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IELE: Semantics of New Cryptocurrency VM in K

In this repository we provide a model of IELE in K.

Structure

The file data.md explains the basic data of IELE (including words and some datastructures over them). This data is defined functionally.

iele.md is the file containing the semantics of IELE. This file contains the configuration (a map of the state), and a simple imperative execution machine which IELE lives on top of. It deals with the semantics of opcodes, the gas cost of execution, and parsing/unparsing/assembling/disassembling.

Gas Analysis

We have defined one analysis tool so far; a very very simple gas analysis tool. This gas analysis tool should be improved before being used for anything significant. We will collect developed analysis tools in analysis.md.

Proofs

Any proofs we perform will be documented in proofs/README.md. These proofs are also run as tests of UIUC-K, though they take quite a while. The file verification.md contains some helper-macros for writing down reachability claims.

Testing

ethereum.md loads test-files from the Ethereum Test Set and executes them, checking that the output is correct. If the output is correct, the entire configuration is cleared. If any check fails, the configuration retains the failed check at the top of the <k> cell.

Using the Definition

There are two versions of K available, RV-K and UIUC-K. This repository contains the build-products for both versions of K (there are slight differences) in .build/$K_VERSION/. Use RV-K for fast concrete execution, and UIUC-K for any symbolic reasoning. Make sure that you have set the K_VERSION environment variable in your shell (add export K_VERSION=uiuck or export K_VERSION=rvk to your .bashrc or equivalent).

The script Build supplied in this repository will build and run the definition (see ./Build help to see more detailed usage information). Running any proofs or symbolic reasoning requires UIUC-K.

To run in a different mode (eg. in GASANALYZE mode), do export cMODE=<OTHER_MODE> before calling ./Build. To run with a different fee schedule (eg. HOMESTEAD instead of DEFAULT), do export cSCHEDULE=<OTHER_SCHEDULE> before calling ./Build.

Dependencies

For using the ./Build command and tests, we depend on xmllint (on Ubuntu via the package libxml2-utils). For developing, we depend on pandoc-tangle.

Interesting Branches

These branches (off of master) are various interesting/useful changes to the semantics.

  • perf and performance are changes which improve performance of concrete execution but cannot do symbolic reasoning.
  • tutorial removes parts of the semantics and places TODO markers for a user to fill in.

Example Runs

Run the file tests/VMTests/vmArithmeticTest/add0.json:

$ ./Build run tests/VMTests/vmArithmeticTest/add0.json

# Which actually calls:
$ krun --directory .build/uiuck/ -cSCHEDULE=DEFAULT -cMODE=VMTESTS tests/VMTests/vmArithmeticTest/add0.json

Run the same file as a test:

$ ./Build test tests/VMTests/vmArithmeticTest/add0.json

To run proofs, you can similarly use ./Build. For example, to prove the specification tests/proofs/hkg/transfer-else-spec.k:

$ ./Build prove tests/proofs/hkg/transfer-else-spec.k

# Which actually calls:
$ krun --directory .build/uiuck/ -cSCHEDULE=DEFAULT -cMODE=NORMAL \
         --z3-executable tests/templates/dummy-proof-input.json --prove tests/proofs/hkg/transferFrom-else-spec.k \
         </dev/null

Finally, if you want to debug a given program (by stepping through its execution), you can use the debug option:

$ ./Build debug tests/VMTests/vmArithmeticTest/add0.json
...
KDebug> s
1 Step(s) Taken.
KDebug> p
... Big Configuration Here ...
KDebug>

Helper Script with-k

Not everyone wants to go through the process of installing K, so the script ./tests/ci/with-k can be used to avoid that. The following will call the same ./Build commands as above, but only after downloading, building, and setting up a fresh copy of RV-K or UIUC-K (as specified).

$ ./tests/ci/with-k rvk   ./Build run tests/VMTests/vmArithmeticTest/add0.json
$ ./tests/ci/with-k uiuck ./Build prove tests/proofs/hkg/transfer-else-spec.k
$ ./tests/ci/with-k rvk   ./Build test tests/VMTests/vmArithmeticTest/add0.json
$ ./tests/ci/with-k uiuck ./Build prove tests/proofs/hkg/transfer-else-spec.k
$ ./tests/ci/with-k uiuck ./Build debug tests/VMTests/vmArithmeticTest/add0.json

Note that running ./tests/ci/with-k takes quite some time, which can be a pain when actively developing. To only download and setup K once for each session, you can do the following:

# Downloads and installs RV-K
$ ./tests/ci/with-k rvk `which bash`

# Now can just run `./Build` directly
$ ./Build run tests/VMTests/vmArithmeticTest/add0.json
$ ./Build test tests/VMTests/vmArithmeticTest/add0.json

The script with-k sets up the development environment with the fresh copy of K built and prefixed to PATH for the remaining commands.

Contributing

Any pull requests into this repository will not be reviewed until at least some conditions are met. Here we'll accumulate the standards that this repository is held to.

Code style guidelines, while somewhat subjective, will still be inspected before going to review. In general, read the rest of the definition for examples about how to style new K code; we collect a few common flubs here.

Writing tests and more contract proofs is always appreciated. Tests can come in the form of proofs done over contracts too :).

Hard - Every Commit

These are hard requirements (must be met before review), and they must be true for every commit in the PR.

  • The build products which we store in the repository (K definition files and proof specification files) must be up-to-date with the files they are generated from. We do our development directly in the Markdown files and build the definition files (*.k) from them using pandoc-tangle. Not everyone wants to install pandoc-tangle or pandoc, so the build products are kept in the repository for people who just want to experiment quickly.

  • If a new feature is introduced in the PR, and later a bug is fixed in the new feature, the bug fix must be squashed back into the feature introduction. The only exceptions to this are if you want to document the bug because it was quite tricky or is something you believe should be fixed about K. In these exceptional cases, place the bug-fix commit directly after the feature introduction commit and leave useful commit messages. In addition, mark the feature introduction commit with [skip-ci] if tests will fail on that commit so that we know not to waste time testing it.

  • No tab characters, 4 spaces instead. Linux-style line endings; if you're on a Windows machine make sure to run dos2unix on the files.

Hard - PR Tip

These are hard requirements (must be met before review), but they only have to be true for the tip of the PR before review.

  • Every test in the repository must pass. We will test this with ./tests/ci/with-k bothk ./Build test-all (or ./tests/ci/with-k bothk ./Build partest-all on parallel machines).

Soft - Every Commit

These are soft requirements (review may start without these being met), and they will be considered for every commit in the PR.

  • Comments do not live in the K code blocks, but rather in the surrounding Markdown (unless there is a really good reason to localize the comment).

  • You should consider prefixing "internal" symbols (symbols that a user would not write in a program) with a hash (#).

  • Place a line of - after each block of syntax declarations.

        syntax Foo ::= "newSymbol"
     // --------------------------
        rule <k> newSymbol => . ... </k>
    

    Notice that if there are rules immediately following the syntax declaration, a commented-out line of - is inserted afterward. Notice that the width of the line of - matches that of the preceding line.

  • Place spaces around parentheses and commas in K's pretty functional-style syntax declarations.

        syntax Foo ::= newFunctionalSyntax ( Int , String )
     // ---------------------------------------------------
    
  • When multiple structurally-similar rules are present, line up as much as possible (and makes sense).

        rule <k> #do1       => . ... </k> <cell1> not-done => done        </cell1>
        rule <k> #do1Longer => . ... </k> <cell1> not-done => done-longer </cell1>
    
        rule <k> #do2     => . ... </k> <cell2> not-done => done2 </cell2>
        rule <k> #doShort => . ... </k> <cell2> nd       => done2 </cell2>
    

    This makes it simpler to make changes to entire groups of rules at a time using sufficiently modern editors. Notice that if we break alignment (eg. from the #do1 group above to the #do2 group), we put an extra line between the groups of rules.

  • Line up the r in requires with the l in rule (if it's not all on one line). Similarly, line up the end of andBool for extra side-conditions with the end of requires.

        rule <k> A => B ... </k>
             SOME_LARGE_CONFIGURATION
    
          requires A > 3
           andBool isPrime(A)
    

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Semantics of Virtual Machine for IELE prototype blockchain

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