mirror of
https://github.com/ceph/ceph-csi.git
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47b202554e
This commit adds the Azure SDK for Azure key vault KMS integration to the Ceph CSI driver. Signed-off-by: Praveen M <m.praveen@ibm.com>
171 lines
5.5 KiB
Go
171 lines
5.5 KiB
Go
// Copyright 2015 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package pkcs12
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import (
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"bytes"
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"crypto/sha1"
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"math/big"
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)
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var (
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one = big.NewInt(1)
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)
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// sha1Sum returns the SHA-1 hash of in.
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func sha1Sum(in []byte) []byte {
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sum := sha1.Sum(in)
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return sum[:]
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}
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// fillWithRepeats returns v*ceiling(len(pattern) / v) bytes consisting of
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// repeats of pattern.
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func fillWithRepeats(pattern []byte, v int) []byte {
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if len(pattern) == 0 {
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return nil
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}
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outputLen := v * ((len(pattern) + v - 1) / v)
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return bytes.Repeat(pattern, (outputLen+len(pattern)-1)/len(pattern))[:outputLen]
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}
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func pbkdf(hash func([]byte) []byte, u, v int, salt, password []byte, r int, ID byte, size int) (key []byte) {
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// implementation of https://tools.ietf.org/html/rfc7292#appendix-B.2 , RFC text verbatim in comments
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// Let H be a hash function built around a compression function f:
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// Z_2^u x Z_2^v -> Z_2^u
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// (that is, H has a chaining variable and output of length u bits, and
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// the message input to the compression function of H is v bits). The
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// values for u and v are as follows:
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// HASH FUNCTION VALUE u VALUE v
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// MD2, MD5 128 512
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// SHA-1 160 512
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// SHA-224 224 512
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// SHA-256 256 512
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// SHA-384 384 1024
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// SHA-512 512 1024
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// SHA-512/224 224 1024
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// SHA-512/256 256 1024
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// Furthermore, let r be the iteration count.
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// We assume here that u and v are both multiples of 8, as are the
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// lengths of the password and salt strings (which we denote by p and s,
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// respectively) and the number n of pseudorandom bits required. In
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// addition, u and v are of course non-zero.
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// For information on security considerations for MD5 [19], see [25] and
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// [1], and on those for MD2, see [18].
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// The following procedure can be used to produce pseudorandom bits for
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// a particular "purpose" that is identified by a byte called "ID".
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// This standard specifies 3 different values for the ID byte:
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// 1. If ID=1, then the pseudorandom bits being produced are to be used
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// as key material for performing encryption or decryption.
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// 2. If ID=2, then the pseudorandom bits being produced are to be used
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// as an IV (Initial Value) for encryption or decryption.
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// 3. If ID=3, then the pseudorandom bits being produced are to be used
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// as an integrity key for MACing.
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// 1. Construct a string, D (the "diversifier"), by concatenating v/8
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// copies of ID.
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var D []byte
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for i := 0; i < v; i++ {
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D = append(D, ID)
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}
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// 2. Concatenate copies of the salt together to create a string S of
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// length v(ceiling(s/v)) bits (the final copy of the salt may be
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// truncated to create S). Note that if the salt is the empty
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// string, then so is S.
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S := fillWithRepeats(salt, v)
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// 3. Concatenate copies of the password together to create a string P
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// of length v(ceiling(p/v)) bits (the final copy of the password
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// may be truncated to create P). Note that if the password is the
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// empty string, then so is P.
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P := fillWithRepeats(password, v)
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// 4. Set I=S||P to be the concatenation of S and P.
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I := append(S, P...)
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// 5. Set c=ceiling(n/u).
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c := (size + u - 1) / u
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// 6. For i=1, 2, ..., c, do the following:
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A := make([]byte, c*20)
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var IjBuf []byte
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for i := 0; i < c; i++ {
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// A. Set A2=H^r(D||I). (i.e., the r-th hash of D||1,
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// H(H(H(... H(D||I))))
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Ai := hash(append(D, I...))
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for j := 1; j < r; j++ {
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Ai = hash(Ai)
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}
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copy(A[i*20:], Ai[:])
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if i < c-1 { // skip on last iteration
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// B. Concatenate copies of Ai to create a string B of length v
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// bits (the final copy of Ai may be truncated to create B).
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var B []byte
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for len(B) < v {
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B = append(B, Ai[:]...)
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}
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B = B[:v]
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// C. Treating I as a concatenation I_0, I_1, ..., I_(k-1) of v-bit
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// blocks, where k=ceiling(s/v)+ceiling(p/v), modify I by
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// setting I_j=(I_j+B+1) mod 2^v for each j.
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{
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Bbi := new(big.Int).SetBytes(B)
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Ij := new(big.Int)
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for j := 0; j < len(I)/v; j++ {
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Ij.SetBytes(I[j*v : (j+1)*v])
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Ij.Add(Ij, Bbi)
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Ij.Add(Ij, one)
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Ijb := Ij.Bytes()
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// We expect Ijb to be exactly v bytes,
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// if it is longer or shorter we must
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// adjust it accordingly.
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if len(Ijb) > v {
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Ijb = Ijb[len(Ijb)-v:]
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}
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if len(Ijb) < v {
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if IjBuf == nil {
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IjBuf = make([]byte, v)
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}
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bytesShort := v - len(Ijb)
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for i := 0; i < bytesShort; i++ {
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IjBuf[i] = 0
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}
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copy(IjBuf[bytesShort:], Ijb)
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Ijb = IjBuf
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}
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copy(I[j*v:(j+1)*v], Ijb)
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}
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}
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}
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}
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// 7. Concatenate A_1, A_2, ..., A_c together to form a pseudorandom
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// bit string, A.
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// 8. Use the first n bits of A as the output of this entire process.
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return A[:size]
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// If the above process is being used to generate a DES key, the process
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// should be used to create 64 random bits, and the key's parity bits
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// should be set after the 64 bits have been produced. Similar concerns
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// hold for 2-key and 3-key triple-DES keys, for CDMF keys, and for any
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// similar keys with parity bits "built into them".
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}
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