/************************************************************************* * * * YAP Prolog * * * * Yap Prolog was developed at NCCUP - Universidade do Porto * * * * Copyright L.Damas, V.S.Costa and Universidade do Porto 1985-1997 * * * ************************************************************************** * * * File: arrays.c * * Last rev: * * mods: * * comments: Array Manipulation Routines * * * *************************************************************************/ #include "Yap.h" #include "Yatom.h" #include "Heap.h" #include "eval.h" #include "heapgc.h" #if HAVE_ERRNO_H #include #else extern int errno; #endif #if HAVE_STRING_H #include #endif #if __simplescalar__ #ifdef HAVE_MMAP #undef HAVE_MMAP #endif #endif STATIC_PROTO(Int p_compile_array_refs, (void)); STATIC_PROTO(Int p_array_refs_compiled, (void)); STATIC_PROTO(Int p_sync_mmapped_arrays, (void)); /* * * This file works together with pl/arrays.yap and arrays.h. * * YAP now supports a very simple notion of arrays. Arrays may be * allocated dynamically or statically: * * o anonymous arrays are created during execution and allocated * in the heap. They have the lifetime of any other other heap * object. Any term can be an argument to a dynamic array. * * Dynamic arrays are named as a free variable and are * initialised with free variables. * * o named arrays are created during execution but allocated * in the code space. They have the lifetime of an heap * object. Any term can be an argument to a dynamic array. * * Named arrays are named with atoms and are initialised with * free variables. * * o static arrays are allocated in the heap. Their space is * never recovered unless explictly said so by the * program. Arguments to these arrays must have fixed size, * and can only be atomic (at least for now). * * Static arrays can be named through an atom. They are * initialised with []. * * Users create arrays by a declaration X array Arity. If X is an atom * A, then this it is a static array and A's the array name, otherwise * X refers to a dynamic array. * * As in C, arrays start counting from 0. * * Users access arrays by a token X[I] or a[I], this token can appear * anywhere within the computation, so a[2] = X[3*4] means that the * second element of global array a should unify with the 12th element * of array X. The mechanism used to implement this is the same * mechanism used to implement suspension variables. * * Representation: * * Dynamic Arrays are represented as a compound term of arity N, where * N is the size of the array. Even so, I will not include array bound * checking for now. * * |--------------------------------------------------------------| * | $ARRAY/N|.... * |______________________________________________________________ * * * Unbound Var is used as a place to point to. * * Static Arrays are represented as a special property for an atom, * with field size and * * A term of the form X[I] is represented as a Reference pointing to * the compound term: * * '$array_arg'(X,I) * * Dereferecing will automatically find X[I]. * * The only exception is the compiler, which uses a different * dereferencing routine. The clause cl(a[2], Y[X], Y) will be * compiled as: * * cl(A, B, Y) :- '$access_array'(a, A, 2), '$access_array'(Y, B, X). * * There are three operations to access arrays: * * X[I] = A, This is normal unification. * * X[I] := A, This is multiassignment, and therefore * backtrackable. * * X[I] ::= A, This is non-backtrackable multiassignment, ans most * useful for static arrays. * * The LHS of := and of ::= must be an array element! * */ STATIC_PROTO(Term AccessNamedArray, (Atom, Int)); STATIC_PROTO(void InitNamedArray, (ArrayEntry *, Int)); STATIC_PROTO(void CreateNamedArray, (PropEntry *, Int, AtomEntry *)); STATIC_PROTO(void ResizeStaticArray, (StaticArrayEntry *, Int)); #if HAVE_MMAP STATIC_PROTO(Int CloseMmappedArray, (StaticArrayEntry *, void *)); STATIC_PROTO(void ResizeMmappedArray, (StaticArrayEntry *, Int, void *)); #endif STATIC_PROTO(Int p_create_array, (void)); STATIC_PROTO(Int p_create_mmapped_array, (void)); STATIC_PROTO(void replace_array_references_complex, (CELL *, CELL *, CELL *, Term)); STATIC_PROTO(Term replace_array_references, (Term)); STATIC_PROTO(Int p_array_references, (void)); STATIC_PROTO(Int p_create_static_array, (void)); STATIC_PROTO(Int p_resize_static_array, (void)); STATIC_PROTO(Int p_close_static_array, (void)); STATIC_PROTO(Int p_access_array, (void)); STATIC_PROTO(Int p_assign_static, (void)); static Term AccessNamedArray(Atom a, Int indx) { AtomEntry *ae = RepAtom(a); ArrayEntry *pp; READ_LOCK(ae->ARWLock); pp = RepArrayProp(ae->PropsOfAE); while (!EndOfPAEntr(pp) && pp->KindOfPE != ArrayProperty) pp = RepArrayProp(pp->NextOfPE); READ_UNLOCK(ae->ARWLock); if (!EndOfPAEntr(pp)) { if (ArrayIsDynamic(pp)) { Term out; READ_LOCK(pp->ArRWLock); if (IsVarTerm(pp->ValueOfVE)) { READ_UNLOCK(pp->ArRWLock); return(FALSE); } out = RepAppl(pp->ValueOfVE)[indx+1]; READ_UNLOCK(pp->ArRWLock); return(out); } else { StaticArrayEntry *ptr = (StaticArrayEntry *)pp; READ_LOCK(ptr->ArRWLock); if (-(pp->ArrayEArity) <= indx || indx < 0) { /* Error(DOMAIN_ERROR_ARRAY_OVERFLOW, MkIntegerTerm(indx), "access_array");*/ READ_UNLOCK(ptr->ArRWLock); P = (yamop *)FAILCODE; return(TermNil); } switch (ptr->ArrayType) { case array_of_ints: { Term out; out = MkIntegerTerm(ptr->ValueOfVE.ints[indx]); READ_UNLOCK(ptr->ArRWLock); return (out); } case array_of_doubles: { Term out; out = MkEvalFl(ptr->ValueOfVE.floats[indx]); READ_UNLOCK(ptr->ArRWLock); return (out); } case array_of_ptrs: { Term out; out = MkIntegerTerm((Int)(ptr->ValueOfVE.ptrs[indx])); READ_UNLOCK(ptr->ArRWLock); return (out); } case array_of_atoms: { Term out; out = ptr->ValueOfVE.atoms[indx]; READ_UNLOCK(ptr->ArRWLock); if (out == 0L) out = TermNil; else return(out); } /* just return the atom */ case array_of_chars: { Term out; out = MkIntegerTerm((Int)(ptr->ValueOfVE.chars[indx])); READ_UNLOCK(ptr->ArRWLock); return (out); } case array_of_uchars: { Term out; out = MkIntegerTerm((Int)(ptr->ValueOfVE.uchars[indx])); READ_UNLOCK(ptr->ArRWLock); return (out); } case array_of_dbrefs: { /* The object is now in use */ Term TRef = ptr->ValueOfVE.dbrefs[indx]; READ_UNLOCK(ptr->ArRWLock); if (TRef != 0L) { DBRef ref = DBRefOfTerm(TRef); #if defined(YAPOR) || defined(THREADS) LOCK(ref->lock); INC_DBREF_COUNT(ref); TRAIL_REF(ref); /* So that fail will erase it */ UNLOCK(ref->lock); #else if (!(ref->Flags & InUseMask)) { ref->Flags |= InUseMask; TRAIL_REF(ref); /* So that fail will erase it */ } #endif } else { P = (yamop *)FAILCODE; TRef = TermNil; } return (TRef); } case array_of_terms: { /* The object is now in use */ DBRef ref = ptr->ValueOfVE.terms[indx]; Term TRef; READ_UNLOCK(ptr->ArRWLock); if (ref != NULL) { TRef = FetchTermFromDB(ref,3); } else { P = (yamop *)FAILCODE; TRef = TermNil; } return (TRef); } default: READ_UNLOCK(ptr->ArRWLock); return(TermNil); } } } else { Error(EXISTENCE_ERROR_ARRAY,MkAtomTerm(a),"named array"); return (TermNil); } } static Int p_access_array(void) { Term t = Deref(ARG1); Term ti = Deref(ARG2); Term tf; UInt indx; if (IsNonVarTerm(ti)) { union arith_ret v; if (IsIntTerm(ti)) indx = IntOfTerm(ti); else if (Eval(ti, &v) == long_int_e) indx = v.Int; else { Error(TYPE_ERROR_INTEGER,ti,"access_array"); return (FALSE); } } else { Error(INSTANTIATION_ERROR,ti,"access_array"); return (TermNil); } if (IsNonVarTerm(t)) { if (IsApplTerm(t)) { if (indx >= ArityOfFunctor(FunctorOfTerm(t))) { /* Error(DOMAIN_ERROR_ARRAY_OVERFLOW, MkIntegerTerm(indx), "access_array");*/ P = (yamop *)FAILCODE; return(FALSE); } tf = (RepAppl(t))[indx + 1]; } else if (IsAtomTerm(t)) { tf = AccessNamedArray(AtomOfTerm(t), indx); } else { Error(TYPE_ERROR_ARRAY,t,"access_array"); return(FALSE); } } else { Error(INSTANTIATION_ERROR,t,"access_array"); return(FALSE); } return (unify(tf, ARG3)); } static Int p_array_arg(void) { register Term ti = Deref(ARG3), t; register Int indx; if (IsNonVarTerm(ti)) { union arith_ret v; if (IsIntTerm(ti)) indx = IntOfTerm(ti); else if (Eval(ti, &v) == long_int_e) indx = v.Int; else { Error(TYPE_ERROR_INTEGER,ti,"array_arg"); return (FALSE); } } else { Error(INSTANTIATION_ERROR,ti,"array_arg"); return (FALSE); } t = Deref(ARG2); if (IsNonVarTerm(t)) { if (IsApplTerm(t)) { return (unify(((RepAppl(t))[indx + 1]), ARG1)); } else if (IsAtomTerm(t)) { Term tf = AccessNamedArray(AtomOfTerm(t), indx); return (unify(tf, ARG1)); } else Error(TYPE_ERROR_ARRAY,t,"array_arg"); } else Error(INSTANTIATION_ERROR,t,"array_arg"); return (FALSE); } static void InitNamedArray(ArrayEntry * p, Int dim) { Term *tp; WRITE_LOCK(p->ArRWLock); /* Leave a pointer so that we can reclaim array space when * we backtrack or when we abort */ /* place terms in reverse order */ Bind_Global(&(p->ValueOfVE),AbsAppl(H)); tp = H; tp[0] = (CELL)MkFunctor(AtomArray, dim); tp++; p->ArrayEArity = dim; /* Initialise the array as a set of variables */ H = tp+dim; for (; tp < H; tp++) { RESET_VARIABLE(tp); } WRITE_UNLOCK(p->ArRWLock); } /* we assume the atom ae is already locked */ static void CreateNamedArray(PropEntry * pp, Int dim, AtomEntry *ae) { ArrayEntry *p; p = (ArrayEntry *) AllocAtomSpace(sizeof(*p)); p->KindOfPE = ArrayProperty; p->NextOfPE = ae->PropsOfAE; INIT_RWLOCK(p->ArRWLock); ae->PropsOfAE = AbsArrayProp(p); InitNamedArray(p, dim); } static void AllocateStaticArraySpace(StaticArrayEntry *p, static_array_types atype, Int array_size) { Int asize = 0; switch (atype) { case array_of_doubles: asize = array_size*sizeof(Float); break; case array_of_ints: asize = array_size*sizeof(Int); break; case array_of_chars: asize = array_size*sizeof(char); break; case array_of_uchars: asize = array_size*sizeof(unsigned char); break; case array_of_ptrs: asize = array_size*sizeof(AtomEntry *); break; case array_of_dbrefs: case array_of_atoms: asize = array_size*sizeof(Term); break; case array_of_terms: asize = array_size*sizeof(DBRef); break; } while ((p->ValueOfVE.floats = (Float *) AllocAtomSpace(asize) ) == NULL) { YAPLeaveCriticalSection(); if (!growheap(FALSE)) { Error(SYSTEM_ERROR, TermNil, "YAP failed to reserve space in growheap"); return; } YAPEnterCriticalSection(); } } /* ae and p are assumed to be locked, if they exist */ static void CreateStaticArray(AtomEntry *ae, Int dim, static_array_types type, CODEADDR start_addr, StaticArrayEntry *p) { if (EndOfPAEntr(p)) { p = (StaticArrayEntry *) AllocAtomSpace(sizeof(*p)); p->KindOfPE = ArrayProperty; p->NextOfPE = ae->PropsOfAE; INIT_RWLOCK(p->ArRWLock); WRITE_LOCK(p->ArRWLock); } p->ArrayEArity = -dim; p->ArrayType = type; ae->PropsOfAE = AbsArrayProp((ArrayEntry *)p); WRITE_UNLOCK(ae->ARWLock); if (start_addr == NULL) { int i; AllocateStaticArraySpace(p, type, dim); switch(type) { case array_of_ints: for (i = 0; i < dim; i++) p->ValueOfVE.ints[i] = 0; break; case array_of_chars: for (i = 0; i < dim; i++) p->ValueOfVE.chars[i] = '\0'; break; case array_of_uchars: for (i = 0; i < dim; i++) p->ValueOfVE.uchars[i] = '\0'; break; case array_of_doubles: for (i = 0; i < dim; i++) p->ValueOfVE.floats[i] = 0.0; break; case array_of_ptrs: for (i = 0; i < dim; i++) p->ValueOfVE.ptrs[i] = NULL; break; case array_of_atoms: case array_of_dbrefs: for (i = 0; i < dim; i++) p->ValueOfVE.atoms[i] = 0L; break; case array_of_terms: for (i = 0; i < dim; i++) p->ValueOfVE.terms[i] = NULL; break; } } else { /* external array */ p->ValueOfVE.chars = (char *)start_addr; } WRITE_UNLOCK(p->ArRWLock); } static void ResizeStaticArray(StaticArrayEntry *pp, Int dim) { statarray_elements old_v = pp->ValueOfVE; static_array_types type = pp->ArrayType; Int old_dim = - pp->ArrayEArity; Int mindim = (dim < old_dim ? dim : old_dim), i; WRITE_LOCK(pp->ArRWLock); /* change official size */ if (pp->ArrayEArity >= 0) return; pp->ArrayEArity = -dim; #if HAVE_MMAP if (pp->ValueOfVE.chars < (char *)HeapBase || pp->ValueOfVE.chars > (char *)HeapTop) { ResizeMmappedArray(pp, dim, (void *)(pp->ValueOfVE.chars)); return; } #endif AllocateStaticArraySpace(pp, type, dim); switch(type) { case array_of_ints: for (i = 0; i ValueOfVE.ints[i] = old_v.ints[i]; for (i = mindim; iValueOfVE.ints[i] = 0; break; case array_of_chars: for (i = 0; i ValueOfVE.chars[i] = old_v.chars[i]; for (i = mindim; iValueOfVE.chars[i] = '\0'; break; case array_of_uchars: for (i = 0; i ValueOfVE.uchars[i] = old_v.uchars[i]; for (i = mindim; iValueOfVE.uchars[i] = '\0'; break; case array_of_doubles: for (i = 0; i ValueOfVE.floats[i] = old_v.floats[i]; for (i = mindim; iValueOfVE.floats[i] = 0.0; break; case array_of_ptrs: for (i = 0; i ValueOfVE.ptrs[i] = old_v.ptrs[i]; for (i = mindim; iValueOfVE.ptrs[i] = NULL; break; case array_of_atoms: for (i = 0; i ValueOfVE.atoms[i] = old_v.atoms[i]; for (i = mindim; iValueOfVE.atoms[i] = TermNil; break; case array_of_dbrefs: for (i = 0; i ValueOfVE.dbrefs[i] = old_v.dbrefs[i]; for (i = mindim; iValueOfVE.dbrefs[i] = 0L; break; case array_of_terms: for (i = 0; i ValueOfVE.terms[i] = old_v.terms[i]; for (i = mindim; iValueOfVE.terms[i] = NULL; break; } WRITE_UNLOCK(pp->ArRWLock); } CELL * ClearNamedArray(CELL *pt0) { /* given a key to an array, just take it off-line */ PropEntry *pp; AtomEntry *ae = (AtomEntry *)RepAppl(pt0[-1]); READ_LOCK(ae->ARWLock); pp = RepProp(ae->PropsOfAE); while (!EndOfPAEntr(pp) && pp->KindOfPE != ArrayProperty) { pp = RepProp(pp->NextOfPE); } READ_UNLOCK(ae->ARWLock); WRITE_LOCK(((ArrayEntry *)pp)->ArRWLock); if (!EndOfPAEntr(pp)) { ((ArrayEntry *) pp)->ArrayEArity = 0; /* tell backtracking to skip two cells */ WRITE_UNLOCK(((ArrayEntry *)pp)->ArRWLock); return(pt0-2); } else { WRITE_UNLOCK(((ArrayEntry *)pp)->ArRWLock); Error(EXISTENCE_ERROR_ARRAY,TermNil,"clear array"); return(pt0); /* just make GCC happy */ } } /* create an array (?Name, + Size) */ static Int p_create_array(void) { Term ti; Term t; Int size; restart: ti = Deref(ARG2); t = Deref(ARG1); { union arith_ret v; if (IsIntTerm(ti)) size = IntOfTerm(ti); else if (Eval(ti, &v) == long_int_e) size = v.Int; else { Error(TYPE_ERROR_INTEGER,ti,"create_array"); return (FALSE); } } if (IsVarTerm(t)) { /* Create an anonymous array */ Functor farray; farray = MkFunctor(AtomArray, size); if (H+1+size > ASP-1024) { if (!gc(2, ENV, P)) { Error(SYSTEM_ERROR,TermNil,"YAP could not grow stack in array/2"); return(FALSE); } else { if (H+1+size > ASP-1024) { growstack( sizeof(CELL) * (size+1-(H-ASP-1024))); } } goto restart; } t = AbsAppl(H); *H++ = (CELL) farray; for (; size >= 0; size--) { RESET_VARIABLE(H); H++; } return (unify(t, ARG1)); } else if (IsAtomTerm(t)) { /* Create a named array */ AtomEntry *ae = RepAtom(AtomOfTerm(t)); PropEntry *pp; WRITE_LOCK(ae->ARWLock); pp = RepProp(ae->PropsOfAE); while (!EndOfPAEntr(pp) && pp->KindOfPE != ArrayProperty) pp = RepProp(pp->NextOfPE); if (EndOfPAEntr(pp)) { if (H+1+size > ASP-1024) { WRITE_UNLOCK(ae->ARWLock); if (!gc(2, ENV, P)) { Error(SYSTEM_ERROR,TermNil,"YAP could not grow stack in array/2"); return(FALSE); } else goto restart; } CreateNamedArray(pp, size, ae); WRITE_UNLOCK(ae->ARWLock); return (TRUE); } else { ArrayEntry *app = (ArrayEntry *) pp; WRITE_UNLOCK(ae->ARWLock); if (!IsUnboundVar(app->ValueOfVE)) Error(PERMISSION_ERROR_CREATE_ARRAY,t,"create_array", ae->StrOfAE); else { if (H+1+size > ASP-1024) { if (!gc(2, ENV, P)) { Error(SYSTEM_ERROR,TermNil,"YAP could not grow stack in array/2"); return(FALSE); } else goto restart; } InitNamedArray(app, size); return (TRUE); } } } return (FALSE); } /* create an array (+Name, + Size, +Props) */ static Int p_create_static_array(void) { Term ti = Deref(ARG2); Term t = Deref(ARG1); Term tprops = Deref(ARG3); Int size; static_array_types props; if (IsVarTerm(ti)) { Error(INSTANTIATION_ERROR,ti,"create static array"); return (FALSE); } else if (IsIntTerm(ti)) size = IntOfTerm(ti); else { union arith_ret v; if (Eval(ti, &v) == long_int_e) { size = v.Int; } else { Error(TYPE_ERROR_INTEGER,ti,"create static array"); return (FALSE); } } if (IsVarTerm(tprops)) { Error(INSTANTIATION_ERROR,tprops,"create static array"); return (FALSE); } else if (IsAtomTerm(tprops)) { char *atname = RepAtom(AtomOfTerm(tprops))->StrOfAE; if (!strcmp(atname, "int")) props = array_of_ints; else if (!strcmp(atname, "dbref")) props = array_of_dbrefs; else if (!strcmp(atname, "float")) props = array_of_doubles; else if (!strcmp(atname, "ptr")) props = array_of_ptrs; else if (!strcmp(atname, "atom")) props = array_of_atoms; else if (!strcmp(atname, "byte")) props = array_of_chars; else if (!strcmp(atname, "unsigned_byte")) props = array_of_uchars; else if (!strcmp(atname, "term")) props = array_of_terms; else { Error(DOMAIN_ERROR_ARRAY_TYPE,tprops,"create static array"); return(FALSE); } } else { Error(TYPE_ERROR_ATOM,tprops,"create static array"); return (FALSE); } if (IsVarTerm(t)) { Error(INSTANTIATION_ERROR,t,"create static array"); return (FALSE); } else if (IsAtomTerm(t)) { /* Create a named array */ AtomEntry *ae = RepAtom(AtomOfTerm(t)); StaticArrayEntry *pp; WRITE_LOCK(ae->ARWLock); pp = RepStaticArrayProp(ae->PropsOfAE); while (!EndOfPAEntr(pp) && pp->KindOfPE != ArrayProperty) pp = RepStaticArrayProp(pp->NextOfPE); if (EndOfPAEntr(pp) || pp->ValueOfVE.ints == NULL) { CreateStaticArray(ae, size, props, NULL, pp); return (TRUE); } else { WRITE_UNLOCK(ae->ARWLock); Error(PERMISSION_ERROR_CREATE_ARRAY,t,"create static array"); return(FALSE); } } else { Error(TYPE_ERROR_ATOM,t,"create static array"); return (FALSE); } } /* has a static array associated (+Name) */ static Int p_has_static_array(void) { Term t = Deref(ARG1); if (IsVarTerm(t)) { return (FALSE); } else if (IsAtomTerm(t)) { /* Create a named array */ AtomEntry *ae = RepAtom(AtomOfTerm(t)); StaticArrayEntry *pp; READ_LOCK(ae->ARWLock); pp = RepStaticArrayProp(ae->PropsOfAE); while (!EndOfPAEntr(pp) && pp->KindOfPE != ArrayProperty) pp = RepStaticArrayProp(pp->NextOfPE); if (EndOfPAEntr(pp) || pp->ValueOfVE.ints == NULL) { READ_UNLOCK(ae->ARWLock); return (FALSE); } else { READ_UNLOCK(ae->ARWLock); return(TRUE); } } else { return (FALSE); } } /* resize a static array (+Name, + Size, +Props) */ /* does not work for mmap arrays yet */ static Int p_resize_static_array(void) { Term ti = Deref(ARG3); Term t = Deref(ARG1); Int size; if (IsVarTerm(ti)) { Error(INSTANTIATION_ERROR,ti,"resize a static array"); return (FALSE); } else if (IsIntTerm(ti)) size = IntOfTerm(ti); else { union arith_ret v; if (Eval(ti, &v) == long_int_e) { size = v.Int; } else { Error(TYPE_ERROR_INTEGER,ti,"resize a static array"); return (FALSE); } } if (IsVarTerm(t)) { Error(INSTANTIATION_ERROR,t,"resize a static array"); return (FALSE); } else if (IsAtomTerm(t)) { /* resize a named array */ Atom a = AtomOfTerm(t); StaticArrayEntry *pp = RepStaticArrayProp(RepAtom(a)->PropsOfAE); while (!EndOfPAEntr(pp) && pp->KindOfPE != ArrayProperty) pp = RepStaticArrayProp(pp->NextOfPE); if (EndOfPAEntr(pp) || pp->ValueOfVE.ints == NULL) { Error(PERMISSION_ERROR_RESIZE_ARRAY,t,"resize a static array"); return(FALSE); } else { Int osize = - pp->ArrayEArity; ResizeStaticArray(pp, size); return(unify(ARG2,MkIntegerTerm(osize))); } } else { Error(TYPE_ERROR_ATOM,t,"resize a static array"); return (FALSE); } } /* Close a named array (+Name) */ static Int p_close_static_array(void) { /* does not work for mmap arrays yet */ Term t = Deref(ARG1); if (IsVarTerm(t)) { Error(INSTANTIATION_ERROR,t,"close static array"); return (FALSE); } else if (IsAtomTerm(t)) { /* Create a named array */ AtomEntry *ae = RepAtom(AtomOfTerm(t)); PropEntry *pp; READ_LOCK(ae->ARWLock); pp = RepProp(ae->PropsOfAE); while (!EndOfPAEntr(pp) && pp->KindOfPE != ArrayProperty) pp = RepProp(pp->NextOfPE); READ_UNLOCK(ae->ARWLock); if (EndOfPAEntr(pp)) { return (FALSE); } else { StaticArrayEntry *ptr = (StaticArrayEntry *)pp; if (ptr->ValueOfVE.ints != NULL) { #if HAVE_MMAP if (ptr->ValueOfVE.chars < (char *)HeapBase || ptr->ValueOfVE.chars > (char *)HeapTop) { return(CloseMmappedArray(ptr, (void *)ptr->ValueOfVE.chars)); } #endif FreeAtomSpace((char *)(ptr->ValueOfVE.ints)); ptr->ValueOfVE.ints = NULL; ptr->ArrayEArity = 0; return(TRUE); } else { return(FALSE); } } } else { Error(TYPE_ERROR_ATOM,t,"close static array"); return (FALSE); } } #if HAVE_MMAP #if HAVE_UNISTD_H #include #endif #if HAVE_SYS_MMAN_H #include #endif #if HAVE_SYS_STAT_H #include #endif #if HAVE_FCNTL_H #include #endif STATIC_PROTO(void ResizeMmappedArray, (StaticArrayEntry *,Int ,void *)); /* keep a list of mmaped blocks to synch on exit */ typedef struct MMAP_ARRAY_BLOCK { Atom name; void *start; size_t size; Int items; int fd; struct MMAP_ARRAY_BLOCK *next; } mmap_array_block; static mmap_array_block *mmap_arrays = NULL; static Int CloseMmappedArray(StaticArrayEntry *pp, void *area) { mmap_array_block *ptr = mmap_arrays, *optr = mmap_arrays; while (ptr != NULL && ptr->start != area) { ptr = ptr->next; optr = ptr; } if (ptr == NULL) { Error(SYSTEM_ERROR,ARG1,"close_mmapped_array (array chain incoherent)", strerror(errno)); return(FALSE); } if (munmap(ptr->start, ptr->size) == -1) { Error(SYSTEM_ERROR,ARG1,"close_mmapped_array (munmap: %s)", strerror(errno)); return(FALSE); } optr->next = ptr->next; pp->ValueOfVE.ints = NULL; pp->ArrayEArity = 0; if (close(ptr->fd) < 0) { Error(SYSTEM_ERROR,ARG1,"close_mmapped_array (close: %s)", strerror(errno)); return(FALSE); } FreeAtomSpace((char *)ptr); return(TRUE); } static void ResizeMmappedArray(StaticArrayEntry *pp, Int dim, void *area) { mmap_array_block *ptr = mmap_arrays; size_t total_size; while (ptr != NULL && ptr->start != area) { ptr = ptr->next; } if (ptr == NULL) return; /* This is a very stupid algorithm to change size for an array. First, we unmap it, then we actually change the size for the file, and last we initialise again */ if (munmap(ptr->start, ptr->size) == -1) { Error(SYSTEM_ERROR,ARG1,"resize_mmapped_array (munmap: %s)", strerror(errno)); return; } total_size = (ptr->size / ptr->items)*dim; if (ftruncate(ptr->fd, total_size) < 0) { Error(SYSTEM_ERROR,ARG1,"resize_mmapped_array (ftruncate: %s)", strerror(errno)); return; } if (lseek(ptr->fd, total_size-1, SEEK_SET) < 0) { Error(SYSTEM_ERROR,ARG1,"resize_mmapped_array (lseek: %s)", strerror(errno)); return; } if (write(ptr->fd, "", 1) < 0) { Error(SYSTEM_ERROR,ARG1,"resize_mmapped_array (write: %s)", strerror(errno)); return; } if ((ptr->start = (void *)mmap(0, (size_t) total_size, PROT_READ | PROT_WRITE, MAP_SHARED, ptr->fd, 0)) == (void *) - 1) { Error(SYSTEM_ERROR,ARG1,"resize_mmapped_array (mmap: %s)", strerror(errno)); return; } ptr->size = total_size; ptr->items = dim; pp->ValueOfVE.chars = ptr->start; } #endif /* create an array (+Name, + Size, +Props) */ static Int p_create_mmapped_array(void) { #ifdef HAVE_MMAP Term ti = Deref(ARG2); Term t = Deref(ARG1); Term tprops = Deref(ARG3); Term tfile = Deref(ARG4); Int size; static_array_types props; size_t total_size; CODEADDR array_addr; int fd; if (IsVarTerm(ti)) { Error(INSTANTIATION_ERROR,ti,"create_mmapped_array"); return (FALSE); } else if (IsIntTerm(ti)) size = IntOfTerm(ti); else { union arith_ret v; if (Eval(ti, &v) == long_int_e) { size = v.Int; } else { Error(TYPE_ERROR_INTEGER,ti,"create_mmapped_array"); return (FALSE); } } if (IsVarTerm(tprops)) { Error(INSTANTIATION_ERROR,tprops,"create_mmapped_array"); return (FALSE); } else if (IsAtomTerm(tprops)) { char *atname = RepAtom(AtomOfTerm(tprops))->StrOfAE; if (!strcmp(atname, "int")) { props = array_of_ints; total_size = size*sizeof(Int); } else if (!strcmp(atname, "dbref")) { props = array_of_dbrefs; total_size = size*sizeof(Int); } else if (!strcmp(atname, "float")) { props = array_of_doubles; total_size = size*sizeof(Float); } else if (!strcmp(atname, "ptr")) { props = array_of_ptrs; total_size = size*sizeof(AtomEntry *); } else if (!strcmp(atname, "atom")) { props = array_of_atoms; total_size = size*sizeof(Term); } else if (!strcmp(atname, "byte")) { props = array_of_chars; total_size = size*sizeof(char); } else if (!strcmp(atname, "unsigned_byte")) { props = array_of_uchars; total_size = size*sizeof(unsigned char); } else { Error(DOMAIN_ERROR_ARRAY_TYPE,tprops,"create_mmapped_array"); return(FALSE); } } else { Error(TYPE_ERROR_ATOM,tprops,"create_mmapped_array"); return (FALSE); } if (IsVarTerm(tfile)) { Error(INSTANTIATION_ERROR,tfile,"create_mmapped_array"); return (FALSE); } else if (IsAtomTerm(tfile)) { char *filename = RepAtom(AtomOfTerm(tfile))->StrOfAE; fd = open(filename, O_RDWR|O_CREAT, S_IRUSR|S_IWUSR); if (fd == -1) { Error(SYSTEM_ERROR,ARG1,"create_mmapped_array (open: %s)", strerror(errno)); return(FALSE); } if (lseek(fd, total_size-1, SEEK_SET) < 0) Error(SYSTEM_ERROR,tfile,"create_mmapped_array (lseek: %s)", strerror(errno)); if (write(fd, "", 1) < 0) Error(SYSTEM_ERROR,tfile,"create_mmapped_array (write: %s)", strerror(errno)); /* if (ftruncate(fd, total_size) < 0) Error(SYSTEM_ERROR,tfile,"create_mmapped_array"); */ if ((array_addr = (CODEADDR)mmap(0, (size_t) total_size, PROT_READ | PROT_WRITE, MAP_SHARED, fd, 0)) == (CODEADDR) - 1) Error(SYSTEM_ERROR,tfile,"create_mmapped_array (mmap: %s)", strerror(errno)); } else { Error(TYPE_ERROR_ATOM,tfile,"create_mmapped_array"); return (FALSE); } if (IsVarTerm(t)) { Error(INSTANTIATION_ERROR,t,"create_mmapped_array"); return (FALSE); } else if (IsAtomTerm(t)) { /* Create a named array */ AtomEntry *ae = RepAtom(AtomOfTerm(t)); StaticArrayEntry *pp; WRITE_LOCK(ae->ARWLock); pp = RepStaticArrayProp(ae->PropsOfAE); while (!EndOfPAEntr(pp) && pp->KindOfPE != ArrayProperty) pp = RepStaticArrayProp(pp->NextOfPE); if (!EndOfPAEntr(pp)) { WRITE_LOCK(pp->ArRWLock); } if (EndOfPAEntr(pp) || pp->ValueOfVE.ints == NULL) { mmap_array_block *ptr; CreateStaticArray(ae, size, props, array_addr, pp); ptr = (mmap_array_block *)AllocAtomSpace(sizeof(mmap_array_block)); ptr->name = AbsAtom(ae); ptr->size = total_size; ptr->items = size; ptr->start = (void *)array_addr; ptr->fd = fd; ptr->next = mmap_arrays; mmap_arrays = ptr; return(TRUE); } else { WRITE_UNLOCK(pp->ArRWLock); WRITE_UNLOCK(ae->ARWLock); Error(DOMAIN_ERROR_ARRAY_TYPE,t,"create_mmapped_array", ae->StrOfAE); return(FALSE); } } else { Error(TYPE_ERROR_ATOM,t,"create_mmapped_array"); return (FALSE); } #else Error(SYSTEM_ERROR,ARG1,"create_mmapped_array (mmap)"); return (FALSE); #endif } /* This routine verifies whether a complex has variables. */ static void replace_array_references_complex(register CELL *pt0, register CELL *pt0_end, register CELL *ptn, Term Var) { register CELL **to_visit = (CELL **) PreAllocCodeSpace(); CELL **to_visit_base = to_visit; loop: while (pt0 < pt0_end) { register CELL d0; ++pt0; d0 = Derefa(pt0); if (IsVarTerm(d0)) { *ptn++ = d0; } else if (IsPairTerm(d0)) { /* store the terms to visit */ *ptn++ = AbsPair(H); #ifdef RATIONAL_TREES to_visit[0] = pt0; to_visit[1] = pt0_end; to_visit[2] = ptn; to_visit[3] = (CELL *)*pt0; to_visit += 4; *pt0 = TermNil; #else if (pt0 < pt0_end) { to_visit[0] = pt0; to_visit[1] = pt0_end; to_visit[2] = ptn; to_visit += 3; } #endif pt0 = RepPair(d0) - 1; pt0_end = RepPair(d0) + 1; /* write the head and tail of the list */ ptn = H; H += 2; } else if (IsApplTerm(d0)) { register Functor f; f = FunctorOfTerm(d0); /* store the terms to visit */ if (IsExtensionFunctor(f)) { { *ptn++ = d0; continue; } } *ptn++ = AbsAppl(H); /* store the terms to visit */ #ifdef RATIONAL_TREES to_visit[0] = pt0; to_visit[1] = pt0_end; to_visit[2] = ptn; to_visit[3] = (CELL *)*pt0; to_visit += 4; *pt0 = TermNil; #else if (pt0 < pt0_end) { to_visit[0] = pt0; to_visit[1] = pt0_end; to_visit[2] = ptn; to_visit += 3; } #endif pt0 = RepAppl(d0); d0 = ArityOfFunctor(f); pt0_end = pt0 + d0; /* start writing the compound term */ ptn = H; *ptn++ = (CELL) f; H += d0 + 1; } else { /* AtomOrInt */ *ptn++ = d0; } /* just continue the loop */ } /* Do we still have compound terms to visit */ if (to_visit > (CELL **) to_visit_base) { #ifdef RATIONAL_TREES to_visit -= 4; pt0 = to_visit[0]; pt0_end = to_visit[1]; ptn = to_visit[2]; *pt0 = (CELL)to_visit[3]; #else to_visit -= 3; pt0 = to_visit[0]; pt0_end = to_visit[1]; ptn = to_visit[2]; #endif goto loop; } Bind_Global(PtrOfTerm(Var), TermNil); ReleasePreAllocCodeSpace((ADDR)to_visit); } /* * * Given a term t0, build a new term tf of the form ta+tb, where ta is * obtained by replacing the array references in t0 by empty * variables, and tb is a list of array references and corresponding * variables. */ static Term replace_array_references(Term t0) { Term t; t = Deref(t0); do { if (IsVarTerm(t)) { /* we found a variable */ return (MkPairTerm(t, TermNil)); } else if (IsAtomOrIntTerm(t)) { return (MkPairTerm(t, TermNil)); } else if (IsPairTerm(t)) { Term VList = MkVarTerm(); CELL *h0 = H; H += 2; replace_array_references_complex(RepPair(t) - 1, RepPair(t) + 1, h0, VList); return (MkPairTerm(AbsPair(h0), VList)); } else { Term VList = MkVarTerm(); CELL *h0 = H; Functor f = FunctorOfTerm(t); *H++ = (CELL) (f); H += ArityOfFunctor(f); replace_array_references_complex(RepAppl(t), RepAppl(t) + ArityOfFunctor(FunctorOfTerm(t)), h0 + 1, VList); return (MkPairTerm(AbsAppl(h0), VList)); } } while (TRUE); /* make lcc happy */ return(FALSE); } static Int p_array_references(void) { Term t = replace_array_references(ARG1); Term t1 = HeadOfTerm(t); Term t2 = TailOfTerm(t); return (unify(t1, ARG2) && unify(t2, ARG3)); } static Int p_assign_static(void) { Term t1, t2, t3; StaticArrayEntry *ptr; Int indx; t2 = Deref(ARG2); if (IsNonVarTerm(t2)) { if (IsIntTerm(t2)) indx = IntOfTerm(t2); else { union arith_ret v; if (Eval(t2, &v) == long_int_e) { indx = v.Int; } else { Error(TYPE_ERROR_INTEGER,t2,"update_array"); return (FALSE); } } } else { Error(INSTANTIATION_ERROR,t2,"update_array"); return (FALSE); } t3 = Deref(ARG3); t1 = Deref(ARG1); if (IsVarTerm(t1)) { Error(INSTANTIATION_ERROR,t1,"update_array"); return(FALSE); } if (!IsAtomTerm(t1)) { if (IsApplTerm(t1)) { CELL *ptr; Functor f = FunctorOfTerm(t1); /* store the terms to visit */ if (IsExtensionFunctor(f)) { Error(TYPE_ERROR_ARRAY,t1,"update_array"); return(FALSE); } if (indx > 0 && (UInt)indx > ArityOfFunctor(f)) { Error(DOMAIN_ERROR_ARRAY_OVERFLOW,t2,"update_array"); return(FALSE); } ptr = RepAppl(t1)+indx+1; #ifdef MULTI_ASSIGNMENT_VARIABLES MaBind(ptr, t3); return(TRUE); #else Error(SYSTEM_ERROR,t2,"update_array"); return(FALSE); #endif } else { Error(TYPE_ERROR_ATOM,t1,"update_array"); return(FALSE); } } { AtomEntry *ae = RepAtom(AtomOfTerm(t1)); READ_LOCK(ae->ARWLock); ptr = RepStaticArrayProp(ae->PropsOfAE); while (!EndOfPAEntr(ptr) && ptr->KindOfPE != ArrayProperty) ptr = RepStaticArrayProp(ptr->NextOfPE); READ_UNLOCK(ae->ARWLock); } if (EndOfPAEntr(ptr)) { Error(EXISTENCE_ERROR_ARRAY,t1,"assign_static %s", RepAtom(AtomOfTerm(t1))->StrOfAE); return(FALSE); } WRITE_LOCK(ptr->ArRWLock); if (ArrayIsDynamic((ArrayEntry *)ptr)) { ArrayEntry *pp = (ArrayEntry *)ptr; CELL *pt; if (indx < 0 || indx >= pp->ArrayEArity) { Error(DOMAIN_ERROR_ARRAY_OVERFLOW,t2,"assign_static"); READ_UNLOCK(((ArrayEntry *)ptr)->ArRWLock); return(FALSE); } pt = RepAppl(pp->ValueOfVE) + indx + 1; WRITE_UNLOCK(((ArrayEntry *)ptr)->ArRWLock); #ifdef MULTI_ASSIGNMENT_VARIABLES /* the evil deed is to be done now */ MaBind(pt, t3); return(TRUE); #else Error(SYSTEM_ERROR,t2,"update_array"); return(FALSE); #endif } /* a static array */ if (IsVarTerm(t3)) { WRITE_UNLOCK(ptr->ArRWLock); Error(INSTANTIATION_ERROR,t3,"assign_static"); return (FALSE); } if (indx < 0 || indx >= - ptr->ArrayEArity) { WRITE_UNLOCK(ptr->ArRWLock); Error(DOMAIN_ERROR_ARRAY_OVERFLOW,t2,"assign_static"); } switch (ptr->ArrayType) { case array_of_ints: { Int i; union arith_ret v; if (IsIntTerm(t3)) i = IntOfTerm(t3); else if (Eval(t3, &v) == long_int_e) i = v.Int; else { WRITE_UNLOCK(ptr->ArRWLock); Error(TYPE_ERROR_INTEGER,t3,"assign_static"); return (FALSE); } ptr->ValueOfVE.ints[indx]= i; } break; case array_of_chars: { Int i; union arith_ret v; if (IsIntTerm(t3)) i = IntOfTerm(t3); else if (Eval(t3, &v) == long_int_e) i = v.Int; else { Error(TYPE_ERROR_INTEGER,t3,"assign_static"); return (FALSE); } if (i > 127 || i < -128) { WRITE_UNLOCK(ptr->ArRWLock); Error(TYPE_ERROR_BYTE,t3,"assign_static"); return (FALSE); } ptr->ValueOfVE.chars[indx]= i; } break; case array_of_uchars: { Int i; union arith_ret v; if (IsIntTerm(t3)) i = IntOfTerm(t3); else if (Eval(t3, &v) == long_int_e) i = v.Int; else { WRITE_UNLOCK(ptr->ArRWLock); Error(TYPE_ERROR_INTEGER,t3,"assign_static"); return (FALSE); } if (i > 255 || i < 0) { WRITE_UNLOCK(ptr->ArRWLock); Error(TYPE_ERROR_UBYTE,t3,"assign_static"); return (FALSE); } ptr->ValueOfVE.chars[indx]= i; } break; case array_of_doubles: { Float f; union arith_ret v; if (IsFloatTerm(t3)) f = FloatOfTerm(t3); else if (Eval(t3, &v) == double_e) f = v.dbl; else { WRITE_UNLOCK(ptr->ArRWLock); Error(TYPE_ERROR_FLOAT,t3,"assign_static"); return (FALSE); } ptr->ValueOfVE.floats[indx]= f; } break; case array_of_ptrs: { Int r; if (IsIntegerTerm(t3)) r = IntegerOfTerm(t3); else { WRITE_UNLOCK(ptr->ArRWLock); Error(TYPE_ERROR_PTR,t3,"assign_static"); return (FALSE); } ptr->ValueOfVE.ptrs[indx]= (AtomEntry *)r; } break; case array_of_atoms: { if (!IsAtomTerm(t3)) { WRITE_UNLOCK(ptr->ArRWLock); Error(TYPE_ERROR_ATOM,t3,"assign_static"); return (FALSE); } ptr->ValueOfVE.atoms[indx]= t3; } break; case array_of_dbrefs: { Term t0 = ptr->ValueOfVE.dbrefs[indx]; if (!IsDBRefTerm(t3)) { WRITE_UNLOCK(ptr->ArRWLock); Error(TYPE_ERROR_DBREF,t3,"assign_static"); return (FALSE); } ptr->ValueOfVE.dbrefs[indx]= t3; if (t0 != 0L) DBRefOfTerm(t0)->NOfRefsTo--; DBRefOfTerm(t3)->NOfRefsTo++; } break; case array_of_terms: { DBRef ref = ptr->ValueOfVE.terms[indx]; if (ref != NULL) { ReleaseTermFromDB(ref); } ptr->ValueOfVE.terms[indx] = StoreTermInDB(t3,3); } break; } WRITE_UNLOCK(ptr->ArRWLock); return(TRUE); } int compile_arrays = FALSE; static Int p_compile_array_refs(void) { compile_arrays = TRUE; return (TRUE); } static Int p_array_refs_compiled(void) { return (compile_arrays); } static Int p_sync_mmapped_arrays(void) { #ifdef HAVE_MMAP mmap_array_block *ptr = mmap_arrays; while (ptr != NULL) { msync(ptr->start, ptr->size, MS_SYNC); ptr = ptr->next; } #endif return(TRUE); } /* This is a hack, to steal the first element of a key. It first fetches the first element in the chain, and then erases it through its reference. Be careful when using this routine. It is especially evil because if the term is ground it should be copied to the stack, as space for the entry may be deleted. For the moment, the terms I want are just integers, so no problemo, amigo. */ static Term StealFirstFromDB(DBRef ref) { Term TermDB, out; if ((TermDB = FetchTermFromDB(ref,3)) == (CELL)0) { /* oops, we are in trouble, not enough stack space */ return(TermNil); } if (IsVarTerm(TermDB) || !IsApplTerm(TermDB)) /* it's not a wonderful world afterall */ return(TermNil); out = ArgOfTerm(1,TermDB); /* now, return what once was there, only nevermore */ return(out); } Int SetDBForThrow(Term Message) { Term cut_pt_term; Atom a = FullLookupAtom("$catch_queue"); AtomEntry *ae = RepAtom(a); StaticArrayEntry *ptr; DBRef ref; READ_LOCK(ae->ARWLock); ptr = RepStaticArrayProp(ae->PropsOfAE); while (!EndOfPAEntr(ptr) && ptr->KindOfPE != ArrayProperty) ptr = RepStaticArrayProp(ptr->NextOfPE); READ_UNLOCK(ae->ARWLock); ref = ptr->ValueOfVE.terms[0]; cut_pt_term = StealFirstFromDB(ref); if (IsVarTerm(cut_pt_term) || !IsIntegerTerm(cut_pt_term)) { /* ooops, babe we are in trouble */ return(-1); } /* OK, we've got the place to cut to, next store the new throw */ ptr->ValueOfVE.terms[1] = StoreTermInDB(Message,3); return(IntegerOfTerm(cut_pt_term)); } void InitArrayPreds(void) { InitCPred("$create_array", 2, p_create_array, SyncPredFlag); InitCPred("$array_references", 3, p_array_references, SafePredFlag); InitCPred("$array_arg", 3, p_array_arg, SafePredFlag); InitCPred("static_array", 3, p_create_static_array, SafePredFlag|SyncPredFlag); InitCPred("resize_static_array", 3, p_resize_static_array, SafePredFlag|SyncPredFlag); InitCPred("mmapped_array", 4, p_create_mmapped_array, SafePredFlag|SyncPredFlag); InitCPred("update_array", 3, p_assign_static, SafePredFlag); InitCPred("array_element", 3, p_access_array, 0); InitCPred("close_static_array", 1, p_close_static_array, SafePredFlag); InitCPred("$sync_mmapped_arrays", 0, p_sync_mmapped_arrays, SafePredFlag); InitCPred("$compile_array_refs", 0, p_compile_array_refs, SafePredFlag); InitCPred("$array_refs_compiled", 0, p_array_refs_compiled, SafePredFlag); InitCPred("$has_static_array", 1, p_has_static_array, TestPredFlag|SafePredFlag); }