apkverify/src/v3.rs - android_packages_modules_Virtualization - Gitiles

 /*
  * Copyright (C) 2021 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 //! Verifies APK Signature Scheme V3

 // TODO(jooyung) remove this
 #![allow(dead_code)]

 use anyhow::{anyhow, bail, Context, Result};
 use bytes::Bytes;
 use ring::signature::{
     UnparsedPublicKey, VerificationAlgorithm, ECDSA_P256_SHA256_ASN1, RSA_PKCS1_2048_8192_SHA256,
     RSA_PKCS1_2048_8192_SHA512, RSA_PSS_2048_8192_SHA256, RSA_PSS_2048_8192_SHA512,
 };
 use std::fs::File;
 use std::io::{Read, Seek};
 use std::ops::Range;
 use std::path::Path;
 use x509_parser::{parse_x509_certificate, prelude::FromDer, x509::SubjectPublicKeyInfo};

 use crate::bytes_ext::{BytesExt, LengthPrefixed, ReadFromBytes};
 use crate::sigutil::*;

 pub const APK_SIGNATURE_SCHEME_V3_BLOCK_ID: u32 = 0xf05368c0;

 // TODO(jooyung): get "ro.build.version.sdk"
 const SDK_INT: u32 = 31;

 /// Data model for Signature Scheme V3
 /// https://source.android.com/security/apksigning/v3#verification

 type Signers = LengthPrefixed<Vec<LengthPrefixed<Signer>>>;

 struct Signer {
     signed_data: LengthPrefixed<Bytes>, // not verified yet
     min_sdk: u32,
     max_sdk: u32,
     signatures: LengthPrefixed<Vec<LengthPrefixed<Signature>>>,
     public_key: LengthPrefixed<Bytes>,
 }

 impl Signer {
     fn sdk_range(&self) -> Range<u32> {
         self.min_sdk..self.max_sdk
     }
 }

 struct SignedData {
     digests: LengthPrefixed<Vec<LengthPrefixed<Digest>>>,
     certificates: LengthPrefixed<Vec<LengthPrefixed<X509Certificate>>>,
     min_sdk: u32,
     max_sdk: u32,
     additional_attributes: LengthPrefixed<Vec<LengthPrefixed<AdditionalAttributes>>>,
 }

 impl SignedData {
     fn sdk_range(&self) -> Range<u32> {
         self.min_sdk..self.max_sdk
     }
 }

 #[derive(Debug)]
 struct Signature {
     signature_algorithm_id: u32,
     signature: LengthPrefixed<Bytes>,
 }

 struct Digest {
     signature_algorithm_id: u32,
     digest: LengthPrefixed<Bytes>,
 }

 type X509Certificate = Bytes;
 type AdditionalAttributes = Bytes;

 /// Verifies APK Signature Scheme v3 signatures of the provided APK and returns the public key
 /// associated with the signer.
 pub fn verify<P: AsRef<Path>>(path: P) -> Result<Box<[u8]>> {
     let f = File::open(path.as_ref())?;
     let mut sections = ApkSections::new(f)?;
     find_signer_and_then(&mut sections, |(signer, sections)| signer.verify(sections))
 }

 /// Finds the supported signer and execute a function on it.
 fn find_signer_and_then<R, U, F>(sections: &mut ApkSections<R>, f: F) -> Result<U>
 where
     R: Read + Seek,
     F: FnOnce((&Signer, &mut ApkSections<R>)) -> Result<U>,
 {
     let mut block = sections.find_signature(APK_SIGNATURE_SCHEME_V3_BLOCK_ID)?;
     // parse v3 scheme block
     let signers = block.read::<Signers>()?;

     // find supported by platform
     let supported = signers.iter().filter(|s| s.sdk_range().contains(&SDK_INT)).collect::<Vec<_>>();

     // there should be exactly one
     if supported.len() != 1 {
         bail!(
             "APK Signature Scheme V3 only supports one signer: {} signers found.",
             supported.len()
         )
     }

     // Call the supplied function
     f((supported[0], sections))
 }

 /// Gets the public key (in DER format) that was used to sign the given APK/APEX file
 pub fn get_public_key_der<P: AsRef<Path>>(path: P) -> Result<Box<[u8]>> {
     let f = File::open(path.as_ref())?;
     let mut sections = ApkSections::new(f)?;
     find_signer_and_then(&mut sections, |(signer, _)| {
         Ok(signer.public_key.to_vec().into_boxed_slice())
     })
 }

 impl Signer {
     fn verify<R: Read + Seek>(&self, sections: &mut ApkSections<R>) -> Result<Box<[u8]>> {
         // 1. Choose the strongest supported signature algorithm ID from signatures. The strength
         //    ordering is up to each implementation/platform version.
         let strongest: &Signature = self
             .signatures
             .iter()
             .filter(|sig| is_supported_signature_algorithm(sig.signature_algorithm_id))
             .max_by_key(|sig| rank_signature_algorithm(sig.signature_algorithm_id).unwrap())
             .ok_or_else(|| anyhow!("No supported signatures found"))?;

         // 2. Verify the corresponding signature from signatures against signed data using public key.
         //    (It is now safe to parse signed data.)
         let (_, key_info) = SubjectPublicKeyInfo::from_der(self.public_key.as_ref())?;
         verify_signed_data(&self.signed_data, strongest, &key_info)?;

         // It is now safe to parse signed data.
         let signed_data: SignedData = self.signed_data.slice(..).read()?;

         // 3. Verify the min and max SDK versions in the signed data match those specified for the
         //    signer.
         if self.sdk_range() != signed_data.sdk_range() {
             bail!("SDK versions mismatch between signed and unsigned in v3 signer block.");
         }

         // 4. Verify that the ordered list of signature algorithm IDs in digests and signatures is
         //    identical. (This is to prevent signature stripping/addition.)
         if !self
             .signatures
             .iter()
             .map(|sig| sig.signature_algorithm_id)
             .eq(signed_data.digests.iter().map(|dig| dig.signature_algorithm_id))
         {
             bail!("Signature algorithms don't match between digests and signatures records");
         }

         // 5. Compute the digest of APK contents using the same digest algorithm as the digest
         //    algorithm used by the signature algorithm.
         let digest = signed_data
             .digests
             .iter()
             .find(|&dig| dig.signature_algorithm_id == strongest.signature_algorithm_id)
             .unwrap(); // ok to unwrap since we check if two lists are the same above
         let computed = sections.compute_digest(digest.signature_algorithm_id)?;

         // 6. Verify that the computed digest is identical to the corresponding digest from digests.
         if computed != digest.digest.as_ref() {
             bail!(
                 "Digest mismatch: computed={:?} vs expected={:?}",
                 to_hex_string(&computed),
                 to_hex_string(&digest.digest),
             );
         }

         // 7. Verify that SubjectPublicKeyInfo of the first certificate of certificates is identical
         //    to public key.
         let cert = signed_data.certificates.first().context("No certificates listed")?;
         let (_, cert) = parse_x509_certificate(cert.as_ref())?;
         if cert.tbs_certificate.subject_pki != key_info {
             bail!("Public key mismatch between certificate and signature record");
         }

         // TODO(jooyung) 8. If the proof-of-rotation attribute exists for the signer verify that the struct is valid and this signer is the last certificate in the list.
         Ok(self.public_key.to_vec().into_boxed_slice())
     }
 }

 fn verify_signed_data(
     data: &Bytes,
     signature: &Signature,
     key_info: &SubjectPublicKeyInfo,
 ) -> Result<()> {
     let verification_alg: &dyn VerificationAlgorithm = match signature.signature_algorithm_id {
         SIGNATURE_RSA_PSS_WITH_SHA256 => &RSA_PSS_2048_8192_SHA256,
         SIGNATURE_RSA_PSS_WITH_SHA512 => &RSA_PSS_2048_8192_SHA512,
         SIGNATURE_RSA_PKCS1_V1_5_WITH_SHA256 | SIGNATURE_VERITY_RSA_PKCS1_V1_5_WITH_SHA256 => {
             &RSA_PKCS1_2048_8192_SHA256
         }
         SIGNATURE_RSA_PKCS1_V1_5_WITH_SHA512 => &RSA_PKCS1_2048_8192_SHA512,
         SIGNATURE_ECDSA_WITH_SHA256 | SIGNATURE_VERITY_ECDSA_WITH_SHA256 => &ECDSA_P256_SHA256_ASN1,
         // TODO(b/190343842) not implemented signature algorithm
         SIGNATURE_ECDSA_WITH_SHA512
         | SIGNATURE_DSA_WITH_SHA256
         | SIGNATURE_VERITY_DSA_WITH_SHA256 => {
             bail!(
                 "TODO(b/190343842) not implemented signature algorithm: {:#x}",
                 signature.signature_algorithm_id
             );
         }
         _ => bail!("Unsupported signature algorithm: {:#x}", signature.signature_algorithm_id),
     };
     let key = UnparsedPublicKey::new(verification_alg, &key_info.subject_public_key);
     key.verify(data.as_ref(), signature.signature.as_ref())?;
     Ok(())
 }

 // ReadFromBytes implementations
 // TODO(jooyung): add derive macro: #[derive(ReadFromBytes)]

 impl ReadFromBytes for Signer {
     fn read_from_bytes(buf: &mut Bytes) -> Result<Self> {
         Ok(Self {
             signed_data: buf.read()?,
             min_sdk: buf.read()?,
             max_sdk: buf.read()?,
             signatures: buf.read()?,
             public_key: buf.read()?,
         })
     }
 }

 impl ReadFromBytes for SignedData {
     fn read_from_bytes(buf: &mut Bytes) -> Result<Self> {
         Ok(Self {
             digests: buf.read()?,
             certificates: buf.read()?,
             min_sdk: buf.read()?,
             max_sdk: buf.read()?,
             additional_attributes: buf.read()?,
         })
     }
 }

 impl ReadFromBytes for Signature {
     fn read_from_bytes(buf: &mut Bytes) -> Result<Self> {
         Ok(Signature { signature_algorithm_id: buf.read()?, signature: buf.read()? })
     }
 }

 impl ReadFromBytes for Digest {
     fn read_from_bytes(buf: &mut Bytes) -> Result<Self> {
         Ok(Self { signature_algorithm_id: buf.read()?, digest: buf.read()? })
     }
 }

 #[inline]
 fn to_hex_string(buf: &[u8]) -> String {
     buf.iter().map(|b| format!("{:02X}", b)).collect()
 }
	/*
	* Copyright (C) 2021 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	//! Verifies APK Signature Scheme V3

	// TODO(jooyung) remove this
	#![allow(dead_code)]

	use anyhow::{anyhow, bail, Context, Result};
	use bytes::Bytes;
	use ring::signature::{
	UnparsedPublicKey, VerificationAlgorithm, ECDSA_P256_SHA256_ASN1, RSA_PKCS1_2048_8192_SHA256,
	RSA_PKCS1_2048_8192_SHA512, RSA_PSS_2048_8192_SHA256, RSA_PSS_2048_8192_SHA512,
	};
	use std::fs::File;
	use std::io::{Read, Seek};
	use std::ops::Range;
	use std::path::Path;
	use x509_parser::{parse_x509_certificate, prelude::FromDer, x509::SubjectPublicKeyInfo};

	use crate::bytes_ext::{BytesExt, LengthPrefixed, ReadFromBytes};
	use crate::sigutil::*;

	pub const APK_SIGNATURE_SCHEME_V3_BLOCK_ID: u32 = 0xf05368c0;

	// TODO(jooyung): get "ro.build.version.sdk"
	const SDK_INT: u32 = 31;

	/// Data model for Signature Scheme V3
	/// https://source.android.com/security/apksigning/v3#verification

	type Signers = LengthPrefixed<Vec<LengthPrefixed<Signer>>>;

	struct Signer {
	signed_data: LengthPrefixed<Bytes>, // not verified yet
	min_sdk: u32,
	max_sdk: u32,
	signatures: LengthPrefixed<Vec<LengthPrefixed<Signature>>>,
	public_key: LengthPrefixed<Bytes>,
	}

	impl Signer {
	fn sdk_range(&self) -> Range<u32> {
	self.min_sdk..self.max_sdk
	}
	}

	struct SignedData {
	digests: LengthPrefixed<Vec<LengthPrefixed<Digest>>>,
	certificates: LengthPrefixed<Vec<LengthPrefixed<X509Certificate>>>,
	min_sdk: u32,
	max_sdk: u32,
	additional_attributes: LengthPrefixed<Vec<LengthPrefixed<AdditionalAttributes>>>,
	}

	impl SignedData {
	fn sdk_range(&self) -> Range<u32> {
	self.min_sdk..self.max_sdk
	}
	}

	#[derive(Debug)]
	struct Signature {
	signature_algorithm_id: u32,
	signature: LengthPrefixed<Bytes>,
	}

	struct Digest {
	signature_algorithm_id: u32,
	digest: LengthPrefixed<Bytes>,
	}

	type X509Certificate = Bytes;
	type AdditionalAttributes = Bytes;

	/// Verifies APK Signature Scheme v3 signatures of the provided APK and returns the public key
	/// associated with the signer.
	pub fn verify<P: AsRef<Path>>(path: P) -> Result<Box<[u8]>> {
	let f = File::open(path.as_ref())?;
	let mut sections = ApkSections::new(f)?;
	find_signer_and_then(&mut sections, \|(signer, sections)\| signer.verify(sections))
	}

	/// Finds the supported signer and execute a function on it.
	fn find_signer_and_then<R, U, F>(sections: &mut ApkSections<R>, f: F) -> Result<U>
	where
	R: Read + Seek,
	F: FnOnce((&Signer, &mut ApkSections<R>)) -> Result<U>,
	{
	let mut block = sections.find_signature(APK_SIGNATURE_SCHEME_V3_BLOCK_ID)?;
	// parse v3 scheme block
	let signers = block.read::<Signers>()?;

	// find supported by platform
	let supported = signers.iter().filter(\|s\| s.sdk_range().contains(&SDK_INT)).collect::<Vec<_>>();

	// there should be exactly one
	if supported.len() != 1 {
	bail!(
	"APK Signature Scheme V3 only supports one signer: {} signers found.",
	supported.len()
	)
	}

	// Call the supplied function
	f((supported[0], sections))
	}

	/// Gets the public key (in DER format) that was used to sign the given APK/APEX file
	pub fn get_public_key_der<P: AsRef<Path>>(path: P) -> Result<Box<[u8]>> {
	let f = File::open(path.as_ref())?;
	let mut sections = ApkSections::new(f)?;
	find_signer_and_then(&mut sections, \|(signer, _)\| {
	Ok(signer.public_key.to_vec().into_boxed_slice())
	})
	}

	impl Signer {
	fn verify<R: Read + Seek>(&self, sections: &mut ApkSections<R>) -> Result<Box<[u8]>> {
	// 1. Choose the strongest supported signature algorithm ID from signatures. The strength
	// ordering is up to each implementation/platform version.
	let strongest: &Signature = self
	.signatures
	.iter()
	.filter(\|sig\| is_supported_signature_algorithm(sig.signature_algorithm_id))
	.max_by_key(\|sig\| rank_signature_algorithm(sig.signature_algorithm_id).unwrap())
	.ok_or_else(\|\| anyhow!("No supported signatures found"))?;

	// 2. Verify the corresponding signature from signatures against signed data using public key.
	// (It is now safe to parse signed data.)
	let (_, key_info) = SubjectPublicKeyInfo::from_der(self.public_key.as_ref())?;
	verify_signed_data(&self.signed_data, strongest, &key_info)?;

	// It is now safe to parse signed data.
	let signed_data: SignedData = self.signed_data.slice(..).read()?;

	// 3. Verify the min and max SDK versions in the signed data match those specified for the
	// signer.
	if self.sdk_range() != signed_data.sdk_range() {
	bail!("SDK versions mismatch between signed and unsigned in v3 signer block.");
	}

	// 4. Verify that the ordered list of signature algorithm IDs in digests and signatures is
	// identical. (This is to prevent signature stripping/addition.)
	if !self
	.signatures
	.iter()
	.map(\|sig\| sig.signature_algorithm_id)
	.eq(signed_data.digests.iter().map(\|dig\| dig.signature_algorithm_id))
	{
	bail!("Signature algorithms don't match between digests and signatures records");
	}

	// 5. Compute the digest of APK contents using the same digest algorithm as the digest
	// algorithm used by the signature algorithm.
	let digest = signed_data
	.digests
	.iter()
	.find(\|&dig\| dig.signature_algorithm_id == strongest.signature_algorithm_id)
	.unwrap(); // ok to unwrap since we check if two lists are the same above
	let computed = sections.compute_digest(digest.signature_algorithm_id)?;

	// 6. Verify that the computed digest is identical to the corresponding digest from digests.
	if computed != digest.digest.as_ref() {
	bail!(
	"Digest mismatch: computed={:?} vs expected={:?}",
	to_hex_string(&computed),
	to_hex_string(&digest.digest),
	);
	}

	// 7. Verify that SubjectPublicKeyInfo of the first certificate of certificates is identical
	// to public key.
	let cert = signed_data.certificates.first().context("No certificates listed")?;
	let (_, cert) = parse_x509_certificate(cert.as_ref())?;
	if cert.tbs_certificate.subject_pki != key_info {
	bail!("Public key mismatch between certificate and signature record");
	}

	// TODO(jooyung) 8. If the proof-of-rotation attribute exists for the signer verify that the struct is valid and this signer is the last certificate in the list.
	Ok(self.public_key.to_vec().into_boxed_slice())
	}
	}

	fn verify_signed_data(
	data: &Bytes,
	signature: &Signature,
	key_info: &SubjectPublicKeyInfo,
	) -> Result<()> {
	let verification_alg: &dyn VerificationAlgorithm = match signature.signature_algorithm_id {
	SIGNATURE_RSA_PSS_WITH_SHA256 => &RSA_PSS_2048_8192_SHA256,
	SIGNATURE_RSA_PSS_WITH_SHA512 => &RSA_PSS_2048_8192_SHA512,
	SIGNATURE_RSA_PKCS1_V1_5_WITH_SHA256 \| SIGNATURE_VERITY_RSA_PKCS1_V1_5_WITH_SHA256 => {
	&RSA_PKCS1_2048_8192_SHA256
	}
	SIGNATURE_RSA_PKCS1_V1_5_WITH_SHA512 => &RSA_PKCS1_2048_8192_SHA512,
	SIGNATURE_ECDSA_WITH_SHA256 \| SIGNATURE_VERITY_ECDSA_WITH_SHA256 => &ECDSA_P256_SHA256_ASN1,
	// TODO(b/190343842) not implemented signature algorithm
	SIGNATURE_ECDSA_WITH_SHA512
	\| SIGNATURE_DSA_WITH_SHA256
	\| SIGNATURE_VERITY_DSA_WITH_SHA256 => {
	bail!(
	"TODO(b/190343842) not implemented signature algorithm: {:#x}",
	signature.signature_algorithm_id
	);
	}
	_ => bail!("Unsupported signature algorithm: {:#x}", signature.signature_algorithm_id),
	};
	let key = UnparsedPublicKey::new(verification_alg, &key_info.subject_public_key);
	key.verify(data.as_ref(), signature.signature.as_ref())?;
	Ok(())
	}

	// ReadFromBytes implementations
	// TODO(jooyung): add derive macro: #[derive(ReadFromBytes)]

	impl ReadFromBytes for Signer {
	fn read_from_bytes(buf: &mut Bytes) -> Result<Self> {
	Ok(Self {
	signed_data: buf.read()?,
	min_sdk: buf.read()?,
	max_sdk: buf.read()?,
	signatures: buf.read()?,
	public_key: buf.read()?,
	})
	}
	}

	impl ReadFromBytes for SignedData {
	fn read_from_bytes(buf: &mut Bytes) -> Result<Self> {
	Ok(Self {
	digests: buf.read()?,
	certificates: buf.read()?,
	min_sdk: buf.read()?,
	max_sdk: buf.read()?,
	additional_attributes: buf.read()?,
	})
	}
	}

	impl ReadFromBytes for Signature {
	fn read_from_bytes(buf: &mut Bytes) -> Result<Self> {
	Ok(Signature { signature_algorithm_id: buf.read()?, signature: buf.read()? })
	}
	}

	impl ReadFromBytes for Digest {
	fn read_from_bytes(buf: &mut Bytes) -> Result<Self> {
	Ok(Self { signature_algorithm_id: buf.read()?, digest: buf.read()? })
	}
	}

	#[inline]
	fn to_hex_string(buf: &[u8]) -> String {
	buf.iter().map(\|b\| format!("{:02X}", b)).collect()
	}