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We currently increment the SSL_CTX stats.sess_accept field in tls_setup_handshake(), which is invoked from the state machine well before ClientHello processing would have had a chance to switch the SSL_CTX attached to the SSL object due to a provided SNI value. However, stats.sess_accept_good is incremented in tls_finish_handshake(), and uses the s->ctx.stats field (i.e., the new SSL_CTX that was switched to as a result of SNI processing). This leads to the confusing (nonsensical) situation where stats.sess_accept_good is larger than stats.sess_accept, as the "sess_accept" value was counted on the s->session_ctx. In order to provide some more useful numbers, increment s->ctx.stats.sess_accept after SNI processing if the SNI processing changed s->ctx to differ from s->session_ctx. To preserve the property that any given accept is counted only once, make the corresponding decrement to s->session_ctx.stats.sess_accept when doing so. Reviewed-by: Matt Caswell <matt@openssl.org> Reviewed-by: Paul Dale <paul.dale@oracle.com> (Merged from https://github.com/openssl/openssl/pull/4549) |
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extensions_clnt.c | ||
extensions_cust.c | ||
extensions_srvr.c | ||
extensions.c | ||
README | ||
statem_clnt.c | ||
statem_dtls.c | ||
statem_lib.c | ||
statem_locl.h | ||
statem_srvr.c | ||
statem.c | ||
statem.h |
State Machine Design ==================== This file provides some guidance on the thinking behind the design of the state machine code to aid future maintenance. The state machine code replaces an older state machine present in OpenSSL versions 1.0.2 and below. The new state machine has the following objectives: - Remove duplication of state code between client and server - Remove duplication of state code between TLS and DTLS - Simplify transitions and bring the logic together in a single location so that it is easier to validate - Remove duplication of code between each of the message handling functions - Receive a message first and then work out whether that is a valid transition - not the other way around (the other way causes lots of issues where we are expecting one type of message next but actually get something else) - Separate message flow state from handshake state (in order to better understand each) - message flow state = when to flush buffers; handling restarts in the event of NBIO events; handling the common flow of steps for reading a message and the common flow of steps for writing a message etc - handshake state = what handshake message are we working on now - Control complexity: only the state machine can change state: keep all the state changes local to the state machine component The message flow state machine is divided into a reading sub-state machine and a writing sub-state machine. See the source comments in statem.c for a more detailed description of the various states and transitions possible. Conceptually the state machine component is designed as follows: libssl | ---------------------------|-----statem.h-------------------------------------- | _______V____________________ | | | statem.c | | | | Core state machine code | |____________________________| statem_locl.h ^ ^ _________| |_______ | | _____________|____________ _____________|____________ | | | | | statem_clnt.c | | statem_srvr.c | | | | | | TLS/DTLS client specific | | TLS/DTLS server specific | | state machine code | | state machine code | |__________________________| |__________________________| | |_______________|__ | | ________________| | | | | | | ____________V_______V________ ________V______V_______________ | | | | | statem_both.c | | statem_dtls.c | | | | | | Non core functions common | | Non core functions common to | | to both servers and clients | | both DTLS servers and clients | |_____________________________| |_______________________________|