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nobs/drbg/ctr_drbg.go

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// This is initial implementation of CTR_DRBG with AES-256. Code is tested
// and functionaly correct. Nevertheless it will be changed
//
// TODO: Following things still need to be done
// * Add other AES key lengts
// * Validate sizes from table 3 of SP800-90A
// * Improve reseeding so that code returns an error when reseed is needed
// * Add case with derivation function (maybe)
// * Code cleanup
// * Implement benchmark
// * Add rest of the test vectors from CAVP
package drbg
import (
"github.com/henrydcase/nobs/drbg/internal/aes"
"github.com/henrydcase/nobs/utils"
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)
// Constants below correspond to AES-256, which is currently
// the only block cipher supported.
const (
BlockLen = 16
KeyLen = 32
SeedLen = BlockLen + KeyLen
)
type CtrDrbg struct {
v [BlockLen]byte
key [KeyLen]byte
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counter uint
strength uint
resistance bool
blockEnc aes.IAES
tmpBlk [3 * BlockLen]byte
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}
func NewCtrDrbg() *CtrDrbg {
if utils.X86.HasAES {
return &CtrDrbg{blockEnc: &aes.AESAsm{}}
}
return &CtrDrbg{blockEnc: &aes.AES{}}
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}
func (c *CtrDrbg) inc() {
for i := BlockLen - 1; i >= 0; i-- {
if c.v[i] == 0xff {
c.v[i] = 0x00
} else {
c.v[i]++
break
}
}
}
func (c *CtrDrbg) Init(entropy, personalization []byte) bool {
var lsz int
var seedBuf [SeedLen]byte
// Minimum entropy input (SP800-90A, 10.2.1)
if len(entropy) < int(c.strength/8) {
return false
}
// Security strength for AES-256 as per SP800-57, 5.6.1
c.strength = 256
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lsz = len(entropy)
if lsz > SeedLen {
lsz = SeedLen
}
copy(seedBuf[:], entropy[:lsz])
lsz = len(personalization)
if lsz > SeedLen {
lsz = SeedLen
}
for i := 0; i < lsz; i++ {
seedBuf[i] ^= personalization[i]
}
c.blockEnc.SetKey(c.key[:])
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c.update(seedBuf[:])
c.counter = 1
return true
}
func (c *CtrDrbg) update(data []byte) {
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if len(data) != SeedLen {
panic("Provided data is not equal to strength/8")
}
// deliberatelly not using len(c.tmpBlk)
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for i := 0; i < 3*BlockLen; i += BlockLen {
c.inc()
c.blockEnc.SetKey(c.key[:])
c.blockEnc.Encrypt(c.tmpBlk[i:], c.v[:])
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}
for i := 0; i < 3*BlockLen; i++ {
c.tmpBlk[i] ^= data[i]
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}
copy(c.key[:], c.tmpBlk[:KeyLen])
copy(c.v[:], c.tmpBlk[KeyLen:])
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}
func (c *CtrDrbg) Reseed(entropy, data []byte) {
var seedBuf [SeedLen]byte
var lsz int
lsz = len(entropy)
if lsz > SeedLen {
lsz = SeedLen
}
copy(seedBuf[:], entropy[:lsz])
lsz = len(data)
if lsz > SeedLen {
lsz = SeedLen
}
for i := 0; i < lsz; i++ {
seedBuf[i] ^= data[i]
}
c.update(seedBuf[:])
c.counter = 1
}
func (c *CtrDrbg) ReadWithAdditionalData(out, ad []byte) (n int, err error) {
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var seedBuf [SeedLen]byte
// TODO: check reseed_counter > reseed_interval
if len(ad) > 0 {
// pad additional data with zeros if needed
copy(seedBuf[:], ad)
c.update(seedBuf[:])
}
// Number of blocks to write minus last one
blocks := len(out) / BlockLen
for i := 0; i < blocks; i++ {
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c.inc()
c.blockEnc.SetKey(c.key[:])
c.blockEnc.Encrypt(out[i*BlockLen:], c.v[:])
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}
// Copy remainder - case for out being not block aligned
c.blockEnc.Encrypt(c.tmpBlk[:], c.v[:])
copy(out[blocks*BlockLen:], c.tmpBlk[:len(out)%BlockLen])
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c.update(seedBuf[:])
c.counter += 1
return len(out), nil
}
// Read reads data from DRBG. Size of data is determined by
// out buffer.
func (c *CtrDrbg) Read(out []byte) (n int, err error) {
return c.ReadWithAdditionalData(out, nil)
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}