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I need to (de)cipher some data at a time. Extra padding bytes may have to be added to the target data bytes at the beginning and at the end. The built-in crypto API works on struct scatterlist objects, as you can see with the definition of the encrypt method of a block cipher :

int (*encrypt)(struct blkcipher_desc *desc, struct scatterlist *dst,
           struct scatterlist *src, unsigned int nbytes);

Now the procedure I am following for the ciphering operation :

  1. Get a data buffer buf (length L)
  2. Compute left padding and right padding bytes (rpad and lpad)
  3. Cipher the whole thing (lpad and buf and rpad)
  4. Get rid of the padding bytes in the result

The most simple and unefficient solution would be to allocate L + rpad + lpad bytes and copy the buffer's content in this new area appropriately. But since the API uses those scatterlist objects, I was wondering if there was a way to avoid this pure waste of resources.

I read a couple of articles on LWN about scatterlist chaining but a quick glance at the header file worries me : it looks like I have to manually set up the whole thing, which is a pretty bad practice ...

Any clue on how to use the scatterlist API properly ? Ideally, I would like to do the following :

  1. Allocates buffers for the padding bytes for both input and output
  2. Allocate a "payload" buffer that will only store the "useful" ciphered bytes
  3. Create the scatterlist objects that includes padding buffers and target buffer
  4. Cipher the whole and store the result in output padding buffers + output "payload" buffer
  5. Discard the input and output padding buffers
  6. Return the ciphered "payload" buffer to the user
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3 Answers 3

first, sorry for my pour english,I am not a native english speaker.I think you are looking for this api in kernel " blkcipher_walk_virt" , you can find the usage of this in ecb.c "crypto_ecb_crypt". and you also can see the padlock_aes.c

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That is exactly what I did, unfortunately you arrived too late. Anyway, useful hint and since you cannot comment, here's a +1 – Rerito Feb 22 '13 at 12:07
up vote 2 down vote accepted

After having investigated through the code, I found a suitable solution. It follows quite well the procedure I listed in my question, though there are some subtle differences.

As suggested by JohnsonDiao, I dived into the scatterwalk.c file to see how the Crypto API was making use of the scatterlist objects.

The problem that has arisen is the "boundary" between two subsequent scatterlist. Let's say I have two chained scatterlist. The first one hold information about a 12 bytes buffer, the second to a 20 bytes buffer. I want to encrypt the two buffers as a whole using AES128-CTR. In this particular case, the API will :

  1. Encrypt the 12 bytes of the buffer referenced by the first scatterlist.
  2. Increment the counter
  3. Encrypt the 16 first bytes of the second scatterlist
  4. Increment the counter
  5. Encrypt the last remaining 4 bytes

The behaviour I would have expected was :

  1. Encrypt the 12 bytes of first buffer + the 4 first bytes of second buffer
  2. Increment the counter
  3. Encrypt the last 16 bytes of the second buffer

Thus, to enforce this, one must allocate a 16-byte aligned padding buffer in the pattern :

Let npad the number of padding bytes needed for the requested encryption. Then we have : Buf length

Where lbuf is the total length of the padding buffer. Now, the last lbuf - npad bytes must be filled with the first input data bytes. If the input is too short to ensure a full copy, that's not a matter.

Therefore we copy the first lcpy = min(lbuf - npad, ldata) bytes at the offset npad in the padding buffer

In short, here is the procedure :

  1. Allocate the appropriate padding buffer with length lbuf
  2. Copy the first lcpy bytes of the payload buffer at offset npad in the padding buffer
  3. Reference the padding buffer in a scatterlist
  4. Reference the payload buffer in another scatterlist (with a lcpy shift)
  5. Ask for the ciphering
  6. Extract the payload bytes present in the padding buffer
  7. Discard the padding buffer

I tested this and it seemed to work perfectly.

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I am also learning this part. and this is my analysis:

if your encryption device need cipher 16-bytes at once, you should set the alignment to (16-1). just like the padlock_aes.c , see ecb_aes_alg.cra_alignmask. the kernel would handle this in blkcipher_next_copy and blkcipher_next_slow. but I am puzzled, in aes_generic.c the alignmask is 3, how the kernel handle this without blkcipher_next_copy?

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It is may be the alignment required by the scatterlist interface. The page pointer of a scatterlist must be 4-aligned since the two last bits of the pointer are used to store information for scatterlist chaining (see ). A 3 alignmask value enforces 4-aligned pointers. – Rerito Feb 24 '13 at 6:58

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