usually, there is always a sender around `getRecipient` call.
no need to recalculate sender. and more important, in some of
JSON-RPC/GraphQL call, the sender is come from `rpcCallData`,
not from `tx.getSender`. or in ohter situation when the tx is
an unsigned tx, without `r,s,v` fields to calculate sender.
Move the EVM setup and call in `macro_assembler` (`runVM`) entirely to new
function `asmCallEvm` in `call_evm`. Extra return values needed for
testing are returned specially from `asmCallEvm`.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
The second `asmSetupComputation looks up state by block number and preceding
block number, modifies the first transaction with code for testing, and uses
some parts of that transaction to setup an an EVM test.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
In the `macro_assembler` test code, `initComputation` is another variant of
`rpcSetupComputation` and `txSetupComputation` with slightly different
paremeters. The similarity is obvious.
It is a special setup for testing, though, as it requires a contract-creation
transaction for parameters, but sets up a `CALL` execution not `CREATE`.
Gather this into `call_evm`: `initComputation` -> `asmSetupComputation`.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
The point of the `call_vm` exercise is to allow `Computation` to become an
internal type of the EVM, not used as API by the rest of the program. So
`rpcSetupComputation` should be private. It was left exported by mistake.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
Split out and move the EVM setup and call in `processTransaction` to
`call_evm`. This is the last part of the main program which calls the EVM
to be moved. (There's still test code.)
While we're here, move the EIP2929 access list setup too, as the similarity
to `rpcInitialAccessListEIP2929` is obvious.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
There's only one call left to `refundGas(Transaction, ...)`, and the
similarity to the tail of `rpcEstimateGas` is obvious.
Gather this into `call_evm`: `refundGas` -> `txRefundGas`.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
After recent changes, there's only one call left to `setupComputation`, and
it's just a variant like `rpcSetupComputation` but for transaction processing.
The similarity to `rpcSetupComputation` is obvious.
Gather this into `call_evm`: `setupComputation` -> `txSetupComputation`.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
It's possible for `tx.value` in the transaction to have a deliberately
constructed large 256-bit value, such that adding `gasLimit * gasPrice` to it
overflows to a small value.
Prior to this patch, the code would allow such a transaction to pass
validation, even though such a large transfer cannot be valid.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
Change `rpcEstimateGas` to setup and execute a computation directly, in a
similar way to `rpcDoCall` and `rpcMakeCall`, instead of constructing a fake
transaction and then validating it.
This patch does not (or should not) change any behaviour.
Although this looks a bit messy as it duplicates parts of `validateTransaction`
and `processTransaction`, proc names have been used to hopefully keep the
meanings clear, and it's just a stepping stone as those transaction functions
will be changed next. Also the behaviour of RPC `estimateGas` may not be
correct (although this patch is careful not to change it), so it's good to make
it explicit so we can see how it differs from other RPCs.
Doing this change exposed some interesting behaviour differences between the
`call` RPC and `estimateGas` RPC, which may be bugs, or may be intentional.
These differences are now obvious and explicit.
The unclear areas are not well documented by any of the clients, even Infura
which says a bit more than the others. So to find out if they are intended,
we'll have to run tests against other Ethereum services.
Guessing, on the face of it, it looks likely that RPC `call` should:
- Setup EIP2929 access lists
- Account for intrinsic gas (maybe not because zero-gas transactions are ok)
And it looks likely that RPC `estimateGas` should:
- Not return zero when an account has insufficient balance
- Maybe use a different gas cost estimate when one isn't supplied in the RPC
Signed-off-by: Jamie Lokier <jamie@shareable.org>
The RPC `estimateGas` behaves differently from RPC `call` in a number of ways.
These differences may be bugs due to `rpcEstimateGas` calling the EVM in a very
different way than `rpcDoCall`, or they may be intentional. To be sure, we'll
need to test behaviour with Geth, Infura etc to find out (their documentation
isn't enough.) For now, though, we'll keep the same behaviour as we always had.
`rpcEstimateGas` cannot use `rpcSetupComputation` as it is, because
`estimateGas` accounts for "intrinsic gas", and `call` does not.
This patch changes `rpcSetupComputation` to accomodate both behaviours.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
`makeCall` used by GraphQL is another way to setup and call the EVM.
Move it to `transaction/call_evm`.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
`estimateGas` used by JSON-RPC is another way to setup and call the EVM,
also used by GraphQL. Move it to `transaction/call_evm`.
This function has too much direct knowledge of details that shouldn't be used
outside transaction handling code, details we need to change when changing the
db and transaction memory layer.
Moving this one exposed quite a bit of abstraction leakage, as it calls
directly to the hexary trie db around `processTransaction`.
It looks like the _intended_ functionality of `estimateGas` is similar to
`rpcDoCall` with the only real difference being to not store the final state.
It looks like the extra stuff in `estimateGas` compared with `doCall` is a
messy workaround for computation not exposing the right API ("don't save final
state") for RPC to use.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
`doCall` used by JSON-RPC is another way to setup and call the EVM.
Move it to `transaction/call_evm`.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
Start gathering the functions that call the EVM into one place,
`transaction/call_evm.nim`.
This is first of a series of changes to gather all ways the EVM is called to
one place. Duplicate, slightly different setup functions have accumulated over
time, each with some knowledge of EVM internals. When they are brought
together, these methods will be changed to use a single entry point to the EVM,
allowing the entry point to be refactored, EVMC to be completed, and async
concurrency to be implemented on top. This also simplifies the callers.
First, a helper function used by RPC and GraphQL to make EVM calls without
permanently modifying the account state. `setupComputation` ->
`rpcSetupComputation`.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
nim-graphql v0.2.2 have numerous bugfixes, but notable ones are:
- only one non-introspection field are allowed in subscription root
- @skip and @include should not allowed for subscription root
- more descriptive error message for playground ethapi, fixes
- fixes GraphiQL client complaint about our instrospection system is old
- graphql http server enhancements: gzip encoding and chunked transfer
the `processArguments` now have overloaded proc, one with opt param and one without.
the OptParser now can be passed to `opt` param.
this is useful in scenario where in test code we need to simulate something
without using real command line arguments.
rather than initialize it to 0, those block numbers
are initialized to high(BlockNumber). this will fix
issue when imported genesis.json doesn't contains all
forks' blockNumber.
- fixes http server response status code
- fixes `__schema.types` and `__schema.directives` implementation
- fixes 'getOperation' in executor.nim
- web ui(graphiql) for http server
The account database code is not supposed to raise exceptions in the EVM, and
the behaviour is not well defined if it does. It isn't compliant with EVMC
spec either. But that will be dealt with properly when the account state-cache
is dealt with, as there is some work to be done on it.
Meanwhile, if it raises in code under `chainTo` and then `(continuation)()`,
the behaviour was changed slightly by the stack-shrink patches.
Before those patches, an exception after the recursion-point was converted to
`c.setError` "Opcode Dispatch Error" in `executeOpcodes. After, it would
propagate out, a different behaviour. (It still correctly walked the chain of
`c.dispose()` calls to clean up.)
It's easy to restore the original behaviour just by moving the continuation
call, so let's do that.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
We can't use `ulimit -s` to limit stack size on Windows. Even though Bash
accepts `ulimit -s` and the numbers change it has no effect and is not passed
to child processes.
(See https://public-inbox.org/git/alpine.DEB.2.21.1.1709131448390.4132@virtualbox/)
Instead, set it when building the test executable, following, a suggestion from
@stefantalpalaru.
https://github.com/status-im/nimbus-eth1/pull/598#discussion_r621107128
To ensure no conflict with `config.nims`, `-d:windowsNoSetStack` is used. This
proved unnecessary in practice because the command-line option is passed to the
linker after the config file option. But given we don't have an automated test
to verify linker behaviour, it's best not to rely on the option order, neither
how the linker treats it, or whether Nim will always send them in that order.
Testing:
This has been verified by using a smaller limit. At 200k, all `ENABLE_EVMC=0`
OS targets passed as expected, and all `ENABLE_EVMC=1` OS targets failed with
expected kinds of errors due to stack overflow, including Windows.
(400k wasn't small enough; 32-bit x86 Windows passed on that).
Signed-off-by: Jamie Lokier <jamie@shareable.org>
Make `run-nimbus-sync` look for and use `~/.nimbus/$TESTNET/nimbus/nodekey`
during Ethereum sync tests. This is a private key which identifies the node.
If you have created that file, its contents should be a hex nodekey, same
format as Geth. In fact you can use Geth to generate one. If found,
`run-nimbus-sync` will use it as the nodekey, instead of Nimbus's default,
which is a random nodekey each time it is run.
Using the same nodekey for each run allows us to add the corresponding
`enode:...` URL (public key) as a trusted peer to the dedicated Geth instances,
using Geth's `admin.addTrustedPeer`.
This ensures Geth will almost always accept our connections, which is very
helpful for sync testing, instead of waiting a long time for a good peer.
Indeed, without this we might never get a willing good peer, due to reputation
effects while working on new sync methods.
Signed-off-by: Jamie Lokier <jamie@shareable.org>
why:
only two public functions left: executeOpcodes() and execCallOrCreate()
where the former one was originally in interpreter_dispatch.nim and
the latter one calls this one.
improves maintainability
overview:
can be verified by running "make check_vm2 X=0" in the nimbus directory
(be patient when running it.) the X=0 flag is necessary if there is a
native NIM compiler which may bail out at some vendor imports.
details:
when compiling state_transaction.nim, the nim flag vm2_enabled must
be set in order to avoid implicit import of native VM definitions.
why:
kludge not needed anymore for oph_handlers.nim sub-sources and sources
that rely on oph_handlers.nim (but not state_transactions.nim which
relies on computation.nim.)
also:
re-integrated stack_defs.nim back into stack.nim
why:
the v2 prefix of the file name was used as a visual aid when
comparing vm2 against vm sources
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
why:
on 32bit windows 7, there seems to be a 64k memory ceiling for the gcc
compiler which was exceeded on some test platform.
details:
compiling VM2 for low memory C compiler can be triggered with
"make ENABLE_VM2LOWMEM". this comes with a ~24% longer execution time
of the test suite against old VM and optimised VM2.
why:
the new implementation lost more then 25% execution time on the test
suite when compared to the original VM. so the handler call and the
surrounding statements have been wrapped in a big case statement similar
to the original VM implementation. on Linux/x64, the execution time of
the new VM2 seems to be on par with the old VM.
details:
on Linux/x64, computed goto works and is activated with the -d:release
flag. here the execution time of the new VM2 was tested short of 0.02%
better than the old VM. without the computed goto, it is short of
0.4% slower than the old VM.
why:
using function stubs made it possible to check the syntax of an op
handler source file by compiling this very file. this was previously
impossible due cyclic import/include mechanism.
details:
only oph_call.nim, oph_create.nim and subsequently op_handlers.nim
still need the -d:kludge:1 flag for syntax check compiling. this flag
also works with interpreter_dispatch.nim which imports op_handlers.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.