e5f4633c39
which included commits to RCS files with non-trunk default branches. git-svn-id: https://yap.svn.sf.net/svnroot/yap/trunk@5 b08c6af1-5177-4d33-ba66-4b1c6b8b522a
124 lines
4.6 KiB
Plaintext
124 lines
4.6 KiB
Plaintext
/*************************************************************************
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* *
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* YAP Prolog %W% %G% *
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* Yap Prolog was developed at NCCUP - Universidade do Porto *
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* *
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* Copyright L.Damas, V.S.Costa and Universidade do Porto 1985-1997 *
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* *
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**************************************************************************
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* *
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* File: Tags_32Ops.h.m4 *
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* Last rev: December 90 *
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* mods: *
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* comments: Original Tag Scheme for machines with 32 bits adresses *
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* version: $Id: Tags_32Ops.h.m4,v 1.1.1.1 2001-04-09 19:53:46 vsc Exp $ *
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*************************************************************************/
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/*
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Version for 32 bit addresses machines,
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Each term is represented internally as an unsigned 32 bit integer as
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follows:
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tag value
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ints 1m1....01 numeric value
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atoms 1m0....01 offset of atom entry
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pairs 1mr....11 ptr to pair
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aplied functor 1mr....00 ptr to functor followed by args
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undefined 0mr....00 address of cell pointing to itself
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functors are represented as ptrs to the functor entry in the atom
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property list
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This version speeds up access to lists and to compound
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terms by using the XOR and NOT operations to build their tags. This
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saves operations on RISC machines.
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As a further optimisation, only pairs or compound terms have
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the second lowest bit set. This allows one to recognise lists or
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compound terms with a single operation.
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The main problem is that the default value of the M and R bits for GC
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are now 1 in compound terms and structures.
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*/
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#define TAGS_FAST_OPS 1
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#define SHIFT_HIGH_TAG 29
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#define MKTAG(HI,LO) ((((UInt) (HI))<<SHIFT_HIGH_TAG)|(LO))
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#define TagBits /* 0xb0000003L */ MKTAG(0x5,3)
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#define LowTagBits /* 0x00000003L */ MKTAG(0x0,3)
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#define LowBit /* 0x00000001L */ MKTAG(0x0,1)
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#define HighTagBits /* 0xf0000000L */ MKTAG(0x7,0)
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#define AdrHiBit /* 0x08000000L */ (((UInt)1) << (SHIFT_HIGH_TAG-1))
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#define MaskAdr /* 0x1ffffffcL */ ((((UInt)1) << (SHIFT_HIGH_TAG))-4)
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#define MaskPrim /* 0x0ffffffcL */ ((((UInt)1) << (SHIFT_HIGH_TAG))-4)
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#define NumberTag /* 0xb0000001L */ MKTAG(0x5,2)
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#define AtomTag /* 0x90000001L */ MKTAG(0x4,2)
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#define MAX_ABS_INT /* 0xfe00000LL */ ((Int)0x04000000L)
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/* bits that should not be used by anyone but us */
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#define YAP_PROTECTED_MASK 0xe0000000L
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#define MaskBits 4
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/*
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UNIQUE_TAG_FOR_PAIR gives the representation for pair an
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unique tag
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This allows optimisation of switch_list
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*/
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#if defined(i386) || defined(sparc) || defined(_POWER)
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#define UNIQUE_TAG_FOR_PAIRS 1
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#endif
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#if UNIQUE_TAG_FOR_PAIRS
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#define PairBit /* 0x00000001L */ 1
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#define ApplBit /* 0x00000000L */ 0
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#else
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#define PairBit /* 0x00000000L */ 0
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#define ApplBit /* 0x00000001L */ 1
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#endif
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#define NonTagPart(X) (Signed(X) & MaskPrim)
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#define TAGGEDA(TAG,V) (TAG | Unsigned(V))
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#define TAGGED(TAG,V) (TAG | NonTagPart(Unsigned(V)<<2))
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#define NONTAGGED(TAG,V) NonTagPart(Unsigned(V)<<2)
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#define BitOn(Bit,V) (Bit & Unsigned(V))
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#define CHKTAG(t,Tag) ((Unsigned(t)&TagBits)==Tag)
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/* never forget to surround arguments to a macro by brackets */
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Inline(IsVarTerm, int, Term, t, Signed(t) >= 0)
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Inline(IsNonVarTerm, int, Term, t, Signed(t) < 0)
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#if UNIQUE_TAG_FOR_PAIRS
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Inline(RepPair, Term *, Term, t, (~(t)))
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Inline(AbsPair, Term, Term *, p, (~Unsigned(p)))
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Inline(IsPairTerm, Int, Term, t, ((t) & PairBit))
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Inline(RepAppl, Term *, Term, t, (-Signed(t)))
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Inline(AbsAppl, Term, Term *, p, (-Signed(p)))
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Inline(IsApplTerm, Int, Term, t, (!((t) & LowTagBits)))
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#else
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Inline(RepPair, Term *, Term, t, (-Signed(t)))
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Inline(AbsPair, Term, Term *, p, ((CELL)(-Signed(p))))
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Inline(IsPairTerm, Int, Term, t, (!((t) & LowTagBits)))
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Inline(RepAppl, Term *, Term, t, (~(t)))
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Inline(AbsAppl, Term, Term *, p, (~Unsigned(p)))
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Inline(IsApplTerm, Int, Term, t, ((t) & ApplBit))
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#endif
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Inline(IsAtomOrIntTerm, Int, Term, t, ((Unsigned(t) & LowTagBits) == 0x2))
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Inline(IntOfTerm, Int, Term, t, (Int)(Unsigned(t) << 3) >> 5)
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#if UNIQUE_TAG_FOR_PAIRS
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Inline2(AdjustPtr, Term, Term, t, Term, off, ((IsVarTerm(t) || IsAtomOrIntTerm(t)) ? (t)+(off) : (IsPairTerm(t) ? (CELL)AbsPair((CELL *)((CELL)RepPair(t)+(off))) : (t)-(off))))
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Inline2(AdjustIDBPtr, Term, Term, t, Term, off, IsVarTerm(t) ? (t)+(off) : (t)-(off))
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#else
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Inline2(AdjustPtr, Term, Term, t, Term, off, ((IsVarTerm(t) || IsAtomOrIntTerm(t)) ? (t)+(off) : (IsApplTerm(t) ? (CELL)AbsAppl((CELL *)((CELL)RepAppl(t)+(off))) : (t)-(off))))
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Inline2(AdjustIDBPtr, Term, Term, t, Term, off, IsVarTerm(t) ? (t)+(off) : (IsApplTerm(t) ? (CELL)AbsAppl((CELL *)((CELL)RepAppl(t)+(off))) : (t)-(off)))
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#endif
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