Commit Graph

9 Commits

Author SHA1 Message Date
Jordan Hrycaj 5d0d44c38f re-named compu_helper.nim => computation.nim
why:
  exports all except one of the original computation.nim functional
  objects
2021-04-28 15:24:14 +03:00
Jordan Hrycaj 77518446d9 shift functions from computation.nim => compu_helper.nim
why:
  insulate exec functions in computation.nim
2021-04-28 15:24:14 +03:00
Jordan Hrycaj ff6921eb1a re-named some v2*.nim sources to its original name *.nim (without the v2)
why:
  the v2 prefix of the file name was used as a visual aid when
  comparing vm2 against vm sources

details:
  all renamed v2*.nim sources compile locally with the -d:kludge:1 flag
  set or without (some work with either)

  only sources not renamed yet: v2state_transactions.nim
2021-04-28 15:24:14 +03:00
Jordan Hrycaj b2ce6d9e70 re-arrange functions from v2computation.nim and interpreter_dispatch.nim
why:
  step towards breaking circular dependency

details:
  some functions from v2computation.nim have been extracted into
  compu_helper.nim which does not explicitly back-import
  v2computation.nim. all non recursive op handlers now import this source
  file rather than v2computation.nim.

  recursive call/create op handler still need to import v2computation.nim.

  the executeOpcodes() function from interpreter_dispatch.nim has been
  moved to v2computation.nim which allows for <import> rather than
  <include> the interpreter_dispatch.nim source.
2021-04-28 15:24:14 +03:00
Jordan Hrycaj e02c6d4c3d renamed computation.nim, memory.nim, utils_numeric.nim, interpreter.nim => v2*.nim
why:
  these files provide part of the externally accessible interface
  provided by vm_cpmputation.nim, vm_internals.nim. so the
  new filename indicates that the source code belongs to vm2 (rather
  than vm).
2021-04-23 14:04:06 +03:00
Jordan Hrycaj b4f8450968 provide identical copy of vm folder => vm2, activated by make flag ENABLE_VM2=1
why:
  vm2 enabled by ENABLE_VM2=1 behaves as vm without ENABLE_EVMC=1 until
  it doesn't in some future fatch set. this leaves some wiggle room
  to work on a vm copy without degrading the original implementation.

details:
  + additional make flag ENABLE_VM2=1 (or ENABLE_VM2=0 to explicitely disable)
  + when both flags ENABLE_EVMC=1 and ENABLE_VM2=1 are present, the former
    flag ENABLE_EVMC=1 takes precedence, this is implemented at the NIM
    compiler level for -d:evmc_enabled and -d:vm2_enabled
2021-04-23 14:04:06 +03:00
Jamie Lokier 8211db1ea8
EVM: Small patch that reduces EVM stack usage to almost nothing
There's been a lot of talk about the Nimbus EVM "stack problem".  I think we
assumed changing it would require big changes to the interpreter code, touching
a lot of functions.

It turned out to be a low hanging fruit.

This patch solves the stack problem, but hardly touches anything.  The change
in EVM stack memory is from 13 MB worst case to just 48 kB, a 250x reduction.

I've been doing work on the database/storage/trie code.  While looking at the
API between the EVM and the database/storage/trie, this stack patch stood out
and made itself obvious.  As it's tiny, rather than more talk, here it is.

Note: This patch is intentionally small, non-invasive, and hopefully easy to
understand, so that it doesn't conflict with other work done on the EVM, and
can easily be grafted into any other EVM structure.

Motivation
==========

- We run out of space and crash on some targets, unless the stack limit is
  raised above its default.  Surprise segmentation faults are unhelpful.

- Some CI targets have been disabled for months due to this.

- Because usage borders on the system limits, when working on
  database/storage/trie/sync code (called from the EVM), segmentation faults
  occur and are misleading.  They cause lost time due to thinking there's a
  crash bug in the code being worked on, when there's nothing wrong with it.

- Sometimes unrelated, trivial code changes elsewhere trigger CI test failures.
  It looks like abrupt termination.  A simple, recent patch was crashing in
  `make test` even though it was a trivial refactor.  Turns out it pushed the
  stack over the edge.

- A large stack has to be scanned by the Nim garbage collector sometimes.
  Larger stack means slower GC and memory allocation.

- The structure of this small patch suggests how to weave async into the EVM
  with almost no changes to the EVM, and no async transformation overhead.

- The patch seemed obvious when working on the API between EVM and storage.

Measurements before
===================

All these tests were run on Ubuntu 20.04 server, x86-64.  This is one of the
targets that has been disabled for a while in CI in EVMC mode due to crashing,
and excessive stack usage is the cause.

Testing commit 0c34a8e3 `2021-04-08 17:46:00 +0200 CI: use MSYS2 on Windows`.

    $ rm -f build/all_tests && make ENABLE_EVMC=1 test
    $ ulimit -S -s 16384 # Requires larger stack than default to avoid crash.
    $ ./build/all_tests 9 | tee tlog
    [Suite] persist block json tests
    ...
	Stack range 38496 depthHigh 3
    ...
    Stack range 13140272 depthHigh 1024
    [OK] tests/fixtures/PersistBlockTests/block1431916.json

These tests use 13.14 MB of stack to run, and so crash with the default stack
limit on Ubuntu Server 20.04 (8MB).  Exactly 12832 bytes per EVM call stack
frame.  It's interesting to see some stack frames take a bit more.

    $ rm -f build/all_tests && make ENABLE_EVMC=1 test
    $ ulimit -S -s 16384 # Requires larger stack than default.
    $ ./build/all_tests 7 | tee tlog
    [Suite] new generalstate json tests
	...
	Stack range 15488 depthHigh 2
	...
	Stack range 3539312 depthHigh 457
    [OK] tests/fixtures/eth_tests/GeneralStateTests/stRandom2/randomStatetest639.json
    ...
	Stack range 3756144 depthHigh 485
    [OK] tests/fixtures/eth_tests/GeneralStateTests/stRandom2/randomStatetest458.json
	...
	Stack range 7929968 depthHigh 1024
     [OK] tests/fixtures/eth_tests/GeneralStateTests/stCreate2/Create2OnDepth1024.json

These tests use 7.92MB of stack to run.  About 7264 bytes per EVM call stack
frame.  It _only just_ avoids crashing with the default Ubuntu Server stack
limit of 8 MB.  However, it still crashes on Windows x86-64, which is why the
CI target is currently disabled.

On Linux where this passes, this is so borderline that it affects work and
testing of storage and sync code, because that's called from the EVM.  Which
was a motivation for dealing with the stack instead of letting this linger.

Also, this stack greatly exceeds the default thread stack size.

    $ rm -f build/all_tests && make ENABLE_EVMC=0 test
    $ ulimit -S -s 16384 # Requires larger stack than default to avoid crash.
    $ ./build/all_tests 9 | tee tlog
    [Suite] persist block json tests
    ...
    Stack range 33216 depthHigh 3
    ...
    Stack range 11338032 depthHigh 1024
    [OK] tests/fixtures/PersistBlockTests/block1431916.json

These tests use 11.33 MB stack to run, and so crash with a default stack limit
of 8MB.  Exactly 11072 bytes per EVM call stack frame.  It's interesting to see
some stack frames take a bit more.

    $ rm -f build/all_tests && make ENABLE_EVMC=0 test
    $ ulimit -S -s 16384 # Requires larger stack than default.
    $ ./build/all_tests 7 | tee tlog
    [Suite] new generalstate json tests
	...
    Stack range 10224 depthHigh 2
	...
    Stack range 2471760 depthHigh 457
    [OK] tests/fixtures/eth_tests/GeneralStateTests/stRandom2/randomStatetest639.json
    ...
    Stack range 2623184 depthHigh 485
    [OK] tests/fixtures/eth_tests/GeneralStateTests/stRandom2/randomStatetest458.json
	...
    Stack range 5537824 depthHigh 1024
    [OK] tests/fixtures/eth_tests/GeneralStateTests/stCreate2/Create2OnDepth1024.json

These tests use 5.54 MB of stack to run, and avoid crashing on with a default
stack limit of 8 MB.  About 5408 bytes per EVM call stack frame.

However, this is uncomfortably close to the limit, as the stack frame size is
sensitive to changes in the code.

Also, this stack greatly exceeds the default thread stack size.

Measurements after
==================

(This patch doesn't address EVMC mode, which is not our default.  EVMC stack
usage remains about the same.  EVMC mode is addressed in another tiny patch.)

    $ rm -f build/all_tests && make ENABLE_EVMC=0 test
    $ ulimit -S -s 80 # Because we can!  80k stack.
    $ ./build/all_tests 9 | tee tlog
    [Suite] persist block json tests
    ...
    Stack range 496 depthHigh 3
    ...
    Stack range 49504 depthHigh 1024
    [OK] tests/fixtures/PersistBlockTests/block1431916.json

    $ rm -f build/all_tests && make ENABLE_EVMC=0 test
    $ ulimit -S -s 72 # Because we can!  72k stack.
    $ ./build/all_tests 7 | tee tlog
    [Suite] new generalstate json tests
	...
    Stack range 448 depthHigh 2
	...
    Stack range 22288 depthHigh 457
    [OK] tests/fixtures/eth_tests/GeneralStateTests/stRandom2/randomStatetest639.json
    ...
    Stack range 23632 depthHigh 485
    [OK] tests/fixtures/eth_tests/GeneralStateTests/stRandom2/randomStatetest458.json
	...
    Stack range 49504 depthHigh 1024
    [OK] tests/fixtures/eth_tests/GeneralStateTests/stCreate2/Create2OnDepth1024.json

For both tests, a satisfying *48 bytes* per EVM call stack frame, and EVM takes
not much more than 48 kB.  With other overheads, both tests run in 80 kB stack
total at maximum EVM depth.

We must add some headroom on this for database activity called from the EVM,
and different compile targets.  But it means the EVM itself is no longer a
stack burden.

This is much smaller than the default thread stack size on Linux (2MB), with
plenty of margin.  It's even smaller than Linux from a long time ago (128kB),
and some small embedded C targets.  (Just fyi, though, some JVM environments
allocated just 32 kB to thread stacks.)

This size is also well suited to running EVMs in threads, if that's useful.

Subtle exception handling and `dispose`
=======================================

It is important that each `snapshot` has a corresponding `dispose` in the event
of an exception being raised.  This code does do that, but in a subtle way.

The pair of functions `execCallOrCreate` and `execCallOrCreateAux` are
equivalent to the following code, where you can see `dispose` more clearly:

    proc execCallOrCreate*(c: Computation) =
      defer: c.dispose()
      if c.beforeExec():
        return
      c.executeOpcodes()
      while not c.continuation.isNil:
        c.child.execCallOrCreate()
        c.child = nil
        (c.continuation)()
        c.executeOpcodes()
      c.afterExec()

That works fine, but only reduces the stack used to 300-700 kB instead of 48 kB.

To get lower we split the above into separate `execCallOrCreate` and
`execCallOrCreateAux`.  Only the outermost has `defer`, and instead of handling
one level, it walks the entire `c.parent` chain calling `dispose` if needed.
The inner one avoids `defer`, which greatly reduces the size of its stackframe.

`c` is a `var` parameter, at each level of recursion.  So the outermost proc
sees the temporary changes made by all inner calls.  This is why `c` is updated
and the `c.parent` chain is maintained at each step.

Signed-off-by: Jamie Lokier <jamie@shareable.org>
2021-04-13 23:35:26 +01:00
Jordan Hrycaj 9e365734e6
renamed nvm_ prefixed modules to its original names
why:
  the nvm_ prefix was used inside the vm folder to hide them temporarily
  from the outside world while writing export wrappers. now all
  functionality is accessed via vm_*, rather than vm/* imports.

todo:
  at a later stage the import headers of the vm modules need to get fixed
  to meet style guide standards (as jacek kindly pointed out.)
2021-03-31 17:19:54 +01:00
Jordan Hrycaj cf3a356d76
provide vm_computation as import/export wrapper
details:
  moved original vm/computation.nim => vm/nvm_computation.nim
2021-03-31 16:38:10 +01:00