372 lines
14 KiB
Nim
372 lines
14 KiB
Nim
import
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../vm_types, interpreter/[gas_meter, gas_costs, utils/utils_numeric, vm_forks],
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../errors, stint, eth/[keys, common], chronicles, tables, macros,
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message, math, nimcrypto, bncurve/[fields, groups], blake2b_f
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type
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PrecompileAddresses* = enum
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# Frontier to Spurious Dragron
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paEcRecover = 1,
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paSha256,
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paRipeMd160,
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paIdentity,
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# Byzantium and Constantinople
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paModExp,
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paEcAdd,
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paEcMul,
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paPairing,
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# Istanbul
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paBlake2bf = 9
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proc getSignature(computation: BaseComputation): (array[32, byte], Signature) =
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# input is Hash, V, R, S
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template data: untyped = computation.msg.data
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var bytes: array[65, byte] # will hold R[32], S[32], V[1], in that order
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let maxPos = min(data.high, 127)
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# if we don't have at minimum 64 bytes, there can be no valid V
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if maxPos >= 63:
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let v = data[63]
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# check if V[32] is 27 or 28
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if not (v.int in 27..28):
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raise newException(ValidationError, "Invalid V in getSignature")
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for x in 32..<63:
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if data[x] != 0:
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raise newException(ValidationError, "Invalid V in getSignature")
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bytes[64] = v - 27
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# if there is more data for R and S, copy it. Else, defaulted zeroes are
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# used for R and S
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if maxPos >= 64:
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# Copy message data to buffer
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bytes[0..(maxPos-64)] = data[64..maxPos]
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if recoverSignature(bytes, result[1]) != EthKeysStatus.Success:
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raise newException(ValidationError, "Could not recover signature computation")
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# extract message hash, only need to copy when there is a valid signature
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result[0][0..31] = data[0..31]
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else:
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raise newException(ValidationError, "Invalid V in getSignature")
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proc getPoint[T: G1|G2](t: typedesc[T], data: openarray[byte]): Point[T] =
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when T is G1:
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const nextOffset = 32
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var px, py: FQ
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else:
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const nextOffset = 64
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var px, py: FQ2
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if not px.fromBytes2(data.toOpenArray(0, nextOffset - 1)):
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raise newException(ValidationError, "Could not get point value")
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if not py.fromBytes2(data.toOpenArray(nextOffset, nextOffset * 2 - 1)):
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raise newException(ValidationError, "Could not get point value")
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# "ecpairing_perturb_g2_by_field_modulus_again.json",
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# "ecpairing_perturb_zeropoint_by_field_modulus.json",
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# "ecpairing_perturb_g2_by_field_modulus.json",
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# modulus comparion in FQ2.fromBytes produce different result
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const
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modulus = Uint256.fromHex("30644e72e131a029b85045b68181585d97816a916871ca8d3c208c16d87cfd47")
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let a = Uint256.fromBytesBE(data.toOpenArray(0, 31), false)
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let b = Uint256.fromBytesBE(data.toOpenArray(32, 63), false)
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when T is G2:
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let c = Uint256.fromBytesBE(data.toOpenArray(64, 95), false)
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let d = Uint256.fromBytesBE(data.toOpenArray(96, 127), false)
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if a >= modulus or b >= modulus or c >= modulus or d >= modulus:
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raise newException(ValidationError, "value greater than field modulus")
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else:
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if a >= modulus or b >= modulus:
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raise newException(ValidationError, "value greater than field modulus")
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if px.isZero() and py.isZero():
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result = T.zero()
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else:
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var ap: AffinePoint[T]
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if not ap.init(px, py):
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raise newException(ValidationError, "Point is not on curve")
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result = ap.toJacobian()
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proc getFR(data: openarray[byte]): FR =
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if not result.fromBytes2(data):
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raise newException(ValidationError, "Could not get FR value")
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proc ecRecover*(computation: BaseComputation) =
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computation.gasMeter.consumeGas(
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GasECRecover,
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reason="ECRecover Precompile")
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var
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(msgHash, sig) = computation.getSignature()
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pubKey: PublicKey
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if sig.recoverSignatureKey(msgHash, pubKey) != EthKeysStatus.Success:
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raise newException(ValidationError, "Could not derive public key from computation")
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computation.rawOutput.setLen(32)
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computation.rawOutput[12..31] = pubKey.toCanonicalAddress()
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trace "ECRecover precompile", derivedKey = pubKey.toCanonicalAddress()
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proc sha256*(computation: BaseComputation) =
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let
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wordCount = wordCount(computation.msg.data.len)
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gasFee = GasSHA256 + wordCount * GasSHA256Word
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computation.gasMeter.consumeGas(gasFee, reason="SHA256 Precompile")
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computation.rawOutput = @(nimcrypto.sha_256.digest(computation.msg.data).data)
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trace "SHA256 precompile", output = computation.rawOutput.toHex
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proc ripemd160*(computation: BaseComputation) =
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let
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wordCount = wordCount(computation.msg.data.len)
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gasFee = GasRIPEMD160 + wordCount * GasRIPEMD160Word
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computation.gasMeter.consumeGas(gasFee, reason="RIPEMD160 Precompile")
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computation.rawOutput.setLen(32)
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computation.rawOutput[12..31] = @(nimcrypto.ripemd160.digest(computation.msg.data).data)
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trace "RIPEMD160 precompile", output = computation.rawOutput.toHex
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proc identity*(computation: BaseComputation) =
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let
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wordCount = wordCount(computation.msg.data.len)
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gasFee = GasIdentity + wordCount * GasIdentityWord
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computation.gasMeter.consumeGas(gasFee, reason="Identity Precompile")
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computation.rawOutput = computation.msg.data
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trace "Identity precompile", output = computation.rawOutput.toHex
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proc modExpInternal(computation: BaseComputation, base_len, exp_len, mod_len: int, T: type StUint) =
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template rawMsg: untyped {.dirty.} =
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computation.msg.data
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block: # Gas cost
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func gasModExp_f(x: Natural): int =
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## Estimates the difficulty of Karatsuba multiplication
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# x: maximum length in bytes between modulo and base
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# TODO: Deal with negative max_len
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result = case x
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of 0 .. 64: x * x
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of 65 .. 1024: x * x div 4 + 96 * x - 3072
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else: x * x div 16 + 480 * x - 199680
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let adj_exp_len = block:
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# TODO deal with negative length
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let first32 = rawMsg.rangeToPadded2[:Uint256](96 + base_len, 95 + base_len + exp_len, min(exp_len, 32))
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if exp_len <= 32:
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if first32.isZero(): 0
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else: log2(first32) # highest-bit in exponent
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else:
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# TODO: `modexpRandomInput.json` require Uint256 arithmetic for this code below
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if not first32.isZero:
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8 * (exp_len - 32) + first32.log2
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else:
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8 * (exp_len - 32)
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let gasFee = block:
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(
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max(mod_len, base_len).gasModExp_f *
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max(adj_exp_len, 1)
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) div GasQuadDivisor
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computation.gasMeter.consumeGas(gasFee, reason="ModExp Precompile")
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block: # Processing
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let
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base = rawMsg.rangeToPadded[:T](96, 95 + base_len, base_len)
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exp = rawMsg.rangeToPadded[:T](96 + base_len, 95 + base_len + exp_len, exp_len)
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modulo = rawMsg.rangeToPadded[:T](96 + base_len + exp_len, 95 + base_len + exp_len + mod_len, mod_len)
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# TODO: specs mentions that we should return in "M" format
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# i.e. if Base and exp are uint512 and Modulo an uint256
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# we should return a 256-bit big-endian byte array
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# Force static evaluation
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func zero(): array[T.bits div 8, byte] {.compileTime.} = discard
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func one(): array[T.bits div 8, byte] {.compileTime.} =
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when cpuEndian == bigEndian:
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result[0] = 1
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else:
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result[^1] = 1
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# Start with EVM special cases
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let output = if modulo <= 1:
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# If m == 0: EVM returns 0.
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# If m == 1: we can shortcut that to 0 as well
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zero()
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elif exp.isZero():
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# If 0^0: EVM returns 1
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# For all x != 0, x^0 == 1 as well
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one()
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else:
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powmod(base, exp, modulo).toByteArrayBE
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# maximum output len is the same as mod_len
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# if it less than mod_len, it will be zero padded at left
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if output.len >= mod_len:
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computation.rawOutput = @(output[^mod_len..^1])
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else:
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computation.rawOutput = newSeq[byte](mod_len)
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computation.rawOutput[^output.len..^1] = output[0..^1]
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proc modExp*(computation: BaseComputation) =
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## Modular exponentiation precompiled contract
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## Yellow Paper Appendix E
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## EIP-198 - https://github.com/ethereum/EIPs/blob/master/EIPS/eip-198.md
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# Parsing the data
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template rawMsg: untyped {.dirty.} =
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computation.msg.data
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let # lengths Base, Exponent, Modulus
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base_len = rawMsg.rangeToPadded[:Uint256](0, 31).safeInt
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exp_len = rawMsg.rangeToPadded[:Uint256](32, 63).safeInt
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mod_len = rawMsg.rangeToPadded[:Uint256](64, 95).safeInt
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let maxBytes = max(base_len, max(exp_len, mod_len))
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if maxBytes <= 32:
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computation.modExpInternal(base_len, exp_len, mod_len, UInt256)
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elif maxBytes <= 64:
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computation.modExpInternal(base_len, exp_len, mod_len, StUint[512])
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elif maxBytes <= 128:
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computation.modExpInternal(base_len, exp_len, mod_len, StUint[1024])
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elif maxBytes <= 256:
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computation.modExpInternal(base_len, exp_len, mod_len, StUint[2048])
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elif maxBytes <= 512:
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computation.modExpInternal(base_len, exp_len, mod_len, StUint[4096])
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elif maxBytes <= 1024:
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computation.modExpInternal(base_len, exp_len, mod_len, StUint[8192])
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else:
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raise newException(EVMError, "The Nimbus VM doesn't support modular exponentiation with numbers larger than uint8192")
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proc bn256ecAdd*(computation: BaseComputation, fork: Fork = FkByzantium) =
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let gasFee = if fork < FkIstanbul: GasECAdd else: GasECAddIstanbul
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computation.gasMeter.consumeGas(gasFee, reason = "ecAdd Precompile")
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var
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input: array[128, byte]
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output: array[64, byte]
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# Padding data
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let msglen = len(computation.msg.data)
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let tocopy = if msglen < 128: msglen else: 128
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if tocopy > 0:
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copyMem(addr input[0], addr computation.msg.data[0], tocopy)
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var p1 = G1.getPoint(input.toOpenArray(0, 63))
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var p2 = G1.getPoint(input.toOpenArray(64, 127))
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var apo = (p1 + p2).toAffine()
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if isSome(apo):
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# we can discard here because we supply proper buffer
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discard apo.get().toBytes(output)
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computation.rawOutput = @output
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proc bn256ecMul*(computation: BaseComputation, fork: Fork = FkByzantium) =
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let gasFee = if fork < FkIstanbul: GasECMul else: GasECMulIstanbul
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computation.gasMeter.consumeGas(gasFee, reason="ecMul Precompile")
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var
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input: array[96, byte]
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output: array[64, byte]
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# Padding data
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let msglen = len(computation.msg.data)
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let tocopy = if msglen < 96: msglen else: 96
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if tocopy > 0:
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copyMem(addr input[0], addr computation.msg.data[0], tocopy)
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var p1 = G1.getPoint(input.toOpenArray(0, 63))
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var fr = getFR(input.toOpenArray(64, 95))
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var apo = (p1 * fr).toAffine()
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if isSome(apo):
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# we can discard here because we supply buffer of proper size
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discard apo.get().toBytes(output)
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computation.rawOutput = @output
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proc bn256ecPairing*(computation: BaseComputation, fork: Fork = FkByzantium) =
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let msglen = len(computation.msg.data)
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if msglen mod 192 != 0:
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raise newException(ValidationError, "Invalid input length")
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let numPoints = msglen div 192
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let gasFee = if fork < FkIstanbul:
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GasECPairingBase + numPoints * GasECPairingPerPoint
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else:
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GasECPairingBaseIstanbul + numPoints * GasECPairingPerPointIstanbul
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computation.gasMeter.consumeGas(gasFee, reason="ecPairing Precompile")
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var output: array[32, byte]
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if msglen == 0:
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# we can discard here because we supply buffer of proper size
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discard BNU256.one().toBytes(output)
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else:
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# Calculate number of pairing pairs
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let count = msglen div 192
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# Pairing accumulator
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var acc = FQ12.one()
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for i in 0..<count:
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let s = i * 192
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# Loading AffinePoint[G1], bytes from [0..63]
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var p1 = G1.getPoint(computation.msg.data.toOpenArray(s, s + 63))
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# Loading AffinePoint[G2], bytes from [64..191]
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var p2 = G2.getPoint(computation.msg.data.toOpenArray(s + 64, s + 191))
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# Accumulate pairing result
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acc = acc * pairing(p1, p2)
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if acc == FQ12.one():
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# we can discard here because we supply buffer of proper size
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discard BNU256.one().toBytes(output)
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computation.rawOutput = @output
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proc blake2bf*(computation: BaseComputation) =
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template input(): untyped =
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computation.msg.data
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if len(input) == blake2FInputLength:
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let gasFee = GasInt(beLoad32(input, 0))
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computation.gasMeter.consumeGas(gasFee, reason="ecPairing Precompile")
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var output: array[64, byte]
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if not blake2b_F(input, output):
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raise newException(ValidationError, "Blake2b F function invalid input")
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else:
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computation.rawOutput = @output
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proc getMaxPrecompileAddr(fork: Fork): PrecompileAddresses =
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if fork < FkByzantium: paIdentity
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elif fork < FkIstanbul: paPairing
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else: PrecompileAddresses.high
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proc execPrecompiles*(computation: BaseComputation, fork: Fork): bool {.inline.} =
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for i in 0..18:
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if computation.msg.codeAddress[i] != 0: return
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let lb = computation.msg.codeAddress[19]
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let maxPrecompileAddr = getMaxPrecompileAddr(fork)
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if lb in PrecompileAddresses.low.byte .. maxPrecompileAddr.byte:
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result = true
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let precompile = PrecompileAddresses(lb)
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trace "Call precompile", precompile = precompile, codeAddr = computation.msg.codeAddress
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try:
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case precompile
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of paEcRecover: ecRecover(computation)
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of paSha256: sha256(computation)
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of paRipeMd160: ripeMd160(computation)
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of paIdentity: identity(computation)
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of paModExp: modExp(computation)
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of paEcAdd: bn256ecAdd(computation, fork)
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of paEcMul: bn256ecMul(computation, fork)
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of paPairing: bn256ecPairing(computation, fork)
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of paBlake2bf: blake2bf(computation)
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except OutOfGas:
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let msg = getCurrentExceptionMsg()
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# cannot use setError here, cyclic dependency
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computation.error = Error(info: msg, burnsGas: true)
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except CatchableError:
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let msg = getCurrentExceptionMsg()
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if fork >= FKByzantium and precompile > paIdentity:
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computation.error = Error(info: msg, burnsGas: true)
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else:
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# swallow any other precompiles errors
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debug "execPrecompiles validation error", msg=msg
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