Fixes up to TTFB plot
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title="Bringing theoretical design and observed performances face to face"
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title="Confronting theoretical design with observed performances"
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date=2022-09-26
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+++
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*For the past years, we have extensively analyzed possible design decisions and
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their theoretical tradeoffs on Garage, especially on the network, data
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structure, or scheduling side. And it worked well enough for our production
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cluster at Deuxfleurs, but we also knew that people started discovering some
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*During the past years, we have extensively analyzed possible design decisions and
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their theoretical trade-offs for Garage, especially concerning networking, data
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structures, and scheduling. Garage worked well enough for our production
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cluster at Deuxfleurs, but we also knew that people started to discover some
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unexpected behaviors. We thus started a round of benchmark and performance
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measurements to see how Garage behaves compared to our expectations. We split
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them into 3 categories: "efficient I/O", "myriads of objects" and "resiliency"
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measurements to see how Garage behaves compared to our expectations.
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This post presents some of our first results, which cover
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3 aspects of performance: efficient I/O, "myriads of objects" and resiliency,
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to reflect the high-level properties we are seeking.*
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<!-- more -->
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@ -21,61 +22,63 @@ to reflect the high-level properties we are seeking.*
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The following results must be taken with a critical grain of salt due to some
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limitations that are inherent to any benchmark. We try to reference them as
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exhaustively as possible in this section, but other limitations might exist.
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exhaustively as possible in this first section, but other limitations might exist.
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Most of our tests are done on simulated networks that can not represent all the
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diversity of real networks (dynamic drop, jitter, latency, all of them could be
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Most of our tests were made on simulated networks, which by definition cannot represent all the
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diversity of real networks (dynamic drop, jitter, latency, all of which could be
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correlated with throughput or any other external event). We also limited
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ourselves to very small workloads that are not representative of a production
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cluster. Furthermore, we only benchmarked some very specific aspects of Garage:
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our results are thus not an overview of the whole software performance.
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our results are thus not an evaluation of the performance of Garage as a whole.
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For some benchmarks, we used Minio as a reference. It must be noted that we did
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not try to optimize its configuration as we have done on Garage, and more
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generally, we have way less knowledge on Minio than on Garage, which can lead
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to underrated performance measurements for Minio. It must also be noted that
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Garage and Minio are systems with different feature sets, *eg.* Minio supports
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erasure coding for better data density while Garage doesn't, Minio implements
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way more S3 endpoints than Garage, etc. Such features have necessarily a cost
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that you must keep in mind when reading plots. You should consider Minio
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results as a way to contextualize our results, to check that our improvements
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are not artificials compared to existing object storage implementations.
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Garage and Minio are systems with different feature sets. For instance Minio supports
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erasure coding for higher data density, which Garage doesn't, Minio implements
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way more S3 endpoints than Garage, etc. Such features necessarily have a cost
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that you must keep in mind when reading the plots we will present. You should consider
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results on Minio as a way to contextualize our results on Garage, to see that our improvements
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are not artificial compared to existing object storage implementations.
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The impact of the testing environment is also not evaluated (kernel patches,
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configuration, parameters, filesystem, hardware configuration, etc.), some of
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these configurations could favor one configuration/software over another.
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configuration, parameters, filesystem, hardware configuration, etc.). Some of
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these parameters could favor one configuration or software product over another.
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Especially, it must be noted that most of the tests were done on a
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consumer-grade computer and SSD only, which will be different from most
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consumer-grade PC with only an SSD, which is different from most
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production setups. Finally, our results are also provided without statistical
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tests to check their significance, and thus might be statistically not
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significant.
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tests to check their significance, and might thus have insufficient significance
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to be claimed as reliable.
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When reading this post, please keep in mind that **we are not making any
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business or technical recommendations here, this is not a scientific paper
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business or technical recommendations here, and this is not a scientific paper
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either**; we only share bits of our development process as honestly as
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possible. Read [benchmarking crimes](https://gernot-heiser.org/benchmarking-crimes.html),
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make your own
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tests if you need to take a decision, and remain supportive and caring with
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your peers...
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possible.
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Make your own tests if you need to take a decision,
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remember to read [benchmarking crimes](https://gernot-heiser.org/benchmarking-crimes.html)
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and to remain supportive and caring with your peers ;)
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## About our testing environment
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We started a batch of tests on
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We made a first batch of tests on
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[Grid5000](https://www.grid5000.fr/w/Grid5000:Home), a large-scale and flexible
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testbed for experiment-driven research in all areas of computer science, under
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the [Open Access](https://www.grid5000.fr/w/Grid5000:Open-Access) program.
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testbed for experiment-driven research in all areas of computer science,
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which has an
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[Open Access program](https://www.grid5000.fr/w/Grid5000:Open-Access).
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During our tests, we used part of the following clusters:
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[nova](https://www.grid5000.fr/w/Lyon:Hardware#nova),
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[paravance](https://www.grid5000.fr/w/Rennes:Hardware#paravance), and
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[econome](https://www.grid5000.fr/w/Nantes:Hardware#econome) to make a
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[econome](https://www.grid5000.fr/w/Nantes:Hardware#econome), to make a
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geo-distributed topology. We used the Grid5000 testbed only during our
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preliminary tests to identify issues when running Garage on many powerful
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servers, issues that we then reproduced in a controlled environment; don't be
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servers. We then reproduced these issues in a controlled environment
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outside of Grid5000, so don't be
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surprised then if Grid5000 is not mentioned often on our plots.
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To reproduce some environments locally, we have a small set of Python scripts
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named [mknet](https://git.deuxfleurs.fr/Deuxfleurs/mknet) tailored to our
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needs[^ref1]. Most of the following tests were thus run locally with mknet on a
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called [`mknet`](https://git.deuxfleurs.fr/Deuxfleurs/mknet) tailored to our
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needs[^ref1]. Most of the following tests were thus run locally with `mknet` on a
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single computer: a Dell Inspiron 27" 7775 AIO, with a Ryzen 5 1400, 16GB of
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RAM, a 512GB SSD. In terms of software, NixOS 22.05 with the 5.15.50 kernel is
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used with an ext4 encrypted filesystem. The `vm.dirty_background_ratio` and
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@ -84,24 +87,27 @@ values, the system tends to freeze when it is under heavy I/O load.
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## Efficient I/O
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The main goal of an object storage system is to store or retrieve an object
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across the network, and the faster, the better. For this analysis, we focus on
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2 aspects: time to first byte, as many applications can start processing a file
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before receiving it completely, and generic throughput, to understand how well
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Garage can leverage the underlying machine performances.
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The main purpose of an object storage system is to store and retrieve objects
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across the network, and the faster these two functions can be accomplished,
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the more efficient the system as a whole will be. For this analysis, we focus on
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2 aspects of performance. First, since many applications can start processing a file
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before receiving it completely, we will evaulate the Time-to-First-Byte (TTFB)
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on GetObject requests, i.e. the duration between the moment a request is sent
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and the moment where the first bytes of the returned object are received by the client.
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Second, we will evaluate generic throughput, to understand how well
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Garage can leverage the underlying machine's performances.
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**Time To First Byte** - One specificity of Garage is that we implemented S3
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web endpoints, with the idea to make it the platform of choice to publish your
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static website. When publishing a website, one metric you observe is Time To
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First Byte (TTFB), as it will impact the perceived reactivity of your website.
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On Garage, time to first byte was a bit high.
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web endpoints, with the idea to make it a platform of choice to publish
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static websites. When publishing a website, TTFB can be directly observed
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by the end user, as it will impact the perceived reactivity of the websites.
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This is not surprising as, until now, the smallest level of granularity
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internally was handling full blocks. Blocks are 1MB chunks (this is
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[configurable](https://garagehq.deuxfleurs.fr/documentation/reference-manual/configuration/#block-size))
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of a given object. For example, a 4.5MB object will be split into 4 blocks of
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1MB and 1 block of 0.5MB. With this design, when you were sending a GET
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Up to version 0.7.3, Time-to-First-Byte on Garage used to be relatively high.
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This can be explained by the fact that Garage was not able to handle data internally
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at a smaller granularity level than entire data blocks, which are 1MB chunks of a given object
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(this is [configurable](https://garagehq.deuxfleurs.fr/documentation/reference-manual/configuration/#block-size)).
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Let us take the example of a 4.5MB object, which Garage will split into 4 blocks of
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1MB and 1 block of 0.5MB. With the old design, when you were sending a `GET`
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request, the first block had to be fully retrieved by the gateway node from the
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storage node before starting to send any data to the client.
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@ -109,20 +115,24 @@ With Garage v0.8, we integrated a block streaming logic that allows the gateway
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to send the beginning of a block without having to wait for the full block from
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the storage node. We can visually represent the difference as follow:
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<center>
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<img src="schema-streaming.png" alt="A schema depicting how streaming improves the delivery of a block" />
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</center>
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As our default block size is only 1MB, the difference will be very small on
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fast networks: it takes only 8ms to transfer 1MB on a 1Gbps network. However,
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on a very slow network (or a very congested link with many parallel requests
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handled), the impact can be much more important: at 5Mbps, it takes 1.6 seconds
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to transfer our 1MB block, and streaming could heavily improve user experience.
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As our default block size is only 1MB, the difference should be very small on
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fast networks: it takes only 8ms to transfer 1MB on a 1Gbps network,
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thus adding at most 8ms of latency to a GetObject request (assuming no other
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data transfer is happening in parallel). However,
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on a very slow network, or a very congested link with many parallel requests
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handled, the impact can be much more important: on a 5Mbps network, it takes 1.6 seconds
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to transfer our 1MB block, and streaming has the potential of heavily improving user experience.
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We wanted to see if this theory holds in practice: we simulated a low latency
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but slow network on mknet and did some requests with (garage v0.8 beta) and
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without (garage v0.7) block streaming. We also added Minio as a reference. To
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but slow network using `mknet` and did some requests with block streaming (Garage v0.8 beta) and
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without (Garage v0.7.3). We also added Minio as a reference. To
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benchmark this behavior, we wrote a small test named
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[s3ttfb](https://git.deuxfleurs.fr/Deuxfleurs/mknet/src/branch/main/benchmarks/s3ttfb),
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its results are depicted in the following figure.
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whose results are shown on the following figure:
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@ -42,7 +42,7 @@
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</div>
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<div class="content mt-2">
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<div class="text-gray-700 text-lg not-italic">
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{{ page.summary | safe | striptags }}
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{{ page.summary | striptags | safe }}
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</div>
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<a class="group font-semibold p-4 flex items-center space-x-1 text-garage-orange" href='{{ page.permalink }}'>
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<div class="h-0.5 mt-0.5 w-4 group-hover:w-8 group-hover:bg-garage-gray transition-all bg-garage-orange"></div>
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