196 lines
8.3 KiB
Markdown
196 lines
8.3 KiB
Markdown
# Constantine - Constant Time Elliptic Curve Cryptography
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[![License: Apache](https://img.shields.io/badge/License-Apache%202.0-blue.svg)](https://opensource.org/licenses/Apache-2.0)
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[![License: MIT](https://img.shields.io/badge/License-MIT-blue.svg)](https://opensource.org/licenses/MIT)
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![Stability: experimental](https://img.shields.io/badge/stability-experimental-orange.svg)\
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[![Build Status: Travis](https://img.shields.io/travis/com/mratsim/constantine/master?label=Travis%20%28Linux%20x86_64%2FARM64,%20MacOS%20x86_64%29)](https://travis-ci.com/mratsim/constantine)
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[![Build Status: Azure](https://img.shields.io/azure-devops/build/numforge/07a2a7a5-995a-45d3-acd5-f5456fe7b04d/4?label=Azure%20%28Linux%2064-bit%2C%20Windows%2032%2F64-bit%2C%20MacOS%2064-bit%29)](https://dev.azure.com/numforge/Constantine/_build?definitionId=4&branchName=master)
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This library provides constant-time implementation of elliptic curve cryptography.
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> Warning ⚠️: The library is in development state and cannot be used at the moment
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> except as a showcase or to start a discussion on modular big integers internals.
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## Installation
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You can install the developement version of the library through nimble with the following command
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```
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nimble install https://github.com/mratsim/constantine@#master
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```
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For speed it is recommended to prefer Clang, MSVC or ICC over GCC.
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GCC does not properly optimize add-with-carry and sub-with-borrow loops (see [Compiler-caveats](#Compiler-caveats)).
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Further if using GCC, GCC 7 at minimum is required, previous versions
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generated incorrect add-with-carry code.
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## Target audience
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The library aims to be a portable, compact and hardened library for elliptic curve cryptography needs, in particular for blockchain protocols and zero-knowledge proofs system.
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The library focuses on following properties:
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- constant-time (not leaking secret data via side-channels)
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- performance
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- generated code size, datatype size and stack usage
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in this order
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## Security
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Hardening an implementation against all existing and upcoming attack vectors is an extremely complex task.
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The library is provided as is, without any guarantees at least until:
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- it gets audited
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- formal proofs of correctness are produced
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- formal verification of constant-time implementation is possible
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Defense against common attack vectors are provided on a best effort basis.
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Attackers may go to great lengths to retrieve secret data including:
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- Timing the time taken to multiply on an elliptic curve
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- Analysing the power usage of embedded devices
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- Detecting cache misses when using lookup tables
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- Memory attacks like page-faults, allocators, memory retention attacks
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This is would be incomplete without mentioning that the hardware, OS and compiler
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actively hinder you by:
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- Hardware: sometimes not implementing multiplication in constant-time.
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- OS: not providing a way to prevent memory paging to disk, core dumps, a debugger attaching to your process or a context switch (coroutines) leaking register data.
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- Compiler: optimizing away your carefully crafted branchless code and leaking server secrets or optimizing away your secure erasure routine which is "useless" because at the end of the function the data is not used anymore.
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A growing number of attack vectors is being collected for your viewing pleasure
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at https://github.com/mratsim/constantine/wiki/Constant-time-arithmetics
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## Performance
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High-performance is a sought out property.
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Note that security and side-channel resistance takes priority over performance.
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New applications of elliptic curve cryptography like zero-knowledge proofs or
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proof-of-stake based blockchain protocols are bottlenecked by cryptography.
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### In blockchain
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Ethereum 2 clients spent or use to spend anywhere between 30% to 99% of their processing time verifying the signatures of block validators on R&D testnets
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Assuming we want nodes to handle a thousand peers, if a cryptographic pairing takes 1ms, that represents 1s of cryptography per block to sign with a target
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block frequency of 1 every 6 seconds.
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### In zero-knowledge proofs
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According to https://medium.com/loopring-protocol/zksnark-prover-optimizations-3e9a3e5578c0
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a 16-core CPU can prove 20 transfers/second or 10 transactions/second.
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The previous implementation was 15x slower and one of the key optimizations
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was changing the elliptic curve cryptography backend.
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It had a direct implication on hardware cost and/or cloud computing resources required.
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### Compiler caveats
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Unfortunately compilers and in particular GCC are not very good at optimizing big integers and/or cryptographic code even when using intrinsics like `addcarry_u64`.
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Compilers with proper support of `addcarry_u64` like Clang, MSVC and ICC
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may generate code up to 20~25% faster than GCC.
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This is explained by the GMP team: https://gmplib.org/manual/Assembly-Carry-Propagation.html
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and can be reproduced with the following C code.
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See https://gcc.godbolt.org/z/2h768y
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```C
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#include <stdint.h>
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#include <x86intrin.h>
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void add256(uint64_t a[4], uint64_t b[4]){
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uint8_t carry = 0;
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for (int i = 0; i < 4; ++i)
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carry = _addcarry_u64(carry, a[i], b[i], &a[i]);
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}
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```
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GCC
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```asm
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add256:
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movq (%rsi), %rax
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addq (%rdi), %rax
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setc %dl
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movq %rax, (%rdi)
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movq 8(%rdi), %rax
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addb $-1, %dl
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adcq 8(%rsi), %rax
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setc %dl
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movq %rax, 8(%rdi)
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movq 16(%rdi), %rax
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addb $-1, %dl
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adcq 16(%rsi), %rax
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setc %dl
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movq %rax, 16(%rdi)
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movq 24(%rsi), %rax
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addb $-1, %dl
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adcq %rax, 24(%rdi)
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ret
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```
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Clang
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```asm
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add256:
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movq (%rsi), %rax
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addq %rax, (%rdi)
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movq 8(%rsi), %rax
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adcq %rax, 8(%rdi)
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movq 16(%rsi), %rax
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adcq %rax, 16(%rdi)
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movq 24(%rsi), %rax
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adcq %rax, 24(%rdi)
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retq
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```
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### Inline assembly
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Constantine uses inline assembly for a very restricted use-case: "conditional mov",
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and a temporary use-case "hardware 128-bit division" that will be replaced ASAP (as hardware division is not constant-time).
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Using intrinsics otherwise significantly improve code readability, portability, auditability and maintainability.
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#### Future optimizations
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In the future more inline assembly primitives might be added provided the performance benefit outvalues the significant complexity.
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In particular, multiprecision multiplication and squaring on x86 can use the instructions MULX, ADCX and ADOX
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to multiply-accumulate on 2 carry chains in parallel (with instruction-level parallelism)
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and improve performance by 15~20% over an uint128-based implementation.
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As no compiler is able to generate such code even when using the `_mulx_u64` and `_addcarryx_u64` intrinsics,
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either the assembly for each supported bigint size must be hardcoded
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or a "compiler" must be implemented in macros that will generate the required inline assembly at compile-time.
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Such a compiler can also be used to overcome GCC codegen deficiencies, here is an example for add-with-carry:
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https://github.com/mratsim/finite-fields/blob/d7f6d8bb/macro_add_carry.nim
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## Sizes: code size, stack usage
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Thanks to 10x smaller key sizes for the same security level as RSA, elliptic curve cryptography
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is widely used on resource-constrained devices.
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Constantine is actively optimize for code-size and stack usage.
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Constantine does not use heap allocation.
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At the moment Constantine is optimized for 32-bit and 64-bit CPUs.
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When performance and code size conflicts, a careful and informed default is chosen.
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In the future, a compile-time flag that goes beyond the compiler `-Os` might be provided.
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### Example tradeoff
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Unrolling Montgomery Multiplication brings about 15% performance improvement
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which translate to ~15% on all operations in Constantine as field multiplication bottlenecks
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all cryptographic primitives.
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This is considered a worthwhile tradeoff on all but the most constrained CPUs
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with those CPUs probably being 8-bit or 16-bit.
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## License
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Licensed and distributed under either of
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* MIT license: [LICENSE-MIT](LICENSE-MIT) or http://opensource.org/licenses/MIT
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or
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* Apache License, Version 2.0, ([LICENSE-APACHEv2](LICENSE-APACHEv2) or http://www.apache.org/licenses/LICENSE-2.0)
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at your option. This file may not be copied, modified, or distributed except according to those terms.
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