From: Brian Warner Date: Wed, 24 Feb 2010 04:38:13 +0000 (-0500) Subject: docs/performance.txt: split out CPU from network, expand on mutable costs X-Git-Url: https://git.rkrishnan.org/simplejson/using.html?a=commitdiff_plain;h=8ba536319689ec8edd11b1612fa5083be6c37c0e;p=tahoe-lafs%2Ftahoe-lafs.git docs/performance.txt: split out CPU from network, expand on mutable costs --- diff --git a/docs/performance.txt b/docs/performance.txt index c5b4d9e4..03cf235d 100644 --- a/docs/performance.txt +++ b/docs/performance.txt @@ -2,7 +2,8 @@ === Publishing an A-byte immutable file === -cost: O(A) +network: A +memory footprint: N/k*128KiB notes: An immutable file upload requires an additional I/O pass over the entire source file before the upload process can start, since convergent @@ -11,7 +12,9 @@ notes: An immutable file upload requires an additional I/O pass over the entire === Publishing an A-byte mutable file === -cost: O(A) + a large constant for RSA + memory usage. +network: A +memory footprint: N/k*A +cpu: O(A) + a large constant for RSA keypair generation notes: Tahoe-LAFS generates a new RSA keypair for each mutable file that it publishes to a grid. This takes up to 1 or 2 seconds on a @@ -25,8 +28,8 @@ notes: Tahoe-LAFS generates a new RSA keypair for each mutable file that === Downloading B bytes of an A-byte immutable file === -time/cost until the read is satisfied: variable; up to O(A). -cost of the entire operation: O(A) if the file isn't cached. +network: A +memory footprint: 128KiB notes: When asked to read an arbitrary range of an immutable file, Tahoe-LAFS will download from the beginning of the file up until @@ -47,7 +50,8 @@ notes: When asked to read an arbitrary range of an immutable file, === Downloading B bytes of an A-byte mutable file === -cost: O(A) +network: A +memory footprint: N/k*A notes: As currently implemented, mutable files must be downloaded in their entirety before any part of them can be read. We are @@ -55,7 +59,8 @@ notes: As currently implemented, mutable files must be downloaded in === Modifying B bytes of an A-byte mutable file === -cost: O(A) +network: A +memory footprint: N/k*A notes: If you upload a changed version of a mutable file that you earlier put onto your grid with, say, 'tahoe put --mutable', @@ -65,51 +70,54 @@ notes: If you upload a changed version of a mutable file that you essentially uploading the file over again, except that it re-uses the existing RSA keypair instead of generating a new one. -=== Adding/Removing B bytes in an A-byte mutable file === +=== Inserting/Removing B bytes in an A-byte mutable file === -cost: O(A) +network: A +memory footprint: N/k*A notes: Modifying any part of a mutable file in Tahoe-LAFS requires that - the entire file be downloaded, modified, held in memory while it - is encrypted and encoded, and then re-uploaded. Note that this - sort of modification is mostly used internally for directories, - and isn't something that the WUI, CLI, or other interfaces will - do -- instead, they will simply overwrite the file to be - modified, as described in "Modifying B bytes of an A-byte mutable + the entire file be downloaded, modified, held in memory while it is + encrypted and encoded, and then re-uploaded. A future version of the + mutable file layout ("LDMF") may provide efficient inserts and + deletes. Note that this sort of modification is mostly used internally + for directories, and isn't something that the WUI, CLI, or other + interfaces will do -- instead, they will simply overwrite the file to + be modified, as described in "Modifying B bytes of an A-byte mutable file". === Adding an entry to an A-entry directory === -cost: O(A) (roughly) +network: O(A) +memory footprint: N/k*A + notes: In Tahoe-LAFS, directories are implemented as specialized mutable files. So adding an entry to a directory is essentially adding B (actually, 300-330) bytes somewhere in an existing mutable file. === Listing an A entry directory === -cost: O(A) +network: O(A) +memory footprint: N/k*A notes: Listing a directory requires that the mutable file storing the directory be downloaded from the grid. So listing an A entry directory requires downloading a (roughly) 330 * A byte mutable file, since each directory entry is about 300-330 bytes in size. -=== Checking an A-byte file === +=== Performing a file-check on an A-byte file === -cost: variable; between O(N) and O(S), where N is the number of shares - generated when the file was initially uploaded, and S is the - number of servers on your grid. +network: O(S), where S is the number of servers on your grid +memory footprint: negligible -notes: To check a file, Tahoe-LAFS queries the servers that it knows - about until it either runs out of servers, or finds all of the - shares that were originally uploaded. Note that neither of these - values directly depend on the size of the file. This is - relatively inexpensive, compared to the verify and repair - operations. +notes: To check a file, Tahoe-LAFS queries all the servers that it knows + about. Note that neither of these values directly depend on the size + of the file. This is relatively inexpensive, compared to the verify + and repair operations. -=== Verifying an A-byte file === +=== Performing a file-verify on an A-byte file === -cost: O(A) +network: N/k*A +memory footprint: N/k*128KiB notes: To verify a file, Tahoe-LAFS downloads all of the ciphertext shares that were originally uploaded to the grid and integrity @@ -119,9 +127,10 @@ notes: To verify a file, Tahoe-LAFS downloads all of the ciphertext === Repairing an A-byte file (mutable or immutable) === -cost: variable; up to around O(A) +network: variable; up to around O(A) +memory footprint: from 128KiB to (1+N/k)*128KiB -notes: To repair a file, Tahoe-LAFS generates and uploads missing shares - in the same way as when it initially uploads the file. So, - depending on how many shares are missing, this can be about as +notes: To repair a file, Tahoe-LAFS downloads the file, and generates/uploads + missing shares in the same way as when it initially uploads the file. + So, depending on how many shares are missing, this can be about as expensive as initially uploading the file in the first place.