《操作系统》的实验代码。
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This program, malloc.py, allows you to see how a simple memory allocator works. Here are the options that you have at your disposal:

-h, --help show this help message and exit -s SEED, --seed=SEED the random seed -S HEAPSIZE, --size=HEAPSIZE size of the heap -b BASEADDR, --baseAddr=BASEADDR base address of heap -H HEADERSIZE, --headerSize=HEADERSIZE size of the header -a ALIGNMENT, --alignment=ALIGNMENT align allocated units to size; -1->no align -p POLICY, --policy=POLICY list search (BEST, WORST, FIRST) -l ORDER, --listOrder=ORDER list order (ADDRSORT, SIZESORT+, SIZESORT-, INSERT-FRONT, INSERT-BACK) -C, --coalesce coalesce the free list? -n OPSNUM, --numOps=OPSNUM number of random ops to generate -r OPSRANGE, --range=OPSRANGE max alloc size -P OPSPALLOC, --percentAlloc=OPSPALLOC percent of ops that are allocs -A OPSLIST, --allocList=OPSLIST instead of random, list of ops (+10,-0,etc) -c, --compute compute answers for me

One way to use it is to have the program generate some random allocation/free operations and for you to see if you can figure out what the free list would look like, as well as the success or failure of each operation.

Here is a simple example:

prompt> ./malloc.py -S 100 -b 1000 -H 4 -a 4 -l ADDRSORT -p BEST -n 5

ptr[0] = Alloc(3) returned ? List?

Free(ptr[0]) returned ? List?

ptr[1] = Alloc(5) returned ? List?

Free(ptr[1]) returned ? List?

ptr[2] = Alloc(8) returned ? List?

In this example, we specify a heap of size 100 bytes (-S 100), starting at address 1000 (-b 1000). We specify an additional 4 bytes of header per allocated block (-H 4), and make sure each allocated space rounds up to the nearest 4-byte free chunk in size (-a 4). We specify that the free list be kept ordered by address (increasing). Finally, we specify a "best fit" free-list searching policy (-p BEST), and ask for 5 random operations to be generated (-n 5). The results of running this are above; your job is to figure out what each allocation/free operation returns, as well as the state of the free list after each operation.

Here we look at the results by using the -c option.

prompt> ./malloc.py -S 100 -b 1000 -H 4 -a 4 -l ADDRSORT -p BEST -n 5 -c

ptr[0] = Alloc(3) returned 1004 (searched 1 elements) Free List [ Size 1 ]: [ addr:1008 sz:92 ]

Free(ptr[0]) returned 0 Free List [ Size 2 ]: [ addr:1000 sz:8 ] [ addr:1008 sz:92 ]

ptr[1] = Alloc(5) returned 1012 (searched 2 elements) Free List [ Size 2 ]: [ addr:1000 sz:8 ] [ addr:1020 sz:80 ]

Free(ptr[1]) returned 0 Free List [ Size 3 ]: [ addr:1000 sz:8 ] [ addr:1008 sz:12 ] [ addr:1020 sz:80 ]

ptr[2] = Alloc(8) returned 1012 (searched 3 elements) Free List [ Size 2 ]: [ addr:1000 sz:8 ] [ addr:1020 sz:80 ]

As you can see, the first allocation operation (an allocation) returns the following information:

ptr[0] = Alloc(3) returned 1004 (searched 1 elements) Free List [ Size 1 ]: [ addr:1008 sz:92 ]

Because the initial state of the free list is just one large element, it is easy to guess that the Alloc(3) request will succeed. Further, it will just return the first chunk of memory and make the remainder into a free list. The pointer returned will be just beyond the header (address:1004), and the allocated space is rounded up to 4 bytes, leaving the free list with 92 bytes starting at 1008.

The next operation is a Free, of "ptr[0]" which is what stores the results of the previous allocation request. As you can expect, this free will succeed (thus returning "0"), and the free list now looks a little more complicated:

Free(ptr[0]) returned 0 Free List [ Size 2 ]: [ addr:1000 sz:8 ] [ addr:1008 sz:92 ]

Indeed, because we are NOT coalescing the free list, we now have two elements on it, the first being 8 bytes large and holding the just-returned space, and the second being the 92-byte chunk.

We can indeed turn on coalescing via the -C flag, and the result is:

prompt> ./malloc.py -S 100 -b 1000 -H 4 -a 4 -l ADDRSORT -p BEST -n 5 -c -C ptr[0] = Alloc(3) returned 1004 (searched 1 elements) Free List [ Size 1 ]: [ addr:1008 sz:92 ]

Free(ptr[0]) returned 0 Free List [ Size 1 ]: [ addr:1000 sz:100 ]

ptr[1] = Alloc(5) returned 1004 (searched 1 elements) Free List [ Size 1 ]: [ addr:1012 sz:88 ]

Free(ptr[1]) returned 0 Free List [ Size 1 ]: [ addr:1000 sz:100 ]

ptr[2] = Alloc(8) returned 1004 (searched 1 elements) Free List [ Size 1 ]: [ addr:1012 sz:88 ]

You can see that when the Free operations take place, the free list is coalesced as expected.

There are some other interesting options to explore:

  • -p (BEST, WORST, FIRST)

    This option lets you use these three different strategies to look for a chunk of memory to use during an allocation request

  • -l (ADDRSORT, SIZESORT+, SIZESORT-, INSERT-FRONT, INSERT-BACK)

    This option lets you keep the free list in a particular order, say sorted by address of the free chunk, size of free chunk (either increasing with a + or decreasing with a -), or simply returning free chunks to the front (INSERT-FRONT) or back (INSERT-BACK) of the free list.

  • -A (list of ops)

    This option lets you specify an exact series of requests instead of randomly-generated ones.

    For example, running with the flag "-A +10,+10,+10,-0,-2" will allocate three chunks of size 10 bytes (plus header), and then free the first one ("-0") and then free the third one ("-2"). What will the free list look like then?

Those are the basics. Use the questions from the book chapter to explore more, or create new and interesting questions yourself to better understand how allocators function.