ref: ca70040abf8d8ab2cb03575f65131ad8ef8f12a1
dir: /third_party/boringssl/src/PORTING.md/
# Porting from OpenSSL to BoringSSL BoringSSL is an OpenSSL derivative and is mostly source-compatible, for the subset of OpenSSL retained. Libraries ideally need little to no changes for BoringSSL support, provided they do not use removed APIs. In general, see if the library compiles and, on failure, consult the documentation in the header files and see if problematic features can be removed. BoringSSL's `OPENSSL_VERSION_NUMBER` matches the OpenSSL version it targets. Version checks for OpenSSL should ideally work as-is in BoringSSL. BoringSSL also defines upstream's `OPENSSL_NO_*` feature macros corresponding to removed features. If the preprocessor is needed, use these version checks or feature macros where possible, especially when patching third-party projects. Such patches are more generally useful to OpenSSL consumers and thus more appropriate to send upstream. In some cases, BoringSSL-specific code may be necessary. Use the `OPENSSL_IS_BORINGSSL` preprocessor macro in `#ifdef`s. However, first contact the BoringSSL maintainers about the missing APIs. We will typically add compatibility functions for convenience. In particular, *contact BoringSSL maintainers before working around missing OpenSSL 1.1.0 accessors*. BoringSSL was originally derived from OpenSSL 1.0.2 but now targets OpenSSL 1.1.0. Some newer APIs may be missing but can be added on request. (Not all projects have been ported to OpenSSL 1.1.0, so BoringSSL also remains largely compatible with OpenSSL 1.0.2.) The `OPENSSL_IS_BORINGSSL` macro may also be used to distinguish OpenSSL from BoringSSL in configure scripts. Do not use the presence or absence of particular symbols to detect BoringSSL. Note: BoringSSL does *not* have a stable API or ABI. It must be updated with its consumers. It is not suitable for, say, a system library in a traditional Linux distribution. For instance, Chromium statically links the specific revision of BoringSSL it was built against. Likewise, Android's system-internal copy of BoringSSL is not exposed by the NDK and must not be used by third-party applications. ## Major API changes ### Integer types Some APIs have been converted to use `size_t` for consistency and to avoid integer overflows at the API boundary. (Existing logic uses a mismash of `int`, `long`, and `unsigned`.) For the most part, implicit casts mean that existing code continues to compile. In some cases, this may require BoringSSL-specific code, particularly to avoid compiler warnings. Most notably, the `STACK_OF(T)` types have all been converted to use `size_t` instead of `int` for indices and lengths. ### Reference counts and opaque types Some external consumers increment reference counts directly by calling `CRYPTO_add` with the corresponding `CRYPTO_LOCK_*` value. These APIs no longer exist in BoringSSL. Instead, code which increments reference counts should call the corresponding `FOO_up_ref` function, such as `EVP_PKEY_up_ref`. BoringSSL also hides some structs which were previously exposed in OpenSSL 1.0.2, particularly in libssl. Use the relevant accessors instead. Note that some of these APIs were added in OpenSSL 1.1.0, so projects which do not yet support 1.1.0 may need additional `#ifdef`s. Projects supporting OpenSSL 1.1.0 should not require modification. ### Error codes OpenSSL's errors are extremely specific, leaking internals of the library, including even a function code for the function which emitted the error! As some logic in BoringSSL has been rewritten, code which conditions on the error may break (grep for `ERR_GET_REASON` and `ERR_GET_FUNC`). This danger also exists when upgrading OpenSSL versions. Where possible, avoid conditioning on the exact error reason. Otherwise, a BoringSSL `#ifdef` may be necessary. Exactly how best to resolve this issue is still being determined. It's possible some new APIs will be added in the future. Function codes have been completely removed. Remove code which conditions on these as it will break with the slightest change in the library, OpenSSL or BoringSSL. ### `*_ctrl` functions Some OpenSSL APIs are implemented with `ioctl`-style functions such as `SSL_ctrl` and `EVP_PKEY_CTX_ctrl`, combined with convenience macros, such as # define SSL_CTX_set_mode(ctx,op) \ SSL_CTX_ctrl((ctx),SSL_CTRL_MODE,(op),NULL) In BoringSSL, these macros have been replaced with proper functions. The underlying `_ctrl` functions have been removed. For convenience, `SSL_CTRL_*` values are retained as macros to `doesnt_exist` so existing code which uses them (or the wrapper macros) in `#ifdef` expressions will continue to function. However, the macros themselves will not work. Switch any `*_ctrl` callers to the macro/function versions. This works in both OpenSSL and BoringSSL. Note that BoringSSL's function versions will be type-checked and may require more care with types. See the end of this document for a table of functions to use. ### HMAC `EVP_PKEY`s `EVP_PKEY_HMAC` is removed. Use the `HMAC_*` functions in `hmac.h` instead. This is compatible with OpenSSL. ### DSA `EVP_PKEY`s `EVP_PKEY_DSA` is deprecated. It is currently still possible to parse DER into a DSA `EVP_PKEY`, but signing or verifying with those objects will not work. ### DES The `DES_cblock` type has been switched from an array to a struct to avoid the pitfalls around array types in C. Where features which require DES cannot be disabled, BoringSSL-specific codepaths may be necessary. ### TLS renegotiation OpenSSL enables TLS renegotiation by default and accepts renegotiation requests from the peer transparently. Renegotiation is an extremely problematic protocol feature, so BoringSSL rejects peer renegotiations by default. To enable renegotiation, call `SSL_set_renegotiate_mode` and set it to `ssl_renegotiate_once` or `ssl_renegotiate_freely`. Renegotiation is only supported as a client in TLS and the HelloRequest must be received at a quiet point in the application protocol. This is sufficient to support the common use of requesting a new client certificate between an HTTP request and response in (unpipelined) HTTP/1.1. Things which do not work: * There is no support for renegotiation as a server. (Attempts by clients will result in a fatal alert so that ClientHello messages cannot be used to flood a server and escape higher-level limits.) * There is no support for renegotiation in DTLS. * There is no support for initiating renegotiation; `SSL_renegotiate` always fails and `SSL_set_state` does nothing. * Interleaving application data with the new handshake is forbidden. * If a HelloRequest is received while `SSL_write` has unsent application data, the renegotiation is rejected. * Renegotiation does not participate in session resumption. The client will not offer a session on renegotiation or resume any session established by a renegotiation handshake. * The server may not change its certificate in the renegotiation. This mitigates the [triple handshake attack](https://mitls.org/pages/attacks/3SHAKE). Any new stapled OCSP response and SCT list will be ignored. As no authentication state may change, BoringSSL will not re-verify the certificate on a renegotiation. Callbacks such as `SSL_CTX_set_custom_verify` will only run on the initial handshake. ### Lowercase hexadecimal BoringSSL's `BN_bn2hex` function uses lowercase hexadecimal digits instead of uppercase. Some code may require changes to avoid being sensitive to this difference. ### Legacy ASN.1 functions OpenSSL's ASN.1 stack uses `d2i` functions for parsing. They have the form: RSA *d2i_RSAPrivateKey(RSA **out, const uint8_t **inp, long len); In addition to returning the result, OpenSSL places it in `*out` if `out` is not `NULL`. On input, if `*out` is not `NULL`, OpenSSL will usually (but not always) reuse that object rather than allocating a new one. In BoringSSL, these functions are compatibility wrappers over a newer ASN.1 stack. Even if `*out` is not `NULL`, these wrappers will always allocate a new object and free the previous one. Ensure that callers do not rely on this object reuse behavior. It is recommended to avoid the `out` parameter completely and always pass in `NULL`. Note that less error-prone APIs are available for BoringSSL-specific code (see below). ### Memory allocation OpenSSL provides wrappers `OPENSSL_malloc` and `OPENSSL_free` over the standard `malloc` and `free`. Memory allocated by OpenSSL should be released with `OPENSSL_free`, not the standard `free`. However, by default, they are implemented directly using `malloc` and `free`, so code which mixes them up usually works. In BoringSSL, these functions maintain additional book-keeping to zero memory on `OPENSSL_free`, so any mixups must be fixed. ## Optional BoringSSL-specific simplifications BoringSSL makes some changes to OpenSSL which simplify the API but remain compatible with OpenSSL consumers. In general, consult the BoringSSL documentation for any functions in new BoringSSL-only code. ### Return values Most OpenSSL APIs return 1 on success and either 0 or -1 on failure. BoringSSL has narrowed most of these to 1 on success and 0 on failure. BoringSSL-specific code may take advantage of the less error-prone APIs and use `!` to check for errors. ### Initialization OpenSSL has a number of different initialization functions for setting up error strings and loading algorithms, etc. All of these functions still exist in BoringSSL for convenience, but they do nothing and are not necessary. The one exception is `CRYPTO_library_init`. In `BORINGSSL_NO_STATIC_INITIALIZER` builds, it must be called to query CPU capabilities before the rest of the library. In the default configuration, this is done with a static initializer and is also unnecessary. ### Threading OpenSSL provides a number of APIs to configure threading callbacks and set up locks. Without initializing these, the library is not thread-safe. Configuring these does nothing in BoringSSL. Instead, BoringSSL calls pthreads and the corresponding Windows APIs internally and is always thread-safe where the API guarantees it. ### ASN.1 BoringSSL is in the process of deprecating OpenSSL's `d2i` and `i2d` in favor of new functions using the much less error-prone `CBS` and `CBB` types. BoringSSL-only code should use those functions where available. ## Replacements for `CTRL` values When porting code which uses `SSL_CTX_ctrl` or `SSL_ctrl`, use the replacement functions below. If a function has both `SSL_CTX` and `SSL` variants, only the `SSL_CTX` version is listed. Note some values correspond to multiple functions depending on the `larg` parameter. `CTRL` value | Replacement function(s) -------------|------------------------- `DTLS_CTRL_GET_TIMEOUT` | `DTLSv1_get_timeout` `DTLS_CTRL_HANDLE_TIMEOUT` | `DTLSv1_handle_timeout` `SSL_CTRL_CHAIN` | `SSL_CTX_set0_chain` or `SSL_CTX_set1_chain` `SSL_CTRL_CHAIN_CERT` | `SSL_add0_chain_cert` or `SSL_add1_chain_cert` `SSL_CTRL_CLEAR_EXTRA_CHAIN_CERTS` | `SSL_CTX_clear_extra_chain_certs` `SSL_CTRL_CLEAR_MODE` | `SSL_CTX_clear_mode` `SSL_CTRL_CLEAR_OPTIONS` | `SSL_CTX_clear_options` `SSL_CTRL_EXTRA_CHAIN_CERT` | `SSL_CTX_add_extra_chain_cert` `SSL_CTRL_GET_CHAIN_CERTS` | `SSL_CTX_get0_chain_certs` `SSL_CTRL_GET_CLIENT_CERT_TYPES` | `SSL_get0_certificate_types` `SSL_CTRL_GET_EXTRA_CHAIN_CERTS` | `SSL_CTX_get_extra_chain_certs` or `SSL_CTX_get_extra_chain_certs_only` `SSL_CTRL_GET_MAX_CERT_LIST` | `SSL_CTX_get_max_cert_list` `SSL_CTRL_GET_NUM_RENEGOTIATIONS` | `SSL_num_renegotiations` `SSL_CTRL_GET_READ_AHEAD` | `SSL_CTX_get_read_ahead` `SSL_CTRL_GET_RI_SUPPORT` | `SSL_get_secure_renegotiation_support` `SSL_CTRL_GET_SESSION_REUSED` | `SSL_session_reused` `SSL_CTRL_GET_SESS_CACHE_MODE` | `SSL_CTX_get_session_cache_mode` `SSL_CTRL_GET_SESS_CACHE_SIZE` | `SSL_CTX_sess_get_cache_size` `SSL_CTRL_GET_TLSEXT_TICKET_KEYS` | `SSL_CTX_get_tlsext_ticket_keys` `SSL_CTRL_GET_TOTAL_RENEGOTIATIONS` | `SSL_total_renegotiations` `SSL_CTRL_MODE` | `SSL_CTX_get_mode` or `SSL_CTX_set_mode` `SSL_CTRL_NEED_TMP_RSA` | `SSL_CTX_need_tmp_RSA` is equivalent, but [*do not use this function*](https://freakattack.com/). (It is a no-op in BoringSSL.) `SSL_CTRL_OPTIONS` | `SSL_CTX_get_options` or `SSL_CTX_set_options` `SSL_CTRL_SESS_NUMBER` | `SSL_CTX_sess_number` `SSL_CTRL_SET_CURVES` | `SSL_CTX_set1_curves` `SSL_CTRL_SET_ECDH_AUTO` | `SSL_CTX_set_ecdh_auto` `SSL_CTRL_SET_MAX_CERT_LIST` | `SSL_CTX_set_max_cert_list` `SSL_CTRL_SET_MAX_SEND_FRAGMENT` | `SSL_CTX_set_max_send_fragment` `SSL_CTRL_SET_MSG_CALLBACK` | `SSL_set_msg_callback` `SSL_CTRL_SET_MSG_CALLBACK_ARG` | `SSL_set_msg_callback_arg` `SSL_CTRL_SET_MTU` | `SSL_set_mtu` `SSL_CTRL_SET_READ_AHEAD` | `SSL_CTX_set_read_ahead` `SSL_CTRL_SET_SESS_CACHE_MODE` | `SSL_CTX_set_session_cache_mode` `SSL_CTRL_SET_SESS_CACHE_SIZE` | `SSL_CTX_sess_set_cache_size` `SSL_CTRL_SET_TLSEXT_HOSTNAME` | `SSL_set_tlsext_host_name` `SSL_CTRL_SET_TLSEXT_SERVERNAME_ARG` | `SSL_CTX_set_tlsext_servername_arg` `SSL_CTRL_SET_TLSEXT_SERVERNAME_CB` | `SSL_CTX_set_tlsext_servername_callback` `SSL_CTRL_SET_TLSEXT_TICKET_KEYS` | `SSL_CTX_set_tlsext_ticket_keys` `SSL_CTRL_SET_TLSEXT_TICKET_KEY_CB` | `SSL_CTX_set_tlsext_ticket_key_cb` `SSL_CTRL_SET_TMP_DH` | `SSL_CTX_set_tmp_dh` `SSL_CTRL_SET_TMP_DH_CB` | `SSL_CTX_set_tmp_dh_callback` `SSL_CTRL_SET_TMP_ECDH` | `SSL_CTX_set_tmp_ecdh` `SSL_CTRL_SET_TMP_ECDH_CB` | `SSL_CTX_set_tmp_ecdh_callback` `SSL_CTRL_SET_TMP_RSA` | `SSL_CTX_set_tmp_rsa` is equivalent, but [*do not use this function*](https://freakattack.com/). (It is a no-op in BoringSSL.) `SSL_CTRL_SET_TMP_RSA_CB` | `SSL_CTX_set_tmp_rsa_callback` is equivalent, but [*do not use this function*](https://freakattack.com/). (It is a no-op in BoringSSL.) ## Significant API additions In some places, BoringSSL has added significant APIs. Use of these APIs goes beyound “porting” and means giving up on OpenSSL compatibility. One example of this has already been mentioned: the [CBS and CBB](https://commondatastorage.googleapis.com/chromium-boringssl-docs/bytestring.h.html) functions should be used whenever parsing or serialising data. ### CRYPTO\_BUFFER With the standard OpenSSL APIs, when making many TLS connections, the certificate data for each connection is retained in memory in an expensive `X509` structure. Additionally, common certificates often appear in the chains for multiple connections and are needlessly duplicated in memory. A [`CRYPTO_BUFFER`](https://commondatastorage.googleapis.com/chromium-boringssl-docs/pool.h.html) is just an opaque byte string. A `CRYPTO_BUFFER_POOL` is an intern table for these buffers, i.e. it ensures that only a single copy of any given byte string is kept for each pool. The function `TLS_with_buffers_method` returns an `SSL_METHOD` that avoids creating `X509` objects for certificates. Additionally, `SSL_CTX_set0_buffer_pool` can be used to install a pool on an `SSL_CTX` so that certificates can be deduplicated across connections and across `SSL_CTX`s. When using these functions, the application also needs to ensure that it doesn't call other functions that deal with `X509` or `X509_NAME` objects. For example, `SSL_get_peer_certificate` or `SSL_get_peer_cert_chain`. Doing so will trigger an assert in debug mode and will result in NULLs in release mode. Instead, call the buffer-based alternatives such as `SSL_get0_peer_certificates`. (See [ssl.h](https://commondatastorage.googleapis.com/chromium-boringssl-docs/ssl.h.html) for functions taking or returning `CRYPTO_BUFFER`.) The buffer-based alternative functions will work even when not using `TLS_with_buffers_method`, thus application code can transition gradually. In order to use buffers, the application code also needs to implement its own certificate verification using `SSL_[CTX_]set_custom_verify`. Otherwise all connections will fail with a verification error. Auto-chaining is also disabled when using buffers. Once those changes have been completed, the whole of the OpenSSL X.509 and ASN.1 code should be eliminated by the linker if BoringSSL is linked statically. ### Asynchronous and opaque private keys OpenSSL offers the ENGINE API for implementing opaque private keys (i.e. private keys where software only has oracle access because the secrets are held in special hardware or on another machine). While the ENGINE API has been mostly removed from BoringSSL, it is still possible to support opaque keys in this way. However, when using such keys with TLS and BoringSSL, you should strongly prefer using `SSL_PRIVATE_KEY_METHOD` via `SSL[_CTX]_set_private_key_method`. This allows a handshake to be suspended while the private operation is in progress. It also supports more forms of opaque key as it exposes higher-level information about the operation to be performed.