samples/bpf/hbm_edt_kern.c - linux - Git at Google

 // 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.
  *
  * Sample Host Bandwidth Manager (HBM) BPF program.
  *
  * A cgroup skb BPF egress 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 and it is a TCP packet, then the packet
  *    is ECN marked.
  * b) If the packet is a TCP packet, then we probabilistically call tcp_cwr
  *    to reduce the congestion window. The current implementation uses a linear
  *    distribution (0% probability at marking threshold, 100% probability
  *    at drop threshold).
  * c) If the packet is not a TCP packet, then it is dropped.
  *
  * If the credit is below the drop threshold, the packet is dropped. If it
  * is a TCP packet, then it also calls tcp_cwr since packets dropped by
  * a cgroup skb BPF program do not automatically trigger a call to
  * tcp_cwr in the current kernel code.
  *
  * 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
  * a user program, such as hbm, can access.
  */

 #include "hbm_kern.h"

 SEC("cgroup_skb/egress")
 int _hbm_out_cg(struct __sk_buff *skb)
 {
 	long long delta = 0, delta_send;
 	unsigned long long curtime, sendtime;
 	struct hbm_queue_stats *qsp = NULL;
 	unsigned int queue_index = 0;
 	bool congestion_flag = false;
 	bool ecn_ce_flag = false;
 	struct hbm_pkt_info pkti = {};
 	struct hbm_vqueue *qdp;
 	bool drop_flag = false;
 	bool cwr_flag = false;
 	int len = skb->len;
 	int rv = ALLOW_PKT;

 	qsp = bpf_map_lookup_elem(&queue_stats, &queue_index);

 	// Check if we should ignore loopback traffic
 	if (qsp != NULL && !qsp->loopback && (skb->ifindex == 1))
 		return ALLOW_PKT;

 	hbm_get_pkt_info(skb, &pkti);

 	// We may want to account for the length of headers in len
 	// calculation, like ETH header + overhead, specially if it
 	// is a gso packet. But I am not doing it right now.

 	qdp = bpf_get_local_storage(&queue_state, 0);
 	if (!qdp)
 		return ALLOW_PKT;
 	if (qdp->lasttime == 0)
 		hbm_init_edt_vqueue(qdp, 1024);

 	curtime = bpf_ktime_get_ns();

 	// Begin critical section
 	bpf_spin_lock(&qdp->lock);
 	delta = qdp->lasttime - curtime;
 	// bound bursts to 100us
 	if (delta < -BURST_SIZE_NS) {
 		// negative delta is a credit that allows bursts
 		qdp->lasttime = curtime - BURST_SIZE_NS;
 		delta = -BURST_SIZE_NS;
 	}
 	sendtime = qdp->lasttime;
 	delta_send = BYTES_TO_NS(len, qdp->rate);
 	__sync_add_and_fetch(&(qdp->lasttime), delta_send);
 	bpf_spin_unlock(&qdp->lock);
 	// End critical section

 	// Set EDT of packet
 	skb->tstamp = sendtime;

 	// Check if we should update rate
 	if (qsp != NULL && (qsp->rate * 128) != qdp->rate)
 		qdp->rate = qsp->rate * 128;

 	// Set flags (drop, congestion, cwr)
 	// last packet will be sent in the future, bound latency
 	if (delta > DROP_THRESH_NS || (delta > LARGE_PKT_DROP_THRESH_NS &&
 				       len > LARGE_PKT_THRESH)) {
 		drop_flag = true;
 		if (pkti.is_tcp && pkti.ecn == 0)
 			cwr_flag = true;
 	} else if (delta > MARK_THRESH_NS) {
 		if (pkti.is_tcp)
 			congestion_flag = true;
 		else
 			drop_flag = true;
 	}

 	if (congestion_flag) {
 		if (bpf_skb_ecn_set_ce(skb)) {
 			ecn_ce_flag = true;
 		} else {
 			if (pkti.is_tcp) {
 				unsigned int rand = bpf_get_prandom_u32();

 				if (delta >= MARK_THRESH_NS +
 				    (rand % MARK_REGION_SIZE_NS)) {
 					// Do congestion control
 					cwr_flag = true;
 				}
 			} else if (len > LARGE_PKT_THRESH) {
 				// Problem if too many small packets?
 				drop_flag = true;
 				congestion_flag = false;
 			}
 		}
 	}

 	if (pkti.is_tcp && drop_flag && pkti.packets_out <= 1) {
 		drop_flag = false;
 		cwr_flag = true;
 		congestion_flag = false;
 	}

 	if (qsp != NULL && qsp->no_cn)
 			cwr_flag = false;

 	hbm_update_stats(qsp, len, curtime, congestion_flag, drop_flag,
 			 cwr_flag, ecn_ce_flag, &pkti, (int) delta);

 	if (drop_flag) {
 		__sync_add_and_fetch(&(qdp->lasttime), -delta_send);
 		rv = DROP_PKT;
 	}

 	if (cwr_flag)
 		rv |= CWR;
 	return rv;
 }
 char _license[] SEC("license") = "GPL";
	// 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.
	*
	* Sample Host Bandwidth Manager (HBM) BPF program.
	*
	* A cgroup skb BPF egress 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 and it is a TCP packet, then the packet
	* is ECN marked.
	* b) If the packet is a TCP packet, then we probabilistically call tcp_cwr
	* to reduce the congestion window. The current implementation uses a linear
	* distribution (0% probability at marking threshold, 100% probability
	* at drop threshold).
	* c) If the packet is not a TCP packet, then it is dropped.
	*
	* If the credit is below the drop threshold, the packet is dropped. If it
	* is a TCP packet, then it also calls tcp_cwr since packets dropped by
	* a cgroup skb BPF program do not automatically trigger a call to
	* tcp_cwr in the current kernel code.
	*
	* 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
	* a user program, such as hbm, can access.
	*/

	#include "hbm_kern.h"

	SEC("cgroup_skb/egress")
	int _hbm_out_cg(struct __sk_buff *skb)
	{
	long long delta = 0, delta_send;
	unsigned long long curtime, sendtime;
	struct hbm_queue_stats *qsp = NULL;
	unsigned int queue_index = 0;
	bool congestion_flag = false;
	bool ecn_ce_flag = false;
	struct hbm_pkt_info pkti = {};
	struct hbm_vqueue *qdp;
	bool drop_flag = false;
	bool cwr_flag = false;
	int len = skb->len;
	int rv = ALLOW_PKT;

	qsp = bpf_map_lookup_elem(&queue_stats, &queue_index);

	// Check if we should ignore loopback traffic
	if (qsp != NULL && !qsp->loopback && (skb->ifindex == 1))
	return ALLOW_PKT;

	hbm_get_pkt_info(skb, &pkti);

	// We may want to account for the length of headers in len
	// calculation, like ETH header + overhead, specially if it
	// is a gso packet. But I am not doing it right now.

	qdp = bpf_get_local_storage(&queue_state, 0);
	if (!qdp)
	return ALLOW_PKT;
	if (qdp->lasttime == 0)
	hbm_init_edt_vqueue(qdp, 1024);

	curtime = bpf_ktime_get_ns();

	// Begin critical section
	bpf_spin_lock(&qdp->lock);
	delta = qdp->lasttime - curtime;
	// bound bursts to 100us
	if (delta < -BURST_SIZE_NS) {
	// negative delta is a credit that allows bursts
	qdp->lasttime = curtime - BURST_SIZE_NS;
	delta = -BURST_SIZE_NS;
	}
	sendtime = qdp->lasttime;
	delta_send = BYTES_TO_NS(len, qdp->rate);
	__sync_add_and_fetch(&(qdp->lasttime), delta_send);
	bpf_spin_unlock(&qdp->lock);
	// End critical section

	// Set EDT of packet
	skb->tstamp = sendtime;

	// Check if we should update rate
	if (qsp != NULL && (qsp->rate * 128) != qdp->rate)
	qdp->rate = qsp->rate * 128;

	// Set flags (drop, congestion, cwr)
	// last packet will be sent in the future, bound latency
	if (delta > DROP_THRESH_NS \|\| (delta > LARGE_PKT_DROP_THRESH_NS &&
	len > LARGE_PKT_THRESH)) {
	drop_flag = true;
	if (pkti.is_tcp && pkti.ecn == 0)
	cwr_flag = true;
	} else if (delta > MARK_THRESH_NS) {
	if (pkti.is_tcp)
	congestion_flag = true;
	else
	drop_flag = true;
	}

	if (congestion_flag) {
	if (bpf_skb_ecn_set_ce(skb)) {
	ecn_ce_flag = true;
	} else {
	if (pkti.is_tcp) {
	unsigned int rand = bpf_get_prandom_u32();

	if (delta >= MARK_THRESH_NS +
	(rand % MARK_REGION_SIZE_NS)) {
	// Do congestion control
	cwr_flag = true;
	}
	} else if (len > LARGE_PKT_THRESH) {
	// Problem if too many small packets?
	drop_flag = true;
	congestion_flag = false;
	}
	}
	}

	if (pkti.is_tcp && drop_flag && pkti.packets_out <= 1) {
	drop_flag = false;
	cwr_flag = true;
	congestion_flag = false;
	}

	if (qsp != NULL && qsp->no_cn)
	cwr_flag = false;

	hbm_update_stats(qsp, len, curtime, congestion_flag, drop_flag,
	cwr_flag, ecn_ce_flag, &pkti, (int) delta);

	if (drop_flag) {
	__sync_add_and_fetch(&(qdp->lasttime), -delta_send);
	rv = DROP_PKT;
	}

	if (cwr_flag)
	rv \|= CWR;
	return rv;
	}
	char _license[] SEC("license") = "GPL";