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author | Maciek Konstantynowicz <mkonstan@cisco.com> | 2018-10-23 09:55:05 -0700 |
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committer | Vratko Polak <vrpolak@cisco.com> | 2019-03-13 13:19:10 +0000 |
commit | b285fff289f434f0aa988d282a218a9f84e21357 (patch) | |
tree | 4b63092194ae45056afcc57c2954691adb4f5e00 /docs/ietf/draft-vpolak-bmwg-plrsearch-01.md | |
parent | 81e10cc16d6d8f99c3eeb85bd9af5a863ae07729 (diff) |
Updated IETF draft: draft-vpolak-bmwg-plrsearch-01.
Change-Id: I507d44f75383046b01def750af51a911b8ec5aa3
Signed-off-by: Maciek Konstantynowicz <mkonstan@cisco.com>
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diff --git a/docs/ietf/draft-vpolak-bmwg-plrsearch-01.md b/docs/ietf/draft-vpolak-bmwg-plrsearch-01.md new file mode 100644 index 0000000000..57e1a61125 --- /dev/null +++ b/docs/ietf/draft-vpolak-bmwg-plrsearch-01.md @@ -0,0 +1,911 @@ +--- +title: Probabilistic Loss Ratio Search for Packet Throughput (PLRsearch) +# abbrev: PLRsearch +docname: draft-vpolak-bmwg-plrsearch-01 +date: 2019-03-11 + +ipr: trust200902 +area: ops +wg: Benchmarking Working Group +kw: Internet-Draft +cat: info + +coding: us-ascii +pi: # can use array (if all yes) or hash here +# - toc +# - sortrefs +# - symrefs + toc: yes + sortrefs: # defaults to yes + symrefs: yes + +author: + - + ins: M. Konstantynowicz + name: Maciek Konstantynowicz + org: Cisco Systems + role: editor + email: mkonstan@cisco.com + - + ins: V. Polak + name: Vratko Polak + org: Cisco Systems + role: editor + email: vrpolak@cisco.com + +normative: + RFC2544: + RFC8174: + +informative: + draft-vpolak-mkonstan-bmwg-mlrsearch: + target: https://tools.ietf.org/html/draft-vpolak-mkonstan-bmwg-mlrsearch-00 + title: "Multiple Loss Ratio Search for Packet Throughput (MLRsearch)" + date: 2018-11 + +--- abstract + +This document addresses challenges while applying methodologies +described in [RFC2544] to benchmarking software based NFV (Network +Function Virtualization) data planes over an extended period of time, +sometimes referred to as "soak testing". Packet throughput search +approach proposed by this document assumes that system under test is +probabilistic in nature, and not deterministic. + +--- middle + +# Motivation + +Network providers are interested in throughput a system can sustain. + +[RFC2544] assumes loss ratio is given by a deterministic function of +offered load. But NFV software systems are not deterministic enough. +This makes deterministic algorithms (such as Binary Search per [RFC2544] +and [draft-vpolak-mkonstan-bmwg-mlrsearch] with single trial) to return +results, which when repeated show relatively high standard deviation, +thus making it harder to tell what "the throughput" actually is. + +We need another algorithm, which takes this indeterminism into account. + +# Relation To RFC2544 + +The aim of this document is to become an extension of [RFC2544] suitable +for benchmarking networking setups such as software based NFV systems. + +# Terms And Assumptions + +## Device Under Test + +In software networking, "device" denotes a specific piece of software +tasked with packet processing. Such device is surrounded with other +software components (such as operating system kernel). It is not +possible to run devices without also running the other components, and +hardware resources are shared between both. + +For purposes of testing, the whole set of hardware and software +components is called "system under test" (SUT). As SUT is the part of +the whole test setup performance of which can be measured by [RFC2544] +methods, this document uses SUT instead of [RFC2544] DUT. + +Device under test (DUT) can be re-introduced when analysing test results +using whitebox techniques, but this document sticks to blackbox testing. + +## System Under Test + +System under test (SUT) is a part of the whole test setup whose +performance is to be benchmarked. The complete methodology contains +other parts, whose performance is either already established, or not +affecting the benchmarking result. + +## SUT Configuration + +Usually, system under test allows different configurations, affecting +its performance. The rest of this document assumes a single +configuration has been chosen. + +## SUT Setup + +Similarly to [RFC2544], it is assumed that the system under test has +been updated with all the packet forwarding information it needs, before +the trial measurements (see below) start. + +## Network Traffic + +Network traffic is a type of interaction between system under test and +the rest of the system (traffic generator), used to gather information +about the system under test performance. PLRsearch is applicable only to +areas where network traffic consists of packets. + +## Packet + +Unit of interaction between traffic generator and the system under test. +Term "packet" is used also as an abstractions of Ethernet frames. + +### Packet Offered + +Packet can be offered, which means it is sent from traffic generator +to the system under test. + +Each offered packet is assumed to become received or lost in a short +time. + +### Packet Received + +Packet can be received, which means the traffic generator verifies it +has been processed. Typically, when it is succesfully sent from the +system under test to traffic generator. + +It is assumed that each received packet has been caused by an offered +packet, so the number of packets received cannot be larger than the +number of packets offered. + +### Packet Lost + +Packet can be lost, which means sent but not received in a timely +manner. + +It is assumed that each lost packet has been caused by an offered +packet, so the number of packets lost cannot be larger than the number +of packets offered. + +Usually, the number of packets lost is computed as the number of packets +offered, minus the number of packets received. + +### Other Packets + +PLRsearch is not considering other packet behaviors known from +networking (duplicated, reordered, greatly delayed), assuming the test +specification reclassifies those behaviors to fit into the first three +categories. + +### Tasks As Packets + +Ethernet frames are the prime example of packets, but other units are +possible. + +For example, a task processing system can fit the description. Packet +offered can stand for task submitted, packet received for task processed +successfully, and packet lost for task aborted (or not processed +successfully for some other reason). + +In networking context, such a task can be a route update. + +## Traffic Profile + +Usually, the performance of the system under test depends on a "type" of +a particular packet (for example size), and "composition" if the network +traffic consists of a mixture of different packet types. + +Also, some systems under test contain multiple "ports" packets can be +offered to and received from. + +All such qualities together (but not including properties of trial +measurements) are called traffic profile. + +Similarly to system under test configuration, this document assumes only +one traffic profile has been chosen for a particular test. + +## Traffic Generator + +Traffic generator is the part of the whole test setup, distinct from the +system under test, responsible both for offering packets in a highly +predictable manner (so the number of packets offered is known), and for +counting received packets in a precise enough way (to distinguish lost +packets from tolerably delayed packets). + +Traffic generator must offer only packets compatible with the traffic +profile, and only count similarly compatible packets as received. + +## Offered Load + +Offered load is an aggregate rate (measured in packets per second) of +network traffic offered to the system under test, the rate is kept +constant for the duration of trial measurement. + +## Trial Measurement + +Trial measurement is a process of stressing (previously setup) system +under test by offering traffic of a particular offered load, for a +particular duration. + +After that, the system has a short time to become idle, while the +traffic generator decides how many packets were lost. + +After that, another trial measurement (possibly with different offered +load and duration) can be immediately performed. Traffic generator +should ignore received packets caused by packets offered in previous +trial measurements. + +## Trial Duration + +Duration for which the traffic generator was offering packets at +constant offered load. + +In theory, care has to be taken to ensure the offered load and trial +duration predict integer number of packets to offer, and that the +traffic generator really sends appropriate number of packets within +precisely enough timed duration. In practice, such consideration do not +change PLRsearch result in any significant way. + +## Packet Loss + +Packet loss is any quantity describing a result of trial measurement. + +It can be loss count, loss rate or loss ratio. Packet loss is zero (or +non-zero) if either of the three quantities are zero (or non-zero, +respecively). + +### Loss Count + +Number of packets lost (or delayed too much) at a trial measurement by +the system under test as determined by packet generator. Measured in +packets. + +### Loss Rate + +Loss rate is computed as loss count divided by trial duration. Measured +in packets per second. + +### Loss Ratio + +Loss ratio is computed as loss count divided by number of packets +offered. Measured as a real (in practice rational) number between zero +or one (including). + +## Trial Order Independent System + +Trial order independent system is a system under test, proven (or just +assumed) to produce trial measurement results that display trial order +independence. + +That means when a pair of consequent trial measurements are performed, +the probability to observe a pair of specific results is the same, as +the probability to observe the reversed pair of results whe performing +the reversed pair of consequent measurements. + +PLRsearch assumes the system under test is trial order independent. + +In practice, most system under test are not entirely trial order +independent, but it is not easy to devise an algorithm taking that into +account. + +## Trial Measurement Result Distribution + +When a trial order independent system is subjected to repeated trial +measurements of constant offered load and duration, Law of Large Numbers +implies the observed loss count frequencies will converge to a specific +probability distribution over possible loss counts. + +This probability distribution is called trial measurement result +distribution, and it depends on all properties fixed when defining it. +That includes the system under test, its chosen configuration, the +chosen traffic profile, the offered load and the trial duration. + +As the system is trial order independent, trial measurement result +distribution does not depend on results of few initial trial +measurements, of any offered load or (finite) duration. + +## Average Loss Ratio + +Probability distribution over some (finite) set of states enables +computation of probability-weighted average of any quantity evaluated on +the states (called the expected value of the quantity). + +Average loss ratio is simply the expected value of loss ratio for a +given trial measurement result distribution. + +## Duration Independent System + +Duration independent system is a trial order independent system, whose +trial measurement result distribution is proven (or just assumed) to +display practical independence from trial duration. See definition of +trial duration for discussion on practical versus theoretical. + +The only requirement is for average loss ratio to be independent of +trial duration. + +In theory, that would necessitate each trial measurement result +distribution to be a binomial distribution. In practice, more +distributions are allowed. + +PLRsearch assumes the system under test is duration independent, at +least for trial durations typically chosen for trial measurements +initiated by PLRsearch. + +## Load Regions + +For a duration independent system, trial measurement result distribution +depends only on offered load. + +It is convenient to name some areas of offered load space by possible +trial results. + +### Zero Loss Region + +A particular offered load value is said to belong to zero loss region, +if the probability of seeing non-zero loss trial measurement result is +exactly zero, or at least practically indistinguishable from zero. + +### Guaranteed Loss Region + +A particular offered load value is said to belong to guaranteed loss +region, if the probability of seeing zero loss trial measurement result +(for non-negligible count of packets offered) is exactly zero, or at +least practically indistinguishable from zero. + +### Non-Deterministic Region + +A particular offered load value is said to belong to non-deterministic +region, if the probability of seeing zero loss trial measurement result +(for non-negligible count of packets offered) practically +distinguishable from both zero and one. + +### Normal Region Ordering + +Although theoretically the three regions can be arbitrary sets, this +document assumes they are intervals, where zero loss region contains +values smaller than non-deterministic region, which in turn contains +values smaller than guaranteed loss region. + +## Deterministic System + +A hypothetical duration independent system with normal region ordering, +whose non-deterministic region is extremely narrow; only present due to +"practical distinguishibility" and cases when the expected number of +packets offered is not and integer. + +A duration independent system which is not deterministic is called non- +deterministic system. + +## Througphput + +Throughput is the highest offered load provably causing zero packet loss +for trial measurements of duration at least 60 seconds. + +For duration independent systems with normal region ordering, the +throughput is the highest value within the zero loss region. + +## Deterministic Search + +Any algorithm that assumes each measurement is a proof of the offered +load belonging to zero loss region (or not) is called deterministic +search. + +This definition includes algorithms based on "composite measurements" +which perform multiple trial measurements, somehow re-classifying +results pointing at non-deterministic region. + +Binary Search is an example of deterministic search. + +Single run of a deterministic search launched against a deterministic +system is guaranteed to find the throughput with any prescribed +precision (not better than non-deterministic region width). + +Multiple runs of a deterministic search launched against a non- +deterministic system can return varied results within non-deterministic +region. The exact distribution of deterministic search results depends +on the algorithm used. + +## Probabilistic Search + +Any algorithm which performs probabilistic computations based on +observed results of trial measurements, and which does not assume that +non-deterministic region is practically absent is called probabilistic +search. + +A probabilistic search algorithm, which would assume that non- +deterministic region is practically absent, does not really need to +perform probabilistic computations, so it would become a deterministic +search. + +While probabilistic search for estimating throughput is possible, it +would need a careful model for boundary between zero loss region and +non-deterministic region, and it would need a lot of measurements of +almost surely zero loss to reach good precision. + +## Loss Ratio Function + +For any duration independent system, the average loss ratio depends only +on offered load (for a particular test setup). + +Loss ratio function is the name used for the function mapping offered +load to average loss ratio. + +This function is initially unknown. + +## Target Loss Ratio + +Input parameter of PLRsearch. The average loss ratio the output of +PLRsearch aims to achieve. + +## Critical Load + +Aggregate rate of network traffic, which would lead to average loss +ratio exactly matching target loss ratio (when used as the offered load +for infinite many trial measurement). + +## Critical Load Estimate + +Any quantitative description of the possible critical load PLRsearch is +able to give after observing finite amount of trial measurements. + +## Fitting Function + +Any function PLRsearch uses internally instead of the unknown loss ratio +function. Typically chosen from small set of formulas (shapes) with few +parameters to tweak. + +## Shape of Fitting Function + +Any formula with few undetermined parameters. + +## Parameter Space + +A subset of Real Coordinate Space. A point of parameter space is a +vector of real numbers. Fitting function is defined by shape (a formula +with parameters) and point of parameter space (specifying values for the +parameters). + +# Abstract Algorithm + +## High level description + +PLRsearch accepts some input arguments, then iteratively performs trial +measurements at varying offered loads (and durations), and returns some +estimates of critical load. + +PLRsearch input arguments form three groups. + +First group has a single argument: measurer. This is a callback +(function) accepting offered load and duration, and returning the +measured loss count. + +Second group consists of load related arguments required for measurer to +work correctly, typically minimal and maximal load to offer. Also, +target loss ratio (if not hardcoded) is a required argument. + +Third group consists of time related arguments. Typically the duration +for the first trial measurement, duration increment per subsequent trial +measurement and total time for search. Some PLRsearch implementation may +use estimation accuracy parameters as an exit condition instead of total +search time. + +The returned quantities should describe the final (or best) estimate of +critical load. Implementers can chose any description that suits their +users, typically it is average and standard deviation, or lower and +upper boundary. + +## Main Ideas + +The search tries to perform measurements at offered load close to the +critical load, because measurement results at offered loads far from the +critical load give less information on precise location of the critical +load. As virtually every trial measurement result alters the estimate of +the critical load, offered loads vary as they approach the critical +load. + +PLRsearch uses Bayesian Inference, computed using numerical integration, +which takes long time to get reliable enough results. Therefore it takes +some time before the most recent measurement result starts affecting +subsequent offered loads and critical rate estimates. + +During the search, PLRsearch spawns few processes that perform numerical +computations, the main process is calling the measurer to perform trial +measurements, without any significant delays between them. The durations +of the trial measurements are increasing linearly, as higher number of +trial measurement results take longer to process. + +## Probabilistic Notions + +Before internals of PLRsearch are described, we need to define notions +valid for situations when loss ratio is not entirely determined by +offered load. + +Some of the notions already incorporate assumptions the PLRsearch +algorithm applies. + +### Loss Count Only + +It is assumed that the traffic generator detects duplicate packets on +receive, and reports this as an error. + +No latency (or other information) is taken into account. + +### Independent Trials + +PLRsearch still assumes the system under test can be subjected to trial +measurements. The loss count is no longer determined precisely, but it +is assumed that for every system under test, its configuration, traffic +type and trial duration, there is a probability distribution over +possible loss counts. + +This implies trial measurements are probabilistic, but the distribution +is independent of possible previous trial measurements. + +Independence from previous measurements is not guaranteed in the real +world. The previous measurements may improve performance (via long-term +warmup effects), or decrease performance (due to long-term resource +leaks). + +### Trial Durations + +[RFC2544] motivates the usage of at least 60 second duration by the idea +of the system under test slowly running out of resources (such as memory +buffers). + +Practical results when measuring NFV software systems show that relative +change of trial duration has negligible effects on average loss ratio, +compared to relative change in offered load. + +While the standard deviation of loss ratio usually shows some effects of +trial duration, they are hard to model; so further assumtions in +PLRsearch will make it insensitive to trial duration. + +### Target Loss Ratio + +Loss ratio function could be used to generalize throughput as the +biggest offered load which still leads to zero average loss ratio. +Unfortunately, most realistic loss ratio functions always predict non- +zero (even if negligible) average loss ratio. + +On the other hand, users do not really require the average loss ratio to +be an exact zero. Most users are satisfied when the average loss ratio +is small enough. + +One of PLRsearch inputs is called target loss ratio. It is the loss +ratio users would accept as negligible. + +(TODO: Link to why we think 1e-7 is acceptable loss ratio.) + +### Critical Load + +Critical load (sometimes called critical rate) is the offered load which +leads to average loss ratio to become exactly equal to the target loss +ratio. + +In principle, there could be such loss ratio functions which allow more +than one offered load to achieve target loss ratio. To avoid that, +PLRsearch assumes only increasing loss ratio functions are possible. + +Similarly, some loss ratio functions may never return the target loss +ratio. PLRsearch assumes loss ratio function is continuous, that the +average loss ratio approaches zero as offered load approaches zero, and +that the average loss ratio approaches one as offered load approaches +infinity. + +Under these assumptions, each loss ratio function has unique critical +load. PLRsearch attempts to locate the critical load. + +### Load Regions + +Critical region is the interval of offered load close to critical load, +where single measurement is not likely to distinguish whether the +critical load is higher or lower than the current offered load. + +In typical case of small target loss ratio, rates below critical region +form "zero loss region", and rates above form "high loss region". + +### Finite Models + +Of course, finite amount of trial measurements, each of finite duration +does not give enough information to pinpoint the critical load exactly. +Therefore the output of PLRsearch is just an estimate with some +precision. + +Aside of the usual substitution of infinitely precise real numbers by +finitely precise floating point numbers, there are two other instances +within PLRsearch where an objects of high information are replaced by +objects of low information. + +One is the probability distribution of loss count, which is replaced by +average loss ratio. The other is the loss ratio function, which is +replaced by a few parameters, to be described later. + +## PLRsearch Building Blocks + +Here we define notions used by PLRsearch which are not applicable to +other search methods, nor probabilistic systems under test, in general. + +### Bayesian Inference + +Having reduced the model space significantly, the task of estimating the +critical load becomes simple enough so that Bayesian inference can be +used (instead of neural networks, or other Artifical Intelligence +methods). + +In this case, the few parameters describing the loss ration function +become the model space. Given a prior over the model space, and trial +duration results, a posterior distribution can be computed, together +with quantities describing the critical load estimate. + +### Iterative Search + +The idea PLRsearch is to iterate trial measurements, using Bayesian +inference to compute both the current estimate of the critical load and +the next offered load to measure at. + +The required numerical computations are done in parallel with the trial +measurements. + +This means the result of measurement "n" comes as an (additional) input +to the computation running in parallel with measurement "n+1", and the +outputs of the computation are used for determining the offered load for +measurement "n+2". + +Other schemes are possible, aimed to increase the number of measurements +(by decreasing their duration), which would have even higher number of +measurements run before a result of a measurement affects offered load. + +### Poisson Distribution + +For given offered load, number of packets lost during trial measurement +is assumed to come from Poisson distribution, and the (unknown) Poisson +parameter is expressed as average loss ratio. + +Side note: Binomial Distribution is a better fit compared to Poisson +distribution (acknowledging that the number of packets lost cannot be +higher than the number of packets offered), but the difference tends to +be relevant only in high loss region. Using Poisson distribution lowers +the impact of measurements in high loss region, thus helping the +algorithm to focus on critical region better. + +### Fitting Functions + +There are great many increasing functions (as candidates for the loss +ratio function). + +To make the space of possible functions more tractable, some other +simplifying assumptions are needed. As the algorithm will be examining +(also) loads very close to the critical load, linear approximation to +the loss rate function around the critical load is important. But as the +search algorithm needs to evaluate the function also far away from the +critical region, the approximate function has to be reasonably behaved +for every positive offered load, specifically it cannot predict non- +positive packet loss ratio. + +Within this document, "fitting function" is the name for such a +reasonably behaved function, which approximates the loss ratio function +well in the critical region. + +### Measurement Impact + +Results from trials far from the critical region are likely to affect +the critical rate estimate negatively, as the fitting function does not +need to be a good approximation there. This is true mainly for high loss +region, as in zero loss region even badly behaved fitting function +predicts loss count to be "almost zero", so seeing a measurement +confirming the loss has been zero indeed has small impact. + +Discarding some results, or "suppressing" their impact with ad-hoc +methods (other than using Poisson distribution instead of binomial) is +not used, as such methods tend to make the overall search unstable. We +rely on most of measurements being done (eventually) within the critical +region, and overweighting far-off measurements (eventually) for well- +behaved fitting functions. + +Speaking about new trials, each next trial will be done at offered load +equal to the current average of the critical load. Alternative methods +for selecting offered load might be used, in an attempt to speed up +convergence. For example by employing the aforementioned unstable ad-hoc +methods. + +### Fitting Function Coefficients Distribution + +To accomodate systems with different behaviours, the fitting function is +expected to have few numeric parameters affecting its shape (mainly +affecting the linear approximation in the critical region). + +The general search algorithm can use whatever increasing fitting +function, some specific functions can described later. + +It is up to implementer to chose a fitting function and prior +distribution of its parameters. The rest of this document assumes each +parameter is independently and uniformly distributed over a common +interval. Implementers are to add non-linear transformations into their +fitting functions if their prior is different. + +Exit condition for the search is either the standard deviation of the +critical load estimate becoming small enough (or similar), or overal +search time becoming long enough. + +The algorithm should report both average and standard deviation for its +critical load posterior. If the reported averages follow a trend +(without reaching equilibrium), average and standard deviation should +refer to the equilibrium estimates based on the trend, not to immediate +posterior values. + +### Integration + +The posterior distributions for fitting function parameters will not be +integrable in general. + +The search algorithm utilises the fact that trial measurement takes some +time, so this time can be used for numeric integration (using suitable +method, such as Monte Carlo) to achieve sufficient precision. + +### Optimizations + +After enough trials, the posterior distribution will be concentrated in +a narrow area of the parameter space. The integration method should take +advantage of that. + +Even in the concentrated area, the likelihood can be quite small, so the +integration algorithm should avoid underflow errors by some means, +for example by tracking the logarithm of the likelihood. + +# Sample Implementation Specifics: FD.io CSIT + +The search receives min_rate and max_rate values, to avoid measurements +at offered loads not supporeted by the traffic generator. + +The implemented tests cases use bidirectional traffic. The algorithm +stores each rate as bidirectional rate (internally, the algorithm is +agnostic to flows and directions, it only cares about overall counts of +packets sent and packets lost), but debug output from traffic generator +lists unidirectional values. + +## Measurement Delay + +In a sample implemenation in FD.io CSIT project, there is roughly 0.5 +second delay between trials due to restrictons imposed by packet traffic +generator in use (T-Rex). + +As measurements results come in, posterior distribution computation +takes more time (per sample), although there is a considerable constant +part (mostly for inverting the fitting functions). + +Also, the integrator needs a fair amount of samples to reach the region +the posterior distribution is concentrated at. + +And of course, speed of the integrator depends on computing power of the +CPU the algorithm is able to use. + +All those timing related effects are addressed by arithmetically +increasing trial durations with configurable coefficients (currently 5.1 +seconds for the first trial, each subsequent trial being 0.1 second +longer). + +## Rounding Errors and Underflows + +In order to avoid them, the current implementation tracks natural +logarithm (instead of the original quantity) for any quantity which is +never negative. Logarithm of zero is minus infinity (not supported by +Python), so special value "None" is used instead. Specific functions for +frequent operations (such as "logarithm of sum of exponentials") are +defined to handle None correctly. + +## Fitting Functions + +Current implementation uses two fitting functions. In general, their +estimates for critical rate differ, which adds a simple source of +systematic error, on top of randomness error reported by integrator. +Otherwise the reported stdev of critical rate estimate is +unrealistically low. + +Both functions are not only increasing, but also convex (meaning the +rate of increase is also increasing). + +As Primitive Function to any positive function is an increasing +function, and Primitive Function to any increasing function is convex +function; both fitting functions were constructed as double Primitive +Function to a positive function (even though the intermediate increasing +function is easier to describe). + +As not any function is integrable, some more realistic functions +(especially with respect to behavior at very small offered loads) are +not easily available. + +Both fitting functions have a "central point" and a "spread", varied by +simply shifting and scaling (in x-axis, the offered load direction) the +function to be doubly integrated. Scaling in y-axis (the loss rate +direction) is fixed by the requirement of transfer rate staying nearly +constant in very high offered loads. + +In both fitting functions (as they are a double Primitive Function to a +symmetric function), the "central point" turns out to be equal to the +aforementioned limiting transfer rate, so the fitting function parameter +is named "mrr", the same quantity our Maximum Receive Rate tests are +designed to measure. + +Both fitting functions return logarithm of loss rate, to avoid rounding +errors and underflows. Parameters and offered load are not given as +logarithms, as they are not expected to be extreme, and the formulas are +simpler that way. + +Both fitting functions have several mathematically equivalent formulas, +each can lead to an overflow or underflow in different places. Overflows +can be eliminated by using different exact formulas for different +argument ranges. Underflows can be avoided by using approximate formulas +in affected argument ranges, such ranges have their own formulas to +compute. At the end, both fitting function implementations contain +multiple "if" branches, discontinuities are a possibility at range +boundaries. + +Offered load for next trial measurement is the average of critical rate +estimate. During each measurement, two estimates are computed, even +though only one (in alternating order) is used for next offered load. + +### Stretch Function + +The original function (before applying logarithm) is Primitive Function +to Logistic Function. The name "stretch" is used for related a function +in context of neural networks with sigmoid activation function. + +Formula for stretch function: loss rate (r) computed from offered load +(b), mrr parameter (m) and spread parameter (a): + +r = a (Log(E^(b/a) + E^(m/a)) - Log(1 + E^(m/a))) + +### Erf Function + +The original function is double Primitive Function to Gaussian Function. +The name "erf" comes from error function, the first primitive to +Gaussian. + +Formula for erf function: loss rate (r) computed from offered load (b), +mrr parameter (m) and spread parameter (a): + +r = (b + (a (E^(-((b - m)^2/a^2)) - E^(-(m^2/a^2))))/Sqrt(Pi) + (b - m) Erf((b - m)/a) - m Erf(m/a))/2 + +## Prior Distributions + +The numeric integrator expects all the parameters to be distributed +(independently and) uniformly on an interval (-1, 1). + +As both "mrr" and "spread" parameters are positive and not not +dimensionless, a transformation is needed. Dimentionality is inherited +from max_rate value. + +The "mrr" parameter follows a Lomax Distribution with alpha equal to +one, but shifted so that mrr is always greater than 1 packet per second. + +The "stretch" parameter is generated simply as the "mrr" value raised to +a random power between zero and one; thus it follows a Reciprocal +Distribution. + +## Integrator + +After few measurements, the posterior distribution of fitting function +arguments gets quite concentrated into a small area. The integrator is +using Monte Carlo with Importance Sampling where the biased distribution +is Bivariate Gaussian distribution, with deliberately larger variance. +If the generated sample falls outside (-1, 1) interval, another sample +is generated. + +The the center and the covariance matrix for the biased distribution is +based on the first and second moments of samples seen so far (within the +computation), with the following additional features designed to avoid +hyper-focused distributions. + +Each computation starts with the biased distribution inherited from the +previous computation (zero point and unit covariance matrix is used in +the first computation), but the overal weight of the data is set to the +weight of the first sample of the computation. Also, the center is set +to the first sample point. When additional samples come, their weight +(including the importance correction) is compared to the weight of data +seen so far (within the computation). If the new sample is more than one +e-fold more impactful, both weight values (for data so far and for the +new sample) are set to (geometric) average if the two weights. Finally, +the actual sample generator uses covariance matrix scaled up by a +configurable factor (8.0 by default). + +This combination showed the best behavior, as the integrator usually +follows two phases. First phase (where inherited biased distribution or +single big sasmples are dominating) is mainly important for locating the +new area the posterior distribution is concentrated at. The second phase +(dominated by whole sample population) is actually relevant for the +critical rate estimation. + +# IANA Considerations + +.. + +# Security Considerations + +.. + +# Acknowledgements + +.. + +--- back
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