Google Git
Sign in
android / platform / external / rust / crates / openssl / refs/heads/trusty-main / . / src / pkcs12.rs
blob: d4e19dc9f3ceb6300349e3671d72810724dc8af3 [file] [log] [blame]
//! PKCS #12 archives.
use foreign_types::{ForeignType, ForeignTypeRef};
use libc::c_int;
use std::ffi::CString;
use std::ptr;
use crate::error::ErrorStack;
#[cfg(not(boringssl))]
use crate::hash::MessageDigest;
use crate::nid::Nid;
use crate::pkey::{HasPrivate, PKey, PKeyRef, Private};
use crate::stack::Stack;
use crate::util::ForeignTypeExt;
use crate::x509::{X509Ref, X509};
use crate::{cvt, cvt_p};
use openssl_macros::corresponds;
foreign_type_and_impl_send_sync! {
type CType = ffi::PKCS12;
fn drop = ffi::PKCS12_free;
pub struct Pkcs12;
pub struct Pkcs12Ref;
}
impl Pkcs12Ref {
to_der! {
/// Serializes the `Pkcs12` to its standard DER encoding.
#[corresponds(i2d_PKCS12)]
to_der,
ffi::i2d_PKCS12
}
/// Extracts the contents of the `Pkcs12`.
#[corresponds(PKCS12_parse)]
pub fn parse(&self, pass: &str) -> Result<ParsedPkcs12, ErrorStack> {
unsafe {
let pass = CString::new(pass.as_bytes()).unwrap();
let mut pkey = ptr::null_mut();
let mut cert = ptr::null_mut();
let mut chain = ptr::null_mut();
cvt(ffi::PKCS12_parse(
self.as_ptr(),
pass.as_ptr(),
&mut pkey,
&mut cert,
&mut chain,
))?;
let pkey = PKey::from_ptr(pkey);
let cert = X509::from_ptr(cert);
let chain = Stack::from_ptr_opt(chain);
Ok(ParsedPkcs12 { pkey, cert, chain })
}
}
}
impl Pkcs12 {
from_der! {
/// Deserializes a DER-encoded PKCS#12 archive.
#[corresponds(d2i_PKCS12)]
from_der,
Pkcs12,
ffi::d2i_PKCS12
}
/// Creates a new builder for a protected pkcs12 certificate.
///
/// This uses the defaults from the OpenSSL library:
///
/// * `nid_key` - `AES_256_CBC` (3.0.0+) or `PBE_WITHSHA1AND3_KEY_TRIPLEDES_CBC`
/// * `nid_cert` - `AES_256_CBC` (3.0.0+) or `PBE_WITHSHA1AND40BITRC2_CBC`
/// * `iter` - `2048`
/// * `mac_iter` - `2048`
/// * `mac_md` - `SHA-256` (3.0.0+) or `SHA-1` (`SHA-1` only for BoringSSL)
pub fn builder() -> Pkcs12Builder {
ffi::init();
Pkcs12Builder {
nid_key: Nid::UNDEF,
nid_cert: Nid::UNDEF,
iter: ffi::PKCS12_DEFAULT_ITER,
mac_iter: ffi::PKCS12_DEFAULT_ITER,
#[cfg(not(boringssl))]
mac_md: None,
ca: None,
}
}
}
pub struct ParsedPkcs12 {
pub pkey: PKey<Private>,
pub cert: X509,
pub chain: Option<Stack<X509>>,
}
pub struct Pkcs12Builder {
nid_key: Nid,
nid_cert: Nid,
iter: c_int,
mac_iter: c_int,
#[cfg(not(boringssl))]
mac_md: Option<MessageDigest>,
ca: Option<Stack<X509>>,
}
impl Pkcs12Builder {
/// The encryption algorithm that should be used for the key
pub fn key_algorithm(&mut self, nid: Nid) -> &mut Self {
self.nid_key = nid;
self
}
/// The encryption algorithm that should be used for the cert
pub fn cert_algorithm(&mut self, nid: Nid) -> &mut Self {
self.nid_cert = nid;
self
}
/// Key iteration count, default is 2048 as of this writing
pub fn key_iter(&mut self, iter: u32) -> &mut Self {
self.iter = iter as c_int;
self
}
/// MAC iteration count, default is the same as key_iter.
///
/// Old implementations don't understand MAC iterations greater than 1, (pre 1.0.1?), if such
/// compatibility is required this should be set to 1.
pub fn mac_iter(&mut self, mac_iter: u32) -> &mut Self {
self.mac_iter = mac_iter as c_int;
self
}
/// MAC message digest type
#[cfg(not(boringssl))]
pub fn mac_md(&mut self, md: MessageDigest) -> &mut Self {
self.mac_md = Some(md);
self
}
/// An additional set of certificates to include in the archive beyond the one provided to
/// `build`.
pub fn ca(&mut self, ca: Stack<X509>) -> &mut Self {
self.ca = Some(ca);
self
}
/// Builds the PKCS #12 object
///
/// # Arguments
///
/// * `password` - the password used to encrypt the key and certificate
/// * `friendly_name` - user defined name for the certificate
/// * `pkey` - key to store
/// * `cert` - certificate to store
#[corresponds(PKCS12_create)]
pub fn build<T>(
self,
password: &str,
friendly_name: &str,
pkey: &PKeyRef<T>,
cert: &X509Ref,
) -> Result<Pkcs12, ErrorStack>
where
T: HasPrivate,
{
unsafe {
let pass = CString::new(password).unwrap();
let friendly_name = CString::new(friendly_name).unwrap();
let pkey = pkey.as_ptr();
let cert = cert.as_ptr();
let ca = self
.ca
.as_ref()
.map(|ca| ca.as_ptr())
.unwrap_or(ptr::null_mut());
let nid_key = self.nid_key.as_raw();
let nid_cert = self.nid_cert.as_raw();
// According to the OpenSSL docs, keytype is a non-standard extension for MSIE,
// It's values are KEY_SIG or KEY_EX, see the OpenSSL docs for more information:
// https://www.openssl.org/docs/man1.0.2/crypto/PKCS12_create.html
let keytype = 0;
let pkcs12 = cvt_p(ffi::PKCS12_create(
pass.as_ptr() as *const _ as *mut _,
friendly_name.as_ptr() as *const _ as *mut _,
pkey,
cert,
ca,
nid_key,
nid_cert,
self.iter,
self.mac_iter,
keytype,
))
.map(Pkcs12)?;
#[cfg(not(boringssl))]
// BoringSSL does not support overriding the MAC and will always
// use SHA-1
{
let md_type = self
.mac_md
.map(|md_type| md_type.as_ptr())
.unwrap_or(ptr::null());
cvt(ffi::PKCS12_set_mac(
pkcs12.as_ptr(),
pass.as_ptr(),
-1,
ptr::null_mut(),
0,
self.mac_iter,
md_type,
))?;
}
Ok(pkcs12)
}
}
}
#[cfg(test)]
mod test {
use crate::asn1::Asn1Time;
use crate::hash::MessageDigest;
use crate::nid::Nid;
use crate::pkey::PKey;
use crate::rsa::Rsa;
use crate::x509::extension::KeyUsage;
use crate::x509::{X509Name, X509};
use super::*;
#[test]
fn parse() {
#[cfg(ossl300)]
let _provider = crate::provider::Provider::try_load(None, "legacy", true).unwrap();
let der = include_bytes!("../test/identity.p12");
let pkcs12 = Pkcs12::from_der(der).unwrap();
let parsed = pkcs12.parse("mypass").unwrap();
assert_eq!(
hex::encode(parsed.cert.digest(MessageDigest::sha1()).unwrap()),
"59172d9313e84459bcff27f967e79e6e9217e584"
);
let chain = parsed.chain.unwrap();
assert_eq!(chain.len(), 1);
assert_eq!(
hex::encode(chain[0].digest(MessageDigest::sha1()).unwrap()),
"c0cbdf7cdd03c9773e5468e1f6d2da7d5cbb1875"
);
}
#[test]
fn parse_empty_chain() {
#[cfg(ossl300)]
let _provider = crate::provider::Provider::try_load(None, "legacy", true).unwrap();
let der = include_bytes!("../test/keystore-empty-chain.p12");
let pkcs12 = Pkcs12::from_der(der).unwrap();
let parsed = pkcs12.parse("cassandra").unwrap();
if let Some(stack) = parsed.chain {
assert_eq!(stack.len(), 0);
}
}
#[test]
fn create() {
let subject_name = "ns.example.com";
let rsa = Rsa::generate(2048).unwrap();
let pkey = PKey::from_rsa(rsa).unwrap();
let mut name = X509Name::builder().unwrap();
name.append_entry_by_nid(Nid::COMMONNAME, subject_name)
.unwrap();
let name = name.build();
let key_usage = KeyUsage::new().digital_signature().build().unwrap();
let mut builder = X509::builder().unwrap();
builder.set_version(2).unwrap();
builder
.set_not_before(&Asn1Time::days_from_now(0).unwrap())
.unwrap();
builder
.set_not_after(&Asn1Time::days_from_now(365).unwrap())
.unwrap();
builder.set_subject_name(&name).unwrap();
builder.set_issuer_name(&name).unwrap();
builder.append_extension(key_usage).unwrap();
builder.set_pubkey(&pkey).unwrap();
builder.sign(&pkey, MessageDigest::sha256()).unwrap();
let cert = builder.build();
let pkcs12_builder = Pkcs12::builder();
let pkcs12 = pkcs12_builder
.build("mypass", subject_name, &pkey, &cert)
.unwrap();
let der = pkcs12.to_der().unwrap();
let pkcs12 = Pkcs12::from_der(&der).unwrap();
let parsed = pkcs12.parse("mypass").unwrap();
assert_eq!(
&*parsed.cert.digest(MessageDigest::sha1()).unwrap(),
&*cert.digest(MessageDigest::sha1()).unwrap()
);
assert!(parsed.pkey.public_eq(&pkey));
}
}