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Extract circuit_t into its own header

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This commit is contained in:
Nick Mathewson 2018-06-15 11:38:36 -04:00
parent a0bc164af5
commit e0830ff7bf
5 changed files with 176 additions and 157 deletions
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170
src/or/circuit_st.h Normal file
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@ -0,0 +1,170 @@
/* Copyright (c) 2001 Matej Pfajfar.
* Copyright (c) 2001-2004, Roger Dingledine.
* Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson.
* Copyright (c) 2007-2017, The Tor Project, Inc. */
/* See LICENSE for licensing information */
#ifndef CIRCUIT_ST_H
#define CIRCUIT_ST_H
#include "or.h"
/**
* A circuit is a path over the onion routing
* network. Applications can connect to one end of the circuit, and can
* create exit connections at the other end of the circuit. AP and exit
* connections have only one circuit associated with them (and thus these
* connection types are closed when the circuit is closed), whereas
* OR connections multiplex many circuits at once, and stay standing even
* when there are no circuits running over them.
*
* A circuit_t structure can fill one of two roles. First, a or_circuit_t
* links two connections together: either an edge connection and an OR
* connection, or two OR connections. (When joined to an OR connection, a
* circuit_t affects only cells sent to a particular circID on that
* connection. When joined to an edge connection, a circuit_t affects all
* data.)
* Second, an origin_circuit_t holds the cipher keys and state for sending data
* along a given circuit. At the OP, it has a sequence of ciphers, each
* of which is shared with a single OR along the circuit. Separate
* ciphers are used for data going "forward" (away from the OP) and
* "backward" (towards the OP). At the OR, a circuit has only two stream
* ciphers: one for data going forward, and one for data going backward.
*/
struct circuit_t {
uint32_t magic; /**< For memory and type debugging: must equal
* ORIGIN_CIRCUIT_MAGIC or OR_CIRCUIT_MAGIC. */
/** The channel that is next in this circuit. */
channel_t *n_chan;
/**
* The circuit_id used in the next (forward) hop of this circuit;
* this is unique to n_chan, but this ordered pair is globally
* unique:
*
* (n_chan->global_identifier, n_circ_id)
*/
circid_t n_circ_id;
/**
* Circuit mux associated with n_chan to which this circuit is attached;
* NULL if we have no n_chan.
*/
circuitmux_t *n_mux;
/** Queue of cells waiting to be transmitted on n_chan */
cell_queue_t n_chan_cells;
/**
* The hop to which we want to extend this circuit. Should be NULL if
* the circuit has attached to a channel.
*/
extend_info_t *n_hop;
/** True iff we are waiting for n_chan_cells to become less full before
* allowing p_streams to add any more cells. (Origin circuit only.) */
unsigned int streams_blocked_on_n_chan : 1;
/** True iff we are waiting for p_chan_cells to become less full before
* allowing n_streams to add any more cells. (OR circuit only.) */
unsigned int streams_blocked_on_p_chan : 1;
/** True iff we have queued a delete backwards on this circuit, but not put
* it on the output buffer. */
unsigned int p_delete_pending : 1;
/** True iff we have queued a delete forwards on this circuit, but not put
* it on the output buffer. */
unsigned int n_delete_pending : 1;
/** True iff this circuit has received a DESTROY cell in either direction */
unsigned int received_destroy : 1;
uint8_t state; /**< Current status of this circuit. */
uint8_t purpose; /**< Why are we creating this circuit? */
/** How many relay data cells can we package (read from edge streams)
* on this circuit before we receive a circuit-level sendme cell asking
* for more? */
int package_window;
/** How many relay data cells will we deliver (write to edge streams)
* on this circuit? When deliver_window gets low, we send some
* circuit-level sendme cells to indicate that we're willing to accept
* more. */
int deliver_window;
/** Temporary field used during circuits_handle_oom. */
uint32_t age_tmp;
/** For storage while n_chan is pending (state CIRCUIT_STATE_CHAN_WAIT). */
struct create_cell_t *n_chan_create_cell;
/** When did circuit construction actually begin (ie send the
* CREATE cell or begin cannibalization).
*
* Note: This timer will get reset if we decide to cannibalize
* a circuit. It may also get reset during certain phases of hidden
* service circuit use.
*
* We keep this timestamp with a higher resolution than most so that the
* circuit-build-time tracking code can get millisecond resolution.
*/
struct timeval timestamp_began;
/** This timestamp marks when the init_circuit_base constructor ran. */
struct timeval timestamp_created;
/** When the circuit was first used, or 0 if the circuit is clean.
*
* XXXX Note that some code will artificially adjust this value backward
* in time in order to indicate that a circuit shouldn't be used for new
* streams, but that it can stay alive as long as it has streams on it.
* That's a kludge we should fix.
*
* XXX The CBT code uses this field to record when HS-related
* circuits entered certain states. This usage probably won't
* interfere with this field's primary purpose, but we should
* document it more thoroughly to make sure of that.
*
* XXX The SocksPort option KeepaliveIsolateSOCKSAuth will artificially
* adjust this value forward each time a suitable stream is attached to an
* already constructed circuit, potentially keeping the circuit alive
* indefinitely.
*/
time_t timestamp_dirty;
uint16_t marked_for_close; /**< Should we close this circuit at the end of
* the main loop? (If true, holds the line number
* where this circuit was marked.) */
const char *marked_for_close_file; /**< For debugging: in which file was this
* circuit marked for close? */
/** For what reason (See END_CIRC_REASON...) is this circuit being closed?
* This field is set in circuit_mark_for_close and used later in
* circuit_about_to_free. */
int marked_for_close_reason;
/** As marked_for_close_reason, but reflects the underlying reason for
* closing this circuit.
*/
int marked_for_close_orig_reason;
/** Unique ID for measuring tunneled network status requests. */
uint64_t dirreq_id;
/** Index in smartlist of all circuits (global_circuitlist). */
int global_circuitlist_idx;
/** Various statistics about cells being added to or removed from this
* circuit's queues; used only if CELL_STATS events are enabled and
* cleared after being sent to control port. */
smartlist_t *testing_cell_stats;
/** If set, points to an HS token that this circuit might be carrying.
* Used by the HS circuitmap. */
hs_token_t *hs_token;
/** Hashtable node: used to look up the circuit by its HS token using the HS
circuitmap. */
HT_ENTRY(circuit_t) hs_circuitmap_node;
};
#endif

1
src/or/include.am
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@ -193,6 +193,7 @@ ORHEADERS = \
src/or/circuitmux_ewma.h \
src/or/circuitstats.h \
src/or/circuituse.h \
src/or/circuit_st.h \
src/or/command.h \
src/or/config.h \
src/or/confparse.h \

158
src/or/or.h
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@ -2404,163 +2404,7 @@ typedef struct testing_cell_stats_entry_t {
unsigned int exitward:1; /**< 0 for app-ward, 1 for exit-ward. */
} testing_cell_stats_entry_t;
/**
* A circuit is a path over the onion routing
* network. Applications can connect to one end of the circuit, and can
* create exit connections at the other end of the circuit. AP and exit
* connections have only one circuit associated with them (and thus these
* connection types are closed when the circuit is closed), whereas
* OR connections multiplex many circuits at once, and stay standing even
* when there are no circuits running over them.
*
* A circuit_t structure can fill one of two roles. First, a or_circuit_t
* links two connections together: either an edge connection and an OR
* connection, or two OR connections. (When joined to an OR connection, a
* circuit_t affects only cells sent to a particular circID on that
* connection. When joined to an edge connection, a circuit_t affects all
* data.)
* Second, an origin_circuit_t holds the cipher keys and state for sending data
* along a given circuit. At the OP, it has a sequence of ciphers, each
* of which is shared with a single OR along the circuit. Separate
* ciphers are used for data going "forward" (away from the OP) and
* "backward" (towards the OP). At the OR, a circuit has only two stream
* ciphers: one for data going forward, and one for data going backward.
*/
typedef struct circuit_t {
uint32_t magic; /**< For memory and type debugging: must equal
* ORIGIN_CIRCUIT_MAGIC or OR_CIRCUIT_MAGIC. */
/** The channel that is next in this circuit. */
channel_t *n_chan;
/**
* The circuit_id used in the next (forward) hop of this circuit;
* this is unique to n_chan, but this ordered pair is globally
* unique:
*
* (n_chan->global_identifier, n_circ_id)
*/
circid_t n_circ_id;
/**
* Circuit mux associated with n_chan to which this circuit is attached;
* NULL if we have no n_chan.
*/
circuitmux_t *n_mux;
/** Queue of cells waiting to be transmitted on n_chan */
cell_queue_t n_chan_cells;
/**
* The hop to which we want to extend this circuit. Should be NULL if
* the circuit has attached to a channel.
*/
extend_info_t *n_hop;
/** True iff we are waiting for n_chan_cells to become less full before
* allowing p_streams to add any more cells. (Origin circuit only.) */
unsigned int streams_blocked_on_n_chan : 1;
/** True iff we are waiting for p_chan_cells to become less full before
* allowing n_streams to add any more cells. (OR circuit only.) */
unsigned int streams_blocked_on_p_chan : 1;
/** True iff we have queued a delete backwards on this circuit, but not put
* it on the output buffer. */
unsigned int p_delete_pending : 1;
/** True iff we have queued a delete forwards on this circuit, but not put
* it on the output buffer. */
unsigned int n_delete_pending : 1;
/** True iff this circuit has received a DESTROY cell in either direction */
unsigned int received_destroy : 1;
uint8_t state; /**< Current status of this circuit. */
uint8_t purpose; /**< Why are we creating this circuit? */
/** How many relay data cells can we package (read from edge streams)
* on this circuit before we receive a circuit-level sendme cell asking
* for more? */
int package_window;
/** How many relay data cells will we deliver (write to edge streams)
* on this circuit? When deliver_window gets low, we send some
* circuit-level sendme cells to indicate that we're willing to accept
* more. */
int deliver_window;
/** Temporary field used during circuits_handle_oom. */
uint32_t age_tmp;
/** For storage while n_chan is pending (state CIRCUIT_STATE_CHAN_WAIT). */
struct create_cell_t *n_chan_create_cell;
/** When did circuit construction actually begin (ie send the
* CREATE cell or begin cannibalization).
*
* Note: This timer will get reset if we decide to cannibalize
* a circuit. It may also get reset during certain phases of hidden
* service circuit use.
*
* We keep this timestamp with a higher resolution than most so that the
* circuit-build-time tracking code can get millisecond resolution.
*/
struct timeval timestamp_began;
/** This timestamp marks when the init_circuit_base constructor ran. */
struct timeval timestamp_created;
/** When the circuit was first used, or 0 if the circuit is clean.
*
* XXXX Note that some code will artificially adjust this value backward
* in time in order to indicate that a circuit shouldn't be used for new
* streams, but that it can stay alive as long as it has streams on it.
* That's a kludge we should fix.
*
* XXX The CBT code uses this field to record when HS-related
* circuits entered certain states. This usage probably won't
* interfere with this field's primary purpose, but we should
* document it more thoroughly to make sure of that.
*
* XXX The SocksPort option KeepaliveIsolateSOCKSAuth will artificially
* adjust this value forward each time a suitable stream is attached to an
* already constructed circuit, potentially keeping the circuit alive
* indefinitely.
*/
time_t timestamp_dirty;
uint16_t marked_for_close; /**< Should we close this circuit at the end of
* the main loop? (If true, holds the line number
* where this circuit was marked.) */
const char *marked_for_close_file; /**< For debugging: in which file was this
* circuit marked for close? */
/** For what reason (See END_CIRC_REASON...) is this circuit being closed?
* This field is set in circuit_mark_for_close and used later in
* circuit_about_to_free. */
int marked_for_close_reason;
/** As marked_for_close_reason, but reflects the underlying reason for
* closing this circuit.
*/
int marked_for_close_orig_reason;
/** Unique ID for measuring tunneled network status requests. */
uint64_t dirreq_id;
/** Index in smartlist of all circuits (global_circuitlist). */
int global_circuitlist_idx;
/** Various statistics about cells being added to or removed from this
* circuit's queues; used only if CELL_STATS events are enabled and
* cleared after being sent to control port. */
smartlist_t *testing_cell_stats;
/** If set, points to an HS token that this circuit might be carrying.
* Used by the HS circuitmap. */
hs_token_t *hs_token;
/** Hashtable node: used to look up the circuit by its HS token using the HS
circuitmap. */
HT_ENTRY(circuit_t) hs_circuitmap_node;
} circuit_t;
typedef struct circuit_t circuit_t;
typedef struct origin_circuit_t origin_circuit_t;
typedef struct or_circuit_t or_circuit_t;

2
src/or/or_circuit_st.h
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@ -9,6 +9,8 @@
#include "or.h"
#include "circuit_st.h"
struct onion_queue_t;
/** An or_circuit_t holds information needed to implement a circuit at an

2
src/or/origin_circuit_st.h
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@ -9,6 +9,8 @@
#include "or.h"
#include "circuit_st.h"
struct onion_queue_t;
/** An origin_circuit_t holds data necessary to build and use a circuit.