;;; The sort package -- stable vector merge & merge sort -*- Scheme -*-
;;; Copyright (c) 1998 by Olin Shivers.
;;; This code is open-source; see the end of the file for porting and
;;; more copyright information.
;;; Olin Shivers 10/98.

;;; Exports:
;;; (vector-merge  < v1 v2 [start1 end1 start2 end2])          -> vector
;;; (vector-merge! < v v1 v2 [start0 start1 end1 start2 end2]) -> unspecific
;;;
;;; (vector-merge-sort  < v [start end temp]) -> vector
;;; (vector-merge-sort! < v [start end temp]) -> unspecific


;;; Merge
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; (vector-merge < v1 v2 [start1 end1 start2 end2]) -> vector
;;; (vector-merge! < v v1 v2 [start start1 end1 start2 end2]) -> unspecific
;;;
;;; Stable vector merge -- V1's elements come out ahead of equal V2 elements.

(define (vector-merge < v1 v2 . maybe-starts+ends)
  (call-with-values
   (lambda () (vectors-start+end-2 v1 v2 maybe-starts+ends))
   (lambda (start1 end1 start2 end2)
     (let ((ans (make-vector (+ (- end1 start1) (- end2 start2)))))
       (%vector-merge! < ans v1 v2 0 start1 end1 start2 end2)
       ans))))

(define (vector-merge! < v v1 v2 . maybe-starts+ends)
  (call-with-values
   (lambda ()
     (if (pair? maybe-starts+ends)
	 (values (car maybe-starts+ends)
		 (cdr maybe-starts+ends))
	 (values 0
		 '())))
   (lambda (start rest)
     (call-with-values
      (lambda () (vectors-start+end-2 v1 v2 rest))
      (lambda (start1 end1 start2 end2)
	(%vector-merge! < v v1 v2 start start1 end1 start2 end2))))))


;;; This routine is not exported. The code is tightly bummed.
;;;
;;; If these preconditions hold, the routine can be bummed to run with 
;;; unsafe vector-indexing and fixnum arithmetic ops:
;;;   - V V1 V2 are vectors.
;;;   - START START1 END1 START2 END2 are fixnums.
;;;   - (<= 0 START END0 (vector-length V),
;;;     where end0 = start + (end1 - start1) + (end2 - start2)
;;;   - (<= 0 START1 END1 (vector-length V1))
;;;   - (<= 0 START2 END2 (vector-length V2))
;;; If you put these error checks in the two client procedures above, you can
;;; safely convert this procedure to use unsafe ops -- which is why it isn't
;;; exported. This will provide *huge* speedup.

(define (%vector-merge! elt< v v1 v2 start start1 end1 start2 end2)
  (letrec ((vblit (lambda (fromv j i end) ; Blit FROMV[J,END) to V[I,?].
		    (let lp ((j j) (i i))
		      (vector-set! v i (vector-ref fromv j))
		      (let ((j (+ j 1)))
			(if (< j end) (lp j (+ i 1))))))))

    (cond ((<= end1 start1) (if (< start2 end2) (vblit v2 start2 start end2)))
          ((<= end2 start2) (vblit v1 start1 start end1))

	  ;; Invariants: I is next index of V to write; X = V1[J]; Y = V2[K].
	  (else (let lp ((i start)
			 (j start1)  (x (vector-ref v1 start1))
			 (k start2)  (y (vector-ref v2 start2)))
		  (let ((i1 (+ i 1)))	; "i+1" is a complex number in R4RS!
		    (if (elt< y x)
			(let ((k (+ k 1)))
			  (vector-set! v i y)
			  (if (< k end2)
			      (lp i1 j x k (vector-ref v2 k))
			      (vblit v1 j i1 end1)))
			(let ((j (+ j 1)))
			  (vector-set! v i x)
			  (if (< j end1)
			      (lp i1 j (vector-ref v1 j) k y)
			      (vblit v2 k i1 end2))))))))))


;;; (vector-merge-sort  < v [start end temp]) -> vector
;;; (vector-merge-sort! < v [start end temp]) -> unspecific
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; Stable natural vector merge sort

(define (vector-merge-sort! < v . maybe-args)
  (call-with-values
   (lambda () (vector-start+end v maybe-args))
   (lambda (start end)
     (let ((temp (if (and (pair? maybe-args) ; kludge
			  (pair? (cdr maybe-args))
			  (pair? (cddr maybe-args)))
		     (caddr maybe-args)
		     (vector-copy v))))
       (%vector-merge-sort! < v start end temp)))))

(define (vector-merge-sort < v . maybe-args)
  (call-with-values
   (lambda () (vector-start+end v maybe-args))
   (lambda (start end)
     (let ((ans (r7rs-vector-copy v start end)))
       (vector-merge-sort! < ans)
       ans))))


;;; %VECTOR-MERGE-SORT! is not exported.
;;; Preconditions:
;;;   V TEMP vectors
;;;   START END fixnums
;;;   START END legal indices for V and TEMP
;;; If these preconditions are ensured by the cover functions, you
;;; can safely change this code to use unsafe fixnum arithmetic and vector
;;; indexing ops, for *huge* speedup.

;;; This merge sort is "opportunistic" -- the leaves of the merge tree are
;;; contiguous runs of already sorted elements in the vector. In the best
;;; case -- an already sorted vector -- it runs in linear time. Worst case
;;; is still O(n lg n) time.

(define (%vector-merge-sort! elt< v0 l r temp0)
  (define (xor a b) (not (eq? a b)))

  ;; Merge v1[l,l+len1) and v2[l+len1,l+len1+len2) into target[l,l+len1+len2)
  ;; Merge left-to-right, so that TEMP may be either V1 or V2
  ;; (that this is OK takes a little bit of thought).
  ;; V2=TARGET? is true if V2 and TARGET are the same, which allows
  ;; merge to punt the final blit half of the time.
  
  (define (merge target v1 v2 l len1 len2 v2=target?)
    (letrec ((vblit (lambda (fromv j i end)    ; Blit FROMV[J,END) to TARGET[I,?]
		      (let lp ((j j) (i i))    ; J < END. The final copy.
			(vector-set! target i (vector-ref fromv j))
			(let ((j (+ j 1)))
			  (if (< j end) (lp j (+ i 1))))))))
  
      (let* ((r1 (+ l  len1))
	     (r2 (+ r1 len2)))
							; Invariants:
	(let lp ((n l)					; N is next index of 
		 (j l)   (x (vector-ref v1 l))		;   TARGET to write.   
		 (k r1)  (y (vector-ref v2 r1)))	; X = V1[J]          
	  (let ((n+1 (+ n 1)))				; Y = V2[K]          
	    (if (elt< y x)
		(let ((k (+ k 1)))
		  (vector-set! target n y)
		  (if (< k r2)
		      (lp n+1 j x k (vector-ref v2 k))
		      (vblit v1 j n+1 r1)))
		(let ((j (+ j 1)))
		  (vector-set! target n x)
		  (if (< j r1)
		      (lp n+1 j (vector-ref v1 j) k y)
		      (if (not v2=target?) (vblit v2 k n+1 r2))))))))))
  

  ;; Might hack GETRUN so that if the run is short it pads it out to length
  ;; 10 with insert sort...
  
  ;; Precondition: l < r.
  (define (getrun v l r)
    (let lp ((i (+ l 1))  (x (vector-ref v l)))
      (if (>= i r)
	  (- i l)
	  (let ((y (vector-ref v i)))
	    (if (elt< y x)
		(- i l)
		(lp (+ i 1) y))))))
  
  ;; RECUR: Sort V0[L,L+LEN) for some LEN where 0 < WANT <= LEN <= (R-L).
  ;;   That is, sort *at least* WANT elements in V0 starting at index L.
  ;;   May put the result into either V0[L,L+LEN) or TEMP0[L,L+LEN).
  ;;   Must not alter either vector outside this range.
  ;;   Return:
  ;;     - LEN -- the number of values we sorted
  ;;     - ANSVEC -- the vector holding the value
  ;;     - ANS=V0? -- tells if ANSVEC is V0 or TEMP
  ;;
  ;; LP: V[L,L+PFXLEN) holds a sorted prefix of V0.
  ;;     TEMP = if V = V0 then TEMP0 else V0. (I.e., TEMP is the other vec.)
  ;;     PFXLEN2 is a power of 2 <= PFXLEN.
  ;;     Solve RECUR's problem.
  (if (< l r) ; Don't try to sort an empty range.
      (call-with-values
       (lambda ()
	 (let recur ((l l) (want (- r l)))
	   (let ((len (- r l)))
	     (let lp ((pfxlen (getrun v0 l r)) (pfxlen2 1)
		      (v v0) (temp temp0)
		      (v=v0? #t))
	       (if (or (>= pfxlen want) (= pfxlen len))
		   (values pfxlen v v=v0?)
		   (let ((pfxlen2 (let lp ((j pfxlen2))
				    (let ((j*2 (+ j j)))
				      (if (<= j pfxlen) (lp j*2) j))))
			 (tail-len (- len pfxlen)))
		     ;; PFXLEN2 is now the largest power of 2 <= PFXLEN.
		     ;; (Just think of it as being roughly PFXLEN.)
		     (call-with-values
		      (lambda ()
			(recur (+ pfxlen l) pfxlen2))
		      (lambda (nr-len nr-vec nrvec=v0?)
			(merge temp v nr-vec l pfxlen nr-len
			       (xor nrvec=v0? v=v0?))
			(lp (+ pfxlen nr-len) (+ pfxlen2 pfxlen2)
			    temp v (not v=v0?))))))))))
       (lambda (ignored-len ignored-ansvec ansvec=v0?)
	 (if (not ansvec=v0?)
             (r7rs-vector-copy! v0 l temp0 l r))))))


;;; Copyright
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; This code is
;;;     Copyright (c) 1998 by Olin Shivers.
;;; The terms are: You may do as you please with this code, as long as
;;; you do not delete this notice or hold me responsible for any outcome
;;; related to its use.
;;;
;;; Blah blah blah. Don't you think source files should contain more lines
;;; of code than copyright notice?


;;; Code tuning & porting
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;; This code is *tightly* bummed as far as I can go in portable Scheme.
;;;
;;; The two internal primitives that do the real work can be converted to
;;; use unsafe vector-indexing and fixnum-specific arithmetic ops *if* you
;;; alter the four small cover functions to enforce the invariants. This should
;;; provide *big* speedups. In fact, all the code bumming I've done pretty
;;; much disappears in the noise unless you have a good compiler and also
;;; can dump the vector-index checks and generic arithmetic -- so I've really
;;; just set things up for you to exploit.
;;;
;;; The optional-arg parsing, defaulting, and error checking is done with a
;;; portable R4RS macro. But if your Scheme has a faster mechanism (e.g., 
;;; Chez), you should definitely port over to it. Note that argument defaulting
;;; and error-checking are interleaved -- you don't have to error-check 
;;; defaulted START/END args to see if they are fixnums that are legal vector
;;; indices for the corresponding vector, etc.