375 lines
14 KiB
C#
375 lines
14 KiB
C#
///////////////////////////////////////////////////////////////////////////////
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//
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// Microsoft Research Singularity
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//
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// Copyright (c) Microsoft Corporation. All rights reserved.
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//
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///////////////////////////////////////////////////////////////////////////////
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using System;
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using System.Collections;
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namespace Microsoft.Singularity.Policy.Engine {
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// The Wam class implements a restricted version of the Warren
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// Abstract Machine, as described in "Warren's Abstract
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// Machine: A Tutorial Reconstruction" by Hassan Ait-Kaci
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// (February 18, 1999, reprinted from the MIT Press version).
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// All variables are treated as permanent,
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// so there are no temporary Xn registers.
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// The code area is an Area of Instructions.
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// The heap is an Area of Cells, where a
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// Cell can be a Ref, a Str, or a Functor.
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// The stack is an Area of Cells, where a Cell can also be an Environment
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// or a ChoicePoint. These are stored as single cells with a strongly
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// typed internal structure. The cells for permanent variables follow an
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// Environment; the cells for copies of arguments follow a ChoicePoint.
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// Argument registers are stored in a separate Area of Cells.
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// The trail is an Area of Addresses of Cells
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// that must be unbound upon backtracking.
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// The PDL is local to the Unify procedure, and is a .NET Stack.
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// There are no anonymous variables: set_void and unify_void are
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// unimplemented. Anonymous variables can be added as an optimization.
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// There is no environment trimming: the WAM instruction
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// "call P, N" is replaced by the simpler "call P".
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// Environment trimming can be added as an optimization.
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// There is no TCO: execute, put_unsafe_value,
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// set_local_value, and unify_local_value are
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// unimplemented. TCO can be added as an optimization.
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// There are no list instructions: put_list and get_list are
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// unimplemented. List instructions can be added as an optimization.
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// There are no constant instructions: put_constant, set_constant,
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// get_constant, and unify-constant are unimplemented.
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// Constant instructions can be added as an optimization.
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// There are no indexing instructions: switch_on_term, switch_on_constant,
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// switch_on_structure, try, retry, and trust are unimplemented.
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// Indexing instructions can be added as an optimization.
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internal class Wam {
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Area _heap = new Area("HEAP", 1);
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Address _h, _s;
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Area _a;
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// _code really shouldn't be visible
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internal Area _code = new Area("CODE", 0);
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Address _p, _cp;
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// _label really shouldn't be visible
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internal Hashtable _label = new Hashtable();
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Area _stack = new Area("STACK", 2);
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// _e really shouldn't be visible
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internal Address _e;
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enum Mode { None, Read, Write };
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Mode _mode = Mode.None;
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internal Area A { get { return _a; } }
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// BACKTRACKING
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Address _b, _hb;
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// CUT
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Address _b0;
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// TRAIL
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Area _trail = new Area("TRAIL", 3);
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Address _tr;
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// failure
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bool _fail = false;
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// Put instructions. There is no TCO, so put_unsafe_value
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// is unimplemented. There are no list instructions,
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// so put_list is unimplemented. There are no constant
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// instructions, so put_constant is unimplemented.
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// PutVariable always allocates a heap cell.
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internal void PutVariable(Address yn, Address ai) {
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ai._cell = yn._cell = _h._cell = new Ref(_h);
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_h = _h + 1;
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}
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internal void PutValue(Address yn, Address ai) { ai._cell = yn._cell; }
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// PutStructure always allocates a STR cell on the heap.
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internal void PutStructure(Functor fn, Address yn) {
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_h[0] = new Str(_h);
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_h[1] = fn;
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yn._cell = _h._cell;
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_h = _h + 2;
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}
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// Get instructions. There are no list instructions,
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// so get_list is unimplemented. There are no constant
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// instructions, so get_constant is unimplemented.
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internal void GetVariable(Address yn, Address ai) {
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yn._cell = ai._cell;
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}
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internal void GetValue(Address yn, Address ai) {
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Unify(yn, ai);
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if (_fail) { Backtrack(); }
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}
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internal void GetStructure(Functor fn, Address ai) {
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Address addr = Deref(ai);
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if (addr._cell is Ref) {
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_h[0] = new Str(_h + 1);
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_h[1] = fn;
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Bind(addr, _h);
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_h = _h + 2;
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// Is this right? It conflicts with the errata.
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_s = null;
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_mode = Mode.Write;
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} else if (addr._cell is Str) {
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Address a = ((Str)addr._cell).Value;
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if (a._cell.Equals(fn)) {
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_s = a + 1;
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_mode = Mode.Read;
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} else {
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_fail = true;
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}
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} else {
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_fail = true;
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}
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if (_fail) { Backtrack(); }
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}
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// Set instructions. There is no TCO, so set_local_value
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// is unimplemented. There are no constant instructions,
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// so set_constant is unimplemented. There are no
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// anonymous variables, so set_void is unimplemented.
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internal void SetVariable(Address yn) {
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yn._cell = _h._cell = new Ref(_h);
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_h = _h + 1;
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}
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internal void SetValue(Address yn) { _h[0] = yn._cell; _h = _h + 1; }
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// Unify instructions. There is no TCO, so unify_local_value
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// is unimplemented. There are no constant instructions,
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// so unify-constant is unimplemented. There are no
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// anonymous variables, so unify_void is unimplemented.
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internal void UnifyVariable(Address yn) {
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switch (_mode) {
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case Mode.Read:
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yn._cell = _s._cell;
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break;
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case Mode.Write:
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yn._cell = _h._cell = new Ref(_h);
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_h = _h + 1;
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break;
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default:
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throw new Exception();
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}
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_s = _s + 1;
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}
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internal void UnifyValue(Address yn) {
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switch (_mode) {
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case Mode.Read:
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Unify(yn, _s);
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break;
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case Mode.Write:
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_h[0] = yn._cell;
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_h = _h + 1;
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break;
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default:
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throw new Exception();
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}
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_s = _s + 1;
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if (_fail) { Backtrack(); }
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}
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// Control instructions. There is no environment trimming,
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// so the WAM instruction "call P, N" is replaced with
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// "call P". There is no TCO, so execute is unimplemented.
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internal void Allocate(uint n) {
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Address e;
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if (Greater(_e, _b)) {
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e = _e + 1 + ((Environment)_e._cell)._n;
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} else {
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e = _b + 1 + ((ChoicePoint)_b._cell)._n;
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}
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e._cell = new Environment(n, _e, _cp);
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_e = e;
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}
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internal void Deallocate() {
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_cp = ((Environment)_e._cell)._cp;
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_e = ((Environment)_e._cell)._ce;
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}
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internal void Call(Functor P) {
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if (_label.ContainsKey(P)) {
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_cp = _p;
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_p = (Address)_label[P];
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} else {
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Backtrack();
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}
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}
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internal void Proceed() { _p = _cp; }
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// Choice instructions. There are no indexing instructions,
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// so try, retry, and trust are unimplemented.
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internal void TryMeElse(Address L, uint n) {
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Address b;
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if (Greater(_e, _b)) {
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b = _e + 1 + ((Environment)_e._cell)._n;
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} else {
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b = _b + 1 + ((ChoicePoint)_b._cell)._n;
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}
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ChoicePoint b_ = new ChoicePoint(n, _e, _cp, _b, L, _tr, _h, _hb);
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b._cell = b_;
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for (uint i = 1; i <= n; i++) { b[i] = _a[i]; }
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_b = b;
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_hb = _h;
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}
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internal void RetryMeElse(Address L) {
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ChoicePoint b_ = (ChoicePoint)_b._cell;
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uint n = b_._n;
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for (uint i = 1; i <= n; i++) { _a[i] = _b[i]; }
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_e = b_._ce;
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_cp = b_._cp;
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b_._bp = L;
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UnwindTrail(b_._tr._address, _tr._address);
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_tr = b_._tr;
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_h = b_._h;
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_hb = _h;
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}
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internal void TrustMe() {
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ChoicePoint b_ = (ChoicePoint)_b._cell;
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uint n = b_._n;
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for (uint i = 1; i <= n; i++) { _a[i] = _b[i]; }
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_e = b_._ce;
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_cp = b_._cp;
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UnwindTrail(b_._tr._address, _tr._address);
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_tr = b_._tr;
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_h = b_._h;
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_b = b_._b;
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_hb = ((ChoicePoint)_b._cell)._hb;
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}
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// Cut instructions.
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void NeckCut() { if (Greater(_b, _b0)) { _b = _b0; TidyTrail(); } }
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void GetLevel(Address yn) { yn._address = _b0; }
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void Cut(Address yn) {
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if (Greater(_b, yn._address)) { _b0 = yn._address; TidyTrail(); }
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}
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// Ancillary functions.
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internal void Backtrack() {
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_fail = false;
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if (_b == null) {
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throw new Exception("fail and exit program");
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} else {
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_p = ((ChoicePoint)_b._cell)._bp;
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}
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}
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Address Deref(Address a) {
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if (a._cell is Ref) {
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Address value = (a._cell as Ref).Value;
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if (value != a) { return Deref(value); }
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}
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return a;
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}
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void Bind(Address a1, Address a2) {
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// should add an occurs-check
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if (a1._cell is Ref && (!(a2._cell is Ref) || Less(a2, a1))) {
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a1._cell = a2._cell;
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Trail(a1);
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} else {
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a2._cell = a1._cell;
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Trail(a2);
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}
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}
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void Trail(Address a) {
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if (Less(a, _hb) || Less(_h, a) && Less(a, _b)) {
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_tr._address = a;
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_tr = _tr + 1;
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}
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}
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void UnwindTrail(Address a1, Address a2) {
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Address a = a1;
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while (Less(a, a2)) { a._cell = new Ref(a); a = a + 1; }
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}
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void TidyTrail() {
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Address i = ((ChoicePoint)_b._cell)._tr;
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while (Less(i, _tr)) {
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if (
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Less(i._address, _hb)
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|| Less(_h, i._address) && Less(i._address, _b)
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) {
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i = i + 1;
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} else {
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_tr = _tr - 1;
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i._cell = _tr._cell;
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}
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}
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}
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void Unify(Address a1, Address a2) {
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Stack pdl = new Stack();
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pdl.Push(a1);
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pdl.Push(a2);
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_fail = false;
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while (!(pdl.Count == 0 || _fail)) {
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Address d1 = Deref((Address)pdl.Pop());
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Address d2 = Deref((Address)pdl.Pop());
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if (d1 != d2) {
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Cell cell1 = d1._cell;
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Cell cell2 = d2._cell;
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if (cell1 is Ref) {
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Bind(d1, d2);
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} else {
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if (cell2 is Ref) {
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Bind(d1, d2);
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} else if (cell2 is Str) {
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if (!(cell1 is Str)) {
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_fail = true;
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} else {
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Address v1 = ((Str)cell1).Value;
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Address v2 = ((Str)cell2).Value;
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Functor f1 = (Functor)v1._cell;
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Functor f2 = (Functor)v2._cell;
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if (f1 != f2) {
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_fail = true;
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} else {
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for (int i = 1; i <= f1.Arity; i++) {
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pdl.Push(v1 + i);
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pdl.Push(v2 + i);
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}
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}
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}
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} else {
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_fail = true;
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}
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}
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}
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}
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}
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// Other functions
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bool Less(Address a, Address b) {
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return a.Order < b.Order || a.Order == b.Order && a.At < b.At;
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}
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bool Greater(Address a, Address b) { return Less(b, a); }
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// Run starts execution of the WAM at _p (the current instruction).
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internal void Run() {
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while (_p != null) {
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Instruction instr = _p._instruction;
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_p = _p + 1;
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instr._execute();
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}
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}
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// The constructor.
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internal Wam() {
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_h = _hb = new Address(_heap, 0);
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_a = new Area("A", 9);
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_p = new Address(_code, 0);
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_b = new Address(_stack, 0);
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_b[0]
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= new ChoicePoint(0, null, null, null, null, null, null, null);
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_e = _b + 1;
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_e[0] = new Environment(0, null, null);
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_tr = new Address(_trail, 0);
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}
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}
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}
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