVOP*)idop)->op_sv; else idop->op_private |= OPpCONST_NOVER; } else { SV *meth; /* Make copy of idop so we don't free it twice */ pack = newSVOP(OP_CONST, 0, newSVsv(((SVOP*)idop)->op_sv)); /* Fake up a method call to import/unimport */ meth = aver ? newSVpvs_share("import") : newSVpvs_share("unimport"); imop = convert(OP_ENTERSUB, OPf_STACKED|OPf_SPECIAL, op_append_elem(OP_LIST, op_prepend_elem(OP_LIST, pack, list(arg)), newSVOP(OP_METHOD_NAMED, 0, meth))); } /* Fake up the BEGIN {}, which does its thing immediately. */ newATTRSUB(floor, newSVOP(OP_CONST, 0, newSVpvs_share("BEGIN")), NULL, NULL, op_append_elem(OP_LINESEQ, op_append_elem(OP_LINESEQ, newSTATEOP(0, NULL, newUNOP(OP_REQUIRE, 0, idop)), newSTATEOP(0, NULL, veop)), newSTATEOP(0, NULL, imop) )); if (use_version) { /* Enable the * feature bundle that corresponds to the required version. */ use_version = sv_2mortal(new_version(use_version)); S_enable_feature_bundle(aTHX_ use_version); /* If a version >= 5.11.0 is requested, strictures are on by default! */ if (vcmp(use_version, sv_2mortal(upg_version(newSVnv(5.011000), FALSE))) >= 0) { if (!(PL_hints & HINT_EXPLICIT_STRICT_REFS)) PL_hints |= HINT_STRICT_REFS; if (!(PL_hints & HINT_EXPLICIT_STRICT_SUBS)) PL_hints |= HINT_STRICT_SUBS; if (!(PL_hints & HINT_EXPLICIT_STRICT_VARS)) PL_hints |= HINT_STRICT_VARS; } /* otherwise they are off */ else { if (!(PL_hints & HINT_EXPLICIT_STRICT_REFS)) PL_hints &= ~HINT_STRICT_REFS; if (!(PL_hints & HINT_EXPLICIT_STRICT_SUBS)) PL_hints &= ~HINT_STRICT_SUBS; if (!(PL_hints & HINT_EXPLICIT_STRICT_VARS)) PL_hints &= ~HINT_STRICT_VARS; } } /* The "did you use incorrect case?" warning used to be here. * The problem is that on case-insensitive filesystems one * might get false positives for "use" (and "require"): * "use Strict" or "require CARP" will work. This causes * portability problems for the script: in case-strict * filesystems the script will stop working. * * The "incorrect case" warning checked whether "use Foo" * imported "Foo" to your namespace, but that is wrong, too: * there is no requirement nor promise in the language that * a Foo.pm should or would contain anything in package "Foo". * * There is very little Configure-wise that can be done, either: * the case-sensitivity of the build filesystem of Perl does not * help in guessing the case-sensitivity of the runtime environment. */ PL_hints |= HINT_BLOCK_SCOPE; PL_parser->copline = NOLINE; PL_parser->expect = XSTATE; PL_cop_seqmax++; /* Purely for B::*'s benefit */ if (PL_cop_seqmax == PERL_PADSEQ_INTRO) /* not a legal value */ PL_cop_seqmax++; } /* =head1 Embedding Functions =for apidoc load_module Loads the module whose name is pointed to by the string part of name. Note that the actual module name, not its filename, should be given. Eg, "Foo::Bar" instead of "Foo/Bar.pm". flags can be any of PERL_LOADMOD_DENY, PERL_LOADMOD_NOIMPORT, or PERL_LOADMOD_IMPORT_OPS (or 0 for no flags). ver, if specified and not NULL, provides version semantics similar to C. The optional trailing SV* arguments can be used to specify arguments to the module's import() method, similar to C. They must be terminated with a final NULL pointer. Note that this list can only be omitted when the PERL_LOADMOD_NOIMPORT flag has been used. Otherwise at least a single NULL pointer to designate the default import list is required. The reference count for each specified C parameter is decremented. =cut */ void Perl_load_module(pTHX_ U32 flags, SV *name, SV *ver, ...) { va_list args; PERL_ARGS_ASSERT_LOAD_MODULE; va_start(args, ver); vload_module(flags, name, ver, &args); va_end(args); } #ifdef PERL_IMPLICIT_CONTEXT void Perl_load_module_nocontext(U32 flags, SV *name, SV *ver, ...) { dTHX; va_list args; PERL_ARGS_ASSERT_LOAD_MODULE_NOCONTEXT; va_start(args, ver); vload_module(flags, name, ver, &args); va_end(args); } #endif void Perl_vload_module(pTHX_ U32 flags, SV *name, SV *ver, va_list *args) { OP *veop, *imop; OP * const modname = newSVOP(OP_CONST, 0, name); PERL_ARGS_ASSERT_VLOAD_MODULE; modname->op_private |= OPpCONST_BARE; if (ver) { veop = newSVOP(OP_CONST, 0, ver); } else veop = NULL; if (flags & PERL_LOADMOD_NOIMPORT) { imop = sawparens(newNULLLIST()); } else if (flags & PERL_LOADMOD_IMPORT_OPS) { imop = va_arg(*args, OP*); } else { SV *sv; imop = NULL; sv = va_arg(*args, SV*); while (sv) { imop = op_append_elem(OP_LIST, imop, newSVOP(OP_CONST, 0, sv)); sv = va_arg(*args, SV*); } } /* utilize() fakes up a BEGIN { require ..; import ... }, so make sure * that it has a PL_parser to play with while doing that, and also * that it doesn't mess with any existing parser, by creating a tmp * new parser with lex_start(). This won't actually be used for much, * since pp_require() will create another parser for the real work. * The ENTER/LEAVE pair protect callers from any side effects of use. */ ENTER; SAVEVPTR(PL_curcop); lex_start(NULL, NULL, LEX_START_SAME_FILTER); utilize(!(flags & PERL_LOADMOD_DENY), start_subparse(FALSE, 0), veop, modname, imop); LEAVE; } PERL_STATIC_INLINE OP * S_new_entersubop(pTHX_ GV *gv, OP *arg) { return newUNOP(OP_ENTERSUB, OPf_STACKED, newLISTOP(OP_LIST, 0, arg, newUNOP(OP_RV2CV, 0, newGVOP(OP_GV, 0, gv)))); } OP * Perl_dofile(pTHX_ OP *term, I32 force_builtin) { OP *doop; GV *gv; PERL_ARGS_ASSERT_DOFILE; if (!force_builtin && (gv = gv_override("do", 2))) { doop = S_new_entersubop(aTHX_ gv, term); } else { doop = newUNOP(OP_DOFILE, 0, scalar(term)); } return doop; } /* =head1 Optree construction =for apidoc Am|OP *|newSLICEOP|I32 flags|OP *subscript|OP *listval Constructs, checks, and returns an C (list slice) op. I gives the eight bits of C, except that C will be set automatically, and, shifted up eight bits, the eight bits of C, except that the bit with value 1 or 2 is automatically set as required. I and I supply the parameters of the slice; they are consumed by this function and become part of the constructed op tree. =cut */ OP * Perl_newSLICEOP(pTHX_ I32 flags, OP *subscript, OP *listval) { return newBINOP(OP_LSLICE, flags, list(force_list(subscript)), list(force_list(listval)) ); } STATIC I32 S_is_list_assignment(pTHX_ const OP *o) { unsigned type; U8 flags; if (!o) return TRUE; if ((o->op_type == OP_NULL) && (o->op_flags & OPf_KIDS)) o = cUNOPo->op_first; flags = o->op_flags; type = o->op_type; if (type == OP_COND_EXPR) { const I32 t = is_list_assignment(cLOGOPo->op_first->op_sibling); const I32 f = is_list_assignment(cLOGOPo->op_first->op_sibling->op_sibling); if (t && f) return TRUE; if (t || f) yyerror("Assignment to both a list and a scalar"); return FALSE; } if (type == OP_LIST && (flags & OPf_WANT) == OPf_WANT_SCALAR && o->op_private & OPpLVAL_INTRO) return FALSE; if (type == OP_LIST || flags & OPf_PARENS || type == OP_RV2AV || type == OP_RV2HV || type == OP_ASLICE || type == OP_HSLICE || type == OP_KVASLICE || type == OP_KVHSLICE) return TRUE; if (type == OP_PADAV || type == OP_PADHV) return TRUE; if (type == OP_RV2SV) return FALSE; return FALSE; } /* Helper function for newASSIGNOP to detection commonality between the lhs and the rhs. Marks all variables with PL_generation. If it returns TRUE the assignment must be able to handle common variables. */ PERL_STATIC_INLINE bool S_aassign_common_vars(pTHX_ OP* o) { OP *curop; for (curop = cUNOPo->op_first; curop; curop=curop->op_sibling) { if (PL_opargs[curop->op_type] & OA_DANGEROUS) { if (curop->op_type == OP_GV) { GV *gv = cGVOPx_gv(curop); if (gv == PL_defgv || (int)GvASSIGN_GENERATION(gv) == PL_generation) return TRUE; GvASSIGN_GENERATION_set(gv, PL_generation); } else if (curop->op_type == OP_PADSV || curop->op_type == OP_PADAV || curop->op_type == OP_PADHV || curop->op_type == OP_PADANY) { if (PAD_COMPNAME_GEN(curop->op_targ) == (STRLEN)PL_generation) return TRUE; PAD_COMPNAME_GEN_set(curop->op_targ, PL_generation); } else if (curop->op_type == OP_RV2CV) return TRUE; else if (curop->op_type == OP_RV2SV || curop->op_type == OP_RV2AV || curop->op_type == OP_RV2HV || curop->op_type == OP_RV2GV) { if (cUNOPx(curop)->op_first->op_type != OP_GV) /* funny deref? */ return TRUE; } else if (curop->op_type == OP_PUSHRE) { GV *const gv = #ifdef USE_ITHREADS ((PMOP*)curop)->op_pmreplrootu.op_pmtargetoff ? MUTABLE_GV(PAD_SVl(((PMOP*)curop)->op_pmreplrootu.op_pmtargetoff)) : NULL; #else ((PMOP*)curop)->op_pmreplrootu.op_pmtargetgv; #endif if (gv) { if (gv == PL_defgv || (int)GvASSIGN_GENERATION(gv) == PL_generation) return TRUE; GvASSIGN_GENERATION_set(gv, PL_generation); } } else return TRUE; } if (curop->op_flags & OPf_KIDS) { if (aassign_common_vars(curop)) return TRUE; } } return FALSE; } /* =for apidoc Am|OP *|newASSIGNOP|I32 flags|OP *left|I32 optype|OP *right Constructs, checks, and returns an assignment op. I and I supply the parameters of the assignment; they are consumed by this function and become part of the constructed op tree. If I is C, C, or C, then a suitable conditional optree is constructed. If I is the opcode of a binary operator, such as C, then an op is constructed that performs the binary operation and assigns the result to the left argument. Either way, if I is non-zero then I has no effect. If I is zero, then a plain scalar or list assignment is constructed. Which type of assignment it is is automatically determined. I gives the eight bits of C, except that C will be set automatically, and, shifted up eight bits, the eight bits of C, except that the bit with value 1 or 2 is automatically set as required. =cut */ OP * Perl_newASSIGNOP(pTHX_ I32 flags, OP *left, I32 optype, OP *right) { OP *o; if (optype) { if (optype == OP_ANDASSIGN || optype == OP_ORASSIGN || optype == OP_DORASSIGN) { return newLOGOP(optype, 0, op_lvalue(scalar(left), optype), newUNOP(OP_SASSIGN, 0, scalar(right))); } else { return newBINOP(optype, OPf_STACKED, op_lvalue(scalar(left), optype), scalar(right)); } } if (is_list_assignment(left)) { static const char no_list_state[] = "Initialization of state variables" " in list context currently forbidden"; OP *curop; bool maybe_common_vars = TRUE; if (left->op_type == OP_ASLICE || left->op_type == OP_HSLICE) left->op_private &= ~ OPpSLICEWARNING; PL_modcount = 0; left = op_lvalue(left, OP_AASSIGN); curop = list(force_list(left)); o = newBINOP(OP_AASSIGN, flags, list(force_list(right)), curop); o->op_private = (U8)(0 | (flags >> 8)); if (OP_TYPE_IS_OR_WAS(left, OP_LIST)) { OP* lop = ((LISTOP*)left)->op_first; maybe_common_vars = FALSE; while (lop) { if (lop->op_type == OP_PADSV || lop->op_type == OP_PADAV || lop->op_type == OP_PADHV || lop->op_type == OP_PADANY) { if (!(lop->op_private & OPpLVAL_INTRO)) maybe_common_vars = TRUE; if (lop->op_private & OPpPAD_STATE) { if (left->op_private & OPpLVAL_INTRO) { /* Each variable in state($a, $b, $c) = ... */ } else { /* Each state variable in (state $a, my $b, our $c, $d, undef) = ... */ } yyerror(no_list_state); } else { /* Each my variable in (state $a, my $b, our $c, $d, undef) = ... */ } } else if (lop->op_type == OP_UNDEF || OP_TYPE_IS_OR_WAS(lop, OP_PUSHMARK)) { /* undef may be interesting in (state $a, undef, state $c) */ } else { /* Other ops in the list. */ maybe_common_vars = TRUE; } lop = lop->op_sibling; } } else if ((left->op_private & OPpLVAL_INTRO) && ( left->op_type == OP_PADSV || left->op_type == OP_PADAV || left->op_type == OP_PADHV || left->op_type == OP_PADANY)) { if (left->op_type == OP_PADSV) maybe_common_vars = FALSE; if (left->op_private & OPpPAD_STATE) { /* All single variable list context state assignments, hence state ($a) = ... (state $a) = ... state @a = ... state (@a) = ... (state @a) = ... state %a = ... state (%a) = ... (state %a) = ... */ yyerror(no_list_state); } } /* PL_generation sorcery: * an assignment like ($a,$b) = ($c,$d) is easier than * ($a,$b) = ($c,$a), since there is no need for temporary vars. * To detect whether there are common vars, the global var * PL_generation is incremented for each assign op we compile. * Then, while compiling the assign op, we run through all the * variables on both sides of the assignment, setting a spare slot * in each of them to PL_generation. If any of them already have * that value, we know we've got commonality. We could use a * single bit marker, but then we'd have to make 2 passes, first * to clear the flag, then to test and set it. To find somewhere * to store these values, evil chicanery is done with SvUVX(). */ if (maybe_common_vars) { PL_generation++; if (aassign_common_vars(o)) o->op_private |= OPpASSIGN_COMMON; LINKLIST(o); } if (right && right->op_type == OP_SPLIT) { OP* tmpop = ((LISTOP*)right)->op_first; if (tmpop && (tmpop->op_type == OP_PUSHRE)) { PMOP * const pm = (PMOP*)tmpop; if (left->op_type == OP_RV2AV && !(left->op_private & OPpLVAL_INTRO) && !(o->op_private & OPpASSIGN_COMMON) ) { tmpop = ((UNOP*)left)->op_first; if (tmpop->op_type == OP_GV #ifdef USE_ITHREADS && !pm->op_pmreplrootu.op_pmtargetoff #else && !pm->op_pmreplrootu.op_pmtargetgv #endif ) { #ifdef USE_ITHREADS pm->op_pmreplrootu.op_pmtargetoff = cPADOPx(tmpop)->op_padix; cPADOPx(tmpop)->op_padix = 0; /* steal it */ #else pm->op_pmreplrootu.op_pmtargetgv = MUTABLE_GV(cSVOPx(tmpop)->op_sv); cSVOPx(tmpop)->op_sv = NULL; /* steal it */ #endif tmpop = cUNOPo->op_first; /* to list (nulled) */ tmpop = ((UNOP*)tmpop)->op_first; /* to pushmark */ tmpop->op_sibling = NULL; /* don't free split */ right->op_next = tmpop->op_next; /* fix starting loc */ op_free(o); /* blow off assign */ right->op_flags &= ~OPf_WANT; /* "I don't know and I don't care." */ return right; } } else { if (PL_modcount < RETURN_UNLIMITED_NUMBER && ((LISTOP*)right)->op_last->op_type == OP_CONST) { SV ** const svp = &((SVOP*)((LISTOP*)right)->op_last)->op_sv; SV * const sv = *svp; if (SvIOK(sv) && SvIVX(sv) == 0) { if (right->op_private & OPpSPLIT_IMPLIM) { /* our own SV, created in ck_split */ SvREADONLY_off(sv); sv_setiv(sv, PL_modcount+1); } else { /* SV may belong to someone else */ SvREFCNT_dec(sv); *svp = newSViv(PL_modcount+1); } } } } } } return o; } if (!right) right = newOP(OP_UNDEF, 0); if (right->op_type == OP_READLINE) { right->op_flags |= OPf_STACKED; return newBINOP(OP_NULL, flags, op_lvalue(scalar(left), OP_SASSIGN), scalar(right)); } else { o = newBINOP(OP_SASSIGN, flags, scalar(right), op_lvalue(scalar(left), OP_SASSIGN) ); } return o; } /* =for apidoc Am|OP *|newSTATEOP|I32 flags|char *label|OP *o Constructs a state op (COP). The state op is normally a C op, but will be a C op if debugging is enabled for currently-compiled code. The state op is populated from C (or C). If I