зеркало из https://github.com/mozilla/gecko-dev.git
397 строки
12 KiB
C++
397 строки
12 KiB
C++
/* -*- Mode: C; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*-
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*
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* The contents of this file are subject to the Netscape Public
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* License Version 1.1 (the "License"); you may not use this file
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* except in compliance with the License. You may obtain a copy of
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* the License at http://www.mozilla.org/NPL/
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*
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* Software distributed under the License is distributed on an "AS
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* IS" basis, WITHOUT WARRANTY OF ANY KIND, either express or
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* implied. See the License for the specific language governing
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* rights and limitations under the License.
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*
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* The Original Code is mozilla.org code.
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*
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* The Initial Developer of the Original Code is Netscape
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* Communications Corporation. Portions created by Netscape are
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* Copyright (C) 1998 Netscape Communications Corporation. All
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* Rights Reserved.
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*
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* Contributor(s):
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*/
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/*
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* The purpose of this file is to help phase out XP_ library
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* from the image library. In general, XP_ data structures and
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* functions will be replaced with the PR_ or PL_ equivalents.
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* In cases where the PR_ or PL_ equivalents don't yet exist,
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* this file (and its header equivalent) will play the role
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* of the XP_ library.
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*/
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/* This file has func's from
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xpcompat that are needed by
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the local dll. So far,
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1> Mac stuff.
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*/
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#include "prtypes.h"
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#include "prlog.h"
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#include "prmem.h"
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#include "nsCRT.h"
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//#include "xp_mcom.h"
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PR_BEGIN_EXTERN_C
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int MK_UNABLE_TO_LOCATE_FILE = -1;
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int MK_OUT_OF_MEMORY = -2;
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PR_END_EXTERN_C
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#if defined(XP_MAC)
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#ifndef UNIXMINUSMACTIME
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#define UNIXMINUSMACTIME 2082844800UL
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#endif
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/* prototypes for local routines */
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static void shortsort(char *lo, char *hi, unsigned width,
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int ( *comp)(const void *, const void *));
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static void swap(char *p, char *q, unsigned int width);
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/* this parameter defines the cutoff between using quick sort and
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insertion sort for arrays; arrays with lengths shorter or equal to the
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below value use insertion sort */
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#define CUTOFF 8 /* testing shows that this is good value */
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/***
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*XP_QSORT(base, num, wid, comp) - quicksort function for sorting arrays
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*
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*Purpose:
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* quicksort the array of elements
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* side effects: sorts in place
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*
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*Entry:
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* char *base = pointer to base of array
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* unsigned num = number of elements in the array
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* unsigned width = width in bytes of each array element
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* int (*comp)() = pointer to function returning analog of strcmp for
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* strings, but supplied by user for comparing the array elements.
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* it accepts 2 pointers to elements and returns neg if 1<2, 0 if
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* 1=2, pos if 1>2.
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*
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*Exit:
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* returns void
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*
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*Exceptions:
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*
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*******************************************************************************/
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/* sort the array between lo and hi (inclusive) */
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void XP_QSORT (
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void *base,
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size_t num,
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size_t width,
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int ( *comp)(const void *, const void *)
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)
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{
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char *lo, *hi; /* ends of sub-array currently sorting */
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char *mid; /* points to middle of subarray */
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char *loguy, *higuy; /* traveling pointers for partition step */
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unsigned size; /* size of the sub-array */
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char *lostk[30], *histk[30];
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int stkptr; /* stack for saving sub-array to be processed */
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/* Note: the number of stack entries required is no more than
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1 + log2(size), so 30 is sufficient for any array */
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if (num < 2 || width == 0)
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return; /* nothing to do */
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stkptr = 0; /* initialize stack */
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lo = (char*)base;
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hi = (char *)base + width * (num-1); /* initialize limits */
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/* this entry point is for pseudo-recursion calling: setting
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lo and hi and jumping to here is like recursion, but stkptr is
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prserved, locals aren't, so we preserve stuff on the stack */
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recurse:
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size = (hi - lo) / width + 1; /* number of el's to sort */
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/* below a certain size, it is faster to use a O(n^2) sorting method */
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if (size <= CUTOFF) {
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shortsort(lo, hi, width, comp);
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}
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else {
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/* First we pick a partititioning element. The efficiency of the
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algorithm demands that we find one that is approximately the
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median of the values, but also that we select one fast. Using
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the first one produces bad performace if the array is already
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sorted, so we use the middle one, which would require a very
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wierdly arranged array for worst case performance. Testing shows
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that a median-of-three algorithm does not, in general, increase
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performance. */
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mid = lo + (size / 2) * width; /* find middle element */
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swap(mid, lo, width); /* swap it to beginning of array */
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/* We now wish to partition the array into three pieces, one
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consisiting of elements <= partition element, one of elements
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equal to the parition element, and one of element >= to it. This
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is done below; comments indicate conditions established at every
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step. */
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loguy = lo;
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higuy = hi + width;
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/* Note that higuy decreases and loguy increases on every iteration,
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so loop must terminate. */
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for (;;) {
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/* lo <= loguy < hi, lo < higuy <= hi + 1,
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A[i] <= A[lo] for lo <= i <= loguy,
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A[i] >= A[lo] for higuy <= i <= hi */
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do {
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loguy += width;
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} while (loguy <= hi && comp(loguy, lo) <= 0);
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/* lo < loguy <= hi+1, A[i] <= A[lo] for lo <= i < loguy,
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either loguy > hi or A[loguy] > A[lo] */
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do {
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higuy -= width;
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} while (higuy > lo && comp(higuy, lo) >= 0);
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/* lo-1 <= higuy <= hi, A[i] >= A[lo] for higuy < i <= hi,
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either higuy <= lo or A[higuy] < A[lo] */
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if (higuy < loguy)
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break;
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/* if loguy > hi or higuy <= lo, then we would have exited, so
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A[loguy] > A[lo], A[higuy] < A[lo],
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loguy < hi, highy > lo */
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swap(loguy, higuy, width);
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/* A[loguy] < A[lo], A[higuy] > A[lo]; so condition at top
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of loop is re-established */
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}
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/* A[i] >= A[lo] for higuy < i <= hi,
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A[i] <= A[lo] for lo <= i < loguy,
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higuy < loguy, lo <= higuy <= hi
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implying:
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A[i] >= A[lo] for loguy <= i <= hi,
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A[i] <= A[lo] for lo <= i <= higuy,
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A[i] = A[lo] for higuy < i < loguy */
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swap(lo, higuy, width); /* put partition element in place */
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/* OK, now we have the following:
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A[i] >= A[higuy] for loguy <= i <= hi,
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A[i] <= A[higuy] for lo <= i < higuy
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A[i] = A[lo] for higuy <= i < loguy */
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/* We've finished the partition, now we want to sort the subarrays
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[lo, higuy-1] and [loguy, hi].
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We do the smaller one first to minimize stack usage.
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We only sort arrays of length 2 or more.*/
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if ( higuy - 1 - lo >= hi - loguy ) {
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if (lo + width < higuy) {
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lostk[stkptr] = lo;
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histk[stkptr] = higuy - width;
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++stkptr;
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} /* save big recursion for later */
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if (loguy < hi) {
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lo = loguy;
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goto recurse; /* do small recursion */
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}
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}
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else {
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if (loguy < hi) {
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lostk[stkptr] = loguy;
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histk[stkptr] = hi;
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++stkptr; /* save big recursion for later */
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}
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if (lo + width < higuy) {
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hi = higuy - width;
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goto recurse; /* do small recursion */
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}
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}
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}
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/* We have sorted the array, except for any pending sorts on the stack.
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Check if there are any, and do them. */
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--stkptr;
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if (stkptr >= 0) {
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lo = lostk[stkptr];
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hi = histk[stkptr];
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goto recurse; /* pop subarray from stack */
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}
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else
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return; /* all subarrays done */
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}
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/***
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*shortsort(hi, lo, width, comp) - insertion sort for sorting short arrays
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*
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*Purpose:
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* sorts the sub-array of elements between lo and hi (inclusive)
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* side effects: sorts in place
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* assumes that lo < hi
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*
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*Entry:
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* char *lo = pointer to low element to sort
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* char *hi = pointer to high element to sort
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* unsigned width = width in bytes of each array element
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* int (*comp)() = pointer to function returning analog of strcmp for
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* strings, but supplied by user for comparing the array elements.
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* it accepts 2 pointers to elements and returns neg if 1<2, 0 if
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* 1=2, pos if 1>2.
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*
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*Exit:
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* returns void
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*
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*Exceptions:
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*
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*******************************************************************************/
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static void shortsort (
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char *lo,
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char *hi,
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unsigned width,
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int ( *comp)(const void *, const void *)
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)
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{
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char *p, *max;
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/* Note: in assertions below, i and j are alway inside original bound of
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array to sort. */
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while (hi > lo) {
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/* A[i] <= A[j] for i <= j, j > hi */
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max = lo;
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for (p = lo+width; p <= hi; p += width) {
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/* A[i] <= A[max] for lo <= i < p */
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if (comp(p, max) > 0) {
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max = p;
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}
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/* A[i] <= A[max] for lo <= i <= p */
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}
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/* A[i] <= A[max] for lo <= i <= hi */
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swap(max, hi, width);
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/* A[i] <= A[hi] for i <= hi, so A[i] <= A[j] for i <= j, j >= hi */
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hi -= width;
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/* A[i] <= A[j] for i <= j, j > hi, loop top condition established */
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}
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/* A[i] <= A[j] for i <= j, j > lo, which implies A[i] <= A[j] for i < j,
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so array is sorted */
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}
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/***
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*swap(a, b, width) - swap two elements
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*
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*Purpose:
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* swaps the two array elements of size width
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*
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*Entry:
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* char *a, *b = pointer to two elements to swap
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* unsigned width = width in bytes of each array element
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*
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*Exit:
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* returns void
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*
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*Exceptions:
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*
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*******************************************************************************/
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static void swap (
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char *a,
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char *b,
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unsigned width
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)
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{
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char tmp;
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if ( a != b )
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/* Do the swap one character at a time to avoid potential alignment
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problems. */
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while ( width-- ) {
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tmp = *a;
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*a++ = *b;
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*b++ = tmp;
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}
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}
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#endif /* XP_MAC */
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#ifdef XP_MAC
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#include <OSUtils.h>
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#include <time.h>
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static void MyReadLocation(MachineLocation * loc)
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{
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static MachineLocation storedLoc; // InsideMac, OSUtilities, page 4-20
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static Boolean didReadLocation = FALSE;
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if (!didReadLocation)
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{
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ReadLocation(&storedLoc);
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didReadLocation = TRUE;
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}
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*loc = storedLoc;
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}
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// current local time = GMTDelta() + GMT
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// GMT = local time - GMTDelta()
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static long GMTDelta()
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{
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MachineLocation loc;
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long gmtDelta;
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MyReadLocation(&loc);
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gmtDelta = loc.u.gmtDelta & 0x00FFFFFF;
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if ((gmtDelta & 0x00800000) != 0)
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gmtDelta |= 0xFF000000;
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return gmtDelta;
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}
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// This routine simulates stdclib time(), time in seconds since 1.1.1970
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// The time is in GMT
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time_t GetTimeMac()
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{
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unsigned long maclocal;
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// Get Mac local time
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GetDateTime(&maclocal);
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// Get Mac GMT
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maclocal -= GMTDelta();
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// return unix GMT
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return (maclocal - UNIXMINUSMACTIME);
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}
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// Returns the GMT times
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time_t Mactime(time_t *timer)
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{
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time_t t = GetTimeMac();
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if (timer != NULL)
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*timer = t;
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return t;
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}
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#endif /* XP_MAC */
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