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linux-next/samples/bpf/hbm_kern.h

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bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
/* SPDX-License-Identifier: GPL-2.0
*
* Copyright (c) 2019 Facebook
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of version 2 of the GNU General Public
* License as published by the Free Software Foundation.
*
* Include file for sample Host Bandwidth Manager (HBM) BPF programs
*/
#define KBUILD_MODNAME "foo"
#include <stddef.h>
#include <stdbool.h>
#include <uapi/linux/bpf.h>
#include <uapi/linux/if_ether.h>
#include <uapi/linux/if_packet.h>
#include <uapi/linux/ip.h>
#include <uapi/linux/ipv6.h>
#include <uapi/linux/in.h>
#include <uapi/linux/tcp.h>
#include <uapi/linux/filter.h>
#include <uapi/linux/pkt_cls.h>
#include <net/ipv6.h>
#include <net/inet_ecn.h>
#include <bpf/bpf_endian.h>
#include <bpf/bpf_helpers.h>
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
#include "hbm.h"
#define DROP_PKT 0
#define ALLOW_PKT 1
#define TCP_ECN_OK 1
bpf: Add support for fq's EDT to HBM Adds support for fq's Earliest Departure Time to HBM (Host Bandwidth Manager). Includes a new BPF program supporting EDT, and also updates corresponding programs. It will drop packets with an EDT of more than 500us in the future unless the packet belongs to a flow with less than 2 packets in flight. This is done so each flow has at least 2 packets in flight, so they will not starve, and also to help prevent delayed ACK timeouts. It will also work with ECN enabled traffic, where the packets will be CE marked if their EDT is more than 50us in the future. The table below shows some performance numbers. The flows are back to back RPCS. One server sending to another, either 2 or 4 flows. One flow is a 10KB RPC, the rest are 1MB RPCs. When there are more than one flow of a given RPC size, the numbers represent averages. The rate limit applies to all flows (they are in the same cgroup). Tests ending with "-edt" ran with the new BPF program supporting EDT. Tests ending with "-hbt" ran on top HBT qdisc with the specified rate (i.e. no HBM). The other tests ran with the HBM BPF program included in the HBM patch-set. EDT has limited value when using DCTCP, but it helps in many cases when using Cubic. It usually achieves larger link utilization and lower 99% latencies for the 1MB RPCs. HBM ends up queueing a lot of packets with its default parameter values, reducing the goodput of the 10KB RPCs and increasing their latency. Also, the RTTs seen by the flows are quite large. Aggr 10K 10K 10K 1MB 1MB 1MB Limit rate drops RTT rate P90 P99 rate P90 P99 Test rate Flows Mbps % us Mbps us us Mbps ms ms -------- ---- ----- ---- ----- --- ---- ---- ---- ---- ---- ---- cubic 1G 2 904 0.02 108 257 511 539 647 13.4 24.5 cubic-edt 1G 2 982 0.01 156 239 656 967 743 14.0 17.2 dctcp 1G 2 977 0.00 105 324 408 744 653 14.5 15.9 dctcp-edt 1G 2 981 0.01 142 321 417 811 660 15.7 17.0 cubic-htb 1G 2 919 0.00 1825 40 2822 4140 879 9.7 9.9 cubic 200M 2 155 0.30 220 81 532 655 74 283 450 cubic-edt 200M 2 188 0.02 222 87 1035 1095 101 84 85 dctcp 200M 2 188 0.03 111 77 912 939 111 76 325 dctcp-edt 200M 2 188 0.03 217 74 1416 1738 114 76 79 cubic-htb 200M 2 188 0.00 5015 8 14ms 15ms 180 48 50 cubic 1G 4 952 0.03 110 165 516 546 262 38 154 cubic-edt 1G 4 973 0.01 190 111 1034 1314 287 65 79 dctcp 1G 4 951 0.00 103 180 617 905 257 37 38 dctcp-edt 1G 4 967 0.00 163 151 732 1126 272 43 55 cubic-htb 1G 4 914 0.00 3249 13 7ms 8ms 300 29 34 cubic 5G 4 4236 0.00 134 305 490 624 1310 10 17 cubic-edt 5G 4 4865 0.00 156 306 425 759 1520 10 16 dctcp 5G 4 4936 0.00 128 485 221 409 1484 7 9 dctcp-edt 5G 4 4924 0.00 148 390 392 623 1508 11 26 v1 -> v2: Incorporated Andrii's suggestions v2 -> v3: Incorporated Yonghong's suggestions v3 -> v4: Removed credit update that is not needed Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Acked-by: Yonghong Song <yhs@fb.com> Signed-off-by: Daniel Borkmann <daniel@iogearbox.net>
2019-07-03 06:09:52 +08:00
#define CWR 2
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
#ifndef HBM_DEBUG // Define HBM_DEBUG to enable debugging
#undef bpf_printk
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
#define bpf_printk(fmt, ...)
#endif
#define INITIAL_CREDIT_PACKETS 100
#define MAX_BYTES_PER_PACKET 1500
#define MARK_THRESH (40 * MAX_BYTES_PER_PACKET)
#define DROP_THRESH (80 * 5 * MAX_BYTES_PER_PACKET)
#define LARGE_PKT_DROP_THRESH (DROP_THRESH - (15 * MAX_BYTES_PER_PACKET))
#define MARK_REGION_SIZE (LARGE_PKT_DROP_THRESH - MARK_THRESH)
#define LARGE_PKT_THRESH 120
#define MAX_CREDIT (100 * MAX_BYTES_PER_PACKET)
#define INIT_CREDIT (INITIAL_CREDIT_PACKETS * MAX_BYTES_PER_PACKET)
bpf: Add support for fq's EDT to HBM Adds support for fq's Earliest Departure Time to HBM (Host Bandwidth Manager). Includes a new BPF program supporting EDT, and also updates corresponding programs. It will drop packets with an EDT of more than 500us in the future unless the packet belongs to a flow with less than 2 packets in flight. This is done so each flow has at least 2 packets in flight, so they will not starve, and also to help prevent delayed ACK timeouts. It will also work with ECN enabled traffic, where the packets will be CE marked if their EDT is more than 50us in the future. The table below shows some performance numbers. The flows are back to back RPCS. One server sending to another, either 2 or 4 flows. One flow is a 10KB RPC, the rest are 1MB RPCs. When there are more than one flow of a given RPC size, the numbers represent averages. The rate limit applies to all flows (they are in the same cgroup). Tests ending with "-edt" ran with the new BPF program supporting EDT. Tests ending with "-hbt" ran on top HBT qdisc with the specified rate (i.e. no HBM). The other tests ran with the HBM BPF program included in the HBM patch-set. EDT has limited value when using DCTCP, but it helps in many cases when using Cubic. It usually achieves larger link utilization and lower 99% latencies for the 1MB RPCs. HBM ends up queueing a lot of packets with its default parameter values, reducing the goodput of the 10KB RPCs and increasing their latency. Also, the RTTs seen by the flows are quite large. Aggr 10K 10K 10K 1MB 1MB 1MB Limit rate drops RTT rate P90 P99 rate P90 P99 Test rate Flows Mbps % us Mbps us us Mbps ms ms -------- ---- ----- ---- ----- --- ---- ---- ---- ---- ---- ---- cubic 1G 2 904 0.02 108 257 511 539 647 13.4 24.5 cubic-edt 1G 2 982 0.01 156 239 656 967 743 14.0 17.2 dctcp 1G 2 977 0.00 105 324 408 744 653 14.5 15.9 dctcp-edt 1G 2 981 0.01 142 321 417 811 660 15.7 17.0 cubic-htb 1G 2 919 0.00 1825 40 2822 4140 879 9.7 9.9 cubic 200M 2 155 0.30 220 81 532 655 74 283 450 cubic-edt 200M 2 188 0.02 222 87 1035 1095 101 84 85 dctcp 200M 2 188 0.03 111 77 912 939 111 76 325 dctcp-edt 200M 2 188 0.03 217 74 1416 1738 114 76 79 cubic-htb 200M 2 188 0.00 5015 8 14ms 15ms 180 48 50 cubic 1G 4 952 0.03 110 165 516 546 262 38 154 cubic-edt 1G 4 973 0.01 190 111 1034 1314 287 65 79 dctcp 1G 4 951 0.00 103 180 617 905 257 37 38 dctcp-edt 1G 4 967 0.00 163 151 732 1126 272 43 55 cubic-htb 1G 4 914 0.00 3249 13 7ms 8ms 300 29 34 cubic 5G 4 4236 0.00 134 305 490 624 1310 10 17 cubic-edt 5G 4 4865 0.00 156 306 425 759 1520 10 16 dctcp 5G 4 4936 0.00 128 485 221 409 1484 7 9 dctcp-edt 5G 4 4924 0.00 148 390 392 623 1508 11 26 v1 -> v2: Incorporated Andrii's suggestions v2 -> v3: Incorporated Yonghong's suggestions v3 -> v4: Removed credit update that is not needed Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Acked-by: Yonghong Song <yhs@fb.com> Signed-off-by: Daniel Borkmann <daniel@iogearbox.net>
2019-07-03 06:09:52 +08:00
// Time base accounting for fq's EDT
#define BURST_SIZE_NS 100000 // 100us
#define MARK_THRESH_NS 50000 // 50us
#define DROP_THRESH_NS 500000 // 500us
// Reserve 20us of queuing for small packets (less than 120 bytes)
#define LARGE_PKT_DROP_THRESH_NS (DROP_THRESH_NS - 20000)
#define MARK_REGION_SIZE_NS (LARGE_PKT_DROP_THRESH_NS - MARK_THRESH_NS)
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
// rate in bytes per ns << 20
#define CREDIT_PER_NS(delta, rate) ((((u64)(delta)) * (rate)) >> 20)
bpf: Add support for fq's EDT to HBM Adds support for fq's Earliest Departure Time to HBM (Host Bandwidth Manager). Includes a new BPF program supporting EDT, and also updates corresponding programs. It will drop packets with an EDT of more than 500us in the future unless the packet belongs to a flow with less than 2 packets in flight. This is done so each flow has at least 2 packets in flight, so they will not starve, and also to help prevent delayed ACK timeouts. It will also work with ECN enabled traffic, where the packets will be CE marked if their EDT is more than 50us in the future. The table below shows some performance numbers. The flows are back to back RPCS. One server sending to another, either 2 or 4 flows. One flow is a 10KB RPC, the rest are 1MB RPCs. When there are more than one flow of a given RPC size, the numbers represent averages. The rate limit applies to all flows (they are in the same cgroup). Tests ending with "-edt" ran with the new BPF program supporting EDT. Tests ending with "-hbt" ran on top HBT qdisc with the specified rate (i.e. no HBM). The other tests ran with the HBM BPF program included in the HBM patch-set. EDT has limited value when using DCTCP, but it helps in many cases when using Cubic. It usually achieves larger link utilization and lower 99% latencies for the 1MB RPCs. HBM ends up queueing a lot of packets with its default parameter values, reducing the goodput of the 10KB RPCs and increasing their latency. Also, the RTTs seen by the flows are quite large. Aggr 10K 10K 10K 1MB 1MB 1MB Limit rate drops RTT rate P90 P99 rate P90 P99 Test rate Flows Mbps % us Mbps us us Mbps ms ms -------- ---- ----- ---- ----- --- ---- ---- ---- ---- ---- ---- cubic 1G 2 904 0.02 108 257 511 539 647 13.4 24.5 cubic-edt 1G 2 982 0.01 156 239 656 967 743 14.0 17.2 dctcp 1G 2 977 0.00 105 324 408 744 653 14.5 15.9 dctcp-edt 1G 2 981 0.01 142 321 417 811 660 15.7 17.0 cubic-htb 1G 2 919 0.00 1825 40 2822 4140 879 9.7 9.9 cubic 200M 2 155 0.30 220 81 532 655 74 283 450 cubic-edt 200M 2 188 0.02 222 87 1035 1095 101 84 85 dctcp 200M 2 188 0.03 111 77 912 939 111 76 325 dctcp-edt 200M 2 188 0.03 217 74 1416 1738 114 76 79 cubic-htb 200M 2 188 0.00 5015 8 14ms 15ms 180 48 50 cubic 1G 4 952 0.03 110 165 516 546 262 38 154 cubic-edt 1G 4 973 0.01 190 111 1034 1314 287 65 79 dctcp 1G 4 951 0.00 103 180 617 905 257 37 38 dctcp-edt 1G 4 967 0.00 163 151 732 1126 272 43 55 cubic-htb 1G 4 914 0.00 3249 13 7ms 8ms 300 29 34 cubic 5G 4 4236 0.00 134 305 490 624 1310 10 17 cubic-edt 5G 4 4865 0.00 156 306 425 759 1520 10 16 dctcp 5G 4 4936 0.00 128 485 221 409 1484 7 9 dctcp-edt 5G 4 4924 0.00 148 390 392 623 1508 11 26 v1 -> v2: Incorporated Andrii's suggestions v2 -> v3: Incorporated Yonghong's suggestions v3 -> v4: Removed credit update that is not needed Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Acked-by: Yonghong Song <yhs@fb.com> Signed-off-by: Daniel Borkmann <daniel@iogearbox.net>
2019-07-03 06:09:52 +08:00
#define BYTES_PER_NS(delta, rate) ((((u64)(delta)) * (rate)) >> 20)
#define BYTES_TO_NS(bytes, rate) div64_u64(((u64)(bytes)) << 20, (u64)(rate))
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
struct {
__uint(type, BPF_MAP_TYPE_CGROUP_STORAGE);
__type(key, struct bpf_cgroup_storage_key);
__type(value, struct hbm_vqueue);
} queue_state SEC(".maps");
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
struct {
__uint(type, BPF_MAP_TYPE_ARRAY);
__uint(max_entries, 1);
__type(key, u32);
__type(value, struct hbm_queue_stats);
} queue_stats SEC(".maps");
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
struct hbm_pkt_info {
int cwnd;
int rtt;
bpf: Add support for fq's EDT to HBM Adds support for fq's Earliest Departure Time to HBM (Host Bandwidth Manager). Includes a new BPF program supporting EDT, and also updates corresponding programs. It will drop packets with an EDT of more than 500us in the future unless the packet belongs to a flow with less than 2 packets in flight. This is done so each flow has at least 2 packets in flight, so they will not starve, and also to help prevent delayed ACK timeouts. It will also work with ECN enabled traffic, where the packets will be CE marked if their EDT is more than 50us in the future. The table below shows some performance numbers. The flows are back to back RPCS. One server sending to another, either 2 or 4 flows. One flow is a 10KB RPC, the rest are 1MB RPCs. When there are more than one flow of a given RPC size, the numbers represent averages. The rate limit applies to all flows (they are in the same cgroup). Tests ending with "-edt" ran with the new BPF program supporting EDT. Tests ending with "-hbt" ran on top HBT qdisc with the specified rate (i.e. no HBM). The other tests ran with the HBM BPF program included in the HBM patch-set. EDT has limited value when using DCTCP, but it helps in many cases when using Cubic. It usually achieves larger link utilization and lower 99% latencies for the 1MB RPCs. HBM ends up queueing a lot of packets with its default parameter values, reducing the goodput of the 10KB RPCs and increasing their latency. Also, the RTTs seen by the flows are quite large. Aggr 10K 10K 10K 1MB 1MB 1MB Limit rate drops RTT rate P90 P99 rate P90 P99 Test rate Flows Mbps % us Mbps us us Mbps ms ms -------- ---- ----- ---- ----- --- ---- ---- ---- ---- ---- ---- cubic 1G 2 904 0.02 108 257 511 539 647 13.4 24.5 cubic-edt 1G 2 982 0.01 156 239 656 967 743 14.0 17.2 dctcp 1G 2 977 0.00 105 324 408 744 653 14.5 15.9 dctcp-edt 1G 2 981 0.01 142 321 417 811 660 15.7 17.0 cubic-htb 1G 2 919 0.00 1825 40 2822 4140 879 9.7 9.9 cubic 200M 2 155 0.30 220 81 532 655 74 283 450 cubic-edt 200M 2 188 0.02 222 87 1035 1095 101 84 85 dctcp 200M 2 188 0.03 111 77 912 939 111 76 325 dctcp-edt 200M 2 188 0.03 217 74 1416 1738 114 76 79 cubic-htb 200M 2 188 0.00 5015 8 14ms 15ms 180 48 50 cubic 1G 4 952 0.03 110 165 516 546 262 38 154 cubic-edt 1G 4 973 0.01 190 111 1034 1314 287 65 79 dctcp 1G 4 951 0.00 103 180 617 905 257 37 38 dctcp-edt 1G 4 967 0.00 163 151 732 1126 272 43 55 cubic-htb 1G 4 914 0.00 3249 13 7ms 8ms 300 29 34 cubic 5G 4 4236 0.00 134 305 490 624 1310 10 17 cubic-edt 5G 4 4865 0.00 156 306 425 759 1520 10 16 dctcp 5G 4 4936 0.00 128 485 221 409 1484 7 9 dctcp-edt 5G 4 4924 0.00 148 390 392 623 1508 11 26 v1 -> v2: Incorporated Andrii's suggestions v2 -> v3: Incorporated Yonghong's suggestions v3 -> v4: Removed credit update that is not needed Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Acked-by: Yonghong Song <yhs@fb.com> Signed-off-by: Daniel Borkmann <daniel@iogearbox.net>
2019-07-03 06:09:52 +08:00
int packets_out;
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
bool is_ip;
bool is_tcp;
short ecn;
};
static int get_tcp_info(struct __sk_buff *skb, struct hbm_pkt_info *pkti)
{
struct bpf_sock *sk;
struct bpf_tcp_sock *tp;
sk = skb->sk;
if (sk) {
sk = bpf_sk_fullsock(sk);
if (sk) {
if (sk->protocol == IPPROTO_TCP) {
tp = bpf_tcp_sock(sk);
if (tp) {
pkti->cwnd = tp->snd_cwnd;
pkti->rtt = tp->srtt_us >> 3;
bpf: Add support for fq's EDT to HBM Adds support for fq's Earliest Departure Time to HBM (Host Bandwidth Manager). Includes a new BPF program supporting EDT, and also updates corresponding programs. It will drop packets with an EDT of more than 500us in the future unless the packet belongs to a flow with less than 2 packets in flight. This is done so each flow has at least 2 packets in flight, so they will not starve, and also to help prevent delayed ACK timeouts. It will also work with ECN enabled traffic, where the packets will be CE marked if their EDT is more than 50us in the future. The table below shows some performance numbers. The flows are back to back RPCS. One server sending to another, either 2 or 4 flows. One flow is a 10KB RPC, the rest are 1MB RPCs. When there are more than one flow of a given RPC size, the numbers represent averages. The rate limit applies to all flows (they are in the same cgroup). Tests ending with "-edt" ran with the new BPF program supporting EDT. Tests ending with "-hbt" ran on top HBT qdisc with the specified rate (i.e. no HBM). The other tests ran with the HBM BPF program included in the HBM patch-set. EDT has limited value when using DCTCP, but it helps in many cases when using Cubic. It usually achieves larger link utilization and lower 99% latencies for the 1MB RPCs. HBM ends up queueing a lot of packets with its default parameter values, reducing the goodput of the 10KB RPCs and increasing their latency. Also, the RTTs seen by the flows are quite large. Aggr 10K 10K 10K 1MB 1MB 1MB Limit rate drops RTT rate P90 P99 rate P90 P99 Test rate Flows Mbps % us Mbps us us Mbps ms ms -------- ---- ----- ---- ----- --- ---- ---- ---- ---- ---- ---- cubic 1G 2 904 0.02 108 257 511 539 647 13.4 24.5 cubic-edt 1G 2 982 0.01 156 239 656 967 743 14.0 17.2 dctcp 1G 2 977 0.00 105 324 408 744 653 14.5 15.9 dctcp-edt 1G 2 981 0.01 142 321 417 811 660 15.7 17.0 cubic-htb 1G 2 919 0.00 1825 40 2822 4140 879 9.7 9.9 cubic 200M 2 155 0.30 220 81 532 655 74 283 450 cubic-edt 200M 2 188 0.02 222 87 1035 1095 101 84 85 dctcp 200M 2 188 0.03 111 77 912 939 111 76 325 dctcp-edt 200M 2 188 0.03 217 74 1416 1738 114 76 79 cubic-htb 200M 2 188 0.00 5015 8 14ms 15ms 180 48 50 cubic 1G 4 952 0.03 110 165 516 546 262 38 154 cubic-edt 1G 4 973 0.01 190 111 1034 1314 287 65 79 dctcp 1G 4 951 0.00 103 180 617 905 257 37 38 dctcp-edt 1G 4 967 0.00 163 151 732 1126 272 43 55 cubic-htb 1G 4 914 0.00 3249 13 7ms 8ms 300 29 34 cubic 5G 4 4236 0.00 134 305 490 624 1310 10 17 cubic-edt 5G 4 4865 0.00 156 306 425 759 1520 10 16 dctcp 5G 4 4936 0.00 128 485 221 409 1484 7 9 dctcp-edt 5G 4 4924 0.00 148 390 392 623 1508 11 26 v1 -> v2: Incorporated Andrii's suggestions v2 -> v3: Incorporated Yonghong's suggestions v3 -> v4: Removed credit update that is not needed Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Acked-by: Yonghong Song <yhs@fb.com> Signed-off-by: Daniel Borkmann <daniel@iogearbox.net>
2019-07-03 06:09:52 +08:00
pkti->packets_out = tp->packets_out;
return 0;
}
}
}
}
bpf: Add support for fq's EDT to HBM Adds support for fq's Earliest Departure Time to HBM (Host Bandwidth Manager). Includes a new BPF program supporting EDT, and also updates corresponding programs. It will drop packets with an EDT of more than 500us in the future unless the packet belongs to a flow with less than 2 packets in flight. This is done so each flow has at least 2 packets in flight, so they will not starve, and also to help prevent delayed ACK timeouts. It will also work with ECN enabled traffic, where the packets will be CE marked if their EDT is more than 50us in the future. The table below shows some performance numbers. The flows are back to back RPCS. One server sending to another, either 2 or 4 flows. One flow is a 10KB RPC, the rest are 1MB RPCs. When there are more than one flow of a given RPC size, the numbers represent averages. The rate limit applies to all flows (they are in the same cgroup). Tests ending with "-edt" ran with the new BPF program supporting EDT. Tests ending with "-hbt" ran on top HBT qdisc with the specified rate (i.e. no HBM). The other tests ran with the HBM BPF program included in the HBM patch-set. EDT has limited value when using DCTCP, but it helps in many cases when using Cubic. It usually achieves larger link utilization and lower 99% latencies for the 1MB RPCs. HBM ends up queueing a lot of packets with its default parameter values, reducing the goodput of the 10KB RPCs and increasing their latency. Also, the RTTs seen by the flows are quite large. Aggr 10K 10K 10K 1MB 1MB 1MB Limit rate drops RTT rate P90 P99 rate P90 P99 Test rate Flows Mbps % us Mbps us us Mbps ms ms -------- ---- ----- ---- ----- --- ---- ---- ---- ---- ---- ---- cubic 1G 2 904 0.02 108 257 511 539 647 13.4 24.5 cubic-edt 1G 2 982 0.01 156 239 656 967 743 14.0 17.2 dctcp 1G 2 977 0.00 105 324 408 744 653 14.5 15.9 dctcp-edt 1G 2 981 0.01 142 321 417 811 660 15.7 17.0 cubic-htb 1G 2 919 0.00 1825 40 2822 4140 879 9.7 9.9 cubic 200M 2 155 0.30 220 81 532 655 74 283 450 cubic-edt 200M 2 188 0.02 222 87 1035 1095 101 84 85 dctcp 200M 2 188 0.03 111 77 912 939 111 76 325 dctcp-edt 200M 2 188 0.03 217 74 1416 1738 114 76 79 cubic-htb 200M 2 188 0.00 5015 8 14ms 15ms 180 48 50 cubic 1G 4 952 0.03 110 165 516 546 262 38 154 cubic-edt 1G 4 973 0.01 190 111 1034 1314 287 65 79 dctcp 1G 4 951 0.00 103 180 617 905 257 37 38 dctcp-edt 1G 4 967 0.00 163 151 732 1126 272 43 55 cubic-htb 1G 4 914 0.00 3249 13 7ms 8ms 300 29 34 cubic 5G 4 4236 0.00 134 305 490 624 1310 10 17 cubic-edt 5G 4 4865 0.00 156 306 425 759 1520 10 16 dctcp 5G 4 4936 0.00 128 485 221 409 1484 7 9 dctcp-edt 5G 4 4924 0.00 148 390 392 623 1508 11 26 v1 -> v2: Incorporated Andrii's suggestions v2 -> v3: Incorporated Yonghong's suggestions v3 -> v4: Removed credit update that is not needed Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Acked-by: Yonghong Song <yhs@fb.com> Signed-off-by: Daniel Borkmann <daniel@iogearbox.net>
2019-07-03 06:09:52 +08:00
pkti->cwnd = 0;
pkti->rtt = 0;
pkti->packets_out = 0;
return 1;
}
bpf: Add support for fq's EDT to HBM Adds support for fq's Earliest Departure Time to HBM (Host Bandwidth Manager). Includes a new BPF program supporting EDT, and also updates corresponding programs. It will drop packets with an EDT of more than 500us in the future unless the packet belongs to a flow with less than 2 packets in flight. This is done so each flow has at least 2 packets in flight, so they will not starve, and also to help prevent delayed ACK timeouts. It will also work with ECN enabled traffic, where the packets will be CE marked if their EDT is more than 50us in the future. The table below shows some performance numbers. The flows are back to back RPCS. One server sending to another, either 2 or 4 flows. One flow is a 10KB RPC, the rest are 1MB RPCs. When there are more than one flow of a given RPC size, the numbers represent averages. The rate limit applies to all flows (they are in the same cgroup). Tests ending with "-edt" ran with the new BPF program supporting EDT. Tests ending with "-hbt" ran on top HBT qdisc with the specified rate (i.e. no HBM). The other tests ran with the HBM BPF program included in the HBM patch-set. EDT has limited value when using DCTCP, but it helps in many cases when using Cubic. It usually achieves larger link utilization and lower 99% latencies for the 1MB RPCs. HBM ends up queueing a lot of packets with its default parameter values, reducing the goodput of the 10KB RPCs and increasing their latency. Also, the RTTs seen by the flows are quite large. Aggr 10K 10K 10K 1MB 1MB 1MB Limit rate drops RTT rate P90 P99 rate P90 P99 Test rate Flows Mbps % us Mbps us us Mbps ms ms -------- ---- ----- ---- ----- --- ---- ---- ---- ---- ---- ---- cubic 1G 2 904 0.02 108 257 511 539 647 13.4 24.5 cubic-edt 1G 2 982 0.01 156 239 656 967 743 14.0 17.2 dctcp 1G 2 977 0.00 105 324 408 744 653 14.5 15.9 dctcp-edt 1G 2 981 0.01 142 321 417 811 660 15.7 17.0 cubic-htb 1G 2 919 0.00 1825 40 2822 4140 879 9.7 9.9 cubic 200M 2 155 0.30 220 81 532 655 74 283 450 cubic-edt 200M 2 188 0.02 222 87 1035 1095 101 84 85 dctcp 200M 2 188 0.03 111 77 912 939 111 76 325 dctcp-edt 200M 2 188 0.03 217 74 1416 1738 114 76 79 cubic-htb 200M 2 188 0.00 5015 8 14ms 15ms 180 48 50 cubic 1G 4 952 0.03 110 165 516 546 262 38 154 cubic-edt 1G 4 973 0.01 190 111 1034 1314 287 65 79 dctcp 1G 4 951 0.00 103 180 617 905 257 37 38 dctcp-edt 1G 4 967 0.00 163 151 732 1126 272 43 55 cubic-htb 1G 4 914 0.00 3249 13 7ms 8ms 300 29 34 cubic 5G 4 4236 0.00 134 305 490 624 1310 10 17 cubic-edt 5G 4 4865 0.00 156 306 425 759 1520 10 16 dctcp 5G 4 4936 0.00 128 485 221 409 1484 7 9 dctcp-edt 5G 4 4924 0.00 148 390 392 623 1508 11 26 v1 -> v2: Incorporated Andrii's suggestions v2 -> v3: Incorporated Yonghong's suggestions v3 -> v4: Removed credit update that is not needed Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Acked-by: Yonghong Song <yhs@fb.com> Signed-off-by: Daniel Borkmann <daniel@iogearbox.net>
2019-07-03 06:09:52 +08:00
static void hbm_get_pkt_info(struct __sk_buff *skb,
struct hbm_pkt_info *pkti)
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
{
struct iphdr iph;
struct ipv6hdr *ip6h;
pkti->cwnd = 0;
pkti->rtt = 0;
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
bpf_skb_load_bytes(skb, 0, &iph, 12);
if (iph.version == 6) {
ip6h = (struct ipv6hdr *)&iph;
pkti->is_ip = true;
pkti->is_tcp = (ip6h->nexthdr == 6);
pkti->ecn = (ip6h->flow_lbl[0] >> 4) & INET_ECN_MASK;
} else if (iph.version == 4) {
pkti->is_ip = true;
pkti->is_tcp = (iph.protocol == 6);
pkti->ecn = iph.tos & INET_ECN_MASK;
} else {
pkti->is_ip = false;
pkti->is_tcp = false;
pkti->ecn = 0;
}
if (pkti->is_tcp)
get_tcp_info(skb, pkti);
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
}
static __always_inline void hbm_init_vqueue(struct hbm_vqueue *qdp, int rate)
{
bpf: Add support for fq's EDT to HBM Adds support for fq's Earliest Departure Time to HBM (Host Bandwidth Manager). Includes a new BPF program supporting EDT, and also updates corresponding programs. It will drop packets with an EDT of more than 500us in the future unless the packet belongs to a flow with less than 2 packets in flight. This is done so each flow has at least 2 packets in flight, so they will not starve, and also to help prevent delayed ACK timeouts. It will also work with ECN enabled traffic, where the packets will be CE marked if their EDT is more than 50us in the future. The table below shows some performance numbers. The flows are back to back RPCS. One server sending to another, either 2 or 4 flows. One flow is a 10KB RPC, the rest are 1MB RPCs. When there are more than one flow of a given RPC size, the numbers represent averages. The rate limit applies to all flows (they are in the same cgroup). Tests ending with "-edt" ran with the new BPF program supporting EDT. Tests ending with "-hbt" ran on top HBT qdisc with the specified rate (i.e. no HBM). The other tests ran with the HBM BPF program included in the HBM patch-set. EDT has limited value when using DCTCP, but it helps in many cases when using Cubic. It usually achieves larger link utilization and lower 99% latencies for the 1MB RPCs. HBM ends up queueing a lot of packets with its default parameter values, reducing the goodput of the 10KB RPCs and increasing their latency. Also, the RTTs seen by the flows are quite large. Aggr 10K 10K 10K 1MB 1MB 1MB Limit rate drops RTT rate P90 P99 rate P90 P99 Test rate Flows Mbps % us Mbps us us Mbps ms ms -------- ---- ----- ---- ----- --- ---- ---- ---- ---- ---- ---- cubic 1G 2 904 0.02 108 257 511 539 647 13.4 24.5 cubic-edt 1G 2 982 0.01 156 239 656 967 743 14.0 17.2 dctcp 1G 2 977 0.00 105 324 408 744 653 14.5 15.9 dctcp-edt 1G 2 981 0.01 142 321 417 811 660 15.7 17.0 cubic-htb 1G 2 919 0.00 1825 40 2822 4140 879 9.7 9.9 cubic 200M 2 155 0.30 220 81 532 655 74 283 450 cubic-edt 200M 2 188 0.02 222 87 1035 1095 101 84 85 dctcp 200M 2 188 0.03 111 77 912 939 111 76 325 dctcp-edt 200M 2 188 0.03 217 74 1416 1738 114 76 79 cubic-htb 200M 2 188 0.00 5015 8 14ms 15ms 180 48 50 cubic 1G 4 952 0.03 110 165 516 546 262 38 154 cubic-edt 1G 4 973 0.01 190 111 1034 1314 287 65 79 dctcp 1G 4 951 0.00 103 180 617 905 257 37 38 dctcp-edt 1G 4 967 0.00 163 151 732 1126 272 43 55 cubic-htb 1G 4 914 0.00 3249 13 7ms 8ms 300 29 34 cubic 5G 4 4236 0.00 134 305 490 624 1310 10 17 cubic-edt 5G 4 4865 0.00 156 306 425 759 1520 10 16 dctcp 5G 4 4936 0.00 128 485 221 409 1484 7 9 dctcp-edt 5G 4 4924 0.00 148 390 392 623 1508 11 26 v1 -> v2: Incorporated Andrii's suggestions v2 -> v3: Incorporated Yonghong's suggestions v3 -> v4: Removed credit update that is not needed Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Acked-by: Yonghong Song <yhs@fb.com> Signed-off-by: Daniel Borkmann <daniel@iogearbox.net>
2019-07-03 06:09:52 +08:00
bpf_printk("Initializing queue_state, rate:%d\n", rate * 128);
qdp->lasttime = bpf_ktime_get_ns();
qdp->credit = INIT_CREDIT;
qdp->rate = rate * 128;
}
static __always_inline void hbm_init_edt_vqueue(struct hbm_vqueue *qdp,
int rate)
{
unsigned long long curtime;
curtime = bpf_ktime_get_ns();
bpf_printk("Initializing queue_state, rate:%d\n", rate * 128);
qdp->lasttime = curtime - BURST_SIZE_NS; // support initial burst
qdp->credit = 0; // not used
qdp->rate = rate * 128;
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
}
static __always_inline void hbm_update_stats(struct hbm_queue_stats *qsp,
int len,
unsigned long long curtime,
bool congestion_flag,
bool drop_flag,
bool cwr_flag,
bool ecn_ce_flag,
struct hbm_pkt_info *pkti,
int credit)
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
{
int rv = ALLOW_PKT;
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
if (qsp != NULL) {
// Following is needed for work conserving
__sync_add_and_fetch(&(qsp->bytes_total), len);
if (qsp->stats) {
// Optionally update statistics
if (qsp->firstPacketTime == 0)
qsp->firstPacketTime = curtime;
qsp->lastPacketTime = curtime;
__sync_add_and_fetch(&(qsp->pkts_total), 1);
if (congestion_flag) {
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
__sync_add_and_fetch(&(qsp->pkts_marked), 1);
__sync_add_and_fetch(&(qsp->bytes_marked), len);
}
if (drop_flag) {
__sync_add_and_fetch(&(qsp->pkts_dropped), 1);
__sync_add_and_fetch(&(qsp->bytes_dropped),
len);
}
if (ecn_ce_flag)
__sync_add_and_fetch(&(qsp->pkts_ecn_ce), 1);
if (pkti->cwnd) {
__sync_add_and_fetch(&(qsp->sum_cwnd),
pkti->cwnd);
__sync_add_and_fetch(&(qsp->sum_cwnd_cnt), 1);
}
if (pkti->rtt)
__sync_add_and_fetch(&(qsp->sum_rtt),
pkti->rtt);
__sync_add_and_fetch(&(qsp->sum_credit), credit);
if (drop_flag)
rv = DROP_PKT;
if (cwr_flag)
rv |= 2;
if (rv == DROP_PKT)
__sync_add_and_fetch(&(qsp->returnValCount[0]),
1);
else if (rv == ALLOW_PKT)
__sync_add_and_fetch(&(qsp->returnValCount[1]),
1);
else if (rv == 2)
__sync_add_and_fetch(&(qsp->returnValCount[2]),
1);
else if (rv == 3)
__sync_add_and_fetch(&(qsp->returnValCount[3]),
1);
bpf: Sample HBM BPF program to limit egress bw A cgroup skb BPF program to limit cgroup output bandwidth. It uses a modified virtual token bucket queue to limit average egress bandwidth. The implementation uses credits instead of tokens. Negative credits imply that queueing would have happened (this is a virtual queue, so no queueing is done by it. However, queueing may occur at the actual qdisc (which is not used for rate limiting). This implementation uses 3 thresholds, one to start marking packets and the other two to drop packets: CREDIT - <--------------------------|------------------------> + | | | 0 | Large pkt | | drop thresh | Small pkt drop Mark threshold thresh The effect of marking depends on the type of packet: a) If the packet is ECN enabled, then the packet is ECN ce marked. The current mark threshold is tuned for DCTCP. c) Else, it is dropped if it is a large packet. If the credit is below the drop threshold, the packet is dropped. Note that dropping a packet through the BPF program does not trigger CWR (Congestion Window Reduction) in TCP packets. A future patch will add support for triggering CWR. This BPF program actually uses 2 drop thresholds, one threshold for larger packets (>= 120 bytes) and another for smaller packets. This protects smaller packets such as SYNs, ACKs, etc. The default bandwidth limit is set at 1Gbps but this can be changed by a user program through a shared BPF map. In addition, by default this BPF program does not limit connections using loopback. This behavior can be overwritten by the user program. There is also an option to calculate some statistics, such as percent of packets marked or dropped, which the user program can access. A latter patch provides such a program (hbm.c) Signed-off-by: Lawrence Brakmo <brakmo@fb.com> Signed-off-by: Alexei Starovoitov <ast@kernel.org>
2019-03-02 04:38:48 +08:00
}
}
}