Mercurial > hg > xemacs-beta
view tests/automated/hash-table-tests.el @ 939:025200a2163c
[xemacs-hg @ 2002-07-31 07:23:39 by michaels]
2002-07-17 Marcus Crestani <crestani@informatik.uni-tuebingen.de>
Markus Kaltenbach <makalten@informatik.uni-tuebingen.de>
Mike Sperber <mike@xemacs.org>
configure flag to turn these changes on: --use-kkcc
First we added a dumpable flag to lrecord_implementation. It shows,
if the object is dumpable and should be processed by the dumper.
* lrecord.h (struct lrecord_implementation): added dumpable flag
(MAKE_LRECORD_IMPLEMENTATION): fitted the different makro definitions
to the new lrecord_implementation and their calls.
Then we changed mark_object, that it no longer needs a mark method for
those types that have pdump descritions.
* alloc.c:
(mark_object): If the object has a description, the new mark algorithm
is called, and the object is marked according to its description.
Otherwise it uses the mark method like before.
These procedures mark objects according to their descriptions. They
are modeled on the corresponding pdumper procedures.
(mark_with_description):
(get_indirect_count):
(structure_size):
(mark_struct_contents):
These procedures still call mark_object, this is needed while there are
Lisp_Objects without descriptions left.
We added pdump descriptions for many Lisp_Objects:
* extents.c: extent_auxiliary_description
* database.c: database_description
* gui.c: gui_item_description
* scrollbar.c: scrollbar_instance_description
* toolbar.c: toolbar_button_description
* event-stream.c: command_builder_description
* mule-charset.c: charset_description
* device-msw.c: devmode_description
* dialog-msw.c: mswindows_dialog_id_description
* eldap.c: ldap_description
* postgresql.c: pgconn_description
pgresult_description
* tooltalk.c: tooltalk_message_description
tooltalk_pattern_description
* ui-gtk.c: emacs_ffi_description
emacs_gtk_object_description
* events.c:
* events.h:
* event-stream.c:
* event-Xt.c:
* event-gtk.c:
* event-tty.c:
To write a pdump description for Lisp_Event, we converted every struct
in the union event to a Lisp_Object. So we created nine new
Lisp_Objects: Lisp_Key_Data, Lisp_Button_Data, Lisp_Motion_Data,
Lisp_Process_Data, Lisp_Timeout_Data, Lisp_Eval_Data,
Lisp_Misc_User_Data, Lisp_Magic_Data, Lisp_Magic_Eval_Data.
We also wrote makro selectors and mutators for the fields of the new
designed Lisp_Event and added everywhere these new abstractions.
We implemented XD_UNION support in (mark_with_description), so
we can describe exspecially console/device specific data with XD_UNION.
To describe with XD_UNION, we added a field to these objects, which
holds the variant type of the object. This field is initialized in
the appendant constructor. The variant is an integer, it has also to
be described in an description, if XD_UNION is used.
XD_UNION is used in following descriptions:
* console.c: console_description
(get_console_variant): returns the variant
(create_console): added variant initialization
* console.h (console_variant): the different console types
* console-impl.h (struct console): added enum console_variant contype
* device.c: device_description
(Fmake_device): added variant initialization
* device-impl.h (struct device): added enum console_variant devtype
* objects.c: image_instance_description
font_instance_description
(Fmake_color_instance): added variant initialization
(Fmake_font_instance): added variant initialization
* objects-impl.h (struct Lisp_Color_Instance): added color_instance_type
* objects-impl.h (struct Lisp_Font_Instance): added font_instance_type
* process.c: process_description
(make_process_internal): added variant initialization
* process.h (process_variant): the different process types
| author | michaels |
|---|---|
| date | Wed, 31 Jul 2002 07:23:39 +0000 |
| parents | 576fb035e263 |
| children | db7c7e251153 |
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;; Copyright (C) 1998 Free Software Foundation, Inc. ;; Author: Martin Buchholz <martin@xemacs.org> ;; Maintainer: Martin Buchholz <martin@xemacs.org> ;; Created: 1998 ;; Keywords: tests, database ;; This file is part of XEmacs. ;; XEmacs is free software; you can redistribute it and/or modify it ;; under the terms of the GNU General Public License as published by ;; the Free Software Foundation; either version 2, or (at your option) ;; any later version. ;; XEmacs is distributed in the hope that it will be useful, but ;; WITHOUT ANY WARRANTY; without even the implied warranty of ;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU ;; General Public License for more details. ;; You should have received a copy of the GNU General Public License ;; along with XEmacs; see the file COPYING. If not, write to the Free ;; Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA ;; 02111-1307, USA. ;;; Synched up with: Not in FSF. ;;; Commentary: ;;; Test hash tables implementation ;;; See test-harness.el (condition-case err (require 'test-harness) (file-error (when (and (boundp 'load-file-name) (stringp load-file-name)) (push (file-name-directory load-file-name) load-path) (require 'test-harness)))) ;; Test all combinations of make-hash-table keywords (dolist (test '(eq eql equal)) (dolist (size '(0 1 100)) (dolist (rehash-size '(1.1 9.9)) (dolist (rehash-threshold '(0.2 .9)) (dolist (weakness '(nil key value key-or-value key-and-value)) (dolist (data '(() (1 2) (1 2 3 4))) (let ((ht (make-hash-table :test test :size size :rehash-size rehash-size :rehash-threshold rehash-threshold :weakness weakness))) (Assert (equal ht (car (let ((print-readably t)) (read-from-string (prin1-to-string ht)))))) (Assert (eq test (hash-table-test ht))) (Assert (<= size (hash-table-size ht))) (Assert (eql rehash-size (hash-table-rehash-size ht))) (Assert (eql rehash-threshold (hash-table-rehash-threshold ht))) (Assert (eq weakness (hash-table-weakness ht)))))))))) (loop for (fun weakness) in '((make-hashtable nil) (make-weak-hashtable key-and-value) (make-key-weak-hashtable key) (make-value-weak-hashtable value)) do (Assert (eq weakness (hash-table-weakness (funcall fun 10))))) (loop for (type weakness) in '((non-weak nil) (weak key-and-value) (key-weak key) (value-weak value)) do (Assert (equal (make-hash-table :type type) (make-hash-table :weakness weakness)))) (Assert (not (equal (make-hash-table :weakness nil) (make-hash-table :weakness t)))) (let ((ht (make-hash-table :size 20 :rehash-threshold .75 :test 'eq)) (size 80)) (Assert (hashtablep ht)) (Assert (hash-table-p ht)) (Assert (eq 'eq (hash-table-test ht))) (Assert (eq 'non-weak (hash-table-type ht))) (Assert (eq 'non-weak (hashtable-type ht))) (Assert (eq 'nil (hash-table-weakness ht))) (dotimes (j size) (puthash j (- j) ht) (Assert (eq (gethash j ht) (- j))) (Assert (= (hash-table-count ht) (1+ j))) (Assert (= (hashtable-fullness ht) (hash-table-count ht))) (puthash j j ht) (Assert (eq (gethash j ht 'foo) j)) (Assert (= (hash-table-count ht) (1+ j))) (setf (gethash j ht) (- j)) (Assert (eq (gethash j ht) (- j))) (Assert (= (hash-table-count ht) (1+ j)))) (clrhash ht) (Assert (= 0 (hash-table-count ht))) (dotimes (j size) (puthash j (- j) ht) (Assert (eq (gethash j ht) (- j))) (Assert (= (hash-table-count ht) (1+ j)))) (let ((k-sum 0) (v-sum 0)) (maphash #'(lambda (k v) (incf k-sum k) (incf v-sum v)) ht) (print k-sum) (print v-sum) (Assert (= k-sum (/ (* size (- size 1)) 2))) (Assert (= v-sum (- k-sum)))) (let ((count size)) (dotimes (j size) (remhash j ht) (Assert (eq (gethash j ht) nil)) (Assert (eq (gethash j ht 'foo) 'foo)) (Assert (= (hash-table-count ht) (decf count)))))) (let ((ht (make-hash-table :size 30 :rehash-threshold .25 :test 'equal)) (size 70)) (Assert (hashtablep ht)) (Assert (hash-table-p ht)) (Assert (>= (hash-table-size ht) (/ 30 .25))) (Assert (eql .25 (hash-table-rehash-threshold ht))) (Assert (eq 'equal (hash-table-test ht))) (Assert (eq (hash-table-test ht) (hashtable-test-function ht))) (Assert (eq 'non-weak (hash-table-type ht))) (dotimes (j size) (puthash (int-to-string j) (- j) ht) (Assert (eq (gethash (int-to-string j) ht) (- j))) (Assert (= (hash-table-count ht) (1+ j))) (puthash (int-to-string j) j ht) (Assert (eq (gethash (int-to-string j) ht 'foo) j)) (Assert (= (hash-table-count ht) (1+ j)))) (clrhash ht) (Assert (= 0 (hash-table-count ht))) (Assert (equal ht (copy-hash-table ht))) (dotimes (j size) (setf (gethash (int-to-string j) ht) (- j)) (Assert (eq (gethash (int-to-string j) ht) (- j))) (Assert (= (hash-table-count ht) (1+ j)))) (let ((count size)) (dotimes (j size) (remhash (int-to-string j) ht) (Assert (eq (gethash (int-to-string j) ht) nil)) (Assert (eq (gethash (int-to-string j) ht 'foo) 'foo)) (Assert (= (hash-table-count ht) (decf count)))))) (let ((iterations 5) (one 1.0) (two 2.0)) (flet ((check-copy (ht) (let ((copy-of-ht (copy-hash-table ht))) (Assert (equal ht copy-of-ht)) (Assert (not (eq ht copy-of-ht))) (Assert (eq (hash-table-count ht) (hash-table-count copy-of-ht))) (Assert (eq (hash-table-type ht) (hash-table-type copy-of-ht))) (Assert (eq (hash-table-size ht) (hash-table-size copy-of-ht))) (Assert (eql (hash-table-rehash-size ht) (hash-table-rehash-size copy-of-ht))) (Assert (eql (hash-table-rehash-threshold ht) (hash-table-rehash-threshold copy-of-ht)))))) (let ((ht (make-hash-table :size 100 :rehash-threshold .6 :test 'eq))) (dotimes (j iterations) (puthash (+ one 0.0) t ht) (puthash (+ two 0.0) t ht) (puthash (cons 1 2) t ht) (puthash (cons 3 4) t ht)) (Assert (eq (hashtable-test-function ht) 'eq)) (Assert (eq (hash-table-test ht) 'eq)) (Assert (= (* iterations 4) (hash-table-count ht))) (Assert (eq nil (gethash 1.0 ht))) (Assert (eq nil (gethash '(1 . 2) ht))) (check-copy ht) ) (let ((ht (make-hash-table :size 100 :rehash-threshold .6 :test 'eql))) (dotimes (j iterations) (puthash (+ one 0.0) t ht) (puthash (+ two 0.0) t ht) (puthash (cons 1 2) t ht) (puthash (cons 3 4) t ht)) (Assert (eq (hashtable-test-function ht) 'eql)) (Assert (eq (hash-table-test ht) 'eql)) (Assert (= (+ 2 (* 2 iterations)) (hash-table-count ht))) (Assert (eq t (gethash 1.0 ht))) (Assert (eq nil (gethash '(1 . 2) ht))) (check-copy ht) ) (let ((ht (make-hash-table :size 100 :rehash-threshold .6 :test 'equal))) (dotimes (j iterations) (puthash (+ one 0.0) t ht) (puthash (+ two 0.0) t ht) (puthash (cons 1 2) t ht) (puthash (cons 3 4) t ht)) (Assert (eq (hashtable-test-function ht) 'equal)) (Assert (eq (hash-table-test ht) 'equal)) (Assert (= 4 (hash-table-count ht))) (Assert (eq t (gethash 1.0 ht))) (Assert (eq t (gethash '(1 . 2) ht))) (check-copy ht) ) )) ;; Test that weak hash-tables are properly handled (loop for (weakness expected-count expected-k-sum expected-v-sum) in '((nil 6 38 25) (t 3 6 9) (key 4 38 9) (value 4 6 25)) do (let* ((ht (make-hash-table :weakness weakness)) (my-obj (cons ht ht))) (garbage-collect) (puthash my-obj 1 ht) (puthash 2 my-obj ht) (puthash 4 8 ht) (puthash (cons ht ht) 16 ht) (puthash 32 (cons ht ht) ht) (puthash (cons ht ht) (cons ht ht) ht) (let ((k-sum 0) (v-sum 0)) (maphash #'(lambda (k v) (when (integerp k) (incf k-sum k)) (when (integerp v) (incf v-sum v))) ht) (Assert (eq 38 k-sum)) (Assert (eq 25 v-sum))) (Assert (eq 6 (hash-table-count ht))) (garbage-collect) (Assert (eq expected-count (hash-table-count ht))) (let ((k-sum 0) (v-sum 0)) (maphash #'(lambda (k v) (when (integerp k) (incf k-sum k)) (when (integerp v) (incf v-sum v))) ht) (Assert (eq expected-k-sum k-sum)) (Assert (eq expected-v-sum v-sum))))) ;;; Test the ability to puthash and remhash the current elt of a maphash (let ((ht (make-hash-table :test 'eql))) (dotimes (j 100) (setf (gethash j ht) (- j))) (maphash #'(lambda (k v) (if (oddp k) (remhash k ht) (puthash k (- v) ht))) ht) (let ((k-sum 0) (v-sum 0)) (maphash #'(lambda (k v) (incf k-sum k) (incf v-sum v)) ht) (Assert (= (* 50 49) k-sum)) (Assert (= v-sum k-sum)))) ;;; Test reading and printing of hash-table objects (let ((h1 #s(hashtable weakness t rehash-size 3.0 rehash-threshold .2 test eq data (1 2 3 4))) (h2 #s(hash-table weakness t rehash-size 3.0 rehash-threshold .2 test eq data (1 2 3 4))) (h3 (make-hash-table :weakness t :rehash-size 3.0 :rehash-threshold .2 :test 'eq))) (Assert (equal h1 h2)) (Assert (not (equal h1 h3))) (puthash 1 2 h3) (puthash 3 4 h3) (Assert (equal h1 h3))) ;;; Testing equality of hash tables (Assert (equal (make-hash-table :test 'eql :size 300 :rehash-threshold .9 :rehash-size 3.0) (make-hash-table :test 'eql))) (Assert (not (equal (make-hash-table :test 'eq) (make-hash-table :test 'equal)))) (let ((h1 (make-hash-table)) (h2 (make-hash-table))) (Assert (equal h1 h2)) (Assert (not (eq h1 h2))) (puthash 1 2 h1) (Assert (not (equal h1 h2))) (puthash 1 2 h2) (Assert (equal h1 h2)) (puthash 1 3 h2) (Assert (not (equal h1 h2))) (clrhash h1) (Assert (not (equal h1 h2))) (clrhash h2) (Assert (equal h1 h2)) ) ;;; Test sxhash (Assert (= (sxhash "foo") (sxhash "foo"))) (Assert (= (sxhash '(1 2 3)) (sxhash '(1 2 3))))