rename to por

2022-03-18 12:27:11 -06:00 · 2022-03-18 12:27:11 -06:00 · ec754ba0a1
parent befebcf325
commit ec754ba0a1
6 changed files with 608 additions and 0 deletions
--- a/dagger/por.nim
+++ b/dagger/por.nim
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 import ./por/por
 export por
--- a/dagger/por/README.md
+++ b/dagger/por/README.md
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 Nim implementation of Proof of Storage related schemes
--- a/dagger/por/benchmark.nim
+++ b/dagger/por/benchmark.nim
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 import times, strutils
 export strutils.formatFloat
 template benchmark*(benchmarkName: string, code: untyped) =
  let t0 = epochTime()
  code
  let elapsed = epochTime() - t0
  let elapsedStr = elapsed.formatFloat(format = ffDecimal, precision = 3)
  echo "CPU Time [", benchmarkName, "] ", elapsedStr, "s"
--- a/dagger/por/example.txt
+++ b/dagger/por/example.txt
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 The quick brown fox jumps over the lazy dog!
--- a/dagger/por/por.nim
+++ b/dagger/por/por.nim
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 ## Nim-POS
 ## Copyright (c) 2021 Status Research & Development GmbH
 ## Licensed under either of
 ##  * Apache License, version 2.0, ([LICENSE-APACHE](LICENSE-APACHE))
 ##  * MIT license ([LICENSE-MIT](LICENSE-MIT))
 ## at your option.
 ## This file may not be copied, modified, or distributed except according to
 ## those terms.
 # Implementation of the BLS-based public PoS scheme from
 # Shacham H., Waters B., "Compact Proofs of Retrievability"
 # using pairing over BLS12-381 ECC
 #
 # Notation from the paper
 # In Z:
 # - n: number of blocks
 # - s: number of sectors per block
 #
 # In Z_p: modulo curve order
 # - m_{ij}: sectors of the file i:0..n-1 j:0..s-1
 # - α: PoS secret key
 # - name: random string
 # - μ_j: part of proof, j:0..s-1
 #
 # In G_1: multiplicative cyclic group
 # - H: {0,1}∗ →G_1 : hash function
 # - u_1,…,u_s ←R G_1 : random coefficients
 # - σ_i: authenticators
 # - σ: part of proof
 #
 # In G_2: multiplicative cyclic group
 # - g: generator of G_2
 # - v ← g^α: PoS public key
 #
 # In G_T:
 # - used only to calculate the two pairings during validation
 #
 # Implementation:
 # Our implementation uses additive cyclic groups instead of the multiplicative
 # cyclic group in the paper, thus changing the name of the group operation as in
 # blscurve and blst. Thus, point multiplication becomes point addition, and scalar
 # exponentiation becomes scalar multiplicaiton.
 #
 # Number of operations:
 # The following table summarizes the number of operations in different phases
 # using the following notation:
 #  - f: file size expressed in units of 31 bytes
 #  - n: number of blocks
 #  - s: number of sectors per block
 #  - q: number of query items
 #
 # Since f = n * s and s is a parameter of the scheme, it is better to express
 # the cost as a function of f and s. This only matters for Setup, all other
 # phases are independent of the file size assuming a given q.
 #
 # |                |         Setup             | Challenge |   Proof   | Verify    |
 # |----------------|-----------|---------------|-----------|-----------|-----------|
 # | G1 random      | s         = s             | q         |           |           |
 # | G1 scalar mult | n * (s+1) = f * (1 + 1/s) |           | q         | q + s     |
 # | G1 add         | n * s     = f             |           | q-1       | q-1 + s-1 |
 # | Hash to G1     | n         = f / s         |           |           | q         |
 # | Z_p mult       |           =               |           | s * q     |           |
 # | Z_p add        |           =               |           | s * (q-1) |           |
 # | pairing        |           =               |           |           | 2         |
 #
 #
 # Storage and communication cost:
 # The storage overhead for a file of f_b bytes is given by the n authenticators
 # calculated in the setup phase.
 #   f_b = f * 31 = n * s * 31
 # Each authenticator is a point on G_1, which occupies 48 bytes in compressed form.
 # Thus, the overall sorage size in bytes is:
 #   f_pos = fb + n * 48 = fb * (1 + (48/31) * (1/s))
 #
 # Communicaiton cost in the Setup phase is simply related to the storage cost.
 # The size of the challenge is
 #   q * (8 + 48) bytes
 # The size of the proof is instead
 #   s * 32 + 48 bytes
 import std/endians
 import pkg/chronos
 import pkg/blscurve
 import pkg/blscurve/blst/blst_abi
 import ../rng
 import ../streams
 # sector size in bytes. Must be smaller than the subgroup order r
 # which is 255 bits long for BLS12-381
 const
  BytesPerSector = 31
  # length in bytes of the unique (random) name
  Namelen = 512
 type
  # a single sector
  ZChar* = array[BytesPerSector, byte]
  # secret key combining the metadata signing key and the POR generation key
  SecretKey* = object
    signkey: blscurve.SecretKey
    key: blst_scalar
  # public key combining the metadata signing key and the POR validation key
  PublicKey* = object
    signkey: blscurve.PublicKey
    key: blst_p2
  # POR metadata (called "file tag t_0" in the original paper)
  TauZero = object
    name: array[Namelen, byte]
    n:    int64
    u:    seq[blst_p1]
  # signed POR metadata (called "signed file tag t" in the original paper)
  Tau = object
    t: TauZero
    signature: array[96, byte]
  # PoR query element
  QElement = object
    I: int64
    V: blst_scalar
 proc fromBytesBE(a: array[32, byte]): blst_scalar =
  ## Convert data to blst native form
  ##
  blst_scalar_from_bendian(result, a)
  doAssert(blst_scalar_fr_check(result).bool)
 proc fromBytesBE(a: openArray[byte]): blst_scalar =
  ## Convert data to blst native form
  ##
  var b: array[32, byte]
  doAssert(a.len <= b.len)
  let d = b.len - a.len
  for i in 0..<a.len:
    b[i+d] = a[i]
  blst_scalar_from_bendian(result, b)
  doAssert(blst_scalar_fr_check(result).bool)
 proc getSector(
  stream: SeekableStream,
  blockId: int64,
  sectorId: int64,
  spb: int64): Future[ZChar] {.async.} =
  ## Read file sector at given <blockid, sectorid> postion
  ##
  var res: ZChar
  stream.setPos(((blockid * spb + sectorid) * ZChar.high).int)
  discard await stream.readOnce(addr res[0], ZChar.high)
  return res
 proc rndScalar(): blst_scalar =
  ## Generate random scalar within the subroup order r
  ##
  var scal {.noInit.}: array[32, byte]
  var scalar {.noInit.}: blst_scalar
  while true:
    for val in scal.mitems:
      val = byte Rng.instance.rand(0xFF)
    scalar.blst_scalar_from_bendian(scal)
    if blst_scalar_fr_check(scalar).bool:
      break
  return scalar
 proc rndP2(): (blst_p2, blst_scalar) =
  ## Generate random point on G2
  ##
  var
    x {.noInit.}: blst_p2
  x.blst_p2_from_affine(BLS12_381_G2) # init from generator
  let
    scalar = rndScalar()
  x.blst_p2_mult(x, scalar, 255)
  return (x, scalar)
 proc rndP1(): (blst_p1, blst_scalar) =
  ## Generate random point on G1
  var
    x {.noInit.}: blst_p1
  x.blst_p1_from_affine(BLS12_381_G1) # init from generator
  let
    scalar = rndScalar()
  x.blst_p1_mult(x, scalar, 255)
  return (x, scalar)
 template posKeygen(): (blst_p2, blst_scalar) =
  ## Generate POS key pair
  ##
  rndP2()
 proc keyGen*(): (PublicKey, SecretKey) =
  ## Generate key pair for signing metadata and for POS tags
  ##
  var
    pk: PublicKey
    sk: SecretKey
    ikm: array[32, byte]
  for b in ikm.mitems:
    b = byte Rng.instance.rand(0xFF)
  doAssert ikm.keyGen(pk.signkey, sk.signkey)
  (pk.key, sk.key) = posKeygen()
  return (pk, sk)
 proc sectorsCount(stream: SeekableStream, s: int64): int64 =
  ## Calculate number of blocks for a file
  ##
  let
    size = stream.size()
    n = ((size - 1) div (s * sizeof(ZChar))) + 1
  # debugEcho "File size=", size, " bytes",
  #   ", blocks=", n,
  #   ", sectors/block=", $s,
  #   ", sectorsize=", $sizeof(ZChar), " bytes"
  return n
 proc hashToG1[T: byte|char](msg: openArray[T]): blst_p1 =
  ## Hash to curve with Dagger specific domain separation
  ##
  const dst = "DAGGER-PROOF-OF-CONCEPT"
  result.blst_hash_to_g1(msg, dst, aug = "")
 proc hashNameI(name: array[Namelen, byte], i: int64): blst_p1 =
  ## Calculate unique filename and block index based hash
  ##
  # # naive implementation, hashing a long string representation
  # # such as "[255, 242, 23]1"
  # return hashToG1($name & $i)
  # more compact and faster implementation
  var namei: array[sizeof(name) + sizeof(int64), byte]
  namei[0..sizeof(name)-1] = name
  bigEndian64(addr(namei[sizeof(name)]), unsafeAddr(i))
  return hashToG1(namei)
 proc generateAuthenticatorNaive(
  stream: SeekableStream,
  ssk: SecretKey,
  i: int64,
  s: int64,
  t: TauZero): Future[blst_p1] {.async.} =
  ## Naive implementation of authenticator as in the S&W paper.
  ## With the paper's multiplicative notation:
  ##   \sigmai=\(H(file||i)\cdot\prod{j=0}^{s-1}{uj^{m[i][j]}})^{\alpha}
  ##
  var sum: blst_p1
  for j in 0..<s:
    var prod: blst_p1
    prod.blst_p1_mult(t.u[j], fromBytesBE((await stream.getSector(i, j, s))), 255)
    sum.blst_p1_add_or_double(sum, prod)
  blst_p1_add_or_double(result, hashNameI(t.name, i), sum)
  result.blst_p1_mult(result, ssk.key, 255)
 proc generateAuthenticatorOpt(
  stream: SeekableStream,
  ssk: SecretKey,
  i: int64,
  s: int64,
  t: TauZero,
  ubase: seq[blst_scalar]): Future[blst_p1] {.async.} =
  ## Optimized implementation of authenticator generation
  ## This implementation is reduces the number of scalar multiplications
  ## from s+1 to 1+1 , using knowledge about the scalars (r_j)
  ## used to generate u_j as u_j = g^{r_j}
  ##
  ## With the paper's multiplicative notation, we use:
  ##   (H(file||i)\cdot g^{\sum{j=0}^{s-1}{r_j \cdot m[i][j]}})^{\alpha}
  ##
  var sum: blst_fr
  var sums: blst_scalar
  for j in 0..<s:
    var a, b, x: blst_fr
    a.blst_fr_from_scalar(ubase[j])
    b.blst_fr_from_scalar(fromBytesBE((await stream.getSector(i, j, s))))
    x.blst_fr_mul(a, b)
    sum.blst_fr_add(sum, x)
  sums.blst_scalar_from_fr(sum)
  result.blst_p1_from_affine(BLS12_381_G1)
  result.blst_p1_mult(result, sums, 255)
  result.blst_p1_add_or_double(result, hashNameI(t.name, i))
  result.blst_p1_mult(result, ssk.key, 255)
 proc generateAuthenticator(
  stream: SeekableStream,
  ssk: SecretKey,
  i: int64,
  s: int64,
  t: TauZero,
  ubase: seq[blst_scalar]): Future[blst_p1] =
  ## Wrapper to select tag generator implementation
  ##
  # let a = generateAuthenticatorNaive(i, s, t, f, ssk)
  return generateAuthenticatorOpt(stream, ssk, i, s, t, ubase)
  # doAssert(a.blst_p1_is_equal(b).bool)
 proc setupPor*(
  stream: SeekableStream,
  ssk: SecretKey,
  s: int64): Future[(Tau, seq[blst_p1])] {.async.} =
  ## Set up the POR scheme by generating tags and metadata
  ##
  let n = stream.sectorsCount(s)
  var t = TauZero(n: n)
  # generate a random name
  for i in 0..<Namelen:
    t.name[i] = byte Rng.instance.rand(0xFF)
  # generate the coefficient vector for combining sectors of a block: U
  var ubase: seq[blst_scalar]
  for i in 0..<s:
    let (u, ub) = rndP1()
    t.u.add(u)
    ubase.add(ub)
  #TODO: a better bytearray conversion of TauZero for the signature might be needed
  #      the current conversion using $t might be architecture dependent and not unique
  let
    signature = sign(ssk.signkey, $t)
    tau = Tau(t: t, signature: signature.exportRaw())
  #generate sigmas
  var sigmas: seq[blst_p1]
  for i in 0..<n:
    sigmas.add((await stream.generateAuthenticator(ssk, i, s, t, ubase)))
  result = (tau, sigmas)
 proc generateQuery*(tau: Tau, l: int): seq[QElement] =
  ## Generata a random BLS query of given size
  ##
  let n = tau.t.n # number of blocks
  for i in 0..<l:
    var q: QElement
    q.I = Rng.instance.rand(n-1) #TODO: dedup
    q.V = rndScalar() #TODO: fix range
    result.add(q)
 proc generateProof*(
  stream: SeekableStream,
  q: seq[QElement],
  authenticators: seq[blst_p1],
  s: int64): Future[(seq[blst_scalar], blst_p1)] {.async.} =
  ## Generata BLS proofs for a given query
  ##
  var
    mu: seq[blst_scalar]
  for j in 0..<s:
    var
      muj: blst_fr
    for qelem in q:
      let
        sect = fromBytesBE((await stream.getSector(qelem.I, j, s)))
      var
        x, v, sector: blst_fr
      sector.blst_fr_from_scalar(sect)
      v.blst_fr_from_scalar(qelem.V)
      x.blst_fr_mul(v, sector)
      muj.blst_fr_add(muj, x)
    var
      mujs: blst_scalar
    mujs.blst_scalar_from_fr(muj)
    mu.add(mujs)
  var
    sigma: blst_p1
  for qelem in q:
    var
      prod: blst_p1
    prod.blst_p1_mult(authenticators[qelem.I], qelem.V, 255)
    sigma.blst_p1_add_or_double(sigma, prod)
  return (mu, sigma)
 proc pairing(a: blst_p1, b: blst_p2): blst_fp12 =
  ## Calculate pairing G_1,G_2 -> G_T
  ##
  var
    aa: blst_p1_affine
    bb: blst_p2_affine
    l: blst_fp12
  blst_p1_to_affine(aa, a)
  blst_p2_to_affine(bb, b)
  blst_miller_loop(l, bb, aa)
  blst_final_exp(result, l)
 proc verifyPairingsNaive(a1: blst_p1, a2: blst_p2, b1: blst_p1, b2: blst_p2) : bool =
  let e1 = pairing(a1, a2)
  let e2 = pairing(b1, b2)
  return e1 == e2
 proc verifyPairingsNeg(a1: blst_p1, a2: blst_p2, b1: blst_p1, b2: blst_p2) : bool =
  ## Faster pairing verification using 2 miller loops but ony one final exponentiation
  ## based on https://github.com/benjaminion/c-kzg/blob/main/src/bls12_381.c
  ##
  var
    loop0, loop1, gt_point: blst_fp12
    aa1, bb1: blst_p1_affine
    aa2, bb2: blst_p2_affine
  var a1neg = a1
  blst_p1_cneg(a1neg, 1)
  blst_p1_to_affine(aa1, a1neg)
  blst_p1_to_affine(bb1, b1)
  blst_p2_to_affine(aa2, a2)
  blst_p2_to_affine(bb2, b2)
  blst_miller_loop(loop0, aa2, aa1)
  blst_miller_loop(loop1, bb2, bb1)
  blst_fp12_mul(gt_point, loop0, loop1)
  blst_final_exp(gt_point, gt_point)
  return blst_fp12_is_one(gt_point).bool
 proc verifyPairings(a1: blst_p1, a2: blst_p2, b1: blst_p1, b2: blst_p2) : bool =
  ## Wrapper to select verify pairings implementation
  ##
  verifyPairingsNaive(a1, a2, b1, b2)
  #verifyPairingsNeg(a1, a2, b1, b2)
 proc verifyProof*(
  spk: PublicKey,
  tau: Tau,
  q: seq[QElement],
  mus: seq[blst_scalar],
  sigma: blst_p1): bool =
  ## Verify a BLS proof given a query
  ##
  # verify signature on Tau
  var signature: blscurve.Signature
  if not signature.fromBytes(tau.signature):
    return false
  if not verify(spk.signkey, $tau.t, signature):
    return false
  var first: blst_p1
  for qelem in q :
    var prod: blst_p1
    prod.blst_p1_mult(hashNameI(tau.t.name, qelem.I), qelem.V, 255)
    first.blst_p1_add_or_double(first, prod)
    doAssert(blst_p1_on_curve(first).bool)
  let us = tau.t.u
  var second: blst_p1
  for j in 0..<len(us):
    var prod: blst_p1
    prod.blst_p1_mult(us[j], mus[j], 255)
    second.blst_p1_add_or_double(second, prod)
    doAssert(blst_p1_on_curve(second).bool)
  var sum: blst_p1
  sum.blst_p1_add_or_double(first, second)
  var g {.noInit.}: blst_p2
  g.blst_p2_from_affine(BLS12_381_G2)
  return verifyPairings(sum, spk.key, sigma, g)
 proc verifyProofIndex*(
  spk: PublicKey,
  tau: Tau,
  q: seq[QElement],
  mus: seq[blst_scalar],
  sigma: blst_p1): bool =
  ## Verify a BLS proof given a query
  ##
  # verify signature on Tau
  var signature: blscurve.Signature
  if not signature.fromBytes(tau.signature):
    return false
  if not verify(spk.signkey, $tau.t, signature):
    return false
  var first: blst_p1
  for qelem in q:
    var prod: blst_p1
    prod.blst_p1_mult(hashNameI(tau.t.name, qelem.I), qelem.V, 255)
    first.blst_p1_add_or_double(first, prod)
    doAssert(blst_p1_on_curve(first).bool)
  let us = tau.t.u
  var second: blst_p1
  for j in 0..<len(us):
    var prod: blst_p1
    prod.blst_p1_mult(us[j], mus[j], 255)
    second.blst_p1_add_or_double(second, prod)
    doAssert(blst_p1_on_curve(second).bool)
  var sum: blst_p1
  sum.blst_p1_add_or_double(first, second)
  var g {.noInit.}: blst_p2
  g.blst_p2_from_affine(BLS12_381_G2)
  return verifyPairings(sum, spk.key, sigma, g)
--- a/dagger/por/testbls.nim
+++ b/dagger/por/testbls.nim
@ -0,0 +1,45 @@
 ## Nim-POS
 ## Copyright (c) 2021 Status Research & Development GmbH
 ## Licensed under either of
 ##  * Apache License, version 2.0, ([LICENSE-APACHE](LICENSE-APACHE))
 ##  * MIT license ([LICENSE-MIT](LICENSE-MIT))
 ## at your option.
 ## This file may not be copied, modified, or distributed except according to
 ## those terms.
 import ./por
 import benchmark
 import strutils
 const sectorsperblock = 1024.int64
 const querylen = 22
 proc testbls() : bool =
  benchmark "Key generation":
    let
      file = open("/Users/dryajov/Downloads/20181126_152327_bak.mp4")
      por = BLSPoR.init()
  benchmark "Auth generation (s=" & $sectorsperblock & ")":
    let
      (tau, authenticators) = por.setup(sectorsperblock, file)
  #echo "Auth: ", authenticators
  benchmark "Generating challenge (q=" & $querylen & ")":
    let q = por.generateQuery(tau, querylen)
  #echo "Generated!" #, " q:", q
  benchmark "Issuing proof":
    file.setFilePos(0)
    let (mu, sigma) = por.generateProof(q, authenticators, sectorsperblock, file)
  #echo "Issued!" #, " mu:", mu, " sigma:", sigma
  benchmark "Verifying proof":
    result = por.verifyProof(tau, q, mu, sigma)
  echo "Result: ", result
  file.close()
 let r = testbls()
		`@ -0,0 +1 @@`
							`Nim implementation of Proof of Storage related schemes`
		`@ -0,0 +1 @@`
							`The quick brown fox jumps over the lazy dog!`