/************************************************************************* * * * YAP Prolog * * * * Yap Prolog was developed at NCCUP - Universidade do Porto * * * * Copyright L.Damas, V.S.Costa and Universidade do Porto 1985-1997 * * * ************************************************************************** * * * File: arith1.c * * Last rev: * * mods: * * comments: bignum support through gmp * * * *************************************************************************/ #ifdef SCCS static char SccsId[] = "%W% %G%"; #endif #include "Yap.h" #include "Yatom.h" #ifdef USE_GMP #include "Heap.h" #include "eval.h" #include "alloc.h" #if HAVE_STRING_H #include #endif /* This global variable tells how things are going */ static CELL *pre_alloc_base = NULL, *alloc_ptr; /* This is a trivial allocator that use the global space: Each unit has a: size; nof elements; */ static void * AllocBigNumSpace(size_t size) { void *ret = (void *)(alloc_ptr+1); if (pre_alloc_base == NULL) { return((void *)malloc(size)); } size = AdjustSize(size)/CellSize; alloc_ptr[0] = size; alloc_ptr += size+1; return(ret); } static void * ReAllocBigNumSpace(void *optr, size_t osize, size_t size) { void *out; if (pre_alloc_base == NULL) { return((void *)realloc(optr,size)); } size = AdjustSize(size)/CellSize; osize = AdjustSize(osize)/CellSize; if (((CELL *)optr)+osize == alloc_ptr) { alloc_ptr += (size-osize); ((CELL *)optr)[-1] = size; return(optr); } out = AllocBigNumSpace(size); memcpy(out, (const void *)optr, size*CellSize); return(out); } static void FreeBigNumSpace(void *optr, size_t size) { CELL *bp = (CELL *)optr; if (pre_alloc_base == NULL) { free(optr); return; } size = AdjustSize(size)/CellSize; if (bp+size == alloc_ptr) { alloc_ptr = bp-1; return; } /* just say it is free */ bp[-1] = -bp[-1]; } MP_INT * Yap_PreAllocBigNum(void) { MP_INT *ret; #ifdef USE_GMP /* YAP style memory allocation */ mp_set_memory_functions( AllocBigNumSpace, ReAllocBigNumSpace, FreeBigNumSpace); #endif if (pre_alloc_base != H) { /* inform where we are allocating */ alloc_ptr = pre_alloc_base = H; } ret = (MP_INT *)(alloc_ptr+1); /* first reserve space for the functor */ alloc_ptr[0] = 0L; /* now allocate space for mpz_t */ alloc_ptr = (CELL *)(ret+1); /* initialise the fields */ mpz_init(ret); return(ret); } void Yap_CleanBigNum(void) { H = pre_alloc_base; pre_alloc_base = NULL; } MP_INT * Yap_InitBigNum(Int in) { MP_INT *ret; if (pre_alloc_base == NULL) { /* inform where we are allocating */ alloc_ptr = pre_alloc_base = H; } ret = (MP_INT *)(alloc_ptr+1); /* first reserve space for the functor */ /* I use a 0 to indicate this is the first time we are building the bignum */ alloc_ptr[0] = 0L; /* now allocate space for mpz_t */ alloc_ptr = (CELL *)(ret+1); /* initialise the fields */ mpz_init_set_si(ret, in); return(ret); } /* This can be done in several different situations: - we did BigIntOf and want to recover now (check through ret[0]); - we have done PreAlloc() and then a lot happened in between: o our final computation fits in an Int; o our final computation is the first we PreAlloced(); o our final computation is not the first term we PreAlloced(); The result may be an Int, the old BigInt, or a BigInt moved to pre_alloc_base; */ Term Yap_MkBigIntTerm(MP_INT *big) { CELL *new = (CELL *)(big+1); Int nlimbs = (big->_mp_alloc)*(sizeof(mp_limb_t)/CellSize); Int sz; CELL *ret = ((CELL *)big)-1; sz = mpz_sizeinbase(big, 2); /* was already there */ if (ret[0] == (CELL)FunctorBigInt) { /* don't need to do no nothing */ return(AbsAppl(ret)); } if (sz < SIZEOF_LONG_INT*8-1) { Int out; H = pre_alloc_base; pre_alloc_base = NULL; out = mpz_get_si(big); return(MkIntegerTerm(out)); } else { /* we may have created a lot of bignums since we did the first PreAlloc(). We want to recover the space, not leave "holes" on the global stack */ if (pre_alloc_base != ret) { /* copy everything to the start of the temp area */ MP_INT *dst = (MP_INT *)(pre_alloc_base+1); dst->_mp_size = big->_mp_size; dst->_mp_alloc = big->_mp_alloc; new = (CELL *)(dst+1); ret = pre_alloc_base; } ret[0] = (CELL)FunctorBigInt; memmove((void *)new, (const void *)(big->_mp_d), nlimbs*CellSize); H = (CELL *)(new+nlimbs); if ((char *)H-(char *)ret > MAX_SPECIALS_TAG-EndSpecials) { /* too large */ return TermNil; } #if GC_NO_TAGS H[0] = (H-ret)*sizeof(CELL)+EndSpecials; #else H[0] = ((H-ret)*sizeof(CELL)+EndSpecials)|MBIT; #endif H++; pre_alloc_base = NULL; return(AbsAppl(ret)); } } MP_INT * Yap_BigIntOfTerm(Term t) { MP_INT *new = (MP_INT *)(RepAppl(t)+1); new->_mp_d = (mp_limb_t *)(new+1); return(new); } #endif Term Yap_MkULLIntTerm(YAP_ULONG_LONG n) { #ifdef __GNUC__ if (n != (UInt)n) { #if USE_GMP /* try to scan it as a bignum */ MP_INT *new = Yap_PreAllocBigNum(); mpz_init(new); mpz_set_ui(new, n>>32); mpz_mul_2exp(new, new, 32); mpz_add_ui(new, new, (UInt)n); return(Yap_MkBigIntTerm(new)); #else return(MkFloatTerm(n)); #endif } else { return MkIntegerTerm(n); } #else return MkIntegerTerm(n); #endif } static Int p_is_bignum(void) { #ifdef USE_GMP Term t = Deref(ARG1); return(IsNonVarTerm(t) && IsApplTerm(t) && FunctorOfTerm(t) == FunctorBigInt); #else return(FALSE); #endif } void Yap_InitBigNums(void) { Yap_InitCPred("$bignum", 1, p_is_bignum, SafePredFlag|HiddenPredFlag); }