3 ;;;; This software is part of the SBCL system. See the README file for
6 ;;;; This software is derived from the CMU CL system, which was
7 ;;;; written at Carnegie Mellon University and released into the
8 ;;;; public domain. The software is in the public domain and is
9 ;;;; provided with absolutely no warranty. See the COPYING and CREDITS
10 ;;;; files for more information.
12 (in-package "SB!IMPL")
14 ;;; the depthoid explored when calculating hash values
16 ;;; "Depthoid" here is a sort of mixture of what Common Lisp ordinarily calls
17 ;;; depth and what Common Lisp ordinarily calls length; it's incremented either
18 ;;; when we descend into a compound object or when we step through elements of
19 ;;; a compound object.
20 (defconstant +max-hash-depthoid+ 4)
22 ;;;; mixing hash values
24 ;;; a function for mixing hash values
27 ;;; * Non-commutativity keeps us from hashing e.g. #(1 5) to the
28 ;;; same value as #(5 1), and ending up in real trouble in some
29 ;;; special cases like bit vectors the way that CMUCL 18b SXHASH
30 ;;; does. (Under CMUCL 18b, SXHASH of any bit vector is 1..)
31 ;;; * We'd like to scatter our hash values over the entire possible range
32 ;;; of values instead of hashing small or common key values (like
33 ;;; 2 and NIL and #\a) to small FIXNUMs the way that the CMUCL 18b
34 ;;; SXHASH function does, again helping to avoid pathologies like
35 ;;; hashing all bit vectors to 1.
36 ;;; * We'd like this to be simple and fast, too.
38 ;;; FIXME: Should this be INLINE?
39 (declaim (ftype (function ((and fixnum unsigned-byte)
40 (and fixnum unsigned-byte))
41 (and fixnum unsigned-byte)) mix))
43 ;; FIXME: We wouldn't need the nasty (SAFETY 0) here if the compiler
44 ;; were smarter about optimizing ASH. (Without the THE FIXNUM below,
45 ;; and the (SAFETY 0) declaration here to get the compiler to trust
46 ;; it, the sbcl-0.5.0m cross-compiler running under Debian
47 ;; cmucl-2.4.17 turns the ASH into a full call, requiring the
48 ;; UNSIGNED-BYTE 32 argument to be coerced to a bignum, requiring
49 ;; consing, and thus generally obliterating performance.)
50 (declare (optimize (speed 3) (safety 0)))
51 (declare (type (and fixnum unsigned-byte) x y))
53 ;; * Bits diffuse in both directions (shifted left by up to 2 places
54 ;; in the calculation of XY, and shifted right by up to 5 places
56 ;; * The #'+ and #'LOGXOR operations don't commute with each other,
57 ;; so different bit patterns are mixed together as they shift
59 ;; * The arbitrary constant in the #'LOGXOR expression is intended
60 ;; to help break up any weird anomalies we might otherwise get
61 ;; when hashing highly regular patterns.
62 ;; (These are vaguely like the ideas used in many cryptographic
63 ;; algorithms, but we're not pushing them hard enough here for them
64 ;; to be cryptographically strong.)
65 (let* ((xy (+ (* x 3) y)))
66 (declare (type (unsigned-byte 32) xy))
67 (the (and fixnum unsigned-byte)
68 (logand most-positive-fixnum
71 (the fixnum (ash xy -5)))))))
75 ;;;; Note that this operation is used in compiler symbol table lookups, so we'd
76 ;;;; like it to be fast.
78 #!-sb-fluid (declaim (inline %sxhash-substring))
79 (defun %sxhash-substring (string &optional (count (length string)))
80 ;; FIXME: As in MIX above, we wouldn't need (SAFETY 0) here if the
81 ;; cross-compiler were smarter about ASH, but we need it for sbcl-0.5.0m.
82 (declare (optimize (speed 3) (safety 0)))
83 (declare (type string string))
84 (declare (type index count))
85 (let ((result 408967240))
86 (declare (type fixnum result))
88 (declare (type index i))
91 (ash (char-code (aref string i)) 5))))
94 ;;; (let ((ht (make-hash-table :test 'equal)))
95 ;;; (do-all-symbols (symbol)
96 ;;; (let* ((string (symbol-name symbol))
97 ;;; (hash (%sxhash-substring string)))
98 ;;; (if (gethash hash ht)
99 ;;; (unless (string= (gethash hash ht) string)
100 ;;; (format t "collision: ~S ~S~%" string (gethash hash ht)))
101 ;;; (setf (gethash hash ht) string))))
102 ;;; (format t "final count=~W~%" (hash-table-count ht)))
104 (defun %sxhash-simple-string (x)
105 (declare (optimize speed))
106 (declare (type simple-string x))
107 (%sxhash-substring x))
109 (defun %sxhash-simple-substring (x count)
110 (declare (optimize speed))
111 (declare (type simple-string x))
112 (declare (type index count))
113 (%sxhash-substring x count))
115 ;;;; the SXHASH function
118 ;; profiling SXHASH is hard, but we might as well try to make it go
119 ;; fast, in case it is the bottleneck somwhere. -- CSR, 2003-03-14
120 (declare (optimize speed))
121 (labels ((sxhash-number (x)
123 (fixnum (sxhash x)) ; through DEFTRANSFORM
124 (integer (sb!bignum:sxhash-bignum x))
125 (single-float (sxhash x)) ; through DEFTRANSFORM
126 (double-float (sxhash x)) ; through DEFTRANSFORM
127 #!+long-float (long-float (error "stub: no LONG-FLOAT"))
128 (ratio (let ((result 127810327))
129 (declare (type fixnum result))
130 (mixf result (sxhash-number (numerator x)))
131 (mixf result (sxhash-number (denominator x)))
133 (complex (let ((result 535698211))
134 (declare (type fixnum result))
135 (mixf result (sxhash-number (realpart x)))
136 (mixf result (sxhash-number (imagpart x)))
138 (sxhash-recurse (x &optional (depthoid +max-hash-depthoid+))
139 (declare (type index depthoid))
143 (mix (sxhash-recurse (car x) (1- depthoid))
144 (sxhash-recurse (cdr x) (1- depthoid)))
147 (if (or (typep x 'structure-object) (typep x 'condition))
149 (sxhash ; through DEFTRANSFORM
151 (layout-classoid (%instance-layout x)))))
152 (sxhash-instance x)))
153 (symbol (sxhash x)) ; through DEFTRANSFORM
156 (simple-string (sxhash x)) ; through DEFTRANSFORM
157 (string (%sxhash-substring x))
158 (simple-bit-vector (sxhash x)) ; through DEFTRANSFORM
160 ;; FIXME: It must surely be possible to do better
161 ;; than this. The problem is that a non-SIMPLE
162 ;; BIT-VECTOR could be displaced to another, with a
163 ;; non-zero offset -- so that significantly more
164 ;; work needs to be done using the %RAW-BITS
165 ;; approach. This will probably do for now.
166 (sxhash-recurse (copy-seq x) depthoid))
167 (t (logxor 191020317 (sxhash (array-rank x))))))
170 (sxhash (char-code x)))) ; through DEFTRANSFORM
171 ;; general, inefficient case of NUMBER
172 (number (sxhash-number x))
173 (generic-function (sxhash-instance x))
177 ;;;; the PSXHASH function
179 ;;;; FIXME: This code does a lot of unnecessary full calls. It could be made
180 ;;;; more efficient (in both time and space) by rewriting it along the lines
181 ;;;; of the SXHASH code above.
183 ;;; like SXHASH, but for EQUALP hashing instead of EQUAL hashing
184 (defun psxhash (key &optional (depthoid +max-hash-depthoid+))
185 (declare (optimize speed))
186 (declare (type (integer 0 #.+max-hash-depthoid+) depthoid))
187 ;; Note: You might think it would be cleaner to use the ordering given in the
188 ;; table from Figure 5-13 in the EQUALP section of the ANSI specification
189 ;; here. So did I, but that is a snare for the unwary! Nothing in the ANSI
190 ;; spec says that HASH-TABLE can't be a STRUCTURE-OBJECT, and in fact our
191 ;; HASH-TABLEs *are* STRUCTURE-OBJECTs, so we need to pick off the special
192 ;; HASH-TABLE behavior before we fall through to the generic STRUCTURE-OBJECT
193 ;; comparison behavior.
195 (array (array-psxhash key depthoid))
196 (hash-table (hash-table-psxhash key))
197 (structure-object (structure-object-psxhash key depthoid))
198 (cons (list-psxhash key depthoid))
199 (number (number-psxhash key))
200 (character (sxhash (char-upcase key)))
203 (defun array-psxhash (key depthoid)
204 (declare (optimize speed))
205 (declare (type array key))
206 (declare (type (integer 0 #.+max-hash-depthoid+) depthoid))
208 ;; VECTORs have to be treated specially because ANSI specifies
209 ;; that we must respect fill pointers.
212 '(let ((result 572539))
213 (declare (type fixnum result))
214 (mixf result (length key))
215 (dotimes (i (min depthoid (length key)))
216 (declare (type fixnum i))
218 (psxhash (aref key i)
221 ;; CMU can compile SIMPLE-ARRAY operations so much more efficiently
222 ;; than the general case that it's probably worth picking off the
223 ;; common special cases.
226 ;;(format t "~&SIMPLE-STRING special case~%")
229 ;;(format t "~&SIMPLE-VECTOR special case~%")
232 ;; Any other array can be hashed by working with its underlying
233 ;; one-dimensional physical representation.
235 (let ((result 60828))
236 (declare (type fixnum result))
237 (dotimes (i (min depthoid (array-rank key)))
238 (mixf result (array-dimension key i)))
239 (dotimes (i (min depthoid (array-total-size key)))
241 (psxhash (row-major-aref key i)
245 (defun structure-object-psxhash (key depthoid)
246 (declare (optimize speed))
247 (declare (type structure-object key))
248 (declare (type (integer 0 #.+max-hash-depthoid+) depthoid))
249 (let* ((layout (%instance-layout key)) ; i.e. slot #0
250 (length (layout-length layout))
251 (classoid (layout-classoid layout))
252 (name (classoid-name classoid))
253 (result (mix (sxhash name) (the fixnum 79867))))
254 (declare (type fixnum result))
255 (dotimes (i (min depthoid (1- length)))
256 (declare (type fixnum i))
257 (let ((j (1+ i))) ; skipping slot #0, which is for LAYOUT
258 (declare (type fixnum j))
260 (psxhash (%instance-ref key j)
264 (defun list-psxhash (key depthoid)
265 (declare (optimize speed))
266 (declare (type list key))
267 (declare (type (integer 0 #.+max-hash-depthoid+) depthoid))
273 (mix (psxhash (car key) (1- depthoid))
274 (psxhash (cdr key) (1- depthoid))))))
276 (defun hash-table-psxhash (key)
277 (declare (optimize speed))
278 (declare (type hash-table key))
279 (let ((result 103924836))
280 (declare (type fixnum result))
281 (mixf result (hash-table-count key))
282 (mixf result (sxhash (hash-table-test key)))
285 (defun number-psxhash (key)
286 (declare (optimize speed))
287 (declare (type number key))
288 (flet ((sxhash-double-float (val)
289 (declare (type double-float val))
290 ;; FIXME: Check to make sure that the DEFTRANSFORM kicks in and the
291 ;; resulting code works without consing. (In Debian cmucl 2.4.17,
295 (integer (sxhash key))
296 (float (macrolet ((frob (type)
297 (let ((lo (coerce most-negative-fixnum type))
298 (hi (coerce most-positive-fixnum type)))
299 `(cond (;; This clause allows FIXNUM-sized integer
300 ;; values to be handled without consing.
302 (multiple-value-bind (q r)
303 (floor (the (,type ,lo ,hi) key))
304 (if (zerop (the ,type r))
307 (coerce key 'double-float)))))
309 (multiple-value-bind (q r) (floor key)
310 (if (zerop (the ,type r))
313 (coerce key 'double-float)))))))))
315 (single-float (frob single-float))
316 (double-float (frob double-float))
318 (long-float (error "LONG-FLOAT not currently supported")))))
319 (rational (if (and (<= most-negative-double-float
321 most-positive-double-float)
322 (= (coerce key 'double-float) key))
323 (sxhash-double-float (coerce key 'double-float))
325 (complex (if (zerop (imagpart key))
326 (number-psxhash (realpart key))
327 (let ((result 330231))
328 (declare (type fixnum result))
329 (mixf result (number-psxhash (realpart key)))
330 (mixf result (number-psxhash (imagpart key)))