源码库源码
数据库并不是都一样
数据库不是源码的,而是可以独立使用的
数据库分access mysql mssql 等等常见的几种
怎么连接需要看你的程序 需要什么库
不同的库有不同的链接
一般程序代码中都写好了代码 你只需要修改数据库的账户密码
为你自己的密码信息就可以了
这个只有你知道
或者你告诉别人登录查询
‘贰’ 如何看c语言标准库函数的源代码
1、首先标准只是规定了这些函数的接口和具体的运行效率的要求,这些函数具体是怎么写得要看各个编译器的实现和平台。
2、例如使用的编译器是visual studio,微软提供了一部分C运行时(CRT)的源码,里面会有memcpy,strcpy之类的函数的实现,在visual studio 2005下的路径是C:Program FilesMicrosoft Visual Studio 8VCcrtsrc。
‘叁’ 组件库源码怎么运行不了
文件有问题。组件库是指MinUI组件库,是一款工具类型的小程序,其源码运行不了的原因是文件有问题,重新下载一遍文件即可解决。源码指源代码,是指未编译的按照一定的程序设计语言规范书写的文本文件,是一系列人类可读的计算机语言指令。
‘肆’ c库函数源码
不是你表达不清,也许只是你根本不想仔细看一睛VC下面目录的源码,事实上就是有的。后附其中的qsort.c,以证明所言不虚。
VC的库是提供源码的,这东西也不值钱。
X:\Program Files\Microsoft Visual Studio\VCXX\CRT\SRC
注意有些可能本身是用汇编写的。
/***
*qsort.c - quicksort algorithm; qsort() library function for sorting arrays
*
* Copyright (c) 1985-1997, Microsoft Corporation. All rights reserved.
*
*Purpose:
* To implement the qsort() routine for sorting arrays.
*
*******************************************************************************/
#include <cruntime.h>
#include <stdlib.h>
#include <search.h>
/* prototypes for local routines */
static void __cdecl shortsort(char *lo, char *hi, unsigned width,
int (__cdecl *comp)(const void *, const void *));
static void __cdecl swap(char *p, char *q, unsigned int width);
/* this parameter defines the cutoff between using quick sort and
insertion sort for arrays; arrays with lengths shorter or equal to the
below value use insertion sort */
#define CUTOFF 8 /* testing shows that this is good value */
/***
*qsort(base, num, wid, comp) - quicksort function for sorting arrays
*
*Purpose:
* quicksort the array of elements
* side effects: sorts in place
*
*Entry:
* char *base = pointer to base of array
* unsigned num = number of elements in the array
* unsigned width = width in bytes of each array element
* int (*comp)() = pointer to function returning analog of strcmp for
* strings, but supplied by user for comparing the array elements.
* it accepts 2 pointers to elements and returns neg if 1<2, 0 if
* 1=2, pos if 1>2.
*
*Exit:
* returns void
*
*Exceptions:
*
*******************************************************************************/
/* sort the array between lo and hi (inclusive) */
void __cdecl qsort (
void *base,
unsigned num,
unsigned width,
int (__cdecl *comp)(const void *, const void *)
)
{
char *lo, *hi; /* ends of sub-array currently sorting */
char *mid; /* points to middle of subarray */
char *loguy, *higuy; /* traveling pointers for partition step */
unsigned size; /* size of the sub-array */
char *lostk[30], *histk[30];
int stkptr; /* stack for saving sub-array to be processed */
/* Note: the number of stack entries required is no more than
1 + log2(size), so 30 is sufficient for any array */
if (num < 2 || width == 0)
return; /* nothing to do */
stkptr = 0; /* initialize stack */
lo = base;
hi = (char *)base + width * (num-1); /* initialize limits */
/* this entry point is for pseudo-recursion calling: setting
lo and hi and jumping to here is like recursion, but stkptr is
prserved, locals aren't, so we preserve stuff on the stack */
recurse:
size = (hi - lo) / width + 1; /* number of el's to sort */
/* below a certain size, it is faster to use a O(n^2) sorting method */
if (size <= CUTOFF) {
shortsort(lo, hi, width, comp);
}
else {
/* First we pick a partititioning element. The efficiency of the
algorithm demands that we find one that is approximately the
median of the values, but also that we select one fast. Using
the first one proces bad performace if the array is already
sorted, so we use the middle one, which would require a very
wierdly arranged array for worst case performance. Testing shows
that a median-of-three algorithm does not, in general, increase
performance. */
mid = lo + (size / 2) * width; /* find middle element */
swap(mid, lo, width); /* swap it to beginning of array */
/* We now wish to partition the array into three pieces, one
consisiting of elements <= partition element, one of elements
equal to the parition element, and one of element >= to it. This
is done below; comments indicate conditions established at every
step. */
loguy = lo;
higuy = hi + width;
/* Note that higuy decreases and loguy increases on every iteration,
so loop must terminate. */
for (;;) {
/* lo <= loguy < hi, lo < higuy <= hi + 1,
A[i] <= A[lo] for lo <= i <= loguy,
A[i] >= A[lo] for higuy <= i <= hi */
do {
loguy += width;
} while (loguy <= hi && comp(loguy, lo) <= 0);
/* lo < loguy <= hi+1, A[i] <= A[lo] for lo <= i < loguy,
either loguy > hi or A[loguy] > A[lo] */
do {
higuy -= width;
} while (higuy > lo && comp(higuy, lo) >= 0);
/* lo-1 <= higuy <= hi, A[i] >= A[lo] for higuy < i <= hi,
either higuy <= lo or A[higuy] < A[lo] */
if (higuy < loguy)
break;
/* if loguy > hi or higuy <= lo, then we would have exited, so
A[loguy] > A[lo], A[higuy] < A[lo],
loguy < hi, highy > lo */
swap(loguy, higuy, width);
/* A[loguy] < A[lo], A[higuy] > A[lo]; so condition at top
of loop is re-established */
}
/* A[i] >= A[lo] for higuy < i <= hi,
A[i] <= A[lo] for lo <= i < loguy,
higuy < loguy, lo <= higuy <= hi
implying:
A[i] >= A[lo] for loguy <= i <= hi,
A[i] <= A[lo] for lo <= i <= higuy,
A[i] = A[lo] for higuy < i < loguy */
swap(lo, higuy, width); /* put partition element in place */
/* OK, now we have the following:
A[i] >= A[higuy] for loguy <= i <= hi,
A[i] <= A[higuy] for lo <= i < higuy
A[i] = A[lo] for higuy <= i < loguy */
/* We've finished the partition, now we want to sort the subarrays
[lo, higuy-1] and [loguy, hi].
We do the smaller one first to minimize stack usage.
We only sort arrays of length 2 or more.*/
if ( higuy - 1 - lo >= hi - loguy ) {
if (lo + width < higuy) {
lostk[stkptr] = lo;
histk[stkptr] = higuy - width;
++stkptr;
} /* save big recursion for later */
if (loguy < hi) {
lo = loguy;
goto recurse; /* do small recursion */
}
}
else {
if (loguy < hi) {
lostk[stkptr] = loguy;
histk[stkptr] = hi;
++stkptr; /* save big recursion for later */
}
if (lo + width < higuy) {
hi = higuy - width;
goto recurse; /* do small recursion */
}
}
}
/* We have sorted the array, except for any pending sorts on the stack.
Check if there are any, and do them. */
--stkptr;
if (stkptr >= 0) {
lo = lostk[stkptr];
hi = histk[stkptr];
goto recurse; /* pop subarray from stack */
}
else
return; /* all subarrays done */
}
/***
*shortsort(hi, lo, width, comp) - insertion sort for sorting short arrays
*
*Purpose:
* sorts the sub-array of elements between lo and hi (inclusive)
* side effects: sorts in place
* assumes that lo < hi
*
*Entry:
* char *lo = pointer to low element to sort
* char *hi = pointer to high element to sort
* unsigned width = width in bytes of each array element
* int (*comp)() = pointer to function returning analog of strcmp for
* strings, but supplied by user for comparing the array elements.
* it accepts 2 pointers to elements and returns neg if 1<2, 0 if
* 1=2, pos if 1>2.
*
*Exit:
* returns void
*
*Exceptions:
*
*******************************************************************************/
static void __cdecl shortsort (
char *lo,
char *hi,
unsigned width,
int (__cdecl *comp)(const void *, const void *)
)
{
char *p, *max;
/* Note: in assertions below, i and j are alway inside original bound of
array to sort. */
while (hi > lo) {
/* A[i] <= A[j] for i <= j, j > hi */
max = lo;
for (p = lo+width; p <= hi; p += width) {
/* A[i] <= A[max] for lo <= i < p */
if (comp(p, max) > 0) {
max = p;
}
/* A[i] <= A[max] for lo <= i <= p */
}
/* A[i] <= A[max] for lo <= i <= hi */
swap(max, hi, width);
/* A[i] <= A[hi] for i <= hi, so A[i] <= A[j] for i <= j, j >= hi */
hi -= width;
/* A[i] <= A[j] for i <= j, j > hi, loop top condition established */
}
/* A[i] <= A[j] for i <= j, j > lo, which implies A[i] <= A[j] for i < j,
so array is sorted */
}
/***
*swap(a, b, width) - swap two elements
*
*Purpose:
* swaps the two array elements of size width
*
*Entry:
* char *a, *b = pointer to two elements to swap
* unsigned width = width in bytes of each array element
*
*Exit:
* returns void
*
*Exceptions:
*
*******************************************************************************/
static void __cdecl swap (
char *a,
char *b,
unsigned width
)
{
char tmp;
if ( a != b )
/* Do the swap one character at a time to avoid potential alignment
problems. */
while ( width-- ) {
tmp = *a;
*a++ = *b;
*b++ = tmp;
}
}
‘伍’ 源码数据库是什么
源码数据库应该是为了实现版本控制目的而设计的。
通过这个数据库,团队成员可以保持各自代码为最新,同时保证成员间的代码交流,保证团队开发效率。
‘陆’ 源码是什么意思啊
源码指编写的最原始程序的代码。
用户平时使用软件时就是程序把“源码”翻译成我们可直观的形式表现出来供用户使用的。任何一个网站页面,换成源码就是一堆按一定格式书写的文字和符号。
源码主要功用
1、生成目标代码,即计算机可以识别的代码。
2、对软件进行说明,即对软件的编写进行说明。为数不少的初学者,甚至少数有经验的程序员都忽视软件说明的编写,因为这部分虽然不会在生成的程序中直接显示,也不参与编译。
但是说明对软件的学习、分享、维护和软件复用都有巨大的好处。因此,书写软件说明在业界被认为是能创造优秀程序的良好习惯,一些公司也硬性规定必须书写。
(6)源码库源码扩展阅读:
计算机里面运行的所有东西都是用程序编出来的,而编写程序要用到计算机语言,用计算机语言直接编出来的程序就叫源码,比如用VisualBasic编写的源码文件一般为.bas文件,而用C++编写的一般为.cpp文件,源代码不能直接运行,必须编译后才能运行。源码经过编译处理后就可以直接在操作系统下运行了。
从字面意义上来讲,源文件是指一个文件,指源代码的集合.源代码则是一组具有特定意义的可以实现特定功能的字符(程序开发代码)。“源代码”在大多数时候等于“源文件”。