5b60a1b72e
Gramatical and punctuation corrections; addition of missing userSecureId to AuthorizationList schema and removal of extraneous rollbackResistant from same; correction of OS_PATCHLEVEL source property; and addition of missing TAG_UNLOCKED_DEVICE_REQUIRED documentation. Bug: 69550260 Test: N/A Change-Id: I04092b7df3af69201ba1467cddc09f6f44e861a8
1321 lines
76 KiB
Text
1321 lines
76 KiB
Text
/*
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* Copyright (C) 2017 The Android Open Source Project
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*/
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package android.hardware.keymaster@4.0;
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import android.hardware.keymaster@3.0::ErrorCode;
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import android.hardware.keymaster@3.0::KeyFormat;
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/**
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* Keymaster device definition.
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*
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* == Features ==
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*
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* An IKeymasterDevice provides cryptographic services, including the following categories of
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* operations:
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*
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* o Key generation
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* o Import and export (public only) of asymmetric keys
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* o Import of raw symmetric keys
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* o Asymmetric encryption and decryption with appropriate padding modes
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* o Asymmetric signing and verification with digesting and appropriate padding modes
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* o Symmetric encryption and decryption in appropriate modes, including an AEAD mode
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* o Generation and verification of symmetric message authentication codes
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* o Attestation to the presence and configuration of asymmetric keys.
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*
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* Protocol elements, such as purpose, mode and padding, as well as access control constraints, must
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* be specified by the caller when keys are generated or imported and must be permanently bound to
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* the key, ensuring that the key cannot be used in any other way.
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*
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* In addition to the list above, IKeymasterDevice implementations must provide one more service
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* which is not exposed as an API but used internally: Random number generation. The random number
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* generator must be high-quality and must be used for generation of keys, initialization vectors,
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* random padding and other elements of secure protocols that require randomness.
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*
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* == Types of IKeymasterDevices ==
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*
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* All of the operations and storage of key material must occur in a secure environment. Secure
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* environments may be either:
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*
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* 1. Isolated execution environments, such as a separate virtual machine, hypervisor or
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* purpose-built trusted execution environment like ARM TrustZone. The isolated environment
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* must provide complete separation from the Android kernel and user space (collectively called
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* the "non-secure world", or NSW) so that nothing running in the NSW can observe or manipulate
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* the results of any computation in the isolated environment. Isolated execution environments
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* are identified by the SecurityLevel TRUSTED_ENVIRONMENT.
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*
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* 2. Completely separate, purpose-built and certified secure CPUs, called "StrongBox" devices.
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* Examples of StrongBox devices are embedded Secure Elements (eSE) or on-SoC secure processing
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* units (SPU). StrongBox environments are identified by the SecurityLevel STRONGBOX. To
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* qualify as a StrongBox, a device must meet the requirements specified in CDD 9.11.2.
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*
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* == Necessary Primitives ==
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*
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* All IKeymasterDevice implementations must provide support for the following:
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*
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* o RSA
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*
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* - TRUSTED_ENVIRONMENT IKeymasterDevices must support 2048, 3072 and 4096-bit keys.
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* STRONGBOX IKeymasterDevices must support 2048-bit keys.
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* - Public exponent F4 (2^16+1)
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* - Unpadded, RSASSA-PSS and RSASSA-PKCS1-v1_5 padding modes for RSA signing
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* - TRUSTED_ENVIRONMENT IKeymasterDevices must support MD5, SHA1, SHA-2 224, SHA-2 256, SHA-2
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* 384 and SHA-2 512 digest modes for RSA signing. STRONGBOX IKeymasterDevices must support
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* SHA-2 256.
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* - Unpadded, RSAES-OAEP and RSAES-PKCS1-v1_5 padding modes for RSA encryption.
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*
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* o ECDSA
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*
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* - TRUSTED_ENVIRONMENT IKeymasterDevices must support NIST curves P-224, P-256, P-384 and
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* P-521. STRONGBOX IKeymasterDevices must support NIST curve P-256.
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* - TRUSTED_ENVIRONMENT IKeymasterDevices must support SHA1, SHA-2 224, SHA-2 256, SHA-2
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* 384 and SHA-2 512 digest modes. STRONGBOX IKeymasterDevices must support SHA-2 256.
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*
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* o AES
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*
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* - 128 and 256-bit keys
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* - CBC, CTR, ECB and GCM modes. The GCM mode must not allow the use of tags smaller than 96
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* bits or nonce lengths other than 96 bits.
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* - CBC and ECB modes must support unpadded and PKCS7 padding modes. With no padding CBC and
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* ECB-mode operations must fail with ErrorCode::INVALID_INPUT_LENGTH if the input isn't a
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* multiple of the AES block size. With PKCS7 padding, GCM and CTR operations must fail with
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* ErrorCode::INCOMPATIBLE_PADDING_MODE.
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*
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* o 3DES
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*
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* - 168-bit keys.
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* - CBC and ECB mode.
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* - CBC and ECB modes must support unpadded and PKCS7 padding modes. With no padding CBC and
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* ECB-mode operations must fail with ErrorCode::INVALID_INPUT_LENGTH if the input isn't a
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* multiple of the DES block size.
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*
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* o HMAC
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*
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* - Any key size that is between 64 and 512 bits (inclusive) and a multiple of 8 must be
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* supported. STRONGBOX IKeymasterDevices must not support keys larger than 512 bits.
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* - TRUSTED_ENVIRONMENT IKeymasterDevices must support MD-5, SHA1, SHA-2-224, SHA-2-256,
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* SHA-2-384 and SHA-2-512. STRONGBOX IKeymasterDevices must support SHA-2-256.
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*
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* == Key Access Control ==
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*
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* Hardware-based keys that can never be extracted from the device don't provide much security if an
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* attacker can use them at will (though they're more secure than keys which can be
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* exfiltrated). Therefore, IKeymasterDevice must enforce access controls.
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*
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* Access controls are defined as an "authorization list" of tag/value pairs. Authorization tags
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* are 32-bit integers from the Tag enum, and the values are a variety of types, defined in the
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* TagType enum. Some tags may be repeated to specify multiple values. Whether a tag may be
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* repeated is specified in the documentation for the tag and in the TagType. When a key is created
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* or imported, the caller specifies an authorization list. The IKeymasterDevice must divide the
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* caller-provided authorizations into two lists, those it enforces in hardware and those it does
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* not. These two lists are returned as the "hardwareEnforced" and "softwareEnforced" elements of
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* the KeyCharacteristics struct. The IKeymasterDevice must also add the following authorizations
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* to the appropriate list:
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*
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* o Tag::OS_VERSION, must be hardware-enforced.
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* o Tag::OS_PATCHLEVEL, must be hardware-enforced.
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* o Tag::VENDOR_PATCHLEVEL, must be hardware-enforced.
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* o Tag::BOOT_PATCHLEVEL, must be hardware-enforced.
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* o Tag::CREATION_DATETIME, must be software-enforced, unless the IKeymasterDevice has access to
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* a secure time service.
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* o Tag::ORIGIN, must be hardware-enforced.
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*
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* The IKeymasterDevice must accept arbitrary, unknown tags and return them in the softwareEnforced
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* list.
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*
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* All authorization tags and their values, both hardwareEnforced and softwareEnforced, including
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* unknown tags, must be cryptographically bound to the private/secret key material such that any
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* modification of the portion of the key blob that contains the authorization list makes it
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* impossible for the secure environment to obtain the private/secret key material. The recommended
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* approach to meet this requirement is to use the full set of authorization tags associated with a
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* key as input to a secure key derivation function used to derive a key that is used to encrypt the
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* private/secret key material.
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*
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* IKeymasterDevice implementations must place any tags they cannot fully and completely enforce in
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* the softwareEnforced list. For example, Tag::ORIGINATION_EXPIRE_DATETIME provides the date and
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* time after which a key may not be used to encrypt or sign new messages. Unless the
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* IKeymasterDevice has access to a secure source of current date/time information, it is not
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* possible for the IKeymasterDevice to enforce this tag. An IKeymasterDevice implementation may
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* not rely on the non-secure world's notion of time, because it could be controlled by an attacker.
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* Similarly, it cannot rely on GPSr time, even if it has exclusive control of the GPSr, because
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* that might be spoofed by attacker RF signals.
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*
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* It is recommended that IKeymasterDevices not enforce any tags they place in the softwareEnforced
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* list. The IKeymasterDevice caller must enforce them, and it is unnecessary to enforce them
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* twice.
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*
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* Some tags must be enforced by the IKeymasterDevice. See the detailed documentation on each Tag
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* in types.hal.
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*
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* == Root of Trust Binding ==
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*
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* IKeymasterDevice keys must be bound to a root of trust, which is a bitstring that must be
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* provided to the secure environment (by an unspecified, implementation-defined mechanism) during
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* startup, preferably by the bootloader. This bitstring must be cryptographically bound to every
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* key managed by the IKeymasterDevice. As above, the recommended mechanism for this cryptographic
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* binding is to include the Root of Trust data in the input to the key derivation function used to
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* derive a key that is used to encryp the private/secret key material.
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*
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* The root of trust consists of a bitstring that must be derived from the public key used by
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* Verified Boot to verify the signature on the boot image and from the the lock state of the
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* device. If the public key is changed to allow a different system image to be used or if the lock
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* state is changed, then all of the IKeymasterDevice-protected keys created by the previous system
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* state must be unusable, unless the previous state is restored. The goal is to increase the value
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* of the software-enforced key access controls by making it impossible for an attacker-installed
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* operating system to use IKeymasterDevice keys.
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*
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* == Version Binding ==
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*
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* All keys must also be bound to the operating system and patch level of the system image and the
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* patch levels of the vendor image and boot image. This ensures that an attacker who discovers a
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* weakness in an old version of the software cannot roll a device back to the vulnerable version
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* and use keys created with the newer version. In addition, when a key with a given version and
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* patch level is used on a device that has been upgraded to a newer version or patch level, the key
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* must be upgraded (See IKeymasterDevice::upgradeKey()) before it can be used, and the previous
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* version of the key must be invalidated. In this way, as the device is upgraded, the keys will
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* "ratchet" forward along with the device, but any reversion of the device to a previous release
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* will cause the keys to be unusable.
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*
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* This version information must be associated with every key as a set of tag/value pairs in the
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* hardwareEnforced authorization list. Tag::OS_VERSION, Tag::OS_PATCHLEVEL,
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* Tag::VENDOR_PATCHLEVEL, and Tag::BOOT_PATCHLEVEL must be cryptographically bound to every
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* IKeymasterDevice key, as described in the Key Access Control section above.
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*/
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interface IKeymasterDevice {
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/**
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* Returns information about the underlying IKeymasterDevice hardware.
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*
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* @return security level of the IKeymasterDevice implementation accessed through this HAL.
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*
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* @return keymasterName is the name of the IKeymasterDevice implementation.
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*
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* @return keymasterAuthorName is the name of the author of the IKeymasterDevice implementation
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* (organization name, not individual).
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*/
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getHardwareInfo()
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generates (SecurityLevel securityLevel, string keymasterName, string keymasterAuthorName);
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/**
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* Start the creation of an HMAC key, shared with another IKeymasterDevice implementation. Any
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* device with a StrongBox IKeymasterDevice has two IKeymasterDevice instances, because there
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* must be a TEE Keymaster as well. The HMAC key used to MAC and verify authentication tokens
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* (HardwareAuthToken, VerificationToken and ConfirmationToken all use this HMAC key) must be
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* shared between TEE and StrongBox so they can each validate tokens produced by the other.
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* This method is the first step in the process for agreeing on a shared key. It is called by
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* Android during startup. The system calls it on each of the HAL instances and collects the
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* results in preparation for the second step.
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*
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* @return error ErrorCode::OK on success, ErrorCode::UNIMPLEMENTED if HMAC agreement is not
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* implemented (note that all 4.0::IKeymasterDevice HALS must implement HMAC agreement,
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* regardless of whether or not the HAL will be used on a device with StrongBox), or
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* ErrorCode::UNKNOWN_ERROR if the parameters cannot be returned.
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*
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* @return params The HmacSharingParameters to use. As specified in the HmacSharingParameters
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* documentation in types.hal, the seed must contain the same value in every invocation
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* of the method on a given device, and the nonce must return the same value for every
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* invocation during a boot session.
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*/
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getHmacSharingParameters() generates (ErrorCode error, HmacSharingParameters params);
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/**
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* Complete the creation of an HMAC key, shared with another IKeymasterDevice implementation.
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* Any device with a StrongBox IKeymasterDevice has two IKeymasterDevice instances, because
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* there must be a TEE IKeymasterDevice as well. The HMAC key used to MAC and verify
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* authentication tokens must be shared between TEE and StrongBox so they can each validate
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* tokens produced by the other. This method is the second and final step in the process for
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* agreeing on a shared key. It is called by Android during startup. The system calls it on
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* each of the HAL instances, and sends to it all of the HmacSharingParameters returned by all
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* HALs.
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*
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* To ensure consistent ordering of the HmacSharingParameters, the caller must sort the
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* parameters lexicographically. See the support/keymaster_utils.cpp for an operator< that
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* defines the appropriate ordering.
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*
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* This method computes the shared 32-byte HMAC ``H'' as follows (all IKeymasterDevice instances
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* perform the same computation to arrive at the same result):
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*
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* H = CKDF(key = K,
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* context = P1 || P2 || ... || Pn,
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* label = "KeymasterSharedMac")
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*
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* where:
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*
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* ``CKDF'' is the standard AES-CMAC KDF from NIST SP 800-108 in counter mode (see Section
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* 5.1 of the referenced publication). ``key'', ``context'', and ``label'' are
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* defined in the standard. The counter is prefixed and length L appended, as shown
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* in the construction on page 12 of the standard. The label string is UTF-8 encoded.
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*
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* ``K'' is a pre-established shared secret, set up during factory reset. The mechanism for
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* establishing this shared secret is implementation-defined, but see below for a
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* recommended approach, which assumes that the TEE IKeymasterDevice does not have
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* storage available to it, but the StrongBox IKeymasterDevice does.
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*
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* CRITICAL SECURITY REQUIREMENT: All keys created by a IKeymasterDevice instance must
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* be cryptographically bound to the value of K, such that establishing a new K
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* permanently destroys them.
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*
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* ``||'' represents concatenation.
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*
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* ``Pi'' is the i'th HmacSharingParameters value in the params vector. Note that at
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* present only two IKeymasterDevice implementations are supported, but this mechanism
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* extends without modification to any number of implementations. Encoding of an
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* HmacSharingParameters is the concatenation of its two fields, i.e. seed || nonce.
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*
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* Note that the label "KeymasterSharedMac" is the 18-byte UTF-8 encoding of the string.
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*
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* Process for establishing K:
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*
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* Any method of securely establishing K that ensures that an attacker cannot obtain or
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* derive its value is acceptable. What follows is a recommended approach, to be executed
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* during each factory reset. It relies on use of the factory-installed attestation keys to
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* mitigate man-in-the-middle attacks. This protocol requires that one of the instances
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* have secure persistent storage. This model was chosen because StrongBox has secure
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* persistent storage (by definition), but the TEE may not. The instance without storage is
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* assumed to be able to derive a unique hardware-bound key (HBK) which is used only for
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* this purpose, and is not derivable outside the secure environment.
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*
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* In what follows, T is the IKeymasterDevice instance without storage, S is the
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* IKeymasterDevice instance with storage:
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*
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* 1. T generates an ephemeral EC P-256 key pair K1.
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* 2. T sends K1_pub to S, signed with T's attestation key.
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* 3. S validates the signature on K1_pub.
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* 4. S generates an ephemeral EC P-256 key pair K2.
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* 5. S sends {K1_pub, K2_pub}, to T, signed with S's attestation key.
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* 6. T validates the signature on {K1_pub, K2_pub}.
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* 7. T uses {K1_priv, K2_pub} with ECDH to compute session secret Q.
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* 8. T generates a random seed S.
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* 9. T computes K = KDF(HBK, S), where KDF is some secure key derivation function.
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* 10. T sends M = AES-GCM-ENCRYPT(Q, {S || K}) to S.
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* 10. S uses {K2_priv, K1_pub} with ECDH to compute session secret Q.
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* 11. S computes S || K = AES-GCM-DECRYPT(Q, M) and stores S and K.
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*
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* When S receives the getHmacSharingParameters call, it returns the stored S as the seed
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* and a nonce. When T receives the same call, it returns an empty seed and a nonce. When
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* T receives the computeSharedHmac call, it uses the seed provided by S to compute K. S,
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* of course, has K stored.
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*
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* @param params The HmacSharingParameters data returned by all IKeymasterDevice instances when
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* getHmacSharingParameters was called.
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*
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* @return error ErrorCode::OK in the event that there is no error. ErrorCode::INVALID_ARGUMENT
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* if one of the provided parameters is not the value returned by the prior call to
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* getHmacParameters().
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*
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* @return sharingCheck A 32-byte value used to verify that all IKeymasterDevice instances have
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* computed the same shared HMAC key. The sharingCheck value is computed as follows:
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*
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* sharingCheck = HMAC(H, "Keymaster HMAC Verification")
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*
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* The string is UTF-8 encoded, 27 bytes in length. If the returned values of all
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* IKeymasterDevice instances don't match, clients must assume that HMAC agreement
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* failed.
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*/
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computeSharedHmac(vec<HmacSharingParameters> params)
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generates (ErrorCode error, vec<uint8_t> sharingCheck);
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/**
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* Verify authorizations for another IKeymasterDevice instance.
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*
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* On systems with both a StrongBox and a TEE IKeymasterDevice instance it is sometimes useful
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* to ask the TEE IKeymasterDevice to verify authorizations for a key hosted in StrongBox.
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*
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* For every StrongBox operation, Keystore is required to call this method on the TEE Keymaster,
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* passing in the StrongBox key's hardwareEnforced authorization list and the operation handle
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* returned by StrongBox begin(). The TEE IKeymasterDevice must validate all of the
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* authorizations it can and return those it validated in the VerificationToken. If it cannot
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* verify any, the parametersVerified field of the VerificationToken must be empty. Keystore
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* must then pass the VerificationToken to the subsequent invocations of StrongBox update() and
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* finish().
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*
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* StrongBox implementations must return ErrorCode::UNIMPLEMENTED.
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*
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* @param operationHandle the operation handle returned by StrongBox Keymaster's begin().
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*
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* @param parametersToVerify Set of authorizations to verify. The caller may provide an empty
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* vector if the only required information is the TEE timestamp.
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*
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* @param authToken A HardwareAuthToken if needed to authorize key usage.
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*
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* @return error ErrorCode::OK on success or ErrorCode::UNIMPLEMENTED if the IKeymasterDevice is
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* a StrongBox. If the IKeymasterDevice cannot verify one or more elements of
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* parametersToVerify it must not return an error code, but just omit the unverified
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* parameter from the VerificationToken.
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*
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* @return token the verification token. See VerificationToken in types.hal for details.
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*/
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verifyAuthorization(uint64_t operationHandle, vec<KeyParameter> parametersToVerify,
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HardwareAuthToken authToken)
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generates (ErrorCode error, VerificationToken token);
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/**
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* Adds entropy to the RNG used by Keymaster. Entropy added through this method must not be the
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* only source of entropy used, and a secure mixing function must be used to mix the entropy
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* provided by this method with internally-generated entropy. The mixing function must be
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* secure in the sense that if any one of the mixing function inputs is provided with any data
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* the attacker cannot predict (or control), then the output of the seeded CRNG is
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* indistinguishable from random. Thus, if the entropy from any source is good, the output must
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* be good.
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*
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* @param data Bytes to be mixed into the CRNG seed. The caller must not provide more than 2
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* KiB of data per invocation.
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*
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* @return error ErrorCode::OK on success; ErrorCode::INVALID_INPUT_LENGTH if the caller
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* provides more than 2 KiB of data.
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*/
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addRngEntropy(vec<uint8_t> data) generates (ErrorCode error);
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/**
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* Generates a new cryptographic key, specifying associated parameters, which must be
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* cryptographically bound to the key. IKeymasterDevice implementations must disallow any use
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* of a key in any way inconsistent with the authorizations specified at generation time. With
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* respect to parameters that the secure environment cannot enforce, the secure envionment's
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* obligation is limited to ensuring that the unenforceable parameters associated with the key
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* cannot be modified, so that every call to getKeyCharacteristics returns the original
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* values. In addition, the characteristics returned by generateKey places parameters correctly
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* in the hardware-enforced and software-enforced lists. See getKeyCharacteristics for more
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* details.
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*
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* In addition to the parameters provided, generateKey must add the following to the returned
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* characteristics.
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*
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* o Tag::ORIGIN with the value KeyOrigin::GENERATED.
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*
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* o Tag::BLOB_USAGE_REQUIREMENTS with the appropriate value (see KeyBlobUsageRequirements in
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* types.hal).
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*
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* o Tag::CREATION_DATETIME with the appropriate value. Note that it is expected that this will
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* generally be added by the HAL, not by the secure environment, and that it will be in the
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* software-enforced list. It must be cryptographically bound to the key, like all tags.
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*
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* o Tag::OS_VERSION, Tag::OS_PATCHLEVEL, Tag::VENDOR_PATCHLEVEL and Tag::BOOT_PATCHLEVEL with
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* appropriate values.
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*
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* The parameters provided to generateKey depend on the type of key being generated. This
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* section summarizes the necessary and optional tags for each type of key. Tag::ALGORITHM is
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* always necessary, to specify the type.
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*
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* == RSA Keys ==
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*
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* The following parameters are required to generate an RSA key:
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*
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* o Tag::Key_SIZE specifies the size of the public modulus, in bits. If omitted, generateKey
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* must return ErrorCode::UNSUPPORTED_KEY_SIZE. Required values for TEE IKeymasterDevice
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* implementations are 1024, 2048, 3072 and 4096. StrongBox IKeymasterDevice implementations
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* must support 2048.
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*
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* o Tag::RSA_PUBLIC_EXPONENT specifies the RSA public exponent value. If omitted, generateKey
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* must return ErrorCode::INVALID_ARGUMENT. The values 3 and 65537 must be supported. It is
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* recommended to support all prime values up to 2^64. If provided with a non-prime value,
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* generateKey must return ErrorCode::INVALID_ARGUMENT.
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*
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* The following parameters are not necessary to generate a usable RSA key, but generateKey must
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* not return an error if they are omitted:
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*
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* o Tag::PURPOSE specifies allowed purposes. All KeyPurpose values (see types.hal) must be
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* supported for RSA keys.
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*
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* o Tag::DIGEST specifies digest algorithms that may be used with the new key. TEE
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* IKeymasterDevice implementatiosn must support all Digest values (see types.hal) for RSA
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* keys. StrongBox IKeymasterDevice implementations must support SHA_2_256.
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*
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* o Tag::PADDING specifies the padding modes that may be used with the new
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* key. IKeymasterDevice implementations must support PaddingMode::NONE,
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* PaddingMode::RSA_OAEP, PaddingMode::RSA_PSS, PaddingMode::RSA_PKCS1_1_5_ENCRYPT and
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* PaddingMode::RSA_PKCS1_1_5_SIGN for RSA keys.
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*
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* == ECDSA Keys ==
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*
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* Either Tag::KEY_SIZE or Tag::EC_CURVE must be provided to generate an ECDSA key. If neither
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* is provided, generateKey must return ErrorCode::UNSUPPORTED_KEY_SIZE. If Tag::KEY_SIZE is
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* provided, the possible values are 224, 256, 384 and 521, and must be mapped to Tag::EC_CURVE
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* values P_224, P_256, P_384 and P_521, respectively. TEE IKeymasterDevice implementations
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* must support all curves. StrongBox implementations must support P_256.
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*
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* == AES Keys ==
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*
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* Only Tag::KEY_SIZE is required to generate an AES key. If omitted, generateKey must return
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* ErrorCode::UNSUPPORTED_KEY_SIZE. 128 and 256-bit key sizes must be supported.
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*
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* If Tag::BLOCK_MODE is specified with value BlockMode::GCM, then the caller must also provide
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* Tag::MIN_MAC_LENGTH. If omitted, generateKey must return ErrorCode::MISSING_MIN_MAC_LENGTH.
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*
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*
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* @param keyParams Key generation parameters are defined as IKeymasterDevice tag/value pairs,
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* provided in params. See above for detailed specifications of which tags are required
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* for which types of keys.
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*
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* @return keyBlob Opaque descriptor of the generated key. The recommended implementation
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* strategy is to include an encrypted copy of the key material, wrapped in a key
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* unavailable outside secure hardware.
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*
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* @return keyCharacteristics Description of the generated key. See the getKeyCharacteristics
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* method below.
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*/
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generateKey(vec<KeyParameter> keyParams)
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generates (ErrorCode error, vec<uint8_t> keyBlob, KeyCharacteristics keyCharacteristics);
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/**
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* Imports key material into an IKeymasterDevice. Key definition parameters and return values
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* are the same as for generateKey, with the following exceptions:
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*
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* o Tag::KEY_SIZE is not necessary in the input parameters. If not provided, the
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* IKeymasterDevice must deduce the value from the provided key material and add the tag and
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* value to the key characteristics. If Tag::KEY_SIZE is provided, the IKeymasterDevice must
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* validate it against the key material. In the event of a mismatch, importKey must return
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* ErrorCode::IMPORT_PARAMETER_MISMATCH.
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*
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* o Tag::RSA_PUBLIC_EXPONENT (for RSA keys only) is not necessary in the input parameters. If
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* not provided, the IKeymasterDevice must deduce the value from the provided key material and
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* add the tag and value to the key characteristics. If Tag::RSA_PUBLIC_EXPONENT is provided,
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* the IKeymasterDevice must validate it against the key material. In the event of a
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* mismatch, importKey must return ErrorCode::IMPORT_PARAMETER_MISMATCH.
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*
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* o Tag::ORIGIN (returned in keyCharacteristics) must have the value KeyOrigin::IMPORTED.
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*
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* @param keyParams Key generation parameters are defined as IKeymasterDevice tag/value pairs,
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* provided in params.
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*
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* @param keyFormat The format of the key material to import. See KeyFormat in types.hal.
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*
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* @pram keyData The key material to import, in the format specifed in keyFormat.
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*
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* @return keyBlob Opaque descriptor of the imported key. The recommended implementation
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* strategy is to include an encrypted copy of the key material, wrapped in a key
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* unavailable outside secure hardware.
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*
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* @return keyCharacteristics Decription of the generated key. See the getKeyCharacteristics
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* method below.
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*/
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importKey(vec<KeyParameter> keyParams, KeyFormat keyFormat, vec<uint8_t> keyData)
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generates (ErrorCode error, vec<uint8_t> keyBlob, KeyCharacteristics keyCharacteristics);
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/**
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* Securely imports a key, or key pair, returning a key blob and a description of the imported
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* key.
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*
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* @param wrappedKeyData The wrapped key material to import. The wrapped key is in DER-encoded
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* ASN.1 format, specified by the following schema:
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*
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* KeyDescription ::= SEQUENCE(
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* keyFormat INTEGER, # Values from KeyFormat enum.
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* keyParams AuthorizationList,
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* )
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*
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* SecureKeyWrapper ::= SEQUENCE(
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* version INTEGER, # Contains value 0
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* encryptedTransportKey OCTET_STRING,
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* initializationVector OCTET_STRING,
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* keyDescription KeyDescription,
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* encryptedKey OCTET_STRING,
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* tag OCTET_STRING
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* )
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*
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* Where:
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*
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* o keyFormat is an integer from the KeyFormat enum, defining the format of the plaintext
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* key material.
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* o keyParams is the characteristics of the key to be imported (as with generateKey or
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* importKey). If the secure import is successful, these characteristics must be
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* associated with the key exactly as if the key material had been insecurely imported
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* with the @3.0::IKeymasterDevice::importKey. See attestKey() for documentation of the
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* AuthorizationList schema.
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* o encryptedTransportKey is a 256-bit AES key, XORed with a masking key and then encrypted
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* with the wrapping key specified by wrappingKeyBlob.
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* o keyDescription is a KeyDescription, above.
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* o encryptedKey is the key material of the key to be imported, in format keyFormat, and
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* encrypted with encryptedEphemeralKey in AES-GCM mode, with the DER-encoded
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* representation of keyDescription provided as additional authenticated data.
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* o tag is the tag produced by the AES-GCM encryption of encryptedKey.
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*
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* So, importWrappedKey does the following:
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*
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* 1. Get the private key material for wrappingKeyBlob, verifying that the wrapping key has
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* purpose KEY_WRAP, padding mode RSA_OAEP, and digest SHA_2_256, returning the
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* appropriate error if any of those requirements fail.
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* 2. Extract the encryptedTransportKey field from the SecureKeyWrapper, and decrypt
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* it with the wrapping key.
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* 3. XOR the result of step 2 with maskingKey.
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* 4. Use the result of step 3 as an AES-GCM key to decrypt encryptedKey, using the encoded
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* value of keyDescription as the additional authenticated data. Call the result
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* "keyData" for the next step.
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* 5. Perform the equivalent of calling importKey(keyParams, keyFormat, keyData), except
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* that the origin tag should be set to SECURELY_IMPORTED.
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*
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* @param wrappingKeyBlob The opaque key descriptor returned by generateKey() or importKey().
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* This key must have been created with Purpose::WRAP_KEY.
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*
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* @param maskingKey The 32-byte value XOR'd with the transport key in the SecureWrappedKey
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* structure.
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*
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* @param unwrappingParams must contain any parameters needed to perform the unwrapping
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* operation. For example, if the wrapping key is an AES key the block and padding modes
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* must be specified in this argument.
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*
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* @param passwordSid specifies the password secure ID (SID) of the user that owns the key being
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* installed. If the authorization list in wrappedKeyData contains a Tag::USER_SECURE_ID
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* with a value that has the HardwareAuthenticatorType::PASSWORD bit set, the constructed
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* key must be bound to the SID value provided by this argument. If the wrappedKeyData
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* does not contain such a tag and value, this argument must be ignored.
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*
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* @param biometricSid specifies the biometric secure ID (SID) of the user that owns the key
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* being installed. If the authorization list in wrappedKeyData contains a
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* Tag::USER_SECURE_ID with a value that has the HardwareAuthenticatorType::FINGERPRINT
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* bit set, the constructed key must be bound to the SID value provided by this argument.
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* If the wrappedKeyData does not contain such a tag and value, this argument must be
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* ignored.
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*
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* @return keyBlob Opaque descriptor of the imported key. It is recommended that the keyBlob
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* contain a copy of the key material, wrapped in a key unavailable outside secure
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* hardware.
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*/
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importWrappedKey(vec<uint8_t> wrappedKeyData, vec<uint8_t> wrappingKeyBlob,
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vec<uint8_t> maskingKey, vec<KeyParameter> unwrappingParams,
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uint64_t passwordSid, uint64_t biometricSid)
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generates(ErrorCode error, vec<uint8_t> keyBlob, KeyCharacteristics keyCharacteristics);
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/**
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* Returns parameters associated with the provided key, divided into two sets: hardware-enforced
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* and software-enforced. The description here applies equally to the key characteristics lists
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* returned by generateKey, importKey and importWrappedKey. The characteristics returned by
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* this method completely describe the type and usage of the specified key.
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*
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* The rule that IKeymasterDevice implementations must use for deciding whether a given tag
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* belongs in the hardware-enforced or software-enforced list is that if the meaning of the tag
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* is fully assured by secure hardware, it is hardware enforced. Otherwise, it's software
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* enforced.
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*
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*
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* @param keyBlob The opaque descriptor returned by generateKey, importKey or importWrappedKey.
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*
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* @param clientId An opaque byte string identifying the client. This value must match the
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* Tag::APPLICATION_ID data provided during key generation/import. Without the correct
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* value, it must be computationally infeasible for the secure hardware to obtain the key
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* material.
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*
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* @param appData An opaque byte string provided by the application. This value must match the
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* Tag::APPLICATION_DATA data provided during key generation/import. Without the correct
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* value, it must be computationally infeasible for the secure hardware to obtain the key
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* material.
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*
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* @return keyCharacteristics Decription of the generated key. See KeyCharacteristics in
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* types.hal.
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*/
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getKeyCharacteristics(vec<uint8_t> keyBlob, vec<uint8_t> clientId, vec<uint8_t> appData)
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generates (ErrorCode error, KeyCharacteristics keyCharacteristics);
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/**
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* Exports a public key, returning the key in the specified format.
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*
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* @parm keyFormat The format used for export. See KeyFormat in types.hal.
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*
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* @param keyBlob The opaque descriptor returned by generateKey() or importKey(). The
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* referenced key must be asymmetric.
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*
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* @param clientId An opaque byte string identifying the client. This value must match the
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* Tag::APPLICATION_ID data provided during key generation/import. Without the correct
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* value, it must be computationally infeasible for the secure hardware to obtain the key
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* material.
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*
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* @param appData An opaque byte string provided by the application. This value must match the
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* Tag::APPLICATION_DATA data provided during key generation/import. Without the correct
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* value, it must be computationally infeasible for the secure hardware to obtain the key
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* material.
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*
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* @return keyMaterial The public key material in PKCS#8 format.
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*/
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exportKey(KeyFormat keyFormat, vec<uint8_t> keyBlob, vec<uint8_t> clientId,
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vec<uint8_t> appData) generates (ErrorCode error, vec<uint8_t> keyMaterial);
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/**
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* Generates a signed X.509 certificate chain attesting to the presence of keyToAttest in
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* Keymaster.
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*
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* The certificates in the chain must be ordered such that each certificate is signed by the
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* subsequent one, up to the root which must be self-signed. The first certificate in the chain
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* signs the public key info of the attested key and must contain the following entries (see RFC
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* 5280 for details on each):
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*
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* o version -- with value 2
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*
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* o serialNumber -- with value 1 (same value for all keys)
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*
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* o signature -- contains an the AlgorithmIdentifier of the algorithm used to sign, must be
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* ECDSA for EC keys, RSA for RSA keys.
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*
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* o issuer -- must contain the same value as the Subject field of the next certificate.
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*
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* o validity -- SEQUENCE of two dates, containing the values of Tag::ACTIVE_DATETIME and
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* Tag::USAGE_EXPIRE_DATETIME. The tag values are in milliseconds since Jan 1, 1970; see RFD
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* 5280 for the correct representation in certificates. If Tag::ACTIVE_DATETIME is not
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* present in the key, the IKeymasterDevice must use the value of Tag::CREATION_DATETIME. If
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* Tag::USAGE_EXPIRE_DATETIME is not present, the IKeymasterDevice must use the expiration
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* date of the batch attestation certificate (see below).
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*
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* o subject -- CN="Android Keystore Key" (same value for all keys)
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*
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* o subjectPublicKeyInfo -- X.509 SubjectPublicKeyInfo containing the attested public key.
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*
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* o Key Usage extension -- digitalSignature bit must be set iff the attested key has
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* KeyPurpose::SIGN. dataEncipherment bit must be set iff the attested key has
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* KeyPurpose::DECRYPT. keyEncipherment bit must be set iff the attested key has
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* KeyPurpose::KEY_WRAP. All other bits must be clear.
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*
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* In addition to the above, the attestation certificate must contain an extension with OID
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* 1.3.6.1.4.1.11129.2.1.17 and value according to the KeyDescription schema defined as:
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*
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* KeyDescription ::= SEQUENCE {
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* attestationVersion INTEGER, # Value 3
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* attestationSecurityLevel SecurityLevel, # See below
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* keymasterVersion INTEGER, # Value 4
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* keymasterSecurityLevel SecurityLevel, # See below
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* attestationChallenge OCTET_STRING, # Tag::ATTESTATION_CHALLENGE from attestParams
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* uniqueId OCTET_STRING, # Empty unless key has Tag::INCLUDE_UNIQUE_ID
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* softwareEnforced AuthorizationList, # See below
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* hardwareEnforced AuthorizationList, # See below
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* }
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*
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* SecurityLevel ::= ENUMERATED {
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* Software (0),
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* TrustedEnvironment (1),
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* StrongBox (2),
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* }
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*
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* RootOfTrust ::= SEQUENCE {
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* verifiedBootKey OCTET_STRING,
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* deviceLocked BOOLEAN,
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* verifiedBootState VerifiedBootState,
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* # verifiedBootHash must contain 32-byte value that represents the state of all binaries
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* # or other components validated by verified boot. Updating any verified binary or
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* # component must cause this value to change.
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* verifiedBootHash OCTET_STRING,
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* }
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*
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* VerifiedBootState ::= ENUMERATED {
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* Verified (0),
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* SelfSigned (1),
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* Unverified (2),
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* Failed (3),
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* }
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*
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* AuthorizationList ::= SEQUENCE {
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* purpose [1] EXPLICIT SET OF INTEGER OPTIONAL,
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* algorithm [2] EXPLICIT INTEGER OPTIONAL,
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* keySize [3] EXPLICIT INTEGER OPTIONAL,
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* blockMode [4] EXPLICIT SET OF INTEGER OPTIONAL,
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* digest [5] EXPLICIT SET OF INTEGER OPTIONAL,
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* padding [6] EXPLICIT SET OF INTEGER OPTIONAL,
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* callerNonce [7] EXPLICIT NULL OPTIONAL,
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* minMacLength [8] EXPLICIT INTEGER OPTIONAL,
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* ecCurve [10] EXPLICIT INTEGER OPTIONAL,
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* rsaPublicExponent [200] EXPLICIT INTEGER OPTIONAL,
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* rollbackResistance [303] EXPLICIT NULL OPTIONAL,
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|
* activeDateTime [400] EXPLICIT INTEGER OPTIONAL,
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|
* originationExpireDateTime [401] EXPLICIT INTEGER OPTIONAL,
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|
* usageExpireDateTime [402] EXPLICIT INTEGER OPTIONAL,
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|
* userSecureId [502] EXPLICIT INTEGER OPTIONAL,
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* noAuthRequired [503] EXPLICIT NULL OPTIONAL,
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* userAuthType [504] EXPLICIT INTEGER OPTIONAL,
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|
* authTimeout [505] EXPLICIT INTEGER OPTIONAL,
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|
* allowWhileOnBody [506] EXPLICIT NULL OPTIONAL,
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|
* trustedUserPresenceReq [507] EXPLICIT NULL OPTIONAL,
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|
* trustedConfirmationReq [508] EXPLICIT NULL OPTIONAL,
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|
* unlockedDeviceReq [509] EXPLICIT NULL OPTIONAL,
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|
* creationDateTime [701] EXPLICIT INTEGER OPTIONAL,
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|
* origin [702] EXPLICIT INTEGER OPTIONAL,
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|
* rootOfTrust [704] EXPLICIT RootOfTrust OPTIONAL,
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|
* osVersion [705] EXPLICIT INTEGER OPTIONAL,
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|
* osPatchLevel [706] EXPLICIT INTEGER OPTIONAL,
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|
* attestationApplicationId [709] EXPLICIT OCTET_STRING OPTIONAL,
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* attestationIdBrand [710] EXPLICIT OCTET_STRING OPTIONAL,
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|
* attestationIdDevice [711] EXPLICIT OCTET_STRING OPTIONAL,
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|
* attestationIdProduct [712] EXPLICIT OCTET_STRING OPTIONAL,
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|
* attestationIdSerial [713] EXPLICIT OCTET_STRING OPTIONAL,
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|
* attestationIdImei [714] EXPLICIT OCTET_STRING OPTIONAL,
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|
* attestationIdMeid [715] EXPLICIT OCTET_STRING OPTIONAL,
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|
* attestationIdManufacturer [716] EXPLICIT OCTET_STRING OPTIONAL,
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|
* attestationIdModel [717] EXPLICIT OCTET_STRING OPTIONAL,
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|
* vendorPatchLevel [718] EXPLICIT INTEGER OPTIONAL,
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* bootPatchLevel [718] EXPLICIT INTEGER OPTIONAL,
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* }
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|
*
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|
* The above schema is mostly a straightforward translation of the IKeymasterDevice tag/value
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|
* parameter lists to ASN.1:
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|
*
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* o TagType::ENUM, TagType::UINT, TagType::ULONG and TagType::DATE tags are represented as
|
|
* ASN.1 INTEGER.
|
|
*
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* o TagType::ENUM_REP, TagType::UINT_REP and TagType::ULONG_REP tags are represented as ASN.1
|
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* SET of INTEGER.
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|
*
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|
* o TagType::BOOL tags are represented as ASN.1 NULL. All entries in AuthorizationList are
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* OPTIONAL, so the presence of the tag means "true", absence means "false".
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|
*
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|
* o TagType::BYTES tags are represented as ASN.1 OCTET_STRING.
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|
*
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|
* The numeric ASN.1 tag numbers are the same values as the IKeymasterDevice Tag enum values,
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* except with the TagType modifier stripped.
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|
*
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|
* The attestation certificate must be signed by a "batch" key, which must be securely
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* pre-installed into the device, generally in the factory, and securely stored to prevent
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* access or extraction. The batch key must be used only for signing attestation certificates.
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|
* The batch attestation certificate must be signed by a chain or zero or more intermediates
|
|
* leading to a self-signed roots. The intermediate and root certificate signing keys must not
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* exist anywhere on the device.
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|
*
|
|
* == ID Attestation ==
|
|
*
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|
* ID attestation is a special case of key attestation in which unique device ID values are
|
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* included in the signed attestation certificate.
|
|
*
|
|
* @param keyToAttest The opaque descriptor returned by generateKey() or importKey(). The
|
|
* referenced key must be asymmetric.
|
|
*
|
|
* @param attestParams Parameters for the attestation. Must contain Tag::ATTESTATION_CHALLENGE,
|
|
* the value of which must be put in the attestationChallenge field of the KeyDescription
|
|
* ASN.1 structure defined above.
|
|
*
|
|
* @return certChain The attestation certificate, and additional certificates back to the root
|
|
* attestation certificate, which clients will need to check against a known-good value.
|
|
* The certificates must be DER-encoded.
|
|
*/
|
|
attestKey(vec<uint8_t> keyToAttest, vec<KeyParameter> attestParams)
|
|
generates (ErrorCode error, vec<vec<uint8_t>> certChain);
|
|
|
|
/**
|
|
* Upgrades an old key blob. Keys can become "old" in two ways: IKeymasterDevice can be
|
|
* upgraded to a new version with an incompatible key blob format, or the system can be updated
|
|
* to invalidate the OS version (OS_VERSION tag), system patch level (OS_PATCHLEVEL tag), vendor
|
|
* patch level (VENDOR_PATCH_LEVEL tag), boot patch level (BOOT_PATCH_LEVEL tag) or other,
|
|
* implementation-defined patch level (keymaster implementers are encouraged to extend this HAL
|
|
* with a minor version extension to define validatable patch levels for other images; tags must
|
|
* be defined in the implementer's namespace, starting at 10000). In either case, attempts to
|
|
* use an old key blob with getKeyCharacteristics(), exportKey(), attestKey() or begin() must
|
|
* result in IKeymasterDevice returning ErrorCode::KEY_REQUIRES_UPGRADE. The caller must use
|
|
* this method to upgrade the key blob.
|
|
*
|
|
* The upgradeKey method must examine each version or patch level associated with the key. If
|
|
* any one of them is higher than the corresponding current device value upgradeKey() must
|
|
* return ErrorCode::INVALID_ARGUMENT. There is one exception: it is always permissible to
|
|
* "downgrade" from any OS_VERSION number to OS_VERSION 0. For example, if the key has
|
|
* OS_VERSION 080001, it is permisible to upgrade the key if the current system version is
|
|
* 080100, because the new version is larger, or if the current system version is 0, because
|
|
* upgrades to 0 are always allowed. If the system version were 080000, however, keymaster must
|
|
* return ErrorCode::INVALID_ARGUMENT because that value is smaller than 080001. Values other
|
|
* than OS_VERSION must never be downgraded.
|
|
*
|
|
* Note that Keymaster versions 2 and 3 required that the system and boot images have the same
|
|
* patch level and OS version. This requirement is relaxed for 4.0::IKeymasterDevice, and the
|
|
* OS version in the boot image footer is no longer used.
|
|
*
|
|
* @param keyBlobToUpgrade The opaque descriptor returned by generateKey() or importKey();
|
|
*
|
|
* @param upgradeParams A parameter list containing any parameters needed to complete the
|
|
* upgrade, including Tag::APPLICATION_ID and Tag::APPLICATION_DATA.
|
|
*
|
|
* @return upgradedKeyBlob A new key blob that references the same key as keyBlobToUpgrade, but
|
|
* is in the new format, or has the new version data.
|
|
*/
|
|
upgradeKey(vec<uint8_t> keyBlobToUpgrade, vec<KeyParameter> upgradeParams)
|
|
generates (ErrorCode error, vec<uint8_t> upgradedKeyBlob);
|
|
|
|
/**
|
|
* Deletes the key, or key pair, associated with the key blob. Calling this function on a key
|
|
* with Tag::ROLLBACK_RESISTANCE in its hardware-enforced authorization list must render the key
|
|
* permanently unusable. Keys without Tag::ROLLBACK_RESISTANCE may or may not be rendered
|
|
* unusable.
|
|
*
|
|
* @param keyBlob The opaque descriptor returned by generateKey() or importKey();
|
|
*/
|
|
deleteKey(vec<uint8_t> keyBlob) generates (ErrorCode error);
|
|
|
|
/**
|
|
* Deletes all keys in the hardware keystore. Used when keystore is reset completely. After
|
|
* this function is called all keys with Tag::ROLLBACK_RESISTANCE in their hardware-enforced
|
|
* authorization lists must be rendered permanently unusable. Keys without
|
|
* Tag::ROLLBACK_RESISTANCE may or may not be rendered unusable.
|
|
*
|
|
* @return error See the ErrorCode enum.
|
|
*/
|
|
deleteAllKeys() generates (ErrorCode error);
|
|
|
|
/**
|
|
* Destroys knowledge of the device's ids. This prevents all device id attestation in the
|
|
* future. The destruction must be permanent so that not even a factory reset will restore the
|
|
* device ids.
|
|
*
|
|
* Device id attestation may be provided only if this method is fully implemented, allowing the
|
|
* user to permanently disable device id attestation. If this cannot be guaranteed, the device
|
|
* must never attest any device ids.
|
|
*
|
|
* This is a NOP if device id attestation is not supported.
|
|
*/
|
|
destroyAttestationIds() generates (ErrorCode error);
|
|
|
|
/**
|
|
* Begins a cryptographic operation using the specified key. If all is well, begin() must
|
|
* return ErrorCode::OK and create an operation handle which must be passed to subsequent calls
|
|
* to update(), finish() or abort().
|
|
*
|
|
* It is critical that each call to begin() be paired with a subsequent call to finish() or
|
|
* abort(), to allow the IKeymasterDevice implementation to clean up any internal operation
|
|
* state. The caller's failure to do this may leak internal state space or other internal
|
|
* resources and may eventually cause begin() to return ErrorCode::TOO_MANY_OPERATIONS when it
|
|
* runs out of space for operations. Any result other than ErrorCode::OK from begin(), update()
|
|
* or finish() implicitly aborts the operation, in which case abort() need not be called (and
|
|
* must return ErrorCode::INVALID_OPERATION_HANDLE if called). IKeymasterDevice implementations
|
|
* must support 16 concurrent operations.
|
|
*
|
|
* If Tag::APPLICATION_ID or Tag::APPLICATION_DATA were specified during key generation or
|
|
* import, calls to begin must include those tags with the originally-specified values in the
|
|
* inParams argument to this method. If not, begin() must return ErrorCode::INVALID_KEY_BLOB.
|
|
*
|
|
* == Authorization Enforcement ==
|
|
*
|
|
* The following key authorization parameters must be enforced by the IKeymasterDevice secure
|
|
* environment if the tags were returned in the "hardwareEnforced" list in the
|
|
* KeyCharacteristics. Public key operations, meaning KeyPurpose::ENCRYPT and
|
|
* KeyPurpose::VERIFY must be allowed to succeed even if authorization requirements are not met.
|
|
*
|
|
* -- All Key Types --
|
|
*
|
|
* The tags in this section apply to all key types. See below for additional key type-specific
|
|
* tags.
|
|
*
|
|
* o Tag::PURPOSE: The purpose specified in the begin() call must match one of the purposes in
|
|
* the key authorizations. If the specified purpose does not match, begin() must return
|
|
* ErrorCode::UNSUPPORTED_PURPOSE.
|
|
*
|
|
* o Tag::ACTIVE_DATETIME can only be enforced if a trusted UTC time source is available. If
|
|
* the current date and time is prior to the tag value, begin() must return
|
|
* ErrorCode::KEY_NOT_YET_VALID.
|
|
*
|
|
* o Tag::ORIGINATION_EXPIRE_DATETIME can only be enforced if a trusted UTC time source is
|
|
* available. If the current date and time is later than the tag value and the purpose is
|
|
* KeyPurpose::ENCRYPT or KeyPurpose::SIGN, begin() must return ErrorCode::KEY_EXPIRED.
|
|
*
|
|
* o Tag::USAGE_EXPIRE_DATETIME can only be enforced if a trusted UTC time source is
|
|
* available. If the current date and time is later than the tag value and the purpose is
|
|
* KeyPurpose::DECRYPT or KeyPurpose::VERIFY, begin() must return ErrorCode::KEY_EXPIRED.
|
|
|
|
* o Tag::MIN_SECONDS_BETWEEN_OPS must be compared with a trusted relative timer indicating the
|
|
* last use of the key. If the last use time plus the tag value is less than the current
|
|
* time, begin() must return ErrorCode::KEY_RATE_LIMIT_EXCEEDED. See the tag description for
|
|
* important implementation details.
|
|
|
|
* o Tag::MAX_USES_PER_BOOT must be compared against a secure counter that tracks the uses of
|
|
* the key since boot time. If the count of previous uses exceeds the tag value, begin() must
|
|
* return ErrorCode::KEY_MAX_OPS_EXCEEDED.
|
|
*
|
|
* o Tag::USER_SECURE_ID must be enforced by this method if and only if the key also has
|
|
* Tag::AUTH_TIMEOUT (if it does not have Tag::AUTH_TIMEOUT, the Tag::USER_SECURE_ID
|
|
* requirement must be enforced by update() and finish()). If the key has both, then this
|
|
* method must receive a non-empty HardwareAuthToken in the authToken argument. For the auth
|
|
* token to be valid, all of the following have to be true:
|
|
*
|
|
* o The HMAC field must validate correctly.
|
|
*
|
|
* o At least one of the Tag::USER_SECURE_ID values from the key must match at least one of
|
|
* the secure ID values in the token.
|
|
*
|
|
* o The key must have a Tag::USER_AUTH_TYPE that matches the auth type in the token.
|
|
*
|
|
* o The timestamp in the auth token plus the value of the Tag::AUTH_TIMEOUT must be less than
|
|
* the current secure timestamp (which is a monotonic timer counting milliseconds since
|
|
* boot.)
|
|
*
|
|
* If any of these conditions are not met, begin() must return
|
|
* ErrorCode::KEY_USER_NOT_AUTHENTICATED.
|
|
*
|
|
* o Tag::CALLER_NONCE allows the caller to specify a nonce or initialization vector (IV). If
|
|
* the key doesn't have this tag, but the caller provided Tag::NONCE to this method,
|
|
* ErrorCode::CALLER_NONCE_PROHIBITED must be returned.
|
|
*
|
|
* o Tag::BOOTLOADER_ONLY specifies that only the bootloader may use the key. If this method is
|
|
* called with a bootloader-only key after the bootloader has finished executing, it must
|
|
* return ErrorCode::INVALID_KEY_BLOB. The mechanism for notifying the IKeymasterDevice that
|
|
* the bootloader has finished executing is implementation-defined.
|
|
*
|
|
* -- RSA Keys --
|
|
*
|
|
* All RSA key operations must specify exactly one padding mode in inParams. If unspecified or
|
|
* specified more than once, the begin() must return ErrorCode::UNSUPPORTED_PADDING_MODE.
|
|
*
|
|
* RSA signing and verification operations need a digest, as do RSA encryption and decryption
|
|
* operations with OAEP padding mode. For those cases, the caller must specify exactly one
|
|
* digest in inParams. If unspecified or specified more than once, begin() must return
|
|
* ErrorCode::UNSUPPORTED_DIGEST.
|
|
*
|
|
* Private key operations (KeyPurpose::DECRYPT and KeyPurpose::SIGN) need authorization of
|
|
* digest and padding, which means that the key authorizations need to contain the specified
|
|
* values. If not, begin() must return ErrorCode::INCOMPATIBLE_DIGEST or
|
|
* ErrorCode::INCOMPATIBLE_PADDING, as appropriate. Public key operations (KeyPurpose::ENCRYPT
|
|
* and KeyPurpose::VERIFY) are permitted with unauthorized digest or padding modes.
|
|
*
|
|
* With the exception of PaddingMode::NONE, all RSA padding modes are applicable only to certain
|
|
* purposes. Specifically, PaddingMode::RSA_PKCS1_1_5_SIGN and PaddingMode::RSA_PSS only
|
|
* support signing and verification, while PaddingMode::RSA_PKCS1_1_5_ENCRYPT and
|
|
* PaddingMode::RSA_OAEP only support encryption and decryption. begin() must return
|
|
* ErrorCode::UNSUPPORTED_PADDING_MODE if the specified mode does not support the specified
|
|
* purpose.
|
|
*
|
|
* There are some important interactions between padding modes and digests:
|
|
*
|
|
* o PaddingMode::NONE indicates that a "raw" RSA operation is performed. If signing or
|
|
* verifying, Digest::NONE is specified for the digest. No digest is necessary for unpadded
|
|
* encryption or decryption.
|
|
*
|
|
* o PaddingMode::RSA_PKCS1_1_5_SIGN padding requires a digest. The digest may be Digest::NONE,
|
|
* in which case the Keymaster implementation cannot build a proper PKCS#1 v1.5 signature
|
|
* structure, because it cannot add the DigestInfo structure. Instead, the IKeymasterDevice
|
|
* must construct 0x00 || 0x01 || PS || 0x00 || M, where M is the provided message and PS is a
|
|
* random padding string at least eight bytes in length. The size of the RSA key has to be at
|
|
* least 11 bytes larger than the message, otherwise begin() must return
|
|
* ErrorCode::INVALID_INPUT_LENGTH.
|
|
*
|
|
* o PaddingMode::RSA_PKCS1_1_1_5_ENCRYPT padding does not require a digest.
|
|
*
|
|
* o PaddingMode::RSA_PSS padding requires a digest, which may not be Digest::NONE. If
|
|
* Digest::NONE is specified, the begin() must return ErrorCode::INCOMPATIBLE_DIGEST. In
|
|
* addition, the size of the RSA key must be at least 2 + D bytes larger than the output size
|
|
* of the digest, where D is the size of the digest, in bytes. Otherwise begin() must
|
|
* return ErrorCode::INCOMPATIBLE_DIGEST. The salt size must be D.
|
|
*
|
|
* o PaddingMode::RSA_OAEP padding requires a digest, which may not be Digest::NONE. If
|
|
* Digest::NONE is specified, begin() must return ErrorCode::INCOMPATIBLE_DIGEST. The OAEP
|
|
* mask generation function must be MGF1 and the MGF1 digest must be SHA1, regardless of the
|
|
* OAEP digest specified.
|
|
*
|
|
* -- EC Keys --
|
|
*
|
|
* EC key operations must specify exactly one padding mode in inParams. If unspecified or
|
|
* specified more than once, begin() must return ErrorCode::UNSUPPORTED_PADDING_MODE.
|
|
*
|
|
* Private key operations (KeyPurpose::SIGN) need authorization of digest and padding, which
|
|
* means that the key authorizations must contain the specified values. If not, begin() must
|
|
* return ErrorCode::INCOMPATIBLE_DIGEST. Public key operations (KeyPurpose::VERIFY) are
|
|
* permitted with unauthorized digest or padding.
|
|
*
|
|
* -- AES Keys --
|
|
*
|
|
* AES key operations must specify exactly one block mode (Tag::BLOCK_MODE) and one padding mode
|
|
* (Tag::PADDING) in inParams. If either value is unspecified or specified more than once,
|
|
* begin() must return ErrorCode::UNSUPPORTED_BLOCK_MODE or
|
|
* ErrorCode::UNSUPPORTED_PADDING_MODE. The specified modes must be authorized by the key,
|
|
* otherwise begin() must return ErrorCode::INCOMPATIBLE_BLOCK_MODE or
|
|
* ErrorCode::INCOMPATIBLE_PADDING_MODE.
|
|
*
|
|
* If the block mode is BlockMode::GCM, inParams must specify Tag::MAC_LENGTH, and the specified
|
|
* value must be a multiple of 8 that is not greater than 128 or less than the value of
|
|
* Tag::MIN_MAC_LENGTH in the key authorizations. For MAC lengths greater than 128 or
|
|
* non-multiples of 8, begin() must return ErrorCode::UNSUPPORTED_MAC_LENGTH. For values less
|
|
* than the key's minimum length, begin() must return ErrorCode::INVALID_MAC_LENGTH.
|
|
*
|
|
* If the block mode is BlockMode::GCM or BlockMode::CTR, the specified padding mode must be
|
|
* PaddingMode::NONE. For BlockMode::ECB or BlockMode::CBC, the mode may be PaddingMode::NONE
|
|
* or PaddingMode::PKCS7. If the padding mode doesn't meet these conditions, begin() must
|
|
* return ErrorCode::INCOMPATIBLE_PADDING_MODE.
|
|
*
|
|
* If the block mode is BlockMode::CBC, BlockMode::CTR, or BlockMode::GCM, an initialization
|
|
* vector or nonce is required. In most cases, callers shouldn't provide an IV or nonce and the
|
|
* IKeymasterDevice implementation must generate a random IV or nonce and return it via
|
|
* Tag::NONCE in outParams. CBC and CTR IVs are 16 bytes. GCM nonces are 12 bytes. If the key
|
|
* authorizations contain Tag::CALLER_NONCE, then the caller may provide an IV/nonce with
|
|
* Tag::NONCE in inParams. If a nonce is provided when Tag::CALLER_NONCE is not authorized,
|
|
* begin() must return ErrorCode::CALLER_NONCE_PROHIBITED. If a nonce is not provided when
|
|
* Tag::CALLER_NONCE is authorized, IKeymasterDevice msut generate a random IV/nonce.
|
|
*
|
|
* -- HMAC keys --
|
|
*
|
|
* HMAC key operations must specify Tag::MAC_LENGTH in inParams. The specified value must be a
|
|
* multiple of 8 that is not greater than the digest length or less than the value of
|
|
* Tag::MIN_MAC_LENGTH in the key authorizations. For MAC lengths greater than the digest
|
|
* length or non-multiples of 8, begin() must return ErrorCode::UNSUPPORTED_MAC_LENGTH. For
|
|
* values less than the key's minimum length, begin() must return ErrorCode::INVALID_MAC_LENGTH.
|
|
*
|
|
* @param purpose The purpose of the operation, one of KeyPurpose::ENCRYPT, KeyPurpose::DECRYPT,
|
|
* KeyPurpose::SIGN or KeyPurpose::VERIFY. Note that for AEAD modes, encryption and
|
|
* decryption imply signing and verification, respectively, but must be specified as
|
|
* KeyPurpose::ENCRYPT and KeyPurpose::DECRYPT.
|
|
*
|
|
* @param keyBlob The opaque key descriptor returned by generateKey() or importKey(). The key
|
|
* must have a purpose compatible with purpose and all of its usage requirements must be
|
|
* satisfied, or begin() must return an appropriate error code (see above).
|
|
*
|
|
* @param inParams Additional parameters for the operation. If Tag::APPLICATION_ID or
|
|
* Tag::APPLICATION_DATA were provided during generation, they must be provided here, or
|
|
* the operation must fail with ErrorCode::INVALID_KEY_BLOB. For operations that require
|
|
* a nonce or IV, on keys that were generated with Tag::CALLER_NONCE, inParams may
|
|
* contain a tag Tag::NONCE. If Tag::NONCE is provided for a key without
|
|
* Tag:CALLER_NONCE, ErrorCode::CALLER_NONCE_PROHIBITED must be returned.
|
|
*
|
|
* @param authToken Authentication token. Callers that provide no token must set all numeric
|
|
* fields to zero and the MAC must be an empty vector.
|
|
*
|
|
* @return outParams Output parameters. Used to return additional data from the operation
|
|
* initialization, notably to return the IV or nonce from operations that generate an IV
|
|
* or nonce.
|
|
*
|
|
* @return operationHandle The newly-created operation handle which must be passed to update(),
|
|
* finish() or abort().
|
|
*/
|
|
begin(KeyPurpose purpose, vec<uint8_t> keyBlob, vec<KeyParameter> inParams,
|
|
HardwareAuthToken authToken)
|
|
generates (ErrorCode error, vec<KeyParameter> outParams, OperationHandle operationHandle);
|
|
|
|
/**
|
|
* Provides data to, and possibly receives output from, an ongoing cryptographic operation begun
|
|
* with begin(). The operation is specified by the operationHandle paramater.
|
|
*
|
|
* If operationHandle is invalid, update() must return ErrorCode::INVALID_OPERATION_HANDLE.
|
|
*
|
|
* To provide more flexibility for buffer handling, implementations of this method have the
|
|
* option of consuming less data than was provided. The caller is responsible for looping to
|
|
* feed the rest of the data in subsequent calls. The amount of input consumed must be returned
|
|
* in the inputConsumed parameter. Implementations must always consume at least one byte, unless
|
|
* the operation cannot accept any more; if more than zero bytes are provided and zero bytes are
|
|
* consumed, callers must consider this an error and abort the operation.
|
|
*
|
|
* Implementations may also choose how much data to return, as a result of the update. This is
|
|
* only relevant for encryption and decryption operations, because signing and verification
|
|
* return no data until finish. It is recommended to return data as early as possible, rather
|
|
* than buffer it.
|
|
*
|
|
* If this method returns an error code other than ErrorCode::OK, the operation is aborted and
|
|
* the operation handle must be invalidated. Any future use of the handle, with this method,
|
|
* finish, or abort, must return ErrorCode::INVALID_OPERATION_HANDLE.
|
|
*
|
|
* == Authorization Enforcement ==
|
|
*
|
|
* Key authorization enforcement is performed primarily in begin(). The one exception is the
|
|
* case where the key has:
|
|
|
|
* o One or more Tag::USER_SECURE_IDs, and
|
|
*
|
|
* o Does not have a Tag::AUTH_TIMEOUT
|
|
*
|
|
* In this case, the key requires an authorization per operation, and the update method must
|
|
* receive a non-empty and valid HardwareAuthToken. For the auth token to be valid, all of the
|
|
* following has to be true:
|
|
*
|
|
* o The HMAC field must validate correctly.
|
|
*
|
|
* o At least one of the Tag::USER_SECURE_ID values from the key must match at least one of
|
|
* the secure ID values in the token.
|
|
*
|
|
* o The key must have a Tag::USER_AUTH_TYPE that matches the auth type in the token.
|
|
*
|
|
* o The challenge field in the auth token must contain the operationHandle
|
|
*
|
|
* If any of these conditions are not met, update() must return
|
|
* ErrorCode::KEY_USER_NOT_AUTHENTICATED.
|
|
*
|
|
* The caller must provide the auth token on every call to update() and finish().
|
|
*
|
|
* -- RSA keys --
|
|
*
|
|
* For signing and verification operations with Digest::NONE, this method must accept the entire
|
|
* block to be signed or verified in a single update. It may not consume only a portion of the
|
|
* block in these cases. However, the caller may choose to provide the data in multiple updates,
|
|
* and update() must accept the data this way as well. If the caller provides more data to sign
|
|
* than can be used (length of data exceeds RSA key size), update() must return
|
|
* ErrorCode::INVALID_INPUT_LENGTH.
|
|
*
|
|
* -- ECDSA keys --
|
|
*
|
|
* For signing and verification operations with Digest::NONE, this method must accept the entire
|
|
* block to be signed or verified in a single update. This method may not consume only a
|
|
* portion of the block. However, the caller may choose to provide the data in multiple updates
|
|
* and update() must accept the data this way as well. If the caller provides more data to sign
|
|
* than can be used, the data is silently truncated. (This differs from the handling of excess
|
|
* data provided in similar RSA operations. The reason for this is compatibility with legacy
|
|
* clients.)
|
|
*
|
|
* -- AES keys --
|
|
*
|
|
* AES GCM mode supports "associated authentication data," provided via the Tag::ASSOCIATED_DATA
|
|
* tag in the inParams argument. The associated data may be provided in repeated calls
|
|
* (important if the data is too large to send in a single block) but must always precede data
|
|
* to be encrypted or decrypted. An update call may receive both associated data and data to
|
|
* encrypt/decrypt, but subsequent updates must not include associated data. If the caller
|
|
* provides associated data to an update call after a call that includes data to
|
|
* encrypt/decrypt, update() must return ErrorCode::INVALID_TAG.
|
|
*
|
|
* For GCM encryption, the AEAD tag must be appended to the ciphertext by finish(). During
|
|
* decryption, the last Tag::MAC_LENGTH bytes of the data provided to the last update call must
|
|
* be the AEAD tag. Since a given invocation of update cannot know if it's the last invocation,
|
|
* it must process all but the tag length and buffer the possible tag data for processing during
|
|
* finish().
|
|
*
|
|
* @param operationHandle The operation handle returned by begin().
|
|
*
|
|
* @param inParams Additional parameters for the operation. For AEAD modes, this is used to
|
|
* specify Tag::ADDITIONAL_DATA. Note that additional data may be provided in multiple
|
|
* calls to update(), but only until input data has been provided.
|
|
*
|
|
* @param input Data to be processed. Note that update() may or may not consume all of the data
|
|
* provided. See inputConsumed.
|
|
*
|
|
* @param authToken Authentication token. Callers that provide no token must set all numeric
|
|
* fields to zero and the MAC must be an empty vector.
|
|
*
|
|
* @param verificationToken Verification token, used to prove that another IKeymasterDevice HAL
|
|
* has verified some parameters, and to deliver the other HAL's current timestamp, if
|
|
* needed. If not provided, all fields must be initialized to zero and vectors must be
|
|
* empty.
|
|
*
|
|
* @return error See the ErrorCode enum in types.hal.
|
|
*
|
|
* @return inputConsumed Amount of data that was consumed by update(). If this is less than the
|
|
* amount provided, the caller may provide the remainder in a subsequent call to
|
|
* update() or finish(). Every call to update must consume at least one byte, unless
|
|
* the input is empty, and implementations should consume as much data as reasonably
|
|
* possible for each call.
|
|
*
|
|
* @return outParams Output parameters, used to return additional data from the operation.
|
|
*
|
|
* @return output The output data, if any.
|
|
*/
|
|
update(OperationHandle operationHandle, vec<KeyParameter> inParams, vec<uint8_t> input,
|
|
HardwareAuthToken authToken, VerificationToken verificationToken)
|
|
generates (ErrorCode error, uint32_t inputConsumed, vec<KeyParameter> outParams,
|
|
vec<uint8_t> output);
|
|
|
|
/**
|
|
* Finalizes a cryptographic operation begun with begin() and invalidates operationHandle.
|
|
*
|
|
* This method is the last one called in an operation, so all processed data must be returned.
|
|
*
|
|
* Whether it completes successfully or returns an error, this method finalizes the operation
|
|
* and therefore must invalidate the provided operation handle. Any future use of the handle,
|
|
* with finish(), update(), or abort(), must return ErrorCode::INVALID_OPERATION_HANDLE.
|
|
*
|
|
* Signing operations return the signature as the output. Verification operations accept the
|
|
* signature in the signature parameter, and return no output.
|
|
*
|
|
* == Authorization enforcement ==
|
|
*
|
|
* Key authorization enforcement is performed primarily in begin(). The exceptions are
|
|
* authorization per operation keys and confirmation-required keys.
|
|
*
|
|
* Authorization per operation keys are the case where the key has one or more
|
|
* Tag::USER_SECURE_IDs, and does not have a Tag::AUTH_TIMEOUT. In this case, the key requires
|
|
* an authorization per operation, and the finish method must receive a non-empty and valid
|
|
* authToken. For the auth token to be valid, all of the following has to be true:
|
|
*
|
|
* o The HMAC field must validate correctly.
|
|
*
|
|
* o At least one of the Tag::USER_SECURE_ID values from the key must match at least one of
|
|
* the secure ID values in the token.
|
|
*
|
|
* o The key must have a Tag::USER_AUTH_TYPE that matches the auth type in the token.
|
|
*
|
|
* o The challenge field in the auth token must contain the operationHandle
|
|
*
|
|
* If any of these conditions are not met, update() must return
|
|
* ErrorCode::KEY_USER_NOT_AUTHENTICATED.
|
|
*
|
|
* The caller must provide the auth token on every call to update() and finish().
|
|
*
|
|
* Confirmation-required keys are keys that were generated with
|
|
* Tag::TRUSTED_CONFIRMATION_REQUIRED. For these keys, when doing a signing operation the
|
|
* caller must pass a KeyParameter Tag::CONFIRMATION_TOKEN to finish(). Implementations must
|
|
* check the confirmation token by computing the 32-byte HMAC-SHA256 over all of the
|
|
* to-be-signed data, prefixed with the 18-byte UTF-8 encoded string "confirmation token". If
|
|
* the computed value does not match the Tag::CONFIRMATION_TOKEN parameter, finish() must not
|
|
* produce a signature and must return ErrorCode::NO_USER_CONFIRMATION.
|
|
*
|
|
* -- RSA keys --
|
|
*
|
|
* Some additional requirements, depending on the padding mode:
|
|
*
|
|
* o PaddingMode::NONE. For unpadded signing and encryption operations, if the provided data is
|
|
* shorter than the key, the data must be zero-padded on the left before
|
|
* signing/encryption. If the data is the same length as the key, but numerically larger,
|
|
* finish() must return ErrorCode::INVALID_ARGUMENT. For verification and decryption
|
|
* operations, the data must be exactly as long as the key. Otherwise, return
|
|
* ErrorCode::INVALID_INPUT_LENGTH.
|
|
*
|
|
* o PaddingMode::RSA_PSS. For PSS-padded signature operations, the PSS salt length must match
|
|
* the size of the PSS digest selected. The digest specified with Tag::DIGEST in inputParams
|
|
* on begin() must be used as the PSS digest algorithm, MGF1 must be used as the mask
|
|
* generation function and SHA1 must be used as the MGF1 digest algorithm.
|
|
*
|
|
* o PaddingMode::RSA_OAEP. The digest specified with Tag::DIGEST in inputParams on begin is
|
|
* used as the OAEP digest algorithm, MGF1 must be used as the mask generation function and
|
|
* and SHA1 must be used as the MGF1 digest algorithm.
|
|
*
|
|
* -- ECDSA keys --
|
|
*
|
|
* If the data provided for unpadded signing or verification is too long, truncate it.
|
|
*
|
|
* -- AES keys --
|
|
*
|
|
* Some additional conditions, depending on block mode:
|
|
*
|
|
* o BlockMode::ECB or BlockMode::CBC. If padding is PaddingMode::NONE and the data length is
|
|
* not a multiple of the AES block size, finish() must return
|
|
* ErrorCode::INVALID_INPUT_LENGTH. If padding is PaddingMode::PKCS7, pad the data per the
|
|
* PKCS#7 specification, including adding an additional padding block if the data is a multiple
|
|
* of the block length.
|
|
*
|
|
* o BlockMode::GCM. During encryption, after processing all plaintext, compute the tag
|
|
* (Tag::MAC_LENGTH bytes) and append it to the returned ciphertext. During decryption,
|
|
* process the last Tag::MAC_LENGTH bytes as the tag. If tag verification fails, finish()
|
|
* must return ErrorCode::VERIFICATION_FAILED.
|
|
*
|
|
* @param operationHandle The operation handle returned by begin(). This handle must be invalid
|
|
* when finish() returns.
|
|
*
|
|
* @param inParams Additional parameters for the operation. For AEAD modes, this is used to
|
|
* specify Tag::ADDITIONAL_DATA, but only if no input data was provided to update().
|
|
*
|
|
* @param input Data to be processed, per the parameters established in the call to begin().
|
|
* finish() must consume all provided data or return ErrorCode::INVALID_INPUT_LENGTH.
|
|
*
|
|
* @param signature The signature to be verified if the purpose specified in the begin() call
|
|
* was KeyPurpose::VERIFY.
|
|
*
|
|
* @param authToken Authentication token. Callers that provide no token must set all numeric
|
|
* fields to zero and the MAC must be an empty vector.
|
|
*
|
|
* @param verificationToken Verification token, used to prove that another IKeymasterDevice HAL
|
|
* has verified some parameters, and to deliver the other HAL's current timestamp, if
|
|
* needed. If not provided, all fields must be initialized to zero and vectors empty.
|
|
*
|
|
* @return outParams Any output parameters generated by finish().
|
|
*
|
|
* @return output The output data, if any.
|
|
*/
|
|
finish(OperationHandle operationHandle, vec<KeyParameter> inParams, vec<uint8_t> input,
|
|
vec<uint8_t> signature, HardwareAuthToken authToken, VerificationToken verificationToken)
|
|
generates (ErrorCode error, vec<KeyParameter> outParams, vec<uint8_t> output);
|
|
|
|
/**
|
|
* Aborts a cryptographic operation begun with begin(), freeing all internal resources and
|
|
* invalidating operationHandle.
|
|
*
|
|
* @param operationHandle The operation handle returned by begin(). This handle must be
|
|
* invalid when abort() returns.
|
|
*
|
|
* @return error See the ErrorCode enum in types.hal.
|
|
*/
|
|
abort(OperationHandle operationHandle) generates (ErrorCode error);
|
|
};
|