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|
use bitflags::bitflags;
use foreign_types::{ForeignType, ForeignTypeRef};
use libc::c_int;
use std::mem;
use std::ptr;
use crate::bio::{MemBio, MemBioSlice};
use crate::error::ErrorStack;
use crate::pkey::{HasPrivate, PKeyRef};
use crate::stack::{Stack, StackRef};
use crate::symm::Cipher;
use crate::x509::store::X509StoreRef;
use crate::x509::{X509Ref, X509};
use crate::{cvt, cvt_p};
use openssl_macros::corresponds;
foreign_type_and_impl_send_sync! {
type CType = ffi::PKCS7;
fn drop = ffi::PKCS7_free;
/// A PKCS#7 structure.
///
/// Contains signed and/or encrypted data.
pub struct Pkcs7;
/// Reference to `Pkcs7`
pub struct Pkcs7Ref;
}
bitflags! {
pub struct Pkcs7Flags: c_int {
const TEXT = ffi::PKCS7_TEXT;
const NOCERTS = ffi::PKCS7_NOCERTS;
const NOSIGS = ffi::PKCS7_NOSIGS;
const NOCHAIN = ffi::PKCS7_NOCHAIN;
const NOINTERN = ffi::PKCS7_NOINTERN;
const NOVERIFY = ffi::PKCS7_NOVERIFY;
const DETACHED = ffi::PKCS7_DETACHED;
const BINARY = ffi::PKCS7_BINARY;
const NOATTR = ffi::PKCS7_NOATTR;
const NOSMIMECAP = ffi::PKCS7_NOSMIMECAP;
const NOOLDMIMETYPE = ffi::PKCS7_NOOLDMIMETYPE;
const CRLFEOL = ffi::PKCS7_CRLFEOL;
const STREAM = ffi::PKCS7_STREAM;
const NOCRL = ffi::PKCS7_NOCRL;
const PARTIAL = ffi::PKCS7_PARTIAL;
const REUSE_DIGEST = ffi::PKCS7_REUSE_DIGEST;
#[cfg(not(any(ossl101, ossl102, libressl)))]
const NO_DUAL_CONTENT = ffi::PKCS7_NO_DUAL_CONTENT;
}
}
impl Pkcs7 {
from_pem! {
/// Deserializes a PEM-encoded PKCS#7 signature
///
/// The input should have a header of `-----BEGIN PKCS7-----`.
#[corresponds(PEM_read_bio_PKCS7)]
from_pem,
Pkcs7,
ffi::PEM_read_bio_PKCS7
}
from_der! {
/// Deserializes a DER-encoded PKCS#7 signature
#[corresponds(d2i_PKCS7)]
from_der,
Pkcs7,
ffi::d2i_PKCS7
}
/// Parses a message in S/MIME format.
///
/// Returns the loaded signature, along with the cleartext message (if
/// available).
#[corresponds(SMIME_read_PKCS7)]
pub fn from_smime(input: &[u8]) -> Result<(Pkcs7, Option<Vec<u8>>), ErrorStack> {
ffi::init();
let input_bio = MemBioSlice::new(input)?;
let mut bcont_bio = ptr::null_mut();
unsafe {
let pkcs7 =
cvt_p(ffi::SMIME_read_PKCS7(input_bio.as_ptr(), &mut bcont_bio)).map(Pkcs7)?;
let out = if !bcont_bio.is_null() {
let bcont_bio = MemBio::from_ptr(bcont_bio);
Some(bcont_bio.get_buf().to_vec())
} else {
None
};
Ok((pkcs7, out))
}
}
/// Creates and returns a PKCS#7 `envelopedData` structure.
///
/// `certs` is a list of recipient certificates. `input` is the content to be
/// encrypted. `cipher` is the symmetric cipher to use. `flags` is an optional
/// set of flags.
#[corresponds(PKCS7_encrypt)]
pub fn encrypt(
certs: &StackRef<X509>,
input: &[u8],
cipher: Cipher,
flags: Pkcs7Flags,
) -> Result<Pkcs7, ErrorStack> {
let input_bio = MemBioSlice::new(input)?;
unsafe {
cvt_p(ffi::PKCS7_encrypt(
certs.as_ptr(),
input_bio.as_ptr(),
cipher.as_ptr(),
flags.bits,
))
.map(Pkcs7)
}
}
/// Creates and returns a PKCS#7 `signedData` structure.
///
/// `signcert` is the certificate to sign with, `pkey` is the corresponding
/// private key. `certs` is an optional additional set of certificates to
/// include in the PKCS#7 structure (for example any intermediate CAs in the
/// chain).
#[corresponds(PKCS7_sign)]
pub fn sign<PT>(
signcert: &X509Ref,
pkey: &PKeyRef<PT>,
certs: &StackRef<X509>,
input: &[u8],
flags: Pkcs7Flags,
) -> Result<Pkcs7, ErrorStack>
where
PT: HasPrivate,
{
let input_bio = MemBioSlice::new(input)?;
unsafe {
cvt_p(ffi::PKCS7_sign(
signcert.as_ptr(),
pkey.as_ptr(),
certs.as_ptr(),
input_bio.as_ptr(),
flags.bits,
))
.map(Pkcs7)
}
}
}
impl Pkcs7Ref {
/// Converts PKCS#7 structure to S/MIME format
#[corresponds(SMIME_write_PKCS7)]
pub fn to_smime(&self, input: &[u8], flags: Pkcs7Flags) -> Result<Vec<u8>, ErrorStack> {
let input_bio = MemBioSlice::new(input)?;
let output = MemBio::new()?;
unsafe {
cvt(ffi::SMIME_write_PKCS7(
output.as_ptr(),
self.as_ptr(),
input_bio.as_ptr(),
flags.bits,
))
.map(|_| output.get_buf().to_owned())
}
}
to_pem! {
/// Serializes the data into a PEM-encoded PKCS#7 structure.
///
/// The output will have a header of `-----BEGIN PKCS7-----`.
#[corresponds(PEM_write_bio_PKCS7)]
to_pem,
ffi::PEM_write_bio_PKCS7
}
to_der! {
/// Serializes the data into a DER-encoded PKCS#7 structure.
#[corresponds(i2d_PKCS7)]
to_der,
ffi::i2d_PKCS7
}
/// Decrypts data using the provided private key.
///
/// `pkey` is the recipient's private key, and `cert` is the recipient's
/// certificate.
///
/// Returns the decrypted message.
#[corresponds(PKCS7_decrypt)]
pub fn decrypt<PT>(
&self,
pkey: &PKeyRef<PT>,
cert: &X509Ref,
flags: Pkcs7Flags,
) -> Result<Vec<u8>, ErrorStack>
where
PT: HasPrivate,
{
let output = MemBio::new()?;
unsafe {
cvt(ffi::PKCS7_decrypt(
self.as_ptr(),
pkey.as_ptr(),
cert.as_ptr(),
output.as_ptr(),
flags.bits,
))
.map(|_| output.get_buf().to_owned())
}
}
/// Verifies the PKCS#7 `signedData` structure contained by `&self`.
///
/// `certs` is a set of certificates in which to search for the signer's
/// certificate. `store` is a trusted certificate store (used for chain
/// verification). `indata` is the signed data if the content is not present
/// in `&self`. The content is written to `out` if it is not `None`.
#[corresponds(PKCS7_verify)]
pub fn verify(
&self,
certs: &StackRef<X509>,
store: &X509StoreRef,
indata: Option<&[u8]>,
out: Option<&mut Vec<u8>>,
flags: Pkcs7Flags,
) -> Result<(), ErrorStack> {
let out_bio = MemBio::new()?;
let indata_bio = match indata {
Some(data) => Some(MemBioSlice::new(data)?),
None => None,
};
let indata_bio_ptr = indata_bio.as_ref().map_or(ptr::null_mut(), |p| p.as_ptr());
unsafe {
cvt(ffi::PKCS7_verify(
self.as_ptr(),
certs.as_ptr(),
store.as_ptr(),
indata_bio_ptr,
out_bio.as_ptr(),
flags.bits,
))
.map(|_| ())?
}
if let Some(data) = out {
data.clear();
data.extend_from_slice(out_bio.get_buf());
}
Ok(())
}
/// Retrieve the signer's certificates from the PKCS#7 structure without verifying them.
#[corresponds(PKCS7_get0_signers)]
pub fn signers(
&self,
certs: &StackRef<X509>,
flags: Pkcs7Flags,
) -> Result<Stack<X509>, ErrorStack> {
unsafe {
let ptr = cvt_p(ffi::PKCS7_get0_signers(
self.as_ptr(),
certs.as_ptr(),
flags.bits,
))?;
// The returned stack is owned by the caller, but the certs inside are not! Our stack interface can't deal
// with that, so instead we just manually bump the refcount of the certs so that the whole stack is properly
// owned.
let stack = Stack::<X509>::from_ptr(ptr);
for cert in &stack {
mem::forget(cert.to_owned());
}
Ok(stack)
}
}
}
#[cfg(test)]
mod tests {
use crate::hash::MessageDigest;
use crate::pkcs7::{Pkcs7, Pkcs7Flags};
use crate::pkey::PKey;
use crate::stack::Stack;
use crate::symm::Cipher;
use crate::x509::store::X509StoreBuilder;
use crate::x509::X509;
#[test]
fn encrypt_decrypt_test() {
let cert = include_bytes!("../test/certs.pem");
let cert = X509::from_pem(cert).unwrap();
let mut certs = Stack::new().unwrap();
certs.push(cert.clone()).unwrap();
let message: String = String::from("foo");
let cipher = Cipher::des_ede3_cbc();
let flags = Pkcs7Flags::STREAM;
let pkey = include_bytes!("../test/key.pem");
let pkey = PKey::private_key_from_pem(pkey).unwrap();
let pkcs7 =
Pkcs7::encrypt(&certs, message.as_bytes(), cipher, flags).expect("should succeed");
let encrypted = pkcs7
.to_smime(message.as_bytes(), flags)
.expect("should succeed");
let (pkcs7_decoded, _) = Pkcs7::from_smime(encrypted.as_slice()).expect("should succeed");
let decoded = pkcs7_decoded
.decrypt(&pkey, &cert, Pkcs7Flags::empty())
.expect("should succeed");
assert_eq!(decoded, message.into_bytes());
}
#[test]
fn sign_verify_test_detached() {
let cert = include_bytes!("../test/cert.pem");
let cert = X509::from_pem(cert).unwrap();
let certs = Stack::new().unwrap();
let message = "foo";
let flags = Pkcs7Flags::STREAM | Pkcs7Flags::DETACHED;
let pkey = include_bytes!("../test/key.pem");
let pkey = PKey::private_key_from_pem(pkey).unwrap();
let mut store_builder = X509StoreBuilder::new().expect("should succeed");
let root_ca = include_bytes!("../test/root-ca.pem");
let root_ca = X509::from_pem(root_ca).unwrap();
store_builder.add_cert(root_ca).expect("should succeed");
let store = store_builder.build();
let pkcs7 =
Pkcs7::sign(&cert, &pkey, &certs, message.as_bytes(), flags).expect("should succeed");
let signed = pkcs7
.to_smime(message.as_bytes(), flags)
.expect("should succeed");
println!("{:?}", String::from_utf8(signed.clone()).unwrap());
let (pkcs7_decoded, content) =
Pkcs7::from_smime(signed.as_slice()).expect("should succeed");
let mut output = Vec::new();
pkcs7_decoded
.verify(
&certs,
&store,
Some(message.as_bytes()),
Some(&mut output),
flags,
)
.expect("should succeed");
assert_eq!(output, message.as_bytes());
assert_eq!(content.expect("should be non-empty"), message.as_bytes());
}
/// https://marc.info/?l=openbsd-cvs&m=166602943014106&w=2
#[test]
#[cfg_attr(all(libressl360, not(libressl361)), ignore)]
fn sign_verify_test_normal() {
let cert = include_bytes!("../test/cert.pem");
let cert = X509::from_pem(cert).unwrap();
let certs = Stack::new().unwrap();
let message = "foo";
let flags = Pkcs7Flags::STREAM;
let pkey = include_bytes!("../test/key.pem");
let pkey = PKey::private_key_from_pem(pkey).unwrap();
let mut store_builder = X509StoreBuilder::new().expect("should succeed");
let root_ca = include_bytes!("../test/root-ca.pem");
let root_ca = X509::from_pem(root_ca).unwrap();
store_builder.add_cert(root_ca).expect("should succeed");
let store = store_builder.build();
let pkcs7 =
Pkcs7::sign(&cert, &pkey, &certs, message.as_bytes(), flags).expect("should succeed");
let signed = pkcs7
.to_smime(message.as_bytes(), flags)
.expect("should succeed");
let (pkcs7_decoded, content) =
Pkcs7::from_smime(signed.as_slice()).expect("should succeed");
let mut output = Vec::new();
pkcs7_decoded
.verify(&certs, &store, None, Some(&mut output), flags)
.expect("should succeed");
assert_eq!(output, message.as_bytes());
assert!(content.is_none());
}
/// https://marc.info/?l=openbsd-cvs&m=166602943014106&w=2
#[test]
#[cfg_attr(all(libressl360, not(libressl361)), ignore)]
fn signers() {
let cert = include_bytes!("../test/cert.pem");
let cert = X509::from_pem(cert).unwrap();
let cert_digest = cert.digest(MessageDigest::sha256()).unwrap();
let certs = Stack::new().unwrap();
let message = "foo";
let flags = Pkcs7Flags::STREAM;
let pkey = include_bytes!("../test/key.pem");
let pkey = PKey::private_key_from_pem(pkey).unwrap();
let mut store_builder = X509StoreBuilder::new().expect("should succeed");
let root_ca = include_bytes!("../test/root-ca.pem");
let root_ca = X509::from_pem(root_ca).unwrap();
store_builder.add_cert(root_ca).expect("should succeed");
let pkcs7 =
Pkcs7::sign(&cert, &pkey, &certs, message.as_bytes(), flags).expect("should succeed");
let signed = pkcs7
.to_smime(message.as_bytes(), flags)
.expect("should succeed");
let (pkcs7_decoded, _) = Pkcs7::from_smime(signed.as_slice()).expect("should succeed");
let empty_certs = Stack::new().unwrap();
let signer_certs = pkcs7_decoded
.signers(&empty_certs, flags)
.expect("should succeed");
assert_eq!(empty_certs.len(), 0);
assert_eq!(signer_certs.len(), 1);
let signer_digest = signer_certs[0].digest(MessageDigest::sha256()).unwrap();
assert_eq!(*cert_digest, *signer_digest);
}
#[test]
fn invalid_from_smime() {
let input = String::from("Invalid SMIME Message");
let result = Pkcs7::from_smime(input.as_bytes());
assert!(result.is_err());
}
}
|