constantine/benchmarks/bench_fields_template.nim

# Constantine
# Copyright (c) 2018-2019    Status Research & Development GmbH
# Copyright (c) 2020-Present Mamy André-Ratsimbazafy
# Licensed and distributed under either of
#   * MIT license (license terms in the root directory or at http://opensource.org/licenses/MIT).
#   * Apache v2 license (license terms in the root directory or at http://www.apache.org/licenses/LICENSE-2.0).
# at your option. This file may not be copied, modified, or distributed except according to those terms.

# ############################################################
#
#             Benchmark of finite fields
#
# ############################################################

import
  # Internals
  ../constantine/config/[common, curves],
  ../constantine/arithmetic,
  ../constantine/towers,
  ../constantine/curves/zoo_square_roots,
  # Helpers
  ../helpers/prng_unsafe,
  ./bench_blueprint

export notes
proc separator*() = separator(165)
proc smallSeparator*() = separator(8)

proc report(op, field: string, start, stop: MonoTime, startClk, stopClk: int64, iters: int) =
  let ns = inNanoseconds((stop-start) div iters)
  let throughput = 1e9 / float64(ns)
  when SupportsGetTicks:
    echo &"{op:<70} {field:<18} {throughput:>15.3f} ops/s     {ns:>9} ns/op     {(stopClk - startClk) div iters:>9} CPU cycles (approx)"
  else:
    echo &"{op:<70} {field:<18} {throughput:>15.3f} ops/s     {ns:>9} ns/op"

macro fixFieldDisplay(T: typedesc): untyped =
  # At compile-time, enums are integers and their display is buggy
  # we get the Curve ID instead of the curve name.
  let instantiated = T.getTypeInst()
  var name = $instantiated[1][0] # Fp
  name.add "[" & $Curve(instantiated[1][1].intVal) & "]"
  result = newLit name

template bench(op: string, T: typedesc, iters: int, body: untyped): untyped =
  measure(iters, startTime, stopTime, startClk, stopClk, body)
  report(op, fixFieldDisplay(T), startTime, stopTime, startClk, stopClk, iters)

proc addBench*(T: typedesc, iters: int) =
  var x = rng.random_unsafe(T)
  let y = rng.random_unsafe(T)
  bench("Addition", T, iters):
    x += y

proc subBench*(T: typedesc, iters: int) =
  var x = rng.random_unsafe(T)
  let y = rng.random_unsafe(T)
  preventOptimAway(x)
  bench("Substraction", T, iters):
    x -= y

proc negBench*(T: typedesc, iters: int) =
  var r: T
  let x = rng.random_unsafe(T)
  bench("Negation", T, iters):
    r.neg(x)

proc ccopyBench*(T: typedesc, iters: int) =
  var r: T
  let x = rng.random_unsafe(T)
  bench("Conditional Copy", T, iters):
    r.ccopy(x, CtFalse)

proc div2Bench*(T: typedesc, iters: int) =
  var x = rng.random_unsafe(T)
  bench("Division by 2", T, iters):
    x.div2()

proc mulBench*(T: typedesc, iters: int) =
  var r: T
  let x = rng.random_unsafe(T)
  let y = rng.random_unsafe(T)
  preventOptimAway(r)
  bench("Multiplication", T, iters):
    r.prod(x, y)

proc sqrBench*(T: typedesc, iters: int) =
  var r: T
  let x = rng.random_unsafe(T)
  preventOptimAway(r)
  bench("Squaring", T, iters):
    r.square(x)

proc toBigBench*(T: typedesc, iters: int) =
  var r: matchingBigInt(T.C)
  let x = rng.random_unsafe(T)
  preventOptimAway(r)
  bench("BigInt <- field conversion", T, iters):
    r.fromField(x)

proc toFieldBench*(T: typedesc, iters: int) =
  var r: T
  let x = rng.random_unsafe(matchingBigInt(T.C))
  preventOptimAway(r)
  bench("BigInt -> field conversion", T, iters):
    r.fromBig(x)

proc invBench*(T: typedesc, iters: int) =
  var r: T
  let x = rng.random_unsafe(T)
  preventOptimAway(r)
  bench("Inversion (constant-time)", T, iters):
    r.inv(x)

proc sqrtBench*(T: typedesc, iters: int) =
  let x = rng.random_unsafe(T)

  const algoType = block:
    when T.C.hasP3mod4_primeModulus():
      "p ≡ 3 (mod 4)"
    elif T.C.hasP5mod8_primeModulus():
      "p ≡ 5 (mod 8)"
    else:
      "Tonelli-Shanks"
  const addchain = block:
    when T.C.hasSqrtAddchain() or T.C.hasTonelliShanksAddchain():
      "with addition chain"
    else:
      "without addition chain"
  const desc = "Square Root (constant-time " & algoType & " " & addchain & ")"
  bench(desc, T, iters):
    var r = x
    discard r.sqrt_if_square()

proc sqrtRatioBench*(T: typedesc, iters: int) =
  var r: T
  let u = rng.random_unsafe(T)
  let v = rng.random_unsafe(T)
  bench("Fused SquareRoot+Division+isSquare sqrt(u/v)", T, iters):
    let isSquare = r.sqrt_ratio_if_square(u, v)

proc powBench*(T: typedesc, iters: int) =
  let x = rng.random_unsafe(T)
  let exponent = rng.random_unsafe(BigInt[T.C.getCurveOrderBitwidth()])
  bench("Exp curve order (constant-time) - " & $exponent.bits & "-bit", T, iters):
    var r = x
    r.pow(exponent)

proc powUnsafeBench*(T: typedesc, iters: int) =
  let x = rng.random_unsafe(T)
  let exponent = rng.random_unsafe(BigInt[T.C.getCurveOrderBitwidth()])
  bench("Exp curve order (Leak exponent bits) - " & $exponent.bits & "-bit", T, iters):
    var r = x
    r.powUnsafeExponent(exponent)
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`# Constantine`
			`# Copyright (c) 2018-2019 Status Research & Development GmbH`
			`# Copyright (c) 2020-Present Mamy André-Ratsimbazafy`
			`# Licensed and distributed under either of`
			`# * MIT license (license terms in the root directory or at http://opensource.org/licenses/MIT).`
			`# * Apache v2 license (license terms in the root directory or at http://www.apache.org/licenses/LICENSE-2.0).`
			`# at your option. This file may not be copied, modified, or distributed except according to those terms.`

			`# ############################################################`
			`#`
			`# Benchmark of finite fields`
			`#`
			`# ############################################################`

			`import`
			`# Internals`
Field sqrt optimization (#168) * add more Fp tests for Twisted Edwards curves * add fused sqrt+division bench * Significant fused sqrt+division improvement for any prime field over algorithm described in "High-Speed High-Security Signature", Bernstein et al, p15 "Fast decompression", https://ed25519.cr.yp.to/ed25519-20110705.pdf * Activate secp256k1 field benches + spring renaming of field multiplication * addition chains for inversion and sqrt of Curve25519 * Make isSquare use addition chains * add double-prec mul/square bench for <256-bit prime fields. 2022-01-01 15:19:35 +00:00			`../constantine/config/[common, curves],`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`../constantine/arithmetic,`
Refactor: Higher-Kinded Tower of Extension Fields (#25) * Mention that the inverse of 0 is 0 (TODO tests) * Introduce "Higher-Kinded tower extensions" * rename isCOmplexExtension -> fromComplexExtension * update benchmarks with the new tower scheme * Try to recover some speed on mul/squaring for an optimal tower (but this was not it) 2020-04-14 00:05:42 +00:00			`../constantine/towers,`
Field sqrt optimization (#168) * add more Fp tests for Twisted Edwards curves * add fused sqrt+division bench * Significant fused sqrt+division improvement for any prime field over algorithm described in "High-Speed High-Security Signature", Bernstein et al, p15 "Fast decompression", https://ed25519.cr.yp.to/ed25519-20110705.pdf * Activate secp256k1 field benches + spring renaming of field multiplication * addition chains for inversion and sqrt of Curve25519 * Make isSquare use addition chains * add double-prec mul/square bench for <256-bit prime fields. 2022-01-01 15:19:35 +00:00			`../constantine/curves/zoo_square_roots,`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`# Helpers`
Field sqrt optimization (#168) * add more Fp tests for Twisted Edwards curves * add fused sqrt+division bench * Significant fused sqrt+division improvement for any prime field over algorithm described in "High-Speed High-Security Signature", Bernstein et al, p15 "Fast decompression", https://ed25519.cr.yp.to/ed25519-20110705.pdf * Activate secp256k1 field benches + spring renaming of field multiplication * addition chains for inversion and sqrt of Curve25519 * Make isSquare use addition chains * add double-prec mul/square bench for <256-bit prime fields. 2022-01-01 15:19:35 +00:00			`../helpers/prng_unsafe,`
SHA256 Hash function 2020-12-15 18:18:36 +00:00			`./bench_blueprint`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00
SHA256 Hash function 2020-12-15 18:18:36 +00:00			`export notes`
Square Root & Inversion addition chains - 20% perf increase (#132) * Addition chain for sqrt BLS12-381: 20% perf improvement * sqrt addchain for BN254_Snarks - 20% perf improvement as well * Fix operation count [skip ci] * BLS12-377 sqrt - 10% perf improvement * sqrt addition chain for BW6-761 - 6% speedup * BN254_Nogami inversion addchain * sqrt addchain for BN254_Nogami * Inversion addchain for BLS12-377 * inversion ddition chain for BW6-761 2021-01-23 19:55:40 +00:00			`proc separator*() = separator(165)`
Field sqrt optimization (#168) * add more Fp tests for Twisted Edwards curves * add fused sqrt+division bench * Significant fused sqrt+division improvement for any prime field over algorithm described in "High-Speed High-Security Signature", Bernstein et al, p15 "Fast decompression", https://ed25519.cr.yp.to/ed25519-20110705.pdf * Activate secp256k1 field benches + spring renaming of field multiplication * addition chains for inversion and sqrt of Curve25519 * Make isSquare use addition chains * add double-prec mul/square bench for <256-bit prime fields. 2022-01-01 15:19:35 +00:00			`proc smallSeparator*() = separator(8)`
Add EC bench on G1 + Add throughput to benches 2020-04-15 17:38:02 +00:00
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`proc report(op, field: string, start, stop: MonoTime, startClk, stopClk: int64, iters: int) =`
Add EC bench on G1 + Add throughput to benches 2020-04-15 17:38:02 +00:00			`let ns = inNanoseconds((stop-start) div iters)`
			`let throughput = 1e9 / float64(ns)`
Fix benchmark on ARM (#31) 2020-06-04 20:09:30 +00:00			`when SupportsGetTicks:`
Square Root & Inversion addition chains - 20% perf increase (#132) * Addition chain for sqrt BLS12-381: 20% perf improvement * sqrt addchain for BN254_Snarks - 20% perf improvement as well * Fix operation count [skip ci] * BLS12-377 sqrt - 10% perf improvement * sqrt addition chain for BW6-761 - 6% speedup * BN254_Nogami inversion addchain * sqrt addchain for BN254_Nogami * Inversion addchain for BLS12-377 * inversion ddition chain for BW6-761 2021-01-23 19:55:40 +00:00			`echo &"{op:<70} {field:<18} {throughput:>15.3f} ops/s {ns:>9} ns/op {(stopClk - startClk) div iters:>9} CPU cycles (approx)"`
Fix benchmark on ARM (#31) 2020-06-04 20:09:30 +00:00			`else:`
Square Root & Inversion addition chains - 20% perf increase (#132) * Addition chain for sqrt BLS12-381: 20% perf improvement * sqrt addchain for BN254_Snarks - 20% perf improvement as well * Fix operation count [skip ci] * BLS12-377 sqrt - 10% perf improvement * sqrt addition chain for BW6-761 - 6% speedup * BN254_Nogami inversion addchain * sqrt addchain for BN254_Nogami * Inversion addchain for BLS12-377 * inversion ddition chain for BW6-761 2021-01-23 19:55:40 +00:00			`echo &"{op:<70} {field:<18} {throughput:>15.3f} ops/s {ns:>9} ns/op"`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00
			`macro fixFieldDisplay(T: typedesc): untyped =`
			`# At compile-time, enums are integers and their display is buggy`
			`# we get the Curve ID instead of the curve name.`
			`let instantiated = T.getTypeInst()`
			`var name = $instantiated[1][0] # Fp`
			`name.add "[" & $Curve(instantiated[1][1].intVal) & "]"`
			`result = newLit name`

			`template bench(op: string, T: typedesc, iters: int, body: untyped): untyped =`
SHA256 Hash function 2020-12-15 18:18:36 +00:00			`measure(iters, startTime, stopTime, startClk, stopClk, body)`
			`report(op, fixFieldDisplay(T), startTime, stopTime, startClk, stopClk, iters)`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00
Benchmark template for 𝔽p, 𝔽p2, 𝔽p6 2020-03-21 01:31:31 +00:00			`proc addBench*(T: typedesc, iters: int) =`
Implement constant-time `div2` on finite and extension fields 2020-04-15 00:12:45 +00:00			`var x = rng.random_unsafe(T)`
			`let y = rng.random_unsafe(T)`
Benchmark template for 𝔽p, 𝔽p2, 𝔽p6 2020-03-21 01:31:31 +00:00			`bench("Addition", T, iters):`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`x += y`

Benchmark template for 𝔽p, 𝔽p2, 𝔽p6 2020-03-21 01:31:31 +00:00			`proc subBench*(T: typedesc, iters: int) =`
Implement constant-time `div2` on finite and extension fields 2020-04-15 00:12:45 +00:00			`var x = rng.random_unsafe(T)`
			`let y = rng.random_unsafe(T)`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`preventOptimAway(x)`
Benchmark template for 𝔽p, 𝔽p2, 𝔽p6 2020-03-21 01:31:31 +00:00			`bench("Substraction", T, iters):`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`x -= y`

Benchmark template for 𝔽p, 𝔽p2, 𝔽p6 2020-03-21 01:31:31 +00:00			`proc negBench*(T: typedesc, iters: int) =`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`var r: T`
Implement constant-time `div2` on finite and extension fields 2020-04-15 00:12:45 +00:00			`let x = rng.random_unsafe(T)`
Benchmark template for 𝔽p, 𝔽p2, 𝔽p6 2020-03-21 01:31:31 +00:00			`bench("Negation", T, iters):`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`r.neg(x)`

Jacobian coordinates (#95) * Add projective-> affine bench * Add conditional copy and div2 benches * Fp4 benchmarks * Constant-time Jacobian addition * Jacobian doubling * Use a simpler Add+Dbl complete formula * Update tests * Fix conditional negate * Rollaback complete addition, we were only handling curve coef a == 0 2020-10-01 22:01:09 +00:00			`proc ccopyBench*(T: typedesc, iters: int) =`
			`var r: T`
			`let x = rng.random_unsafe(T)`
			`bench("Conditional Copy", T, iters):`
			`r.ccopy(x, CtFalse)`

			`proc div2Bench*(T: typedesc, iters: int) =`
			`var x = rng.random_unsafe(T)`
			`bench("Division by 2", T, iters):`
			`x.div2()`

Benchmark template for 𝔽p, 𝔽p2, 𝔽p6 2020-03-21 01:31:31 +00:00			`proc mulBench*(T: typedesc, iters: int) =`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`var r: T`
Implement constant-time `div2` on finite and extension fields 2020-04-15 00:12:45 +00:00			`let x = rng.random_unsafe(T)`
			`let y = rng.random_unsafe(T)`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`preventOptimAway(r)`
Benchmark template for 𝔽p, 𝔽p2, 𝔽p6 2020-03-21 01:31:31 +00:00			`bench("Multiplication", T, iters):`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`r.prod(x, y)`

Benchmark template for 𝔽p, 𝔽p2, 𝔽p6 2020-03-21 01:31:31 +00:00			`proc sqrBench*(T: typedesc, iters: int) =`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`var r: T`
Implement constant-time `div2` on finite and extension fields 2020-04-15 00:12:45 +00:00			`let x = rng.random_unsafe(T)`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`preventOptimAway(r)`
Benchmark template for 𝔽p, 𝔽p2, 𝔽p6 2020-03-21 01:31:31 +00:00			`bench("Squaring", T, iters):`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`r.square(x)`

Low-level refactoring (#175) * Add specific fromMont conversion routine. Rename montyResidue to getMont * missed test file * Add x86_64 ASM for fromMont * Add x86_64 MULX/ADCX/ADOX for fromMont * rework Montgomery Multiplication with prefetch/latency hiding techniques * Fix ADX autodetection, closes #174. Rollback faster mul_mont attempt, no improvement and debug pain. * finalSub in fromMont & adx_bmi -> adx * Some {.noInit.} to avoid Nim zeroMem (which should be optimized away but who knows) * Uniformize name 'op+domain': mulmod - mulmont * Fix asm codegen bug "0x0000555555565930 <+896>: sbb 0x20(%r8),%r8" with Clang in final substraction * Prepare for skipping final substraction * Don't forget to copy the result when we skip the final substraction * Seems like we need to stash the idea of skipping the final substraction for now, needs bounds analysis https://eprint.iacr.org/2017/1057.pdf * fix condition for ASM 32-bit * optim modular addition when sparebit is available 2022-02-13 23:16:55 +00:00			`proc toBigBench*(T: typedesc, iters: int) =`
			`var r: matchingBigInt(T.C)`
			`let x = rng.random_unsafe(T)`
			`preventOptimAway(r)`
			`bench("BigInt <- field conversion", T, iters):`
			`r.fromField(x)`

			`proc toFieldBench*(T: typedesc, iters: int) =`
			`var r: T`
			`let x = rng.random_unsafe(matchingBigInt(T.C))`
			`preventOptimAway(r)`
			`bench("BigInt -> field conversion", T, iters):`
			`r.fromBig(x)`

Benchmark template for 𝔽p, 𝔽p2, 𝔽p6 2020-03-21 01:31:31 +00:00			`proc invBench*(T: typedesc, iters: int) =`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`var r: T`
Implement constant-time `div2` on finite and extension fields 2020-04-15 00:12:45 +00:00			`let x = rng.random_unsafe(T)`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`preventOptimAway(r)`
Fast modular inversion (#172) * split modular inversion in its own file * Stash fast GCD inversion https://eprint.iacr.org/2020/972.pdf * Stash Pornin's bingcd -> issue with inner modular reduction * Implement Bernstein-Yang inversion * Avoid Nim checks on signed integers (32-bit runtime issue) * cleanup: remove old inversion impls * cleanup: static moduli, move div2 * small comments (skip ci) * comment cleanup (skip ci) * fix total iterations on 32-bit * Add batch conversion to affine coordinates using simultaneous inversion trick * fix conditional setZero and batchAffine conversion * cleanup unneeded branches following affine conversion unification * Fix batchAffine with zero inputs and add fuzz failure to test suite 2022-02-10 13:05:07 +00:00			`bench("Inversion (constant-time)", T, iters):`
30% faster constant-time inversion 2020-03-20 22:03:52 +00:00			`r.inv(x)`
Implement fused sqrt invsqrt on Fp: Accelerate sqrt on Fp2 by 20% (hashToG2 and property-based testing bottleneck, 4 times slower than inversion and 87 times slower than Fp2 multiplication) 2020-06-17 20:44:52 +00:00
			`proc sqrtBench*(T: typedesc, iters: int) =`
			`let x = rng.random_unsafe(T)`
Field sqrt optimization (#168) * add more Fp tests for Twisted Edwards curves * add fused sqrt+division bench * Significant fused sqrt+division improvement for any prime field over algorithm described in "High-Speed High-Security Signature", Bernstein et al, p15 "Fast decompression", https://ed25519.cr.yp.to/ed25519-20110705.pdf * Activate secp256k1 field benches + spring renaming of field multiplication * addition chains for inversion and sqrt of Curve25519 * Make isSquare use addition chains * add double-prec mul/square bench for <256-bit prime fields. 2022-01-01 15:19:35 +00:00
			`const algoType = block:`
			`when T.C.hasP3mod4_primeModulus():`
			`"p ≡ 3 (mod 4)"`
			`elif T.C.hasP5mod8_primeModulus():`
			`"p ≡ 5 (mod 8)"`
			`else:`
			`"Tonelli-Shanks"`
			`const addchain = block:`
			`when T.C.hasSqrtAddchain() or T.C.hasTonelliShanksAddchain():`
			`"with addition chain"`
			`else:`
			`"without addition chain"`
			`const desc = "Square Root (constant-time " & algoType & " " & addchain & ")"`
			`bench(desc, T, iters):`
Implement fused sqrt invsqrt on Fp: Accelerate sqrt on Fp2 by 20% (hashToG2 and property-based testing bottleneck, 4 times slower than inversion and 87 times slower than Fp2 multiplication) 2020-06-17 20:44:52 +00:00			`var r = x`
			`discard r.sqrt_if_square()`

Field sqrt optimization (#168) * add more Fp tests for Twisted Edwards curves * add fused sqrt+division bench * Significant fused sqrt+division improvement for any prime field over algorithm described in "High-Speed High-Security Signature", Bernstein et al, p15 "Fast decompression", https://ed25519.cr.yp.to/ed25519-20110705.pdf * Activate secp256k1 field benches + spring renaming of field multiplication * addition chains for inversion and sqrt of Curve25519 * Make isSquare use addition chains * add double-prec mul/square bench for <256-bit prime fields. 2022-01-01 15:19:35 +00:00			`proc sqrtRatioBench*(T: typedesc, iters: int) =`
hash-to-curve BLS12-381 perf (#163) * fp square noasm split from non-4 non-6 limbs fallback (40% speedup) * optimized cofactor clearing for BLS12-381 G2 * Support jacobian isogenies and point_add on isogenies * fuse addition and isogeny map * {.noInit.} and sparseMul * poly_eval_horner init * dedicated invsqrt + cleanup square root file * hash to field: reduce copy overhead and don't return arrays * h2c isogeny jacobian reuse pow 3 precomputed value * Fix sqrt bench 2021-08-14 19:01:50 +00:00			`var r: T`
Field sqrt optimization (#168) * add more Fp tests for Twisted Edwards curves * add fused sqrt+division bench * Significant fused sqrt+division improvement for any prime field over algorithm described in "High-Speed High-Security Signature", Bernstein et al, p15 "Fast decompression", https://ed25519.cr.yp.to/ed25519-20110705.pdf * Activate secp256k1 field benches + spring renaming of field multiplication * addition chains for inversion and sqrt of Curve25519 * Make isSquare use addition chains * add double-prec mul/square bench for <256-bit prime fields. 2022-01-01 15:19:35 +00:00			`let u = rng.random_unsafe(T)`
			`let v = rng.random_unsafe(T)`
			`bench("Fused SquareRoot+Division+isSquare sqrt(u/v)", T, iters):`
			`let isSquare = r.sqrt_ratio_if_square(u, v)`
Square Root & Inversion addition chains - 20% perf increase (#132) * Addition chain for sqrt BLS12-381: 20% perf improvement * sqrt addchain for BN254_Snarks - 20% perf improvement as well * Fix operation count [skip ci] * BLS12-377 sqrt - 10% perf improvement * sqrt addition chain for BW6-761 - 6% speedup * BN254_Nogami inversion addchain * sqrt addchain for BN254_Nogami * Inversion addchain for BLS12-377 * inversion ddition chain for BW6-761 2021-01-23 19:55:40 +00:00
Implement fused sqrt invsqrt on Fp: Accelerate sqrt on Fp2 by 20% (hashToG2 and property-based testing bottleneck, 4 times slower than inversion and 87 times slower than Fp2 multiplication) 2020-06-17 20:44:52 +00:00			`proc powBench*(T: typedesc, iters: int) =`
			`let x = rng.random_unsafe(T)`
			`let exponent = rng.random_unsafe(BigInt[T.C.getCurveOrderBitwidth()])`
			`bench("Exp curve order (constant-time) - " & $exponent.bits & "-bit", T, iters):`
			`var r = x`
			`r.pow(exponent)`

			`proc powUnsafeBench*(T: typedesc, iters: int) =`
			`let x = rng.random_unsafe(T)`
			`let exponent = rng.random_unsafe(BigInt[T.C.getCurveOrderBitwidth()])`
			`bench("Exp curve order (Leak exponent bits) - " & $exponent.bits & "-bit", T, iters):`
			`var r = x`
			`r.powUnsafeExponent(exponent)`