用于EagleEye3.0 规则集漏报和误报测试的示例项目,项目收集于github和gitee
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/*
* include/haproxy/xprt_quic.h
* This file contains QUIC xprt function prototypes
*
* Copyright 2020 HAProxy Technologies, Frédéric Lécaille <flecaille@haproxy.com>
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation, version 2.1
* exclusively.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
#ifndef _HAPROXY_XPRT_QUIC_H
#define _HAPROXY_XPRT_QUIC_H
#ifdef USE_QUIC
#ifndef USE_OPENSSL
#error "Must define USE_OPENSSL"
#endif
#include <stdint.h>
#include <haproxy/buf.h>
#include <haproxy/chunk.h>
#include <haproxy/net_helper.h>
#include <haproxy/openssl-compat.h>
#include <haproxy/ticks.h>
#include <haproxy/time.h>
#include <haproxy/listener.h>
#include <haproxy/quic_cc.h>
#include <haproxy/quic_frame.h>
#include <haproxy/quic_loss.h>
#include <haproxy/xprt_quic-t.h>
#include <openssl/rand.h>
extern struct pool_head *pool_head_quic_connection_id;
int ssl_quic_initial_ctx(struct bind_conf *bind_conf);
/* Returns the required length in bytes to encode <cid> QUIC connection ID. */
static inline size_t sizeof_quic_cid(const struct quic_cid *cid)
{
return sizeof cid->len + cid->len;
}
/* Copy <src> QUIC CID to <dst>.
* This is the responsibility of the caller to check there is enough room in
* <dst> to copy <src>.
* Always succeeds.
*/
static inline void quic_cid_cpy(struct quic_cid *dst, const struct quic_cid *src)
{
memcpy(dst->data, src->data, src->len);
dst->len = src->len;
}
/* Concatenate the port and address of <saddr> to <cid> QUIC connection ID.
* Returns the number of bytes concatenated to <cid>.
*/
static inline size_t quic_cid_saddr_cat(struct quic_cid *cid, struct sockaddr_storage *saddr)
{
void *port, *addr;
size_t port_len, addr_len;
if (saddr->ss_family == AF_INET6) {
port = &((struct sockaddr_in6 *)saddr)->sin6_port;
addr = &((struct sockaddr_in6 *)saddr)->sin6_addr;
port_len = sizeof ((struct sockaddr_in6 *)saddr)->sin6_port;
addr_len = sizeof ((struct sockaddr_in6 *)saddr)->sin6_addr;
}
else {
port = &((struct sockaddr_in *)saddr)->sin_port;
addr = &((struct sockaddr_in *)saddr)->sin_addr;
port_len = sizeof ((struct sockaddr_in *)saddr)->sin_port;
addr_len = sizeof ((struct sockaddr_in *)saddr)->sin_addr;
}
memcpy(cid->data + cid->len, port, port_len);
cid->len += port_len;
memcpy(cid->data + cid->len, addr, addr_len);
cid->len += addr_len;
return port_len + addr_len;
}
/* Dump the QUIC connection ID value if present (non null length). Used only for
* debugging purposes.
* Always succeeds.
*/
static inline void quic_cid_dump(struct buffer *buf, struct quic_cid *cid)
{
int i;
chunk_appendf(buf, "(%d", cid->len);
if (cid->len)
chunk_appendf(buf, ",");
for (i = 0; i < cid->len; i++)
chunk_appendf(buf, "%02x", cid->data[i]);
chunk_appendf(buf, ")");
}
/* Free the CIDs attached to <conn> QUIC connection.
* Always succeeds.
*/
static inline void free_quic_conn_cids(struct quic_conn *conn)
{
struct eb64_node *node;
node = eb64_first(&conn->cids);
while (node) {
struct quic_connection_id *cid;
cid = eb64_entry(&node->node, struct quic_connection_id, seq_num);
node = eb64_next(node);
eb64_delete(&cid->seq_num);
pool_free(pool_head_quic_connection_id, cid);
}
}
/* Copy <src> new connection ID information to <to> NEW_CONNECTION_ID frame data.
* Always succeeds.
*/
static inline void quic_connection_id_to_frm_cpy(struct quic_frame *dst,
struct quic_connection_id *src)
{
struct quic_new_connection_id *to = &dst->new_connection_id;
dst->type = QUIC_FT_NEW_CONNECTION_ID;
to->seq_num = src->seq_num.key;
to->retire_prior_to = src->retire_prior_to;
to->cid.len = src->cid.len;
to->cid.data = src->cid.data;
to->stateless_reset_token = src->stateless_reset_token;
}
/* Allocate a new CID with <seq_num> as sequence number and attach it to <root>
* ebtree.
* Returns the new CID if succeeded, NULL if not.
*/
static inline struct quic_connection_id *new_quic_cid(struct eb_root *root,
int seq_num)
{
struct quic_connection_id *cid;
cid = pool_alloc(pool_head_quic_connection_id);
if (!cid)
return NULL;
cid->cid.len = QUIC_CID_LEN;
if (RAND_bytes(cid->cid.data, cid->cid.len) != 1 ||
RAND_bytes(cid->stateless_reset_token,
sizeof cid->stateless_reset_token) != 1) {
fprintf(stderr, "Could not generate %d random bytes\n", cid->cid.len);
goto err;
}
cid->seq_num.key = seq_num;
cid->retire_prior_to = 0;
eb64_insert(root, &cid->seq_num);
return cid;
err:
pool_free(pool_head_quic_connection_id, cid);
return NULL;
}
/* The maximum size of a variable-length QUIC integer encoded with 1 byte */
#define QUIC_VARINT_1_BYTE_MAX ((1UL << 6) - 1)
/* The maximum size of a variable-length QUIC integer encoded with 2 bytes */
#define QUIC_VARINT_2_BYTE_MAX ((1UL << 14) - 1)
/* The maximum size of a variable-length QUIC integer encoded with 4 bytes */
#define QUIC_VARINT_4_BYTE_MAX ((1UL << 30) - 1)
/* The maximum size of a variable-length QUIC integer encoded with 8 bytes */
#define QUIC_VARINT_8_BYTE_MAX ((1ULL << 62) - 1)
/* The maximum size of a variable-length QUIC integer */
#define QUIC_VARINT_MAX_SIZE 8
/* The two most significant bits of byte #0 from a QUIC packet gives the 2
* logarithm of the length of a variable length encoded integer.
*/
#define QUIC_VARINT_BYTE_0_BITMASK 0x3f
#define QUIC_VARINT_BYTE_0_SHIFT 6
/* Return a 32-bits integer in <val> from QUIC packet with <buf> as address.
* Makes <buf> point to the data after this 32-bits value if succeeded.
* Note that these 32-bits integers are network bytes ordered.
* Returns 0 if failed (not enough data in the buffer), 1 if succeeded.
*/
static inline int quic_read_uint32(uint32_t *val,
const unsigned char **buf,
const unsigned char *end)
{
if (end - *buf < sizeof *val)
return 0;
*val = ntohl(*(uint32_t *)*buf);
*buf += sizeof *val;
return 1;
}
/* Write a 32-bits integer to a buffer with <buf> as address.
* Make <buf> point to the data after this 32-buts value if succeeded.
* Note that these 32-bits integers are networkg bytes ordered.
* Returns 0 if failed (not enough room in the buffer), 1 if succeeded.
*/
static inline int quic_write_uint32(unsigned char **buf,
const unsigned char *end, uint32_t val)
{
if (end - *buf < sizeof val)
return 0;
*(uint32_t *)*buf = htonl(val);
*buf += sizeof val;
return 1;
}
/* Returns enough log2 of first powers of two to encode QUIC variable length
* integers.
* Returns -1 if <val> if out of the range of lengths supported by QUIC.
*/
static inline int quic_log2(unsigned int val)
{
switch (val) {
case 8:
return 3;
case 4:
return 2;
case 2:
return 1;
case 1:
return 0;
default:
return -1;
}
}
/* Returns the size in bytes required to encode a 64bits integer if
* not out of range (< (1 << 62)), or 0 if out of range.
*/
static inline size_t quic_int_getsize(uint64_t val)
{
switch (val) {
case 0 ... QUIC_VARINT_1_BYTE_MAX:
return 1;
case QUIC_VARINT_1_BYTE_MAX + 1 ... QUIC_VARINT_2_BYTE_MAX:
return 2;
case QUIC_VARINT_2_BYTE_MAX + 1 ... QUIC_VARINT_4_BYTE_MAX:
return 4;
case QUIC_VARINT_4_BYTE_MAX + 1 ... QUIC_VARINT_8_BYTE_MAX:
return 8;
default:
return 0;
}
}
/* Return the difference between the encoded length of <val> and the encoded
* length of <val+1>.
*/
static inline size_t quic_incint_size_diff(uint64_t val)
{
switch (val) {
case QUIC_VARINT_1_BYTE_MAX:
return 1;
case QUIC_VARINT_2_BYTE_MAX:
return 2;
case QUIC_VARINT_4_BYTE_MAX:
return 4;
default:
return 0;
}
}
/* Return the difference between the encoded length of <val> and the encoded
* length of <val-1>.
*/
static inline size_t quic_decint_size_diff(uint64_t val)
{
switch (val) {
case QUIC_VARINT_1_BYTE_MAX + 1:
return 1;
case QUIC_VARINT_2_BYTE_MAX + 1:
return 2;
case QUIC_VARINT_4_BYTE_MAX + 1:
return 4;
default:
return 0;
}
}
/* Returns the maximum value of a QUIC variable-length integer with <sz> as size */
static inline uint64_t quic_max_int(size_t sz)
{
switch (sz) {
case 1:
return QUIC_VARINT_1_BYTE_MAX;
case 2:
return QUIC_VARINT_2_BYTE_MAX;
case 4:
return QUIC_VARINT_4_BYTE_MAX;
case 8:
return QUIC_VARINT_8_BYTE_MAX;
}
return -1;
}
/* Return the maximum number of bytes we must use to completely fill a
* buffer with <sz> as size for a data field of bytes prefixed by its QUIC
* variable-length (may be 0).
* Also put in <*len_sz> the size of this QUIC variable-length.
* So after returning from this function we have : <*len_sz> + <ret> = <sz>.
*/
static inline size_t max_available_room(size_t sz, size_t *len_sz)
{
size_t sz_sz, ret;
size_t diff;
sz_sz = quic_int_getsize(sz);
if (sz <= sz_sz)
return 0;
ret = sz - sz_sz;
*len_sz = quic_int_getsize(ret);
/* Difference between the two sizes. Note that <sz_sz> >= <*len_sz>. */
diff = sz_sz - *len_sz;
if (unlikely(diff > 0))
ret += diff;
return ret;
}
/* This function computes the maximum data we can put into a buffer with <sz> as
* size prefixed with a variable-length field "Length" whose value is the
* remaining data length, already filled of <ilen> bytes which must be taken
* into an account by "Length" field, and finally followed by the data we want
* to put in this buffer prefixed again by a variable-length field.
* <sz> is the size of the buffer to fill.
* <ilen> the number of bytes already put after the "Length" field.
* <dlen> the number of bytes we want to at most put in the buffer.
* Also set <*dlen_sz> to the size of the data variable-length we want to put in
* the buffer. This is typically this function which must be used to fill as
* much as possible a QUIC packet made of only one CRYPTO or STREAM frames.
* Returns this computed size if there is enough room in the buffer, 0 if not.
*/
static inline size_t max_stream_data_size(size_t sz, size_t ilen, size_t dlen)
{
size_t ret, len_sz, dlen_sz;
/*
* The length of variable-length QUIC integers are powers of two.
* Look for the first 3length" field value <len_sz> which match our need.
* As we must put <ilen> bytes in our buffer, the minimum value for
* <len_sz> is the number of bytes required to encode <ilen>.
*/
for (len_sz = quic_int_getsize(ilen);
len_sz <= QUIC_VARINT_MAX_SIZE;
len_sz <<= 1) {
if (sz < len_sz + ilen)
return 0;
ret = max_available_room(sz - len_sz - ilen, &dlen_sz);
if (!ret)
return 0;
/* Check that <*len_sz> matches <ret> value */
if (len_sz + ilen + dlen_sz + ret <= quic_max_int(len_sz))
return ret < dlen ? ret : dlen;
}
return 0;
}
/* Decode a QUIC variable-length integer from <buf> buffer into <val>.
* Note that the result is a 64-bits integer but with the less significant
* 62 bits as relevant information. The most significant 2 remaining bits encode
* the length of the integer.
* Returns 1 if succeeded there was enough data in <buf>), 0 if not.
*/
static inline int quic_dec_int(uint64_t *val,
const unsigned char **buf,
const unsigned char *end)
{
size_t len;
if (*buf >= end)
return 0;
len = 1 << (**buf >> QUIC_VARINT_BYTE_0_SHIFT);
if (*buf + len > end)
return 0;
*val = *(*buf)++ & QUIC_VARINT_BYTE_0_BITMASK;
while (--len)
*val = (*val << 8) | *(*buf)++;
return 1;
}
/* Encode a QUIC variable-length integer from <val> into <buf> buffer with <end> as first
* byte address after the end of this buffer.
* Returns 1 if succeeded (there was enough room in buf), 0 if not.
*/
static inline int quic_enc_int(unsigned char **buf, const unsigned char *end, uint64_t val)
{
size_t len;
unsigned int shift;
unsigned char size_bits, *head;
len = quic_int_getsize(val);
if (!len || end - *buf < len)
return 0;
shift = (len - 1) * 8;
/* set the bits of byte#0 which gives the length of the encoded integer */
size_bits = quic_log2(len) << QUIC_VARINT_BYTE_0_SHIFT;
head = *buf;
while (len--) {
*(*buf)++ = val >> shift;
shift -= 8;
}
*head |= size_bits;
return 1;
}
/* Return the length in bytes of <pn> packet number depending on
* <largest_acked_pn> the largest ackownledged packet number.
*/
static inline size_t quic_packet_number_length(int64_t pn,
int64_t largest_acked_pn)
{
int64_t max_nack_pkts;
/* About packet number encoding, the RFC says:
* The sender MUST use a packet number size able to represent more than
* twice as large a range than the difference between the largest
* acknowledged packet and packet number being sent.
*/
max_nack_pkts = 2 * (pn - largest_acked_pn) + 1;
if (max_nack_pkts > 0xffffff)
return 4;
if (max_nack_pkts > 0xffff)
return 3;
if (max_nack_pkts > 0xff)
return 2;
return 1;
}
/* Encode <pn> packet number with <pn_len> as length in byte into a buffer with
* <buf> as current copy address and <end> as pointer to one past the end of
* this buffer. This is the responsibility of the caller to check there is
* enough room in the buffer to copy <pn_len> bytes.
* Never fails.
*/
static inline void quic_packet_number_encode(unsigned char **buf,
const unsigned char *end,
uint64_t pn, size_t pn_len)
{
/* Encode the packet number. */
switch (pn_len) {
case 1:
**buf = pn;
break;
case 2:
write_n16(*buf, pn);
break;
case 3:
(*buf)[0] = pn >> 16;
(*buf)[1] = pn >> 8;
(*buf)[2] = pn;
break;
case 4:
write_n32(*buf, pn);
break;
}
*buf += pn_len;
}
/* Returns the <ack_delay> field value from <ack_frm> ACK frame for
* <conn> QUIC connection.
*/
static inline unsigned int quic_ack_delay_ms(struct quic_ack *ack_frm,
struct quic_conn *conn)
{
return ack_frm->ack_delay << conn->rx_tps.ack_delay_exponent;
}
/* Initialize <dst> transport parameters from <quic_dflt_trasports_parame>.
* Never fails.
*/
static inline void quic_dflt_transport_params_cpy(struct quic_transport_params *dst)
{
dst->max_packet_size = quic_dflt_transport_params.max_packet_size;
dst->ack_delay_exponent = quic_dflt_transport_params.ack_delay_exponent;
dst->max_ack_delay = quic_dflt_transport_params.max_ack_delay;
}
/* Initialize <p> transport parameters depending <server> boolean value which
* must be set to 1 for a server (haproxy listener), 0 for a client (connection
* to haproxy server).
* Never fails.
*/
static inline void quic_transport_params_init(struct quic_transport_params *p,
int server)
{
quic_dflt_transport_params_cpy(p);
p->idle_timeout = 30000;
p->initial_max_data = 1 * 1024 * 1024;
p->initial_max_stream_data_bidi_local = 256 * 1024;
p->initial_max_stream_data_bidi_remote = 256 * 1024;
p->initial_max_stream_data_uni = 256 * 1024;
p->initial_max_streams_bidi = 100;
p->initial_max_streams_uni = 3;
if (server)
p->with_stateless_reset_token = 1;
p->active_connection_id_limit = 8;
}
/* Encode <addr> preferred address transport parameter in <buf> without its
* "type+len" prefix. Note that the IP addresses must be encoded in network byte
* order.
* So ->ipv4_addr and ->ipv6_addr, which are buffers, must contained values
* already encoded in network byte order.
* It is the responsibility of the caller to check there is enough room in <buf> to encode
* this address.
* Never fails.
*/
static inline void quic_transport_param_enc_pref_addr_val(unsigned char **buf,
const unsigned char *end,
struct preferred_address *addr)
{
write_n16(*buf, addr->ipv4_port);
*buf += sizeof addr->ipv4_port;
memcpy(*buf, addr->ipv4_addr, sizeof addr->ipv4_addr);
*buf += sizeof addr->ipv4_addr;
write_n16(*buf, addr->ipv6_port);
*buf += sizeof addr->ipv6_port;
memcpy(*buf, addr->ipv6_addr, sizeof addr->ipv6_addr);
*buf += sizeof addr->ipv6_addr;
*(*buf)++ = addr->cid.len;
if (addr->cid.len) {
memcpy(*buf, addr->cid.data, addr->cid.len);
*buf += addr->cid.len;
}
memcpy(*buf, addr->stateless_reset_token, sizeof addr->stateless_reset_token);
*buf += sizeof addr->stateless_reset_token;
}
/* Decode into <addr> preferred address transport parameter found in <*buf> buffer.
* Returns 1 if succeeded, 0 if not.
*/
static inline int quic_transport_param_dec_pref_addr(struct preferred_address *addr,
const unsigned char **buf,
const unsigned char *end)
{
ssize_t addr_len;
addr_len = sizeof addr->ipv4_port + sizeof addr->ipv4_addr;
addr_len += sizeof addr->ipv6_port + sizeof addr->ipv6_addr;
addr_len += sizeof addr->cid.len;
if (end - *buf < addr_len)
return 0;
addr->ipv4_port = read_n16(*buf);
*buf += sizeof addr->ipv4_port;
memcpy(addr->ipv4_addr, *buf, sizeof addr->ipv4_addr);
*buf += sizeof addr->ipv4_addr;
addr->ipv6_port = read_n16(*buf);
*buf += sizeof addr->ipv6_port;
memcpy(addr->ipv6_addr, *buf, sizeof addr->ipv6_addr);
*buf += sizeof addr->ipv6_addr;
addr->cid.len = *(*buf)++;
if (addr->cid.len) {
if (end - *buf > addr->cid.len || addr->cid.len > sizeof addr->cid.data)
return 0;
memcpy(addr->cid.data, *buf, addr->cid.len);
*buf += addr->cid.len;
}
if (end - *buf != sizeof addr->stateless_reset_token)
return 0;
memcpy(addr->stateless_reset_token, *buf, end - *buf);
*buf += sizeof addr->stateless_reset_token;
return *buf == end;
}
/* Decode into <p> struct a transport parameter found in <*buf> buffer with
* <type> as type and <len> as length, depending on <server> boolean value which
* must be set to 1 for a server (haproxy listener) or 0 for a client (connection
* to an haproxy server).
*/
static inline int quic_transport_param_decode(struct quic_transport_params *p,
int server, uint64_t type,
const unsigned char **buf, size_t len)
{
const unsigned char *end = *buf + len;
switch (type) {
case QUIC_TP_ORIGINAL_DESTINATION_CONNECTION_ID:
if (!server || len >= sizeof p->original_destination_connection_id.data)
return 0;
if (len)
memcpy(p->original_destination_connection_id.data, *buf, len);
p->original_destination_connection_id.len = len;
*buf += len;
p->original_destination_connection_id_present = 1;
break;
case QUIC_TP_INITIAL_SOURCE_CONNECTION_ID:
if (len >= sizeof p->initial_source_connection_id.data)
return 0;
if (len)
memcpy(p->initial_source_connection_id.data, *buf, len);
p->initial_source_connection_id.len = len;
*buf += len;
p->initial_source_connection_id_present = 1;
break;
case QUIC_TP_STATELESS_RESET_TOKEN:
if (!server || len != sizeof p->stateless_reset_token)
return 0;
memcpy(p->stateless_reset_token, *buf, len);
*buf += len;
p->with_stateless_reset_token = 1;
break;
case QUIC_TP_PREFERRED_ADDRESS:
if (!server)
return 0;
if (!quic_transport_param_dec_pref_addr(&p->preferred_address, buf, *buf + len))
return 0;
p->with_preferred_address = 1;
break;
case QUIC_TP_IDLE_TIMEOUT:
if (!quic_dec_int(&p->idle_timeout, buf, end))
return 0;
break;
case QUIC_TP_MAX_PACKET_SIZE:
if (!quic_dec_int(&p->max_packet_size, buf, end))
return 0;
break;
case QUIC_TP_INITIAL_MAX_DATA:
if (!quic_dec_int(&p->initial_max_data, buf, end))
return 0;
break;
case QUIC_TP_INITIAL_MAX_STREAM_DATA_BIDI_LOCAL:
if (!quic_dec_int(&p->initial_max_stream_data_bidi_local, buf, end))
return 0;
break;
case QUIC_TP_INITIAL_MAX_STREAM_DATA_BIDI_REMOTE:
if (!quic_dec_int(&p->initial_max_stream_data_bidi_remote, buf, end))
return 0;
break;
case QUIC_TP_INITIAL_MAX_STREAM_DATA_UNI:
if (!quic_dec_int(&p->initial_max_stream_data_uni, buf, end))
return 0;
break;
case QUIC_TP_INITIAL_MAX_STREAMS_BIDI:
if (!quic_dec_int(&p->initial_max_streams_bidi, buf, end))
return 0;
break;
case QUIC_TP_INITIAL_MAX_STREAMS_UNI:
if (!quic_dec_int(&p->initial_max_streams_uni, buf, end))
return 0;
break;
case QUIC_TP_ACK_DELAY_EXPONENT:
if (!quic_dec_int(&p->ack_delay_exponent, buf, end) ||
p->ack_delay_exponent > QUIC_TP_ACK_DELAY_EXPONENT_LIMIT)
return 0;
break;
case QUIC_TP_MAX_ACK_DELAY:
if (!quic_dec_int(&p->max_ack_delay, buf, end) ||
p->max_ack_delay > QUIC_TP_MAX_ACK_DELAY_LIMIT)
return 0;
break;
case QUIC_TP_DISABLE_ACTIVE_MIGRATION:
/* Zero-length parameter type. */
if (len != 0)
return 0;
p->disable_active_migration = 1;
break;
case QUIC_TP_ACTIVE_CONNECTION_ID_LIMIT:
if (!quic_dec_int(&p->active_connection_id_limit, buf, end))
return 0;
break;
default:
*buf += len;
};
return *buf == end;
}
/* Encode <type> and <len> variable length values in <buf>.
* Returns 1 if succeeded, 0 if not.
*/
static inline int quic_transport_param_encode_type_len(unsigned char **buf,
const unsigned char *end,
uint64_t type, uint64_t len)
{
return quic_enc_int(buf, end, type) && quic_enc_int(buf, end, len);
}
/* Decode variable length type and length values of a QUIC transport parameter
* into <type> and <len> found in <*buf> buffer.
* Returns 1 if succeeded, 0 if not.
*/
static inline int quic_transport_param_decode_type_len(uint64_t *type, uint64_t *len,
const unsigned char **buf,
const unsigned char *end)
{
return quic_dec_int(type, buf, end) && quic_dec_int(len, buf, end);
}
/* Encode <param> bytes stream with <type> as type and <length> as length into buf.
* Returns 1 if succeeded, 0 if not.
*/
static inline int quic_transport_param_enc_mem(unsigned char **buf, const unsigned char *end,
uint64_t type, void *param, uint64_t length)
{
if (!quic_transport_param_encode_type_len(buf, end, type, length))
return 0;
if (end - *buf < length)
return 0;
if (length)
memcpy(*buf, param, length);
*buf += length;
return 1;
}
/* Encode <val> 64-bits value as variable length integer into <buf>.
* Returns 1 if succeeded, 0 if not.
*/
static inline int quic_transport_param_enc_int(unsigned char **buf,
const unsigned char *end,
uint64_t type, uint64_t val)
{
size_t len;
len = quic_int_getsize(val);
return len && quic_transport_param_encode_type_len(buf, end, type, len) &&
quic_enc_int(buf, end, val);
}
/* Encode <addr> preferred address into <buf>.
* Note that the IP addresses must be encoded in network byte order.
* So ->ipv4_addr and ->ipv6_addr, which are buffers, must contained
* values already encoded in network byte order.
* Returns 1 if succeeded, 0 if not.
*/
static inline int quic_transport_param_enc_pref_addr(unsigned char **buf,
const unsigned char *end,
struct preferred_address *addr)
{
uint64_t addr_len = 0;
addr_len += sizeof addr->ipv4_port + sizeof addr->ipv4_addr;
addr_len += sizeof addr->ipv6_port + sizeof addr->ipv6_addr;
addr_len += sizeof_quic_cid(&addr->cid);
addr_len += sizeof addr->stateless_reset_token;
if (!quic_transport_param_encode_type_len(buf, end, QUIC_TP_PREFERRED_ADDRESS, addr_len))
return 0;
if (end - *buf < addr_len)
return 0;
quic_transport_param_enc_pref_addr_val(buf, end, addr);
return 1;
}
/* Encode <p> transport parameter into <buf> depending on <server> value which
* must be set to 1 for a server (haproxy listener) or 0 for a client
* (connection to a haproxy server).
* Return the number of bytes consumed if succeeded, 0 if not.
*/
static inline int quic_transport_params_encode(unsigned char *buf,
const unsigned char *end,
struct quic_transport_params *p,
int server)
{
unsigned char *head;
unsigned char *pos;
head = pos = buf;
if (server) {
if (!quic_transport_param_enc_mem(&pos, end,
QUIC_TP_ORIGINAL_DESTINATION_CONNECTION_ID,
p->original_destination_connection_id.data,
p->original_destination_connection_id.len))
return 0;
if (p->with_stateless_reset_token &&
!quic_transport_param_enc_mem(&pos, end, QUIC_TP_STATELESS_RESET_TOKEN,
p->stateless_reset_token,
sizeof p->stateless_reset_token))
return 0;
if (p->with_preferred_address &&
!quic_transport_param_enc_pref_addr(&pos, end, &p->preferred_address))
return 0;
}
if (!quic_transport_param_enc_mem(&pos, end,
QUIC_TP_INITIAL_SOURCE_CONNECTION_ID,
p->initial_source_connection_id.data,
p->initial_source_connection_id.len))
return 0;
if (p->idle_timeout &&
!quic_transport_param_enc_int(&pos, end, QUIC_TP_IDLE_TIMEOUT, p->idle_timeout))
return 0;
/*
* "max_packet_size" transport parameter must be transmitted only if different
* of the default value.
*/
if (p->max_packet_size != QUIC_DFLT_MAX_PACKET_SIZE &&
!quic_transport_param_enc_int(&pos, end, QUIC_TP_MAX_PACKET_SIZE, p->max_packet_size))
return 0;
if (p->initial_max_data &&
!quic_transport_param_enc_int(&pos, end, QUIC_TP_INITIAL_MAX_DATA, p->initial_max_data))
return 0;
if (p->initial_max_stream_data_bidi_local &&
!quic_transport_param_enc_int(&pos, end, QUIC_TP_INITIAL_MAX_STREAM_DATA_BIDI_LOCAL,
p->initial_max_stream_data_bidi_local))
return 0;
if (p->initial_max_stream_data_bidi_remote &&
!quic_transport_param_enc_int(&pos, end, QUIC_TP_INITIAL_MAX_STREAM_DATA_BIDI_REMOTE,
p->initial_max_stream_data_bidi_remote))
return 0;
if (p->initial_max_stream_data_uni &&
!quic_transport_param_enc_int(&pos, end, QUIC_TP_INITIAL_MAX_STREAM_DATA_UNI,
p->initial_max_stream_data_uni))
return 0;
if (p->initial_max_streams_bidi &&
!quic_transport_param_enc_int(&pos, end, QUIC_TP_INITIAL_MAX_STREAMS_BIDI,
p->initial_max_streams_bidi))
return 0;
if (p->initial_max_streams_uni &&
!quic_transport_param_enc_int(&pos, end, QUIC_TP_INITIAL_MAX_STREAMS_UNI,
p->initial_max_streams_uni))
return 0;
/*
* "ack_delay_exponent" transport parameter must be transmitted only if different
* of the default value.
*/
if (p->ack_delay_exponent != QUIC_DFLT_ACK_DELAY_COMPONENT &&
!quic_transport_param_enc_int(&pos, end, QUIC_TP_ACK_DELAY_EXPONENT, p->ack_delay_exponent))
return 0;
/*
* "max_ack_delay" transport parameter must be transmitted only if different
* of the default value.
*/
if (p->max_ack_delay != QUIC_DFLT_MAX_ACK_DELAY &&
!quic_transport_param_enc_int(&pos, end, QUIC_TP_MAX_ACK_DELAY, p->max_ack_delay))
return 0;
/* 0-length value */
if (p->disable_active_migration &&
!quic_transport_param_encode_type_len(&pos, end, QUIC_TP_DISABLE_ACTIVE_MIGRATION, 0))
return 0;
if (p->active_connection_id_limit &&
!quic_transport_param_enc_int(&pos, end, QUIC_TP_ACTIVE_CONNECTION_ID_LIMIT,
p->active_connection_id_limit))
return 0;
return pos - head;
}
/* Decode transport parameters found in <buf> buffer into <p>, depending on
* <server> boolean value which must be set to 1 for a server (haproxy listener)
* or 0 for a client (connection to a haproxy server).
* Returns 1 if succeeded, 0 if not.
*/
static inline int quic_transport_params_decode(struct quic_transport_params *p, int server,
const unsigned char *buf,
const unsigned char *end)
{
const unsigned char *pos;
pos = buf;
quic_transport_params_init(p, server);
while (pos != end) {
uint64_t type, len;
if (!quic_transport_param_decode_type_len(&type, &len, &pos, end))
return 0;
if (end - pos < len)
return 0;
if (!quic_transport_param_decode(p, server, type, &pos, len))
return 0;
}
/*
* A server MUST send original_destination_connection_id transport parameter.
* initial_source_connection_id must be present both for server and client.
*/
if ((server && !p->original_destination_connection_id_present) ||
!p->initial_source_connection_id_present)
return 0;
return 1;
}
/* Store transport parameters found in <buf> buffer into <conn> QUIC connection
* depending on <server> value which must be 1 for a server (haproxy listener)
* or 0 for a client (connection to a haproxy server).
* Returns 1 if succeeded, 0 if not.
*/
static inline int quic_transport_params_store(struct quic_conn *conn, int server,
const unsigned char *buf,
const unsigned char *end)
{
if (!quic_transport_params_decode(&conn->rx_tps, server, buf, end))
return 0;
if (conn->rx_tps.max_ack_delay)
conn->max_ack_delay = conn->rx_tps.max_ack_delay;
return 1;
}
/* Initialize a QUIC packet number space.
* Never fails.
*/
static inline void quic_pktns_init(struct quic_pktns *pktns)
{
LIST_INIT(&pktns->tx.frms);
pktns->tx.next_pn = -1;
pktns->tx.pkts = EB_ROOT_UNIQUE;
pktns->tx.largest_acked_pn = -1;
pktns->tx.time_of_last_eliciting = 0;
pktns->tx.loss_time = TICK_ETERNITY;
pktns->tx.in_flight = 0;
pktns->rx.largest_pn = -1;
pktns->rx.nb_ack_eliciting = 0;
pktns->rx.arngs.root = EB_ROOT_UNIQUE;
pktns->rx.arngs.sz = 0;
pktns->rx.arngs.enc_sz = 0;
pktns->flags = 0;
}
/* Discard <pktns> packet number space attached to <qc> QUIC connection.
* Its loss information are reset. Deduce the outstanding bytes for this
* packet number space from the outstanding bytes for the path of this
* connection§.
* Note that all the non acknowledged TX packets and their frames are freed.
* Always succeeds.
*/
static inline void quic_pktns_discard(struct quic_pktns *pktns,
struct quic_conn *qc)
{
struct eb64_node *node;
pktns->tx.time_of_last_eliciting = 0;
pktns->tx.loss_time = TICK_ETERNITY;
pktns->tx.pto_probe = 0;
pktns->tx.in_flight = 0;
qc->path->loss.pto_count = 0;
qc->path->in_flight -= pktns->tx.in_flight;
node = eb64_first(&pktns->tx.pkts);
while (node) {
struct quic_tx_packet *pkt;
struct quic_tx_frm *frm, *frmbak;
pkt = eb64_entry(&node->node, struct quic_tx_packet, pn_node);
node = eb64_next(node);
list_for_each_entry_safe(frm, frmbak, &pkt->frms, list) {
LIST_DEL(&frm->list);
pool_free(pool_head_quic_tx_frm, frm);
}
eb64_delete(&pkt->pn_node);
pool_free(pool_head_quic_tx_packet, pkt);
}
}
/* Initialize <p> QUIC network path depending on <ipv4> boolean
* which is true for an IPv4 path, if not false for an IPv6 path.
*/
static inline void quic_path_init(struct quic_path *path, int ipv4,
struct quic_cc_algo *algo, struct quic_conn *qc)
{
unsigned int max_dgram_sz;
max_dgram_sz = ipv4 ? QUIC_INITIAL_IPV4_MTU : QUIC_INITIAL_IPV6_MTU;
quic_loss_init(&path->loss);
path->mtu = max_dgram_sz;
path->cwnd = QUIC_MIN(10 * max_dgram_sz, QUIC_MAX(max_dgram_sz << 1, 14720U));
path->min_cwnd = max_dgram_sz << 1;
path->prep_in_flight = 0;
path->in_flight = 0;
path->ifae_pkts = 0;
quic_cc_init(&path->cc, algo, qc);
}
/* Return the remaining <room> available on <path> QUIC path. In fact this this
*the remaining number of bytes available in the congestion controller window.
*/
static inline size_t quic_path_room(struct quic_path *path)
{
if (path->in_flight > path->cwnd)
return 0;
return path->cwnd - path->in_flight;
}
/* Return the remaining <room> available on <path> QUIC path for prepared data
* (before being sent). Almost the same that for the QUIC path room, except that
* here this is the data which have been prepared which are taken into an account.
*/
static inline size_t quic_path_prep_data(struct quic_path *path)
{
if (path->in_flight > path->cwnd)
return 0;
return path->cwnd - path->prep_in_flight;
}
/* Return 1 if <pktns> matches with the Application packet number space of
* <conn> connection which is common to the 0-RTT and 1-RTT encryption levels, 0
* if not (handshake packets).
*/
static inline int quic_application_pktns(struct quic_pktns *pktns, struct quic_conn *conn)
{
return pktns == &conn->pktns[QUIC_TLS_PKTNS_01RTT];
}
/* CRYPTO data buffer handling functions. */
static inline unsigned char *c_buf_getpos(struct quic_enc_level *qel, uint64_t offset)
{
int idx;
unsigned char *data;
idx = offset >> QUIC_CRYPTO_BUF_SHIFT;
data = qel->tx.crypto.bufs[idx]->data;
return data + (offset & QUIC_CRYPTO_BUF_MASK);
}
/* Returns 1 if the CRYPTO buffer at <qel> encryption level has been
* consumed (sent to the peer), 0 if not.
*/
static inline int c_buf_consumed(struct quic_enc_level *qel)
{
return qel->tx.crypto.offset == qel->tx.crypto.sz;
}
/* QUIC buffer handling functions */
/* Returns the current buffer which may be used to build outgoing packets. */
static inline struct q_buf *q_wbuf(struct quic_conn *qc)
{
return qc->tx.bufs[qc->tx.wbuf];
}
static inline struct q_buf *q_rbuf(struct quic_conn *qc)
{
return qc->tx.bufs[qc->tx.rbuf];
}
/* Returns the next buffer to be used to send packets from. */
static inline struct q_buf *q_next_rbuf(struct quic_conn *qc)
{
qc->tx.rbuf = (qc->tx.rbuf + 1) & (QUIC_CONN_TX_BUFS_NB - 1);
return q_rbuf(qc);
}
/* Return the next buffer which may be used to build outgoing packets.
* Also decrement by one the number of remaining probing datagrams
* which may be sent.
*/
static inline struct q_buf *q_next_wbuf(struct quic_conn *qc)
{
qc->tx.wbuf = (qc->tx.wbuf + 1) & (QUIC_CONN_TX_BUFS_NB - 1);
/* Decrement the number of prepared datagrams (only when probing). */
if (qc->tx.nb_pto_dgrams)
--qc->tx.nb_pto_dgrams;
return q_wbuf(qc);
}
/* Return the position of <buf> buffer to be used to write outgoing packets. */
static inline unsigned char *q_buf_getpos(struct q_buf *buf)
{
return buf->pos;
}
/* Return the pointer to one past the end of <buf> buffer. */
static inline const unsigned char *q_buf_end(struct q_buf *buf)
{
return buf->end;
}
/* Set the position of <buf> buffer to <pos> value. */
static inline void q_buf_setpos(struct q_buf *buf, unsigned char *pos)
{
buf->pos = pos;
}
/* Returns the remaining amount of room left in <buf> buffer. */
static inline ssize_t q_buf_room(struct q_buf *buf)
{
return q_buf_end(buf) - q_buf_getpos(buf);
}
/* Reset (or empty) <buf> buffer to prepare it for the next writing. */
static inline void q_buf_reset(struct q_buf *buf)
{
buf->pos = buf->area;
buf->data = 0;
}
/* Returns 1 if <buf> is empty, 0 if not. */
static inline int q_buf_empty(struct q_buf *buf)
{
return !buf->data;
}
/* Return 1 if <pkt> header form is long, 0 if not. */
static inline int qc_pkt_long(const struct quic_rx_packet *pkt)
{
return pkt->type != QUIC_PACKET_TYPE_SHORT;
}
/* Increment the reference counter of <pkt> */
static inline void quic_rx_packet_refinc(struct quic_rx_packet *pkt)
{
pkt->refcnt++;
}
/* Decrement the reference counter of <pkt> */
static inline void quic_rx_packet_refdec(struct quic_rx_packet *pkt)
{
if (!--pkt->refcnt)
pool_free(pool_head_quic_rx_packet, pkt);
}
/* Add <pkt> RX packet to <list>, incrementing its reference counter. */
static inline void quic_rx_packet_list_addq(struct list *list,
struct quic_rx_packet *pkt)
{
LIST_ADDQ(list, &pkt->list);
quic_rx_packet_refinc(pkt);
}
/* Remove <pkt> RX packet from <list>, decrementing its reference counter. */
static inline void quic_rx_packet_list_del(struct quic_rx_packet *pkt)
{
LIST_DEL(&pkt->list);
quic_rx_packet_refdec(pkt);
}
/* Add <pkt> RX packet to <root> tree, incrementing its reference counter. */
static inline void quic_rx_packet_eb64_insert(struct eb_root *root,
struct eb64_node *node)
{
eb64_insert(root, node);
quic_rx_packet_refinc(eb64_entry(node, struct quic_rx_packet, pn_node));
}
/* Delete <pkt> RX packet from <root> tree, decrementing its reference counter. */
static inline void quic_rx_packet_eb64_delete(struct eb64_node *node)
{
eb64_delete(node);
quic_rx_packet_refdec(eb64_entry(node, struct quic_rx_packet, pn_node));
}
/* Release the memory allocated for <pkt> RX packet. */
static inline void free_quic_rx_packet(struct quic_rx_packet *pkt)
{
quic_rx_packet_refdec(pkt);
}
int qc_new_conn_init(struct quic_conn *conn, int ipv4,
struct eb_root *quic_initial_clients,
struct eb_root *quic_clients,
unsigned char *dcid, size_t dcid_len,
unsigned char *scid, size_t scid_len);
ssize_t quic_lstnr_dgram_read(char *buf, size_t len, void *owner,
struct sockaddr_storage *saddr);
ssize_t quic_srv_dgram_read(char *buf, size_t len, void *owner,
struct sockaddr_storage *saddr);
#endif /* USE_QUIC */
#endif /* _HAPROXY_XPRT_QUIC_H */