This is a tool for managing Chia plotting operations. The tool runs on the plotting machine and provides the following functionality:
-
Automatic spawning of new plotting jobs, possibly overlapping ("staggered") on multiple temp directories, rate-limited globally and by per-temp-dir limits.
-
Rsync'ing of newly generated plots to a remote host (a farmer/harvester), called "archiving".
-
Monitoring of ongoing plotting and archiving jobs, progress, resources used, temp files, etc.
-
Control of ongoing plotting jobs (suspend, resume, plus kill and clean up temp files).
-
Both an interactive live dashboard mode as well as command line mode tools.
-
(very alpha) Analyzing performance statistics of past jobs, to aggregate on various plotting parameters or temp dir type.
Plotman is designed for the following configuration:
-
A plotting machine with an array of
tmp
dirs, a singletmp2
dir, and an array ofdst
dirs to which the plot jobs plot. Thedst
dirs serve as a temporary buffer space for generated plots. -
A farming machine with a large number of drives, made accessible via an
rsyncd
module, and to be entirely populated with plots. These are known as thearchive
directories. -
Plot jobs are run with STDOUT/STDERR redirected to a log file in a configured directory. This allows analysis of progress (plot phase) as well as timing (e.g. for analyzing performance).
Plotman tools are stateless. Rather than keep an internal record of what jobs have been started, Plotman relies on the process tables, open files, and logfiles of plot jobs to understand "what's going on". This means the tools can be stopped and started, even from a different login session, without loss of information. It also means Plotman can see and manage jobs started manually or by other tools, as long as their STDOUT/STDERR redirected to a file in a known logfile directory. (Note: The tool relies on reading the chia plot command line arguments and the format of the plot tool output. Changes in those may break this tool.)
Plot scheduling is done by waiting for a certain amount of wall time since the
last job was started, finding the best (e.g. least recently used) tmp
dir for
plotting, and ensuring that job has progressed to at least a certain point
(e.g., phase 2, subphase 5).
Plots are output to the dst
dirs, which serve as a temporary buffer until they
are rsync'd ("archived") to the farmer/harvester. The archiver does several
things to attempt to avoid concurrent IO. First, it only allows one rsync
process at a time (more sophisticated scheduling could remove this
restriction, but it's nontrivial). Second, it inspects the pipeline of plot
jobs to see which dst
dirs are about to have plots written to them. This
is balanced against how full the dst
drives are in a priority scheme.
It is, obviously, necessary that your rsync bandwidth exceeds your plotting
bandwidth. Given this, in normal operation, the dst
dirs remain empty until
a plot is finished, after which it is shortly thereafter picked up by the
archive job. However, the decoupling provided by using dst
drives as a
buffer means that should the farmer/harvester or the network become
unavailable, plotting continues uninterrupted.
Plotman 19:01:06 (refresh 9s/20s) | Plotting: stagger (1623s/1800s) Archival: active pid 1599918
Prefixes: tmp=/mnt/tmp dst=/home/chia/chia/plots archive=/plots (remote)
# plot id k tmp dst wall phase tmp pid stat mem user sys io
0 6b4e7375... 32 03 001 0:27 1:2 71G 1590196 SLP 5.5G 0:52 0:02 0s
1 9ab50d0e... 32 02 005 1:00 1:4 199G 1539209 SLP 5.5G 3:50 0:09 0s
2 018cf561... 32 01 000 1:32 1:5 224G 1530045 SLP 5.5G 4:46 0:11 2s
3 f771de9c... 32 00 004 2:03 1:5 241G 1524772 SLP 5.5G 5:43 0:14 2s
...
16 58045bef... 32 10 002 11:23 3:5 193G 1381622 RUN 5.4G 15:02 0:53 0:02
17 8134a2dd... 32 11 003 11:55 3:6 148G 1372206 RUN 5.4G 15:27 0:57 0:03
18 50165422... 32 08 001 12:43 3:6 102G 1357782 RUN 5.4G 16:14 1:00 0:03
19 100df84f... 32 09 005 13:19 4:0 0 1347430 DSK 705.9M 16:44 1:04 0:06
tmp ready phases tmp ready phases dst plots GB free phases priority
00 -- 1:5, 3:4 06 -- 2:4 000 1 1890 1:5, 2:2, 3:4 47
01 -- 1:5, 3:4 07 -- 2:2 001 0 1998 1:2, 1:7, 3:2, 3:6 34
02 -- 1:4, 3:3 08 -- 1:7, 3:6 002 0 1967 1:6, 2:5, 3:5 42
03 -- 1:2, 3:2 09 -- 2:1, 4:0 003 0 1998 1:6, 3:1, 3:6 34
04 OK 3:1 10 -- 1:6, 3:5 004 0 1998 1:5, 2:4, 3:4 46
05 OK 2:5 11 -- 1:6, 3:6 005 0 1955 1:4, 2:1, 3:3, 4:0 18
Archive dirs free space
000: 94GB | 005: 94GB | 012: 24GB | 017: 99GB | 022: 94GB | 027: 94GB | 032: 9998GB | 037: 9998GB
001: 94GB | 006: 93GB | 013: 25GB | 018: 94GB | 023: 94GB | 028: 94GB | 033: 9998GB |
002: 93GB | 009: 25GB | 014: 93GB | 019: 31GB | 024: 94GB | 029: 7777GB | 034: 9998GB |
003: 94GB | 010: 25GB | 015: 94GB | 020: 47GB | 025: 94GB | 030: 9998GB | 035: 9998GB |
004: 94GB | 011: 25GB | 016: 99GB | 021: 93GB | 026: 94GB | 031: 9998GB | 036: 9998GB |
Log:
01-02 18:33:53 Starting plot job: chia plots create -k 32 -r 8 -u 128 -b 4580 -t /mnt/tmp/03 -2 /mnt/tmp/a -d /home/chi
01-02 18:33:53 Starting archive: rsync --bwlimit=100000 --remove-source-files -P /home/chia/chia/plots/004/plot-k32-202
01-02 18:52:40 Starting archive: rsync --bwlimit=100000 --remove-source-files -P /home/chia/chia/plots/000/plot-k32-202
The screenshot shows some of the main features of Plotman.
The first line shows the status. The plotting status shows whether we just
started a plot, or, if not, why not (e.g., stagger time, tmp directories being
ready, etc.; in this case, the 1800s stagger between plots has not been reached
yet). Archival status says whether we are currently archiving (and provides
the rsync
pid) or whether there are no plots available in the dst
drives to
archive.
The second line provides a key to some directory abbrevations used throughout.
For tmp
and dst
directories, we assume they have a common prefix, which is
computed and indicated here, after which they can be referred to (in context)
by their unique suffix. For example, if we have tmp
dirs /mnt/tmp/00
,
/mnt/tmp/01
, /mnt/tmp/02
, etc., we show /mnt/tmp
as the prefix here and
can then talk about tmp
dirs 00
or 01
etc. The archive
directories are
the same except that these are paths on a remote host and accessed via an
rsyncd
module (see src/plotman/resources/plotman.yaml
for details).
The next table shows information about the active plotting jobs. It is
abbreviated to show the most and least recently started jobs (the full list is
available via the command line mode). It shows various information about the
plot jobs, including the plot ID (first 8 chars), the directories used,
walltime, the current plot phase and subphase, space used on the tmp
drive,
pid, etc.
The next tables are a bit hard to read; there is actually a tmp
table on the
left which is split into two tables for rendering purposes, and a dst
table
on the right. The tmp
tables show the phases of the plotting jobs using
them, and whether or not they're ready to take a new plot job. The dst
table
shows how many plots have accumulated, how much free space is left, and the
phases of jobs that are destined to write to them, and finally, the priority
computed for the archive job to move the plots away.
The last table simply shows free space of drives on the remote harverster/farmer.
Finally, the last section shows a log of actions performed -- namely, plot and archive jobs initiated. This is the one part of the interactive tool which is stateful. There is no permanent record of these executed command lines, so if you start a new interactive plotman session, this log is empty.
The system is tested on Linux only. Plotman should be generalizable to other
platforms, but this is not done yet. Some of the issues around making calls
out to command line programs (e.g., running df
over ssh
to obtain the free
space on the remote archive directories) are very linux-y.
The interactive mode uses the curses
library ... poorly. Keypresses are
not received, screen resizing does not work, and the minimum terminal size
is pretty big.
Plotman assumes all plots are k32s. Again, this is just an unimplemented generalization.
Many features are inconsistently supported between either the "interactive" mode or the command line mode.
There are many bugs and TODOs.
Plotman will always look for the plotman.yaml
file within your computer at an OS-based
default location. To generate a default plotman.yaml
, run:
> plotman config generate
To display the current location of your plotman.yaml
file and check if it exists, run:
> plotman config path
(See also).
Installation for Linux and macOS:
- Plotman assumes that a functioning Chia
installation is present on the system.
- virtual environment (Linux, macOS): Activate your
chia
environment by typingsource /path/to/your/chia/install/activate
. - dmg (macOS): Follow these instructions
to add the
chia
binary to thePATH
- virtual environment (Linux, macOS): Activate your
- Then, install Plotman using the following command:
> pip install --force-reinstall git+https://github.com/ericaltendorf/plotman@main
- Plotman will look for
plotman.yaml
within your computer at an OS-based default location. To create a defaultplotman.yaml
and display its location, run the following command:The default configuration file used as a starting point is located here> plotman config generate
- That's it! You can now run Plotman by typing
plotman version
to verify its version. Runplotman --help
to learn about the available commands.
Note: If you see ModuleNotFoundError: No module named 'readline'
when using plotman
on RHEL based linux after installing using chia's guide, install readline-devel
then reinstall chia starting at compiling python in a new build environment; or consider using a project like pyenv
.
-
Install
-
Generate initial config
-
Configure (default location can be found with
plotman config path
). Options explained in the default config file (step 2) -
Create log directory specified in
directories: { log: "" }
-
Start plotman:
plotman plot
orplotman interactive
-
Check status:
plotman status
If you are forking Plotman, simply replace the installation step with pip install --editable .[dev]
from the project root directory to install your version of plotman with test and development extras.