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// Copyright (C) 2011, Gabriel Dos Reis.
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// - Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//
// - Redistributions in binary form must reproduce the above copyright
// notice, this list of conditions and the following disclaimer in
// the documentation and/or other materials provided with the
// distribution.
//
// - Neither the name of OpenAxiom nor the names of its contributors
// may be used to endorse or promote products derived from this
// software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
// TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
// PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER
// OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
// EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
// PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
// --% Author: Gabriel Dos Reis
// --% Description:
// --% Interface and implementation of basic services of the
// --% OpenAxiom Virtual Machine.
#ifndef OPENAXIOM_VM_INCLUDED
#define OPENAXIOM_VM_INCLUDED
#include <open-axiom/storage>
#if HAVE_STDINT_H
# include <stdint.h>
#endif
#include <open-axiom/string-pool>
namespace OpenAxiom {
namespace VM {
// --%
// --% Value representation
// --%
// A far reaching design decision is to provide a uniform
// representation for values. That is all values, irrespective
// of type have fit in a fixed format, i.e. a scalar register.
// This means that values that are more complicated than a scalar,
// that is the vast majority and most interesting values, have to
// be stored in allocated objects and addresses of their container
// objects used in place of the actual values. This is folklore
// in the communities of garbage collected languages.
//
// An unfortunate but widely held belief is that AXIOM-based
// systems (and computer algebra systems in general) are
// Lisp-based systems. Nothing could be further from the truth
// for OpenAxiom. The type system is believed to support
// erasure semantics, at least for values.
//
// However the current implementation, being Lisp-based,
// unwittingly makes use of some Lisp features that are not
// strictly necessary. It would take a certain amount of effort
// to get rid of them. Consequently, we must cope -- at least
// for now -- with the notion of uniform value representation and
// use runtime predicates to descriminate between values.
// On the other hand, we do not want to carry an unduly expensive
// abstraction penalty for perfectly well behaved and well
// disciplined programs. So, here are a few constraints:
// 1. Small integers should represent themselves -- not allocated.
// Furthermore, the maximum range should be sought where possible.
// 2. Since we have to deal with characters, they should be
// directly represented -- not allocated.
// 3. List values and list manipulation should be efficient.
// Ideally, a pair should not occupy more than what it
// takes to store two values in a type-erasure semantics.
// 4. Idealy, pointers to foreign objects (at least) should be
// left unmolested.
//
// * Assumptions:
// (a) the host machine has sizeof(Value) quo 4 = 0.
// (b) allocatd objects can be aligned on sizeof(Value) boundary.
// (c) the host machine has 2's complement arithmetic.
//
// If:
// -- we use a dedicated allocation pool for cons cells
// -- we allocate the first cell in each cons-storage arena
// on a 8-byte boundary
// -- we use exactly 2 * sizeof(Value) to store a cons cell
// therefore realizing constraint (3)
// then:
// every pointer to a cons cell will have its last 3 bits cleared.
//
// Therefore, we can use the last 3 bits to tag a cons value, instead
// of storing the tag inside the cons cell. we can't leave those
// bits cleared for we would not be able to easily and cheaply
// distinguish a pointer to a cons cell from a pointer to other
// objects, in particular foreign objects.
//
// To meet constraint (1), we must logically use at least one bit
// to distinguish a small integer from a pointer to a cons cell.
// The good news is that we need no more than that if pointers
// to foreign pointers do not have the last bit set. Which is
// the case with assumption (a). Furthermore, if we align all
// other internal data on 16 byte boundary, then we have 4 bits
// that we can use to categorize values.
// Therefore we arrive at the first design:
// I. the value representation of small integer always have the
// the least significant bit set. All other bits are
// significant in representing small integers. In other words,
// the last four bits of a small integer are 0bxxx1
//
// As a consequence, the last bit of all other values must be cleared.
//
// Next,
// II. All foreign pointers must have the last two bits cleared.
// In consequence, the last four bits of all foreign addresses
// follow the pattern 0bxx00.
//
// As a consequence, the second bit of a cons cell value must be set
// so that we can distinguish it from foreign pointers.
//
// III. Cons cells are represented by their addresses with the
// last 4 bits matching the pattern 0bx010.
//
// IV. All internal objects are allocated on 16-byte boundary.
// We set their last 4 bit to the pattern 0b0110.
//
// Finally:
// V. The representation of a character shall have the last four
// bits set to 0b1110.
//
// Note: These choices do not fully satisfy constraint 4. This is
// because we restrict foreign pointers to address aligned
// to 4-byte boundaries.
// -----------
// -- Value --
// -----------
// All VM values fit in a universal value datatype.
typedef uintptr_t Value;
// -------------
// -- Fixnum ---
// -------------
// VM integers are divided into classes: small numbers,
// and large numbers. A small number fits entirely in a register.
// A large number is allocated and represented by its address.
typedef intptr_t Fixnum;
const Value fix_tag = 0x1;
inline bool is_fixnum(Value v) {
return (v & 0x1) == fix_tag;
}
inline Fixnum to_fixnum(Value v) {
return Fixnum(v >> 1);
}
inline Value from_fixnum(Fixnum i) {
return (Fixnum(i) << 1 ) | fix_tag;
}
// -------------
// -- Pointer --
// -------------
// Allocated objects are represented by their addresses.
using Memory::Pointer;
const Value ptr_tag = 0x0;
inline bool is_pointer(Value v) {
return (v & 0x3) == ptr_tag;
}
inline Pointer to_pointer(Value v) {
return Pointer(v);
}
inline Value from_pointer(Pointer p) {
return Value(p);
}
// ----------
// -- Pair --
// ----------
struct ConsCell {
Value head;
Value tail;
ConsCell(Value h, Value t) : head(h), tail(t) { }
};
typedef ConsCell* Pair;
const Value pair_tag = 0x2;
inline bool is_pair(Value v) {
return (v & 0x7) == pair_tag;
}
inline Pair to_pair(Value v) {
return Pair(v & ~0x7);
}
inline Value from_pair(Pair p) {
return Value(p) | pair_tag;
}
// If `v' designates a pair, return a pointer to its
// concrete representation.
inline Pair pair_if_can(Value v) {
return is_pair(v) ? to_pair(v) : 0;
}
// ------------
// -- Object --
// ------------
struct BasicObject;
typedef BasicObject* Object;
const Value obj_tag = 0x6;
inline bool is_object(Value v) {
return (v & 0xF) == obj_tag;
}
inline Object to_object(Value v) {
return Object(v & ~0xF);
}
inline Value from_object(Object* o) {
return Value(o) | obj_tag;
}
// ---------------
// -- Character --
// ---------------
// This datatype is prepared for Uncode characters even if
// we do not handle UCN characters.
typedef Value Character;
const Value char_tag = 0xE;
inline bool is_character(Value v) {
return (v & 0xF) == char_tag;
}
inline Character to_character(Value v) {
return Character(v >> 4);
}
inline Value from_character(Character c) {
return (Value(c) << 4) | char_tag;
}
// --
// -- Builtin Operations
// --
// Types for native implementation of builtin operators.
struct BasicContext;
typedef Value (*NullaryCode)(BasicContext*);
typedef Value (*UnaryCode)(BasicContext*, Value);
typedef Value (*BinaryCode)(BasicContext*, Value, Value);
typedef Value (*TernaryCode)(BasicContext*, Value, Value, Value);
// ------------------
// -- BasicContext --
// ------------------
// Provides basic evaluation services.
struct BasicContext : StringPool {
BasicContext();
Pair make_cons(Value, Value);
protected:
Memory::Factory<ConsCell> conses;
};
};
}
#endif // OPENAXIOM_VM_INCLUDED
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