(in-package #:temperance)
;;;; Config
(defvar *step* nil)
;;;; Utilities
(declaim (inline functors-match-p
constants-match-p))
(defun push-unbound-reference! (wam)
"Push a new unbound reference cell onto the heap, returning its address."
(wam-heap-push! wam +cell-type-reference+ (wam-heap-pointer wam)))
(defun push-new-structure! (wam)
"Push a new structure cell onto the heap, returning its address.
The structure cell's value will point at the next address, so make sure you
push something there too!
"
(wam-heap-push! wam +cell-type-structure+ (1+ (wam-heap-pointer wam))))
(defun push-new-list! (wam)
"Push a new list cell onto the heap, returning its address.
The list cell's value will point at the next address, so make sure you push
something there too!
"
(wam-heap-push! wam +cell-type-list+ (1+ (wam-heap-pointer wam))))
(defun push-new-functor! (wam functor arity)
"Push a new functor cell pair onto the heap, returning its address."
(prog1
(wam-heap-push! wam +cell-type-functor+ functor)
(wam-heap-push! wam +cell-type-lisp-object+ arity)))
(defun push-new-constant! (wam constant)
"Push a new constant cell onto the heap, returning its address."
(wam-heap-push! wam +cell-type-constant+ constant))
(defun functors-match-p (f1 a1 f2 a2)
"Return whether the two functor cell values represent the same functor."
(and (eq f1 f2)
(= a1 a2)))
(defun constants-match-p (c1 c2)
"Return whether the two constant cell values unify."
(eq c1 c2))
(defun lisp-objects-match-p (o1 o2)
"Return whether the two lisp object cells unify."
(eql o1 o2))
;;;; "Ancillary" Functions
(declaim (inline deref unbind! trail!))
(defun backtrack! (wam)
"Backtrack after a failure."
(if (wam-backtrack-pointer-unset-p wam)
(setf (wam-fail wam) t)
(setf (wam-program-counter wam) (wam-stack-choice-bp wam)
(wam-cut-pointer wam) (wam-stack-choice-cc wam)
(wam-backtracked wam) t)))
(defun trail! (wam address)
"Push the given address onto the trail (but only if necessary)."
(when (< address (wam-heap-backtrack-pointer wam))
(wam-trail-push! wam address)))
(defun unbind! (wam address)
"Unbind the reference cell at `address`.
No error checking is done, so please don't try to unbind something that's not
(originally) a reference cell.
"
(wam-set-store-cell! wam address +cell-type-reference+ address))
(defun unwind-trail! (wam trail-start trail-end)
"Unbind all the things in the given range of the trail."
(loop :for i :from trail-start :below trail-end :do
(unbind! wam (wam-trail-value wam i))))
(defun tidy-trail! (wam)
(with-accessors ((tr wam-trail-pointer)
(h wam-heap-pointer)
(hb wam-heap-backtrack-pointer)
(b wam-backtrack-pointer)) wam
(loop
;; The book is, yet again, fucked. It just sets `i` to be the trail
;; pointer from the choice point frame. But what if we just popped off
;; the last choice point? If that's the case we need to look over the
;; entire trail.
:with i = (if (wam-backtrack-pointer-unset-p wam b)
0
(wam-stack-choice-tr wam))
:for target = (wam-trail-value wam i)
:while (< i tr) :do
(if (or (< target hb)
(and (< h target)
(< target b)))
(incf i)
(progn
(setf (wam-trail-value wam i)
(wam-trail-value wam (1- tr)))
(decf tr))))))
(defun deref (wam address)
"Dereference the address in the WAM store to its eventual destination.
If the address is a variable that's bound to something, that something will be
looked up (recursively) and the address of whatever it's ultimately bound to
will be returned.
"
;; SBCL won't inline recursive functions :(
(loop
(cell-typecase (wam address)
((:reference ref) (if (= address ref)
(return address) ; unbound ref
(setf address ref))) ; bound ref
(t (return address))))) ; non-ref
(defun bind! (wam address-1 address-2)
"Bind the unbound reference cell to the other.
`bind!` takes two addresses as arguments. You are expected to have `deref`ed
previously to obtain these addresses, so neither of them should ever refer to
a bound reference.
At least one of the arguments *must* refer to an unbound reference cell. This
unbound reference will be bound to point at the other address.
If *both* addresses refer to unbound references, the direction of the binding
is chosen arbitrarily.
"
;; In case it's not absolutely clear from the book: binding has to actually
;; COPY the source cell into the destination.
;;
;; It can't just update the cell value of the destination REF, because if
;; you're binding a REF on the heap to something in a register then doing so
;; would end up with a REF to a register address. This would be bad because
;; that register would probably get clobbered later, and the REF would now be
;; pointing to garbage.
(cond
;; Bind (a1 <- a2) if:
;;
;; * A1 is a REF and A2 is something else, or...
;; * They're both REFs but A2 has a lower address than A1.
((and (cell-type-p (wam address-1) :reference)
(or (not (cell-type-p (wam address-2) :reference))
(< address-2 address-1)))
(wam-copy-store-cell! wam address-1 address-2)
(trail! wam address-1))
;; Bind (a2 <- a1) if A2 is a REF and A1 is something else.
((cell-type-p (wam address-2) :reference)
(wam-copy-store-cell! wam address-2 address-1)
(trail! wam address-2))
;; wut
(t (error "At least one cell must be an unbound reference when binding."))))
(defun unify! (wam a1 a2)
(setf (wam-fail wam) nil)
(wam-unification-stack-push! wam a1 a2)
(until (or (wam-fail wam)
(wam-unification-stack-empty-p wam))
(let* ((d1 (deref wam (wam-unification-stack-pop! wam)))
(d2 (deref wam (wam-unification-stack-pop! wam)))
(t1 (wam-store-type wam d1))
(t2 (wam-store-type wam d2)))
(macrolet ((both (cell-type-designator)
`(and
(cell-type= t1 ,cell-type-designator)
(cell-type= t2 ,cell-type-designator)))
(either (cell-type-designator)
`(or
(cell-type= t1 ,cell-type-designator)
(cell-type= t2 ,cell-type-designator))))
(flet ((match-values (predicate)
(when (not (funcall predicate
(wam-store-value wam d1)
(wam-store-value wam d2)))
(backtrack! wam))))
(when (not (= d1 d2))
(cond
;; If at least one is a reference, bind them.
;;
;; We know that any references we see here will be unbound because
;; we deref'ed them above.
((either :reference)
(bind! wam d1 d2))
;; Otherwise if they're both constants or lisp objects, make sure
;; they match exactly.
((both :constant) (match-values #'constants-match-p))
((both :lisp-object) (match-values #'lisp-objects-match-p))
;; Otherwise if they're both lists, unify their contents.
((both :list)
(wam-unification-stack-push! wam
(wam-store-value wam d1)
(wam-store-value wam d2))
(wam-unification-stack-push! wam
(1+ (wam-store-value wam d1))
(1+ (wam-store-value wam d2))))
;; Otherwise if they're both structures, make sure they match and
;; then schedule their subterms to be unified.
((both :structure)
(let* ((s1 (wam-store-value wam d1)) ; find where they
(s2 (wam-store-value wam d2)) ; start on the heap
(f1 (wam-store-value wam s1)) ; grab the
(f2 (wam-store-value wam s2)) ; functors
(a1 (wam-store-value wam (1+ s1))) ; and the
(a2 (wam-store-value wam (1+ s2)))) ; arities
(if (functors-match-p f1 a1 f2 a2)
;; If the functors match, push their pairs of arguments onto
;; the stack to be unified.
(loop :repeat a1
:for subterm1 :from (+ 2 s1)
:for subterm2 :from (+ 2 s2)
:do (wam-unification-stack-push! wam subterm1 subterm2))
;; Otherwise we're hosed.
(backtrack! wam))))
;; Otherwise we're looking at two different kinds of cells, and are
;; just totally hosed. Backtrack.
(t (backtrack! wam)))))))))
;;;; Instruction Definition
;;; These macros are a pair of real greasy bastards.
;;;
;;; Basically the issue is that there exist two separate types of registers:
;;; local registers and stack registers. The process of retrieving the contents
;;; of a register is different for each type.
;;;
;;; Certain machine instructions take a register as an argument and do something
;;; with it. Because the two register types require different access methods,
;;; the instruction needs to know what kind of register it's dealing with.
;;;
;;; One possible way to solve this would be to encode whether this is
;;; a local/stack register in the register argument itself (e.g. with a tag
;;; bit). This would work, and a previous version of the code did that, but
;;; it's not ideal. It turns out we know the type of the register at compile
;;; time, so requiring a mask/test at run time for every register access is
;;; wasteful.
;;;
;;; Instead we use an ugly, but fast, solution. For every instruction that
;;; takes a register argument we make TWO opcodes instead of just one. The
;;; first is the "-local" variant of the instruction, which treats its register
;;; argument as a local register. The second is the "-stack" variant. When we
;;; compile we can just pick the appropriate opcode, and now we no longer need
;;; a runtime test for every single register assignment.
;;;
;;; To make the process of defining these two "variants" less excruciating we
;;; have these two macros. `define-instruction` (singular) is just a little
;;; sugar around `defun`, for those instructions that don't deal with
;;; arguments.
;;;
;;; `define-instructions` (plural) is the awful one. You pass it a pair of
;;; symbols for the two variant names. Two functions will be defined, both with
;;; the same body, with a few symbols macroletted to the appropriate access
;;; code.
;;;
;;; So in the body, instead of using:
;;;
;;; (wam-set-{local/stack}-register wam reg type value)
;;;
;;; you use:
;;;
;;; (%wam-set-register% wam reg type value)
;;;
;;; and it'll do the right thing.
(defmacro define-instruction
((name &optional should-inline) lambda-list &body body)
"Define an instruction function.
This is just sugar over `defun`.
"
`(progn
(declaim (,(if should-inline 'inline 'notinline) ,name))
(defun ,name ,lambda-list
,@body
nil)))
(defmacro define-instructions
((local-name stack-name &optional should-inline) lambda-list &body body)
"Define a local/stack pair of instructions."
`(progn
(macrolet ((%wam-register% (wam register)
`(wam-local-register-address ,wam ,register))
(%wam-register-type% (wam register)
`(wam-local-register-type ,wam ,register))
(%wam-register-value% (wam register)
`(wam-local-register-value ,wam ,register))
(%wam-set-register% (wam register type value)
`(wam-set-local-register! ,wam ,register ,type ,value))
(%wam-copy-to-register% (wam register source)
`(wam-copy-to-local-register! ,wam ,register ,source)))
(define-instruction (,local-name ,should-inline) ,lambda-list
,@body))
(macrolet ((%wam-register% (wam register)
`(wam-stack-register-address ,wam ,register))
(%wam-register-type% (wam register)
`(wam-stack-register-type ,wam ,register))
(%wam-register-value% (wam register)
`(wam-stack-register-value ,wam ,register))
(%wam-set-register% (wam register type value)
`(wam-set-stack-register! ,wam ,register ,type ,value))
(%wam-copy-to-register% (wam register source)
`(wam-copy-to-stack-register! ,wam ,register ,source)))
(define-instruction (,stack-name ,should-inline) ,lambda-list
,@body))))
;;;; Query Instructions
(define-instruction (%put-structure) (wam functor arity register)
(wam-set-local-register! wam register
+cell-type-structure+
(push-new-functor! wam functor arity))
(setf (wam-mode wam) :write))
(define-instruction (%put-list) (wam register)
(wam-set-local-register! wam register
+cell-type-list+
(wam-heap-pointer wam))
(setf (wam-mode wam) :write))
(define-instructions (%put-variable-local %put-variable-stack)
(wam register argument)
(let ((ref (push-unbound-reference! wam)))
(%wam-copy-to-register% wam register ref)
(wam-copy-to-local-register! wam argument ref)
(setf (wam-mode wam) :write)))
(define-instructions (%put-value-local %put-value-stack)
(wam register argument)
(wam-copy-to-local-register! wam argument (%wam-register% wam register))
(setf (wam-mode wam) :write))
(define-instruction (%put-void) (wam argument)
(wam-copy-to-local-register! wam argument (push-unbound-reference! wam)))
;;;; Program Instructions
(define-instruction (%get-structure) (wam functor arity register)
(cell-typecase (wam (deref wam register) address)
;; If the register points at an unbound reference cell, we push three new
;; cells onto the heap:
;;
;; | N | STR | N+1 |
;; | N+1 | FUN | f |
;; | N+2 | OBJ | n |
;; | | | | <- S
;;
;; Then we bind this reference cell to point at the new structure, set
;; the S register to point beneath it and flip over to write mode.
;;
;; It seems a bit confusing that we don't push the rest of the structure
;; stuff on the heap after it too. But that's going to happen in the
;; next few instructions (which will be subterm-*'s, executed in write
;; mode).
(:reference
(let ((structure-address (push-new-structure! wam))
(functor-address (push-new-functor! wam functor arity)))
(bind! wam address structure-address)
(setf (wam-mode wam) :write
(wam-subterm wam) (+ 2 functor-address))))
;; If the register points at a structure cell, then we look at where
;; that cell points (which will be the functor for the structure):
;;
;; | N | STR | M | points at the structure, not necessarily contiguous
;; | ... |
;; | M | FUN | f | the functor (hopefully it matches)
;; | M+1 | OBJ | 2 | the arity (hopefully it matches)
;; | M+2 | ... | ... | pieces of the structure, always contiguous
;; | M+3 | ... | ... | and always right after the functor
;;
;; If it matches the functor we're looking for, we can proceed. We set
;; the S register to the address of the first subform we need to match
;; (M+2 in the example above).
((:structure functor-address)
(cell-typecase (wam functor-address)
((:functor f n)
(if (functors-match-p functor arity f n)
(setf (wam-mode wam) :read
(wam-subterm wam) (+ 2 functor-address))
(backtrack! wam)))))
;; Otherwise we can't unify, so backtrack.
(t (backtrack! wam))))
(define-instruction (%get-list) (wam register)
(cell-typecase (wam (deref wam register) address)
;; If the register points at a reference (unbound, because we deref'ed) we
;; bind it to a list and flip into write mode to write the upcoming two
;; things as its contents.
(:reference
(bind! wam address (push-new-list! wam))
(setf (wam-mode wam) :write))
;; If this is a list, we need to unify its subterms.
((:list contents)
(setf (wam-mode wam) :read
(wam-subterm wam) contents))
;; Otherwise we can't unify.
(t (backtrack! wam))))
(define-instructions (%get-variable-local %get-variable-stack)
(wam register argument)
(%wam-copy-to-register% wam register argument))
(define-instructions (%get-value-local %get-value-stack)
(wam register argument)
(unify! wam register argument))
;;;; Subterm Instructions
(define-instructions (%subterm-variable-local %subterm-variable-stack)
(wam register)
(%wam-copy-to-register% wam register
(ecase (wam-mode wam)
(:read (wam-subterm wam))
(:write (push-unbound-reference! wam))))
(incf (wam-subterm wam)))
(define-instructions (%subterm-value-local %subterm-value-stack)
(wam register)
(ecase (wam-mode wam)
(:read (unify! wam register (wam-subterm wam)))
(:write (wam-heap-push! wam
(%wam-register-type% wam register)
(%wam-register-value% wam register))))
(incf (wam-subterm wam)))
(define-instruction (%subterm-void) (wam n)
(ecase (wam-mode wam)
(:read (incf (wam-subterm wam) n))
(:write (loop :repeat n
:do (push-unbound-reference! wam)))))
;;;; Control Instructions
(declaim (inline %%procedure-call %%dynamic-procedure-call))
(defun %%procedure-call (wam functor arity program-counter-increment is-tail)
(let* ((target (wam-code-label wam functor arity)))
(if (not target)
;; Trying to call an unknown procedure.
(backtrack! wam)
(progn
(when (not is-tail)
(setf (wam-continuation-pointer wam) ; CP <- next instruction
(+ (wam-program-counter wam) program-counter-increment)))
(setf (wam-number-of-arguments wam) ; set NARGS
arity
(wam-cut-pointer wam) ; set B0 in case we have a cut
(wam-backtrack-pointer wam)
(wam-program-counter wam) ; jump
target)))))
(defun %%dynamic-procedure-call (wam is-tail)
(flet
((%go (functor arity)
(if is-tail
(%%procedure-call
wam functor arity (instruction-size +opcode-dynamic-jump+) t)
(%%procedure-call
wam functor arity (instruction-size +opcode-dynamic-call+) nil)))
(load-arguments (n start-address)
(loop :for arg :from 0 :below n
:for source :from start-address
:do (wam-copy-to-local-register! wam arg source))))
(cell-typecase (wam (deref wam 0)) ; A_0
((:structure functor-address)
;; If we have a non-zero-arity structure, we need to set up the
;; argument registers before we call it. Luckily all the arguments
;; conveniently live contiguously right after the functor cell.
(cell-typecase (wam functor-address)
((:functor functor arity)
(load-arguments arity (+ 2 functor-address))
(%go functor arity))))
;; Zero-arity functors don't need to set up anything at all -- we can
;; just call them immediately.
((:constant c) (%go c 0))
;; It's okay to do (call :var), but :var has to be bound by the time you
;; actually reach it at runtime.
(:reference (error "Cannot dynamically call an unbound variable."))
; You can't call/1 anything else.
(t (error "Cannot dynamically call something other than a structure.")))))
(define-instruction (%jump) (wam functor arity)
(%%procedure-call wam functor arity
(instruction-size +opcode-jump+)
t))
(define-instruction (%call) (wam functor arity)
(%%procedure-call wam functor arity
(instruction-size +opcode-call+)
nil))
(define-instruction (%dynamic-call) (wam)
(%%dynamic-procedure-call wam nil))
(define-instruction (%dynamic-jump) (wam)
(%%dynamic-procedure-call wam t))
(define-instruction (%proceed) (wam)
(setf (wam-program-counter wam) ; P <- CP
(wam-continuation-pointer wam)))
(define-instruction (%allocate) (wam n)
(let ((old-e (wam-environment-pointer wam))
(new-e (wam-stack-top wam)))
(wam-stack-ensure-size wam (+ new-e 4 n))
(setf (wam-stack-word wam new-e) old-e ; CE
(wam-stack-word wam (+ new-e 1)) (wam-continuation-pointer wam) ; CP
(wam-stack-word wam (+ new-e 2)) (wam-cut-pointer wam) ; B0
(wam-stack-word wam (+ new-e 3)) n ; N
(wam-environment-pointer wam) new-e))) ; E <- new-e
(define-instruction (%deallocate) (wam)
(setf (wam-continuation-pointer wam) (wam-stack-frame-cp wam)
(wam-environment-pointer wam) (wam-stack-frame-ce wam)
(wam-cut-pointer wam) (wam-stack-frame-cut wam)))
;;;; Choice Instructions
(declaim (inline reset-choice-point! restore-registers-from-choice-point!))
(defun reset-choice-point! (wam b)
(setf (wam-backtrack-pointer wam) b
;; The book is wrong here: when resetting HB we use the NEW value of B,
;; so the heap backtrack pointer gets set to the heap pointer saved in
;; the PREVIOUS choice point. Thanks to the errata at
;; https://github.com/a-yiorgos/wambook/blob/master/wamerratum.txt for
;; pointing this out.
;;
;; ... well, almost. The errata is also wrong here. If we're popping
;; the FIRST choice point, then just using the HB from the "previous
;; choice point" is going to give us garbage, so we should check for
;; that edge case too. Please kill me.
(wam-heap-backtrack-pointer wam)
(if (wam-backtrack-pointer-unset-p wam b)
+heap-start+
(wam-stack-choice-h wam b))))
(defun restore-registers-from-choice-point! (wam b)
(loop :for register :from 0 :below (wam-stack-choice-n wam b)
:for saved-register :from (wam-stack-choice-argument-address wam 0 b)
:do (wam-copy-to-local-register! wam register saved-register)))
(define-instruction (%try) (wam next-clause)
(let ((new-b (wam-stack-top wam))
(nargs (wam-number-of-arguments wam)))
(wam-stack-ensure-size wam (+ new-b 8 nargs))
(setf (wam-stack-word wam new-b) nargs ; N
(wam-stack-word wam (+ new-b 1)) (wam-environment-pointer wam) ; CE
(wam-stack-word wam (+ new-b 2)) (wam-continuation-pointer wam) ; CP
(wam-stack-word wam (+ new-b 3)) (wam-backtrack-pointer wam) ; CB
(wam-stack-word wam (+ new-b 4)) next-clause ; BP
(wam-stack-word wam (+ new-b 5)) (wam-trail-pointer wam) ; TR
(wam-stack-word wam (+ new-b 6)) (wam-heap-pointer wam) ; H
(wam-stack-word wam (+ new-b 7)) (wam-cut-pointer wam) ; CC
(wam-heap-backtrack-pointer wam) (wam-heap-pointer wam) ; HB
(wam-backtrack-pointer wam) new-b) ; B
(loop :for i :from 0 :below nargs ; A_i
:for n :from 0 :below nargs ; arg N in the choice point frame
:do (wam-copy-to-stack-choice-argument! wam n i new-b))))
(define-instruction (%retry) (wam next-clause)
(let ((b (wam-backtrack-pointer wam)))
(restore-registers-from-choice-point! wam b)
(unwind-trail! wam (wam-stack-choice-tr wam b) (wam-trail-pointer wam))
(setf (wam-environment-pointer wam) (wam-stack-choice-ce wam b)
(wam-continuation-pointer wam) (wam-stack-choice-cp wam b)
;; overwrite the next clause address in the choice point
(wam-stack-word wam (+ b 4)) next-clause
(wam-trail-pointer wam) (wam-stack-choice-tr wam b)
(wam-heap-pointer wam) (wam-stack-choice-h wam b)
(wam-heap-backtrack-pointer wam) (wam-heap-pointer wam))))
(define-instruction (%trust) (wam)
(let* ((b (wam-backtrack-pointer wam))
(old-b (wam-stack-choice-cb wam b)))
(restore-registers-from-choice-point! wam b)
(unwind-trail! wam (wam-stack-choice-tr wam b) (wam-trail-pointer wam))
(setf (wam-environment-pointer wam) (wam-stack-choice-ce wam b)
(wam-continuation-pointer wam) (wam-stack-choice-cp wam b)
(wam-trail-pointer wam) (wam-stack-choice-tr wam b)
(wam-heap-pointer wam) (wam-stack-choice-h wam b))
(reset-choice-point! wam old-b)))
(define-instruction (%cut) (wam)
(let ((current-choice-point (wam-backtrack-pointer wam))
(previous-choice-point (wam-stack-frame-cut wam)))
(when (< previous-choice-point current-choice-point)
(reset-choice-point! wam previous-choice-point)
(tidy-trail! wam))))
;;;; Lisp Object Instructions
(declaim (inline %%match-lisp-object))
(defun %%match-lisp-object (wam object address)
(cell-typecase (wam (deref wam address) address)
;; If the thing points at a reference (unbound, because we deref'ed) we just
;; bind it.
(:reference
(wam-set-store-cell! wam address +cell-type-lisp-object+ object)
(trail! wam address))
;; If this is a lisp object, "unify" them with eql.
((:lisp-object contents)
(when (not (lisp-objects-match-p object contents))
(backtrack! wam)))
;; Otherwise we can't unify.
(t (backtrack! wam))))
(define-instruction (%get-lisp-object) (wam object register)
(%%match-lisp-object wam object register))
(define-instruction (%put-lisp-object) (wam object register)
(wam-set-local-register! wam register +cell-type-lisp-object+ object))
;;;; Constant Instructions
(declaim (inline %%match-constant))
(defun %%match-constant (wam constant address)
(cell-typecase (wam (deref wam address) address)
(:reference
(wam-set-store-cell! wam address +cell-type-constant+ constant)
(trail! wam address))
((:constant c)
(when (not (constants-match-p constant c))
(backtrack! wam)))
(t (backtrack! wam))))
(define-instruction (%put-constant) (wam constant register)
(wam-set-local-register! wam register +cell-type-constant+ constant))
(define-instruction (%get-constant) (wam constant register)
(%%match-constant wam constant register))
(define-instruction (%subterm-constant) (wam constant)
(ecase (wam-mode wam)
(:read (%%match-constant wam constant (wam-subterm wam)))
(:write (push-new-constant! wam constant)))
(incf (wam-subterm wam)))
;;;; Running
(defun extract-things (wam addresses)
"Extract the things at the given store addresses.
The things will be returned in the same order as the addresses were given.
Unbound variables will be turned into uninterned symbols. There will only be
one such symbol for any specific unbound var, so if two addresses are
(eventually) bound to the same unbound var, the symbols returned from this
function will be `eql`.
"
(let ((unbound-vars (list)))
(labels
((mark-unbound-var (address)
(let ((symbol (make-symbol (format nil "?VAR-~D" ; lol
(length unbound-vars)))))
(car (push (cons address symbol) unbound-vars))))
(extract-var (address)
(cdr (or (assoc address unbound-vars)
(mark-unbound-var address))))
(recur (address)
(cell-typecase (wam (deref wam address) address)
(:null "NULL?!")
((:reference r) (extract-var r))
((:structure s) (recur s))
((:list l) (cons (recur l) (recur (1+ l))))
((:constant c) c)
((:functor functor arity)
(list* functor
(loop :repeat arity
:for subterm :from (+ 2 address)
:collect (recur subterm))))
((:lisp-object o) o)
(t (error "What to heck is this?")))))
(mapcar #'recur addresses))))
(defun extract-query-results (wam vars)
(let* ((addresses (loop :for var :in vars
;; TODO: make this suck less
:for i :from (+ (wam-environment-pointer wam) 4)
:collect i))
(results (extract-things wam addresses)))
(weave vars results)))
(defmacro instruction-call (wam instruction code-store pc number-of-arguments)
"Expand into a call of the appropriate machine instruction.
`pc` should be a safe place representing the program counter.
`code-store` should be a safe place representing the instructions.
"
`(,instruction ,wam
,@(loop :for i :from 1 :to number-of-arguments
:collect `(aref ,code-store (+ ,pc ,i)))))
(defmacro opcode-case ((wam code opcode-place) &rest clauses)
"Handle each opcode in the main VM run loop.
Each clause should be of the form:
(opcode &key instruction (increment-pc t) raw)
`opcode` must be a constant by macroexpansion time.
`instruction` should be the corresponding instruction function to call. If
given it will be expanded with the appropriate `aref`s to get its arguments
from the code store.
If `increment-pc` is true an extra `incf` form will be added after the
instruction to handle incrementing the program counter (but only if
backtracking didn't happen).
If a `raw` argument is given it will be spliced in verbatim.
"
;; This macro is pretty nasty, but it's better than trying to write it all out
;; by hand.
;;
;; The main idea is that we want to be able to nicely specify all our
;; opcode/instruction pairs in `run`. Furthermore, we need to handle
;; everything really efficiently because `run` is the hot loop of the entire
;; VM. It is the #1 function you'll see when profiling.
;;
;; This macro handles expanding each case clause into the appropriate `aref`s
;; and such, as well as updating the program counter. The instruction size of
;; each opcode is looked up at macroexpansion time to save cycles.
;;
;; For example, a clause like this:
;;
;; (opcode-case (wam code opcode)
;; ;; ...
;; (#.+opcode-put-structure+ :instruction %put-structure))
;;
;; will get expanded into something like this:
;;
;; (ecase/tree opcode
;; ;; ...
;; (+opcode-put-structure+ (%put-structure wam (aref code (+ program-counter 1))
;; (aref code (+ program-counter 2)))
;; (incf program-counter 3)))
(flet
((parse-opcode-clause (clause)
(destructuring-bind (opcode &key instruction (increment-pc t) raw)
clause
(let ((size (instruction-size opcode)))
`(,opcode
,(when instruction
`(instruction-call ,wam
,instruction
,code
(wam-program-counter ,wam)
,(1- size)))
,(when increment-pc
`(when (not (wam-backtracked ,wam))
(incf (wam-program-counter ,wam) ,size)))
,raw)))))
`(ecase/tree ,opcode-place
,@(mapcar #'parse-opcode-clause clauses))))
(defun run (wam done-thunk &optional (step *step*))
(loop
:with code = (wam-code wam)
:until (or (wam-fail wam) ; failure
(= (wam-program-counter wam) +code-sentinel+)) ; finished
:for opcode = (the opcode (aref (wam-code wam) (wam-program-counter wam)))
:do (progn
(when step
(dump)
(break "About to execute instruction at ~4,'0X" (wam-program-counter wam)))
(opcode-case (wam code opcode)
;; Query
(#.+opcode-put-structure+ :instruction %put-structure)
(#.+opcode-put-variable-local+ :instruction %put-variable-local)
(#.+opcode-put-variable-stack+ :instruction %put-variable-stack)
(#.+opcode-put-value-local+ :instruction %put-value-local)
(#.+opcode-put-value-stack+ :instruction %put-value-stack)
(#.+opcode-put-void+ :instruction %put-void)
;; Program
(#.+opcode-get-structure+ :instruction %get-structure)
(#.+opcode-get-variable-local+ :instruction %get-variable-local)
(#.+opcode-get-variable-stack+ :instruction %get-variable-stack)
(#.+opcode-get-value-local+ :instruction %get-value-local)
(#.+opcode-get-value-stack+ :instruction %get-value-stack)
;; Subterm
(#.+opcode-subterm-variable-local+ :instruction %subterm-variable-local)
(#.+opcode-subterm-variable-stack+ :instruction %subterm-variable-stack)
(#.+opcode-subterm-value-local+ :instruction %subterm-value-local)
(#.+opcode-subterm-value-stack+ :instruction %subterm-value-stack)
(#.+opcode-subterm-void+ :instruction %subterm-void)
;; Constant
(#.+opcode-put-constant+ :instruction %put-constant)
(#.+opcode-get-constant+ :instruction %get-constant)
(#.+opcode-subterm-constant+ :instruction %subterm-constant)
;; Lisp Objects
(#.+opcode-put-lisp-object+ :instruction %put-lisp-object)
(#.+opcode-get-lisp-object+ :instruction %get-lisp-object)
;; List
(#.+opcode-put-list+ :instruction %put-list)
(#.+opcode-get-list+ :instruction %get-list)
;; Choice
(#.+opcode-try+ :instruction %try)
(#.+opcode-retry+ :instruction %retry)
(#.+opcode-trust+ :instruction %trust)
(#.+opcode-cut+ :instruction %cut)
;; Control
(#.+opcode-allocate+ :instruction %allocate)
(#.+opcode-deallocate+ :instruction %deallocate)
(#.+opcode-proceed+ :instruction %proceed :increment-pc nil)
(#.+opcode-jump+ :instruction %jump :increment-pc nil)
(#.+opcode-call+ :instruction %call :increment-pc nil)
(#.+opcode-dynamic-jump+ :instruction %dynamic-jump :increment-pc nil)
(#.+opcode-dynamic-call+ :instruction %dynamic-call :increment-pc nil)
;; Final
(#.+opcode-done+
:increment-pc nil
:raw (if (funcall done-thunk)
(return-from run nil)
(backtrack! wam))))
(setf (wam-backtracked wam) nil)
(when (>= (wam-program-counter wam)
(wam-code-pointer wam))
(error "Fell off the end of the program code store."))))
nil)
(defun %run-query (wam vars result-function)
(setf (wam-program-counter wam) 0
(wam-continuation-pointer wam) +code-sentinel+)
(run wam (lambda ()
(funcall result-function
(extract-query-results wam vars))))
(wam-reset! wam)
nil)
(defun run-query (wam terms &key (result-function
(lambda (results)
(declare (ignore results)))))
"Compile query `terms` and run the instructions on the `wam`.
Resets the heap, etc after running.
When `*step*` is true, break into the debugger before calling the procedure
and after each instruction.
"
(%run-query wam (compile-query wam terms) result-function))
(defun run-aot-compiled-query (wam query-code query-size query-vars
&key (result-function
(lambda (results)
(declare (ignore results)))))
"Run the AOT-compiled query `code`/`vars` on the `wam`.
Resets the heap, etc after running.
When `*step*` is true, break into the debugger before calling the procedure
and after each instruction.
"
(wam-load-query-code! wam query-code query-size)
(%run-query wam query-vars result-function))