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563 lines
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563 lines
25 KiB
4 months ago
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.TH "TC\-HFSC" 7 "31 October 2011" iproute2 Linux
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.SH "NAME"
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tc-hfcs \- Hierarchical Fair Service Curve
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.
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.SH "HISTORY & INTRODUCTION"
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.
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HFSC (Hierarchical Fair Service Curve) is a network packet scheduling algorithm that was first presented at
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SIGCOMM'97. Developed as a part of ALTQ (ALTernative Queuing) on NetBSD, found
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its way quickly to other BSD systems, and then a few years ago became part of
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the linux kernel. Still, it's not the most popular scheduling algorithm \-
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especially if compared to HTB \- and it's not well documented for the enduser. This introduction aims to explain how HFSC works without using
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too much math (although some math it will be
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inevitable).
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In short HFSC aims to:
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.
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.RS 4
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.IP \fB1)\fR 4
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guarantee precise bandwidth and delay allocation for all leaf classes (realtime
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criterion)
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.IP \fB2)\fR
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allocate excess bandwidth fairly as specified by class hierarchy (linkshare &
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upperlimit criterion)
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.IP \fB3)\fR
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minimize any discrepancy between the service curve and the actual amount of
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service provided during linksharing
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.RE
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.PP
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.
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The main "selling" point of HFSC is feature \fB(1)\fR, which is achieved by
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using nonlinear service curves (more about what it actually is later). This is
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particularly useful in VoIP or games, where not only a guarantee of consistent
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bandwidth is important, but also limiting the initial delay of a data stream. Note that
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it matters only for leaf classes (where the actual queues are) \- thus class
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hierarchy is ignored in the realtime case.
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Feature \fB(2)\fR is well, obvious \- any algorithm featuring class hierarchy
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(such as HTB or CBQ) strives to achieve that. HFSC does that well, although
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you might end with unusual situations, if you define service curves carelessly
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\- see section CORNER CASES for examples.
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Feature \fB(3)\fR is mentioned due to the nature of the problem. There may be
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situations where it's either not possible to guarantee service of all curves at
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the same time, and/or it's impossible to do so fairly. Both will be explained
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later. Note that this is mainly related to interior (aka aggregate) classes, as
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the leafs are already handled by \fB(1)\fR. Still, it's perfectly possible to
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create a leaf class without realtime service, and in such a case the caveats will
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naturally extend to leaf classes as well.
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.SH ABBREVIATIONS
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For the remaining part of the document, we'll use following shortcuts:
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.nf
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.RS 4
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RT \- realtime
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LS \- linkshare
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UL \- upperlimit
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SC \- service curve
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.fi
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.
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.SH "BASICS OF HFSC"
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.
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To understand how HFSC works, we must first introduce a service curve.
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Overall, it's a nondecreasing function of some time unit, returning the amount
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of
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service (an allowed or allocated amount of bandwidth) at some specific point in
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time. The purpose of it should be subconsciously obvious: if a class was
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allowed to transfer not less than the amount specified by its service curve,
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then the service curve is not violated.
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Still, we need more elaborate criterion than just the above (although in
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the most generic case it can be reduced to it). The criterion has to take two
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things into account:
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.
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.RS 4
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.IP \(bu 4
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idling periods
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.IP \(bu
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the ability to "look back", so if during current active period the service curve is violated, maybe it
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isn't if we count excess bandwidth received during earlier active period(s)
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.RE
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.PP
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Let's define the criterion as follows:
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.RS 4
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.nf
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.IP "\fB(1)\fR" 4
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For each t1, there must exist t0 in set B, so S(t1\-t0)\~<=\~w(t0,t1)
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.fi
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.RE
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.
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.PP
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Here 'w' denotes the amount of service received during some time period between t0
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and t1. B is a set of all times, where a session becomes active after idling
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period (further denoted as 'becoming backlogged'). For a clearer picture,
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imagine two situations:
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.
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.RS 4
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.IP \fBa)\fR 4
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our session was active during two periods, with a small time gap between them
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.IP \fBb)\fR
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as in (a), but with a larger gap
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.RE
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.
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.PP
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Consider \fB(a)\fR: if the service received during both periods meets
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\fB(1)\fR, then all is well. But what if it doesn't do so during the 2nd
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period? If the amount of service received during the 1st period is larger
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than the service curve, then it might compensate for smaller service during
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the 2nd period \fIand\fR the gap \- if the gap is small enough.
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If the gap is larger \fB(b)\fR \- then it's less likely to happen (unless the
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excess bandwidth allocated during the 1st part was really large). Still, the
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larger the gap \- the less interesting is what happened in the past (e.g. 10
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minutes ago) \- what matters is the current traffic that just started.
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From HFSC's perspective, more interesting is answering the following question:
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when should we start transferring packets, so a service curve of a class is not
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violated. Or rephrasing it: How much X() amount of service should a session
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receive by time t, so the service curve is not violated. Function X() defined
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as below is the basic building block of HFSC, used in: eligible, deadline,
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virtual\-time and fit\-time curves. Of course, X() is based on equation
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\fB(1)\fR and is defined recursively:
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.RS 4
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.IP \(bu 4
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At the 1st backlogged period beginning function X is initialized to generic
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service curve assigned to a class
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.IP \(bu
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At any subsequent backlogged period, X() is:
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.nf
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\fBmin(X() from previous period ; w(t0)+S(t\-t0) for t>=t0),\fR
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.fi
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\&... where t0 denotes the beginning of the current backlogged period.
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.RE
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.
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.PP
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HFSC uses either linear, or two\-piece linear service curves. In case of
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linear or two\-piece linear convex functions (first slope < second slope),
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min() in X's definition reduces to the 2nd argument. But in case of two\-piece
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concave functions, the 1st argument might quickly become lesser for some
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t>=t0. Note, that for some backlogged period, X() is defined only from that
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period's beginning. We also define X^(\-1)(w) as smallest t>=t0, for which
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X(t)\~=\~w. We have to define it this way, as X() is usually not an injection.
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The above generic X() can be one of the following:
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.
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.RS 4
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.IP "E()" 4
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In realtime criterion, selects packets eligible for sending. If none are
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eligible, HFSC will use linkshare criterion. Eligible time \&'et' is calculated
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with reference to packets' heads ( et\~=\~E^(\-1)(w) ). It's based on RT
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service curve, \fIbut in case of a convex curve, uses its 2nd slope only.\fR
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.IP "D()"
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In realtime criterion, selects the most suitable packet from the ones chosen
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by E(). Deadline time \&'dt' corresponds to packets' tails
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(dt\~=\~D^(\-1)(w+l), where \&'l' is packet's length). Based on RT service
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curve.
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.IP "V()"
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In linkshare criterion, arbitrates which packet to send next. Note that V() is
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function of a virtual time \- see \fBLINKSHARE CRITERION\fR section for
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details. Virtual time \&'vt' corresponds to packets' heads
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(vt\~=\~V^(\-1)(w)). Based on LS service curve.
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.IP "F()"
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An extension to linkshare criterion, used to limit at which speed linkshare
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criterion is allowed to dequeue. Fit\-time 'ft' corresponds to packets' heads
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as well (ft\~=\~F^(\-1)(w)). Based on UL service curve.
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.RE
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Be sure to make clean distinction between session's RT, LS and UL service
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curves and the above "utility" functions.
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.
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.SH "REALTIME CRITERION"
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.
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RT criterion \fIignores class hierarchy\fR and guarantees precise bandwidth and
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delay allocation. We say that a packet is eligible for sending, when the
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current real
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time is later than the eligible time of the packet. From all eligible packets, the one most
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suited for sending is the one with the shortest deadline time. This sounds
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simple, but consider the following example:
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Interface 10Mbit, two classes, both with two\-piece linear service curves:
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.RS 4
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.IP \(bu 4
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1st class \- 2Mbit for 100ms, then 7Mbit (convex \- 1st slope < 2nd slope)
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.IP \(bu
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2nd class \- 7Mbit for 100ms, then 2Mbit (concave \- 1st slope > 2nd slope)
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.RE
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.PP
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Assume for a moment, that we only use D() for both finding eligible packets,
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and choosing the most fitting one, thus eligible time would be computed as
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D^(\-1)(w) and deadline time would be computed as D^(\-1)(w+l). If the 2nd
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class starts sending packets 1 second after the 1st class, it's of course
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impossible to guarantee 14Mbit, as the interface capability is only 10Mbit.
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The only workaround in this scenario is to allow the 1st class to send the
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packets earlier that would normally be allowed. That's where separate E() comes
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to help. Putting all the math aside (see HFSC paper for details), E() for RT
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concave service curve is just like D(), but for the RT convex service curve \-
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it's constructed using \fIonly\fR RT service curve's 2nd slope (in our example
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7Mbit).
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The effect of such E() \- packets will be sent earlier, and at the same time
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D() \fIwill\fR be updated \- so the current deadline time calculated from it
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will be later. Thus, when the 2nd class starts sending packets later, both
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the 1st and the 2nd class will be eligible, but the 2nd session's deadline
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time will be smaller and its packets will be sent first. When the 1st class
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becomes idle at some later point, the 2nd class will be able to "buffer" up
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again for later active period of the 1st class.
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A short remark \- in a situation, where the total amount of bandwidth
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available on the interface is larger than the allocated total realtime parts
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(imagine a 10 Mbit interface, but 1Mbit/2Mbit and 2Mbit/1Mbit classes), the sole
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speed of the interface could suffice to guarantee the times.
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Important part of RT criterion is that apart from updating its D() and E(),
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also V() used by LS criterion is updated. Generally the RT criterion is
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secondary to LS one, and used \fIonly\fR if there's a risk of violating precise
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realtime requirements. Still, the "participation" in bandwidth distributed by
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LS criterion is there, so V() has to be updated along the way. LS criterion can
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than properly compensate for non\-ideal fair sharing situation, caused by RT
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scheduling. If you use UL service curve its F() will be updated as well (UL
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service curve is an extension to LS one \- see \fBUPPERLIMIT CRITERION\fR
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section).
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Anyway \- careless specification of LS and RT service curves can lead to
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potentially undesired situations (see CORNER CASES for examples). This wasn't
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the case in HFSC paper where LS and RT service curves couldn't be specified
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separately.
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.SH "LINKSHARING CRITERION"
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.
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LS criterion's task is to distribute bandwidth according to specified class
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hierarchy. Contrary to RT criterion, there're no comparisons between current
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real time and virtual time \- the decision is based solely on direct comparison
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of virtual times of all active subclasses \- the one with the smallest vt wins
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and gets scheduled. One immediate conclusion from this fact is that absolute
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values don't matter \- only ratios between them (so for example, two children
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classes with simple linear 1Mbit service curves will get the same treatment
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from LS criterion's perspective, as if they were 5Mbit). The other conclusion
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is, that in perfectly fluid system with linear curves, all virtual times across
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whole class hierarchy would be equal.
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Why is VC defined in term of virtual time (and what is it)?
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Imagine an example: class A with two children \- A1 and A2, both with let's say
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10Mbit SCs. If A2 is idle, A1 receives all the bandwidth of A (and update its
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V() in the process). When A2 becomes active, A1's virtual time is already
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\fIfar\fR later than A2's one. Considering the type of decision made by LS
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criterion, A1 would become idle for a long time. We can workaround this
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situation by adjusting virtual time of the class becoming active \- we do that
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by getting such time "up to date". HFSC uses a mean of the smallest and the
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biggest virtual time of currently active children fit for sending. As it's not
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real time anymore (excluding trivial case of situation where all classes become
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active at the same time, and never become idle), it's called virtual time.
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Such approach has its price though. The problem is analogous to what was
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presented in previous section and is caused by non\-linearity of service
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curves:
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.IP 1) 4
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either it's impossible to guarantee service curves and satisfy fairness
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during certain time periods:
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.RS 4
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Recall the example from RT section, slightly modified (with 3Mbit slopes
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instead of 2Mbit ones):
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.IP \(bu 4
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1st class \- 3Mbit for 100ms, then 7Mbit (convex \- 1st slope < 2nd slope)
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.IP \(bu
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2nd class \- 7Mbit for 100ms, then 3Mbit (concave \- 1st slope > 2nd slope)
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.PP
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They sum up nicely to 10Mbit \- the interface's capacity. But if we wanted to only
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use LS for guarantees and fairness \- it simply won't work. In LS context,
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only V() is used for making decision which class to schedule. If the 2nd class
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becomes active when the 1st one is in its second slope, the fairness will be
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preserved \- ratio will be 1:1 (7Mbit:7Mbit), but LS itself is of course
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unable to guarantee the absolute values themselves \- as it would have to go
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beyond of what the interface is capable of.
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.RE
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.IP 2) 4
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and/or it's impossible to guarantee service curves of all classes at the same
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time [fairly or not]:
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.RS 4
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This is similar to the above case, but a bit more subtle. We will consider two
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subtrees, arbitrated by their common (root here) parent:
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.nf
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R (root) -\ 10Mbit
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A \- 7Mbit, then 3Mbit
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A1 \- 5Mbit, then 2Mbit
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A2 \- 2Mbit, then 1Mbit
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B \- 3Mbit, then 7Mbit
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.fi
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R arbitrates between left subtree (A) and right (B). Assume that A2 and B are
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constantly backlogged, and at some later point A1 becomes backlogged (when all
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other classes are in their 2nd linear part).
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What happens now? B (choice made by R) will \fIalways\fR get 7 Mbit as R is
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only (obviously) concerned with the ratio between its direct children. Thus A
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subtree gets 3Mbit, but its children would want (at the point when A1 became
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backlogged) 5Mbit + 1Mbit. That's of course impossible, as they can only get
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3Mbit due to interface limitation.
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In the left subtree \- we have the same situation as previously (fair split
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between A1 and A2, but violated guarantees), but in the whole tree \- there's
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no fairness (B got 7Mbit, but A1 and A2 have to fit together in 3Mbit) and
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there's no guarantees for all classes (only B got what it wanted). Even if we
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violated fairness in the A subtree and set A2's service curve to 0, A1 would
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still not get the required bandwidth.
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.RE
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.
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.SH "UPPERLIMIT CRITERION"
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.
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UL criterion is an extensions to LS one, that permits sending packets only
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if current real time is later than fit\-time ('ft'). So the modified LS
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criterion becomes: choose the smallest virtual time from all active children,
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such that fit\-time < current real time also holds. Fit\-time is calculated
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from F(), which is based on UL service curve. As you can see, its role is
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kinda similar to E() used in RT criterion. Also, for obvious reasons \- you
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can't specify UL service curve without LS one.
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The main purpose of the UL service curve is to limit HFSC to bandwidth available on the
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upstream router (think adsl home modem/router, and linux server as
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NAT/firewall/etc. with 100Mbit+ connection to mentioned modem/router).
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Typically, it's used to create a single class directly under root, setting
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a linear UL service curve to available bandwidth \- and then creating your class
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structure from that class downwards. Of course, you're free to add a UL service
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curve (linear or not) to any class with LS criterion.
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An important part about the UL service curve is that whenever at some point in time
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a class doesn't qualify for linksharing due to its fit\-time, the next time it
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does qualify it will update its virtual time to the smallest virtual time of
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all active children fit for linksharing. This way, one of the main things the LS
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criterion tries to achieve \- equality of all virtual times across whole
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hierarchy \- is preserved (in perfectly fluid system with only linear curves,
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all virtual times would be equal).
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Without that, 'vt' would lag behind other virtual times, and could cause
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problems. Consider an interface with a capacity of 10Mbit, and the following leaf classes
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(just in case you're skipping this text quickly \- this example shows behavior
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that \f(BIdoesn't happen\fR):
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.nf
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A \- ls 5.0Mbit
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B \- ls 2.5Mbit
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C \- ls 2.5Mbit, ul 2.5Mbit
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.fi
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If B was idle, while A and C were constantly backlogged, A and C would normally
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(as far as LS criterion is concerned) divide bandwidth in 2:1 ratio. But due
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to UL service curve in place, C would get at most 2.5Mbit, and A would get the
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remaining 7.5Mbit. The longer the backlogged period, the more the virtual times of
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A and C would drift apart. If B became backlogged at some later point in time,
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its virtual time would be set to (A's\~vt\~+\~C's\~vt)/2, thus blocking A from
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sending any traffic until B's virtual time catches up with A.
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.
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.SH "SEPARATE LS / RT SCs"
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.
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Another difference from the original HFSC paper is that RT and LS SCs can be
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specified separately. Moreover, leaf classes are allowed to have only either
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|
RT SC or LS SC. For interior classes, only LS SCs make sense: any RT SC will
|
||
|
be ignored.
|
||
|
.
|
||
|
.SH "CORNER CASES"
|
||
|
.
|
||
|
Separate service curves for LS and RT criteria can lead to certain traps
|
||
|
that come from "fighting" between ideal linksharing and enforced realtime
|
||
|
guarantees. Those situations didn't exist in original HFSC paper, where
|
||
|
specifying separate LS / RT service curves was not discussed.
|
||
|
|
||
|
Consider an interface with a 10Mbit capacity, with the following leaf classes:
|
||
|
|
||
|
.nf
|
||
|
A \- ls 5.0Mbit, rt 8Mbit
|
||
|
B \- ls 2.5Mbit
|
||
|
C \- ls 2.5Mbit
|
||
|
.fi
|
||
|
|
||
|
Imagine A and C are constantly backlogged. As B is idle, A and C would divide
|
||
|
bandwidth in 2:1 ratio, considering LS service curve (so in theory \- 6.66 and
|
||
|
3.33). Alas RT criterion takes priority, so A will get 8Mbit and LS will be
|
||
|
able to compensate class C for only 2 Mbit \- this will cause discrepancy
|
||
|
between virtual times of A and C.
|
||
|
|
||
|
Assume this situation lasts for a long time with no idle periods, and
|
||
|
suddenly B becomes active. B's virtual time will be updated to
|
||
|
(A's\~vt\~+\~C's\~vt)/2, effectively landing in the middle between A's and C's
|
||
|
virtual time. The effect \- B, having no RT guarantees, will be punished and
|
||
|
will not be allowed to transfer until C's virtual time catches up.
|
||
|
|
||
|
If the interface had a higher capacity, for example 100Mbit, this example
|
||
|
would behave perfectly fine though.
|
||
|
|
||
|
Let's look a bit closer at the above example \- it "cleverly" invalidates one
|
||
|
of the basic things LS criterion tries to achieve \- equality of all virtual
|
||
|
times across class hierarchy. Leaf classes without RT service curves are
|
||
|
literally left to their own fate (governed by messed up virtual times).
|
||
|
|
||
|
Also, it doesn't make much sense. Class A will always be guaranteed up to
|
||
|
8Mbit, and this is more than any absolute bandwidth that could happen from its
|
||
|
LS criterion (excluding trivial case of only A being active). If the bandwidth
|
||
|
taken by A is smaller than absolute value from LS criterion, the unused part
|
||
|
will be automatically assigned to other active classes (as A has idling periods
|
||
|
in such case). The only "advantage" is, that even in case of low bandwidth on
|
||
|
average, bursts would be handled at the speed defined by RT criterion. Still,
|
||
|
if extra speed is needed (e.g. due to latency), non linear service curves
|
||
|
should be used in such case.
|
||
|
|
||
|
In the other words: the LS criterion is meaningless in the above example.
|
||
|
|
||
|
You can quickly "workaround" it by making sure each leaf class has RT service
|
||
|
curve assigned (thus guaranteeing all of them will get some bandwidth), but it
|
||
|
doesn't make it any more valid.
|
||
|
|
||
|
Keep in mind - if you use nonlinear curves and irregularities explained above
|
||
|
happen \fIonly\fR in the first segment, then there's little wrong with
|
||
|
"overusing" RT curve a bit:
|
||
|
|
||
|
.nf
|
||
|
A \- ls 5.0Mbit, rt 9Mbit/30ms, then 1Mbit
|
||
|
B \- ls 2.5Mbit
|
||
|
C \- ls 2.5Mbit
|
||
|
.fi
|
||
|
|
||
|
Here, the vt of A will "spike" in the initial period, but then A will never get more
|
||
|
than 1Mbit until B & C catch up. Then everything will be back to normal.
|
||
|
.
|
||
|
.SH "LINUX AND TIMER RESOLUTION"
|
||
|
.
|
||
|
In certain situations, the scheduler can throttle itself and setup so
|
||
|
called watchdog to wakeup dequeue function at some time later. In case of HFSC
|
||
|
it happens when for example no packet is eligible for scheduling, and UL
|
||
|
service curve is used to limit the speed at which LS criterion is allowed to
|
||
|
dequeue packets. It's called throttling, and accuracy of it is dependent on
|
||
|
how the kernel is compiled.
|
||
|
|
||
|
There're 3 important options in modern kernels, as far as timers' resolution
|
||
|
goes: \&'tickless system', \&'high resolution timer support' and \&'timer
|
||
|
frequency'.
|
||
|
|
||
|
If you have \&'tickless system' enabled, then the timer interrupt will trigger
|
||
|
as slowly as possible, but each time a scheduler throttles itself (or any
|
||
|
other part of the kernel needs better accuracy), the rate will be increased as
|
||
|
needed / possible. The ceiling is either \&'timer frequency' if \&'high
|
||
|
resolution timer support' is not available or not compiled in, or it's
|
||
|
hardware dependent and can go \fIfar\fR beyond the highest \&'timer frequency'
|
||
|
setting available.
|
||
|
|
||
|
If \&'tickless system' is not enabled, the timer will trigger at a fixed rate
|
||
|
specified by \&'timer frequency' \- regardless if high resolution timers are
|
||
|
or aren't available.
|
||
|
|
||
|
This is important to keep those settings in mind, as in scenario like: no
|
||
|
tickless, no HR timers, frequency set to 100hz \- throttling accuracy would be
|
||
|
at 10ms. It doesn't automatically mean you would be limited to ~0.8Mbit/s
|
||
|
(assuming packets at ~1KB) \- as long as your queues are prepared to cover for
|
||
|
timer inaccuracy. Of course, in case of e.g. locally generated UDP traffic \-
|
||
|
appropriate socket size is needed as well. Short example to make it more
|
||
|
understandable (assume hardcore anti\-schedule settings \- HZ=100, no HR
|
||
|
timers, no tickless):
|
||
|
|
||
|
.nf
|
||
|
tc qdisc add dev eth0 root handle 1:0 hfsc default 1
|
||
|
tc class add dev eth0 parent 1:0 classid 1:1 hfsc rt m2 10Mbit
|
||
|
.fi
|
||
|
|
||
|
Assuming packet of ~1KB size and HZ=100, that averages to ~0.8Mbit \- anything
|
||
|
beyond it (e.g. the above example with specified rate over 10x larger) will
|
||
|
require appropriate queuing and cause bursts every ~10 ms. As you can
|
||
|
imagine, any HFSC's RT guarantees will be seriously invalidated by that.
|
||
|
Aforementioned example is mainly important if you deal with old hardware \- as
|
||
|
is particularly popular for home server chores. Even then, you can easily
|
||
|
set HZ=1000 and have very accurate scheduling for typical adsl speeds.
|
||
|
|
||
|
Anything modern (apic or even hpet msi based timers + \&'tickless system')
|
||
|
will provide enough accuracy for superb 1Gbit scheduling. For example, on one
|
||
|
of my cheap dual-core AMD boards I have the following settings:
|
||
|
|
||
|
.nf
|
||
|
tc qdisc add dev eth0 parent root handle 1:0 hfsc default 1
|
||
|
tc class add dev eth0 parent 1:0 classid 1:1 hfsc rt m2 300mbit
|
||
|
.fi
|
||
|
|
||
|
And a simple:
|
||
|
|
||
|
.nf
|
||
|
nc \-u dst.host.com 54321 </dev/zero
|
||
|
nc \-l \-p 54321 >/dev/null
|
||
|
.fi
|
||
|
|
||
|
\&...will yield the following effects over a period of ~10 seconds (taken from
|
||
|
/proc/interrupts):
|
||
|
|
||
|
.nf
|
||
|
319: 42124229 0 HPET_MSI\-edge hpet2 (before)
|
||
|
319: 42436214 0 HPET_MSI\-edge hpet2 (after 10s.)
|
||
|
.fi
|
||
|
|
||
|
That's roughly 31000/s. Now compare it with HZ=1000 setting. The obvious
|
||
|
drawback of it is that cpu load can be rather high with servicing that
|
||
|
many timer interrupts. The example with 300Mbit RT service curve on 1Gbit link is
|
||
|
particularly ugly, as it requires a lot of throttling with minuscule delays.
|
||
|
|
||
|
Also note that it's just an example showing the capabilities of current hardware.
|
||
|
The above example (essentially a 300Mbit TBF emulator) is pointless on an internal
|
||
|
interface to begin with: you will pretty much always want a regular LS service
|
||
|
curve there, and in such a scenario HFSC simply doesn't throttle at all.
|
||
|
|
||
|
300Mbit RT service curve (selected columns from mpstat \-P ALL 1):
|
||
|
|
||
|
.nf
|
||
|
10:56:43 PM CPU %sys %irq %soft %idle
|
||
|
10:56:44 PM all 20.10 6.53 34.67 37.19
|
||
|
10:56:44 PM 0 35.00 0.00 63.00 0.00
|
||
|
10:56:44 PM 1 4.95 12.87 6.93 73.27
|
||
|
.fi
|
||
|
|
||
|
So, in the rare case you need those speeds with only a RT service curve, or with a UL
|
||
|
service curve: remember the drawbacks.
|
||
|
.
|
||
|
.SH "CAVEAT: RANDOM ONLINE EXAMPLES"
|
||
|
.
|
||
|
For reasons unknown (though well guessed), many examples you can google love to
|
||
|
overuse UL criterion and stuff it in every node possible. This makes no sense
|
||
|
and works against what HFSC tries to do (and does pretty damn well). Use UL
|
||
|
where it makes sense: on the uppermost node to match upstream router's uplink
|
||
|
capacity. Or in special cases, such as testing (limit certain subtree to some
|
||
|
speed), or customers that must never get more than certain speed. In the last
|
||
|
case you can usually achieve the same by just using a RT criterion without LS+UL
|
||
|
on leaf nodes.
|
||
|
|
||
|
As for the router case - remember it's good to differentiate between "traffic to
|
||
|
router" (remote console, web config, etc.) and "outgoing traffic", so for
|
||
|
example:
|
||
|
|
||
|
.nf
|
||
|
tc qdisc add dev eth0 root handle 1:0 hfsc default 0x8002
|
||
|
tc class add dev eth0 parent 1:0 classid 1:999 hfsc rt m2 50Mbit
|
||
|
tc class add dev eth0 parent 1:0 classid 1:1 hfsc ls m2 2Mbit ul m2 2Mbit
|
||
|
.fi
|
||
|
|
||
|
\&... so "internet" tree under 1:1 and "router itself" as 1:999
|
||
|
.
|
||
|
.SH "LAYER2 ADAPTATION"
|
||
|
.
|
||
|
Please refer to \fBtc\-stab\fR(8)
|
||
|
.
|
||
|
.SH "SEE ALSO"
|
||
|
.
|
||
|
\fBtc\fR(8), \fBtc\-hfsc\fR(8), \fBtc\-stab\fR(8)
|
||
|
|
||
|
Please direct bugreports and patches to: <netdev@vger.kernel.org>
|
||
|
.
|
||
|
.SH "AUTHOR"
|
||
|
.
|
||
|
Manpage created by Michal Soltys (soltys@ziu.info)
|