# NeoGo smart contract compiler The neo-go compiler compiles Go programs to a bytecode that the NEO virtual machine can understand. ## Language compatibility The compiler is mostly compatible with regular Go language specification. However, there are some important deviations that you need to be aware of that make it a dialect of Go rather than a complete port of the language: * `new()` is not supported, most of the time you can substitute structs with composite literals * `make()` is supported for maps and slices with elements of basic types * `copy()` is supported only for byte slices because of the underlying `MEMCPY` opcode * pointers are supported only for struct literals, one can't take an address of an arbitrary variable * there is no real distinction between different integer types, all of them work as big.Int in Go with a limit of 256 bit in width; so you can use `int` for just about anything. This is the way integers work in Neo VM and adding proper Go types emulation is considered to be too costly. * goroutines, channels and garbage collection are not supported and will never be because emulating that aspects of Go runtime on top of Neo VM is close to impossible * `defer` and `recover` are supported except for the cases where panic occurs in `return` statement because this complicates implementation and imposes runtime overhead for all contracts. This can easily be mitigated by first storing values in variables and returning the result. * lambdas are supported, but closures are not. * maps are supported, but valid map keys are booleans, integers and strings with length <= 64 * converting value to interface type doesn't change the underlying type, original value will always be used, therefore it never panics and always "succeeds"; it's up to the programmer whether it's a correct use of a value * type assertion with two return values is not supported; single return value (of the desired type) is supported; type assertion panics if value can't be asserted to the desired type, therefore it's up to the programmer whether assert can be performed successfully. ## VM API (interop layer) Compiler translates interop function calls into NEO VM syscalls or (for custom functions) into NEO VM instructions. [Refer to pkg.go.dev](https://pkg.go.dev/github.com/nspcc-dev/neo-go/pkg/interop) for full API documentation. In general it provides the same level of functionality as Neo .net Framework library. Compiler provides some helpful builtins in `util`, `convert` and `math` packages. Refer to them for detailed documentation. `_deploy()` function has a special meaning and is executed when contract is deployed. It should return no value and accept two arguments: the first one is `data` containing all values `deploy` is aware of and able to make use of; the second one is a bool argument which will be true on contract update. `_deploy()` functions are called for every imported package in the same order as `init()`. ## Quick start ### Go setup The compiler uses Go parser internally and depends on regular Go compiler presence, so make sure you have it installed and set up. On some distributions this requires you to set proper `GOROOT` environment variable, like ``` export GOROOT=/usr/lib64/go/1.15 ``` The best way to create a new contract is to use `contract init` command. This will create an example source file, a config file and `go.mod` with `github.com/nspcc-dev/neo-go/pkg/interop` dependency. ``` $ ./bin/neo-go contract init --name MyAwesomeContract $ cd MyAwesomeContract ``` You'll also need to download dependency modules for your contract like this (in the directory containing contract package): ``` $ go mod tidy ``` ### Compiling ``` ./bin/neo-go contract compile -i contract.go ``` By default, the filename will be the name of your .go file with the .nef extension, the file will be located in the same directory with your Go contract. If you want another location for your compiled contract: ``` ./bin/neo-go contract compile -i contract.go --out /Users/foo/bar/contract.nef ``` If your contract is split across multiple files, you must provide a path to the directory where package files are contained instead of a single Go file (`out.nef` will be used as the default output file in this case): ``` ./bin/neo-go contract compile -i ./path/to/contract ``` ### Debugging You can dump the opcodes generated by the compiler with the following command: ``` ./bin/neo-go contract inspect -i contract.go -c ``` This will result in something like this: ``` INDEX OPCODE PARAMETER 0 INITSLOT 4 local, 2 arg << 3 LDARG1 4 NOT 5 JMPIFNOT_L 151 (146/92000000) 10 SYSCALL System.Storage.GetContext (9bf667ce) 15 NOP 16 STLOC0 17 PUSHDATA1 53746f72616765206b6579206e6f7420796574207365742e2053657474696e6720746f2030 ("Storage key not yet set. Setting to 0") 56 CONVERT Buffer (30) 58 PUSH1 59 PACK 60 STLOC1 61 PUSHDATA1 696e666f ("info") 67 LDLOC1 68 SWAP 69 SYSCALL System.Runtime.Notify (95016f61) 74 NOP 75 PUSH0 76 STLOC2 77 LDLOC0 78 PUSHDATA1 746573742d73746f726167652d6b6579 ("test-storage-key") 96 LDLOC2 97 REVERSE3 98 SYSCALL System.Storage.Put (e63f1884) 103 NOP 104 PUSHDATA1 53746f72616765206b657920697320696e697469616c69736564 ("Storage key is initialised") 132 CONVERT Buffer (30) 134 PUSH1 135 PACK 136 STLOC3 137 PUSHDATA1 696e666f ("info") 143 LDLOC3 144 SWAP 145 SYSCALL System.Runtime.Notify (95016f61) 150 NOP 151 RET 152 INITSLOT 5 local, 0 arg 155 SYSCALL System.Storage.GetContext (9bf667ce) 160 NOP 161 STLOC0 162 LDLOC0 163 PUSHDATA1 746573742d73746f726167652d6b6579 ("test-storage-key") 181 SWAP 182 SYSCALL System.Storage.Get (925de831) 187 NOP 188 STLOC1 189 PUSHDATA1 56616c756520726561642066726f6d2073746f72616765 ("Value read from storage") 214 CONVERT Buffer (30) 216 PUSH1 217 PACK 218 STLOC2 219 PUSHDATA1 696e666f ("info") 225 LDLOC2 226 SWAP 227 SYSCALL System.Runtime.Notify (95016f61) 232 NOP 233 PUSHDATA1 53746f72616765206b657920616c7265616479207365742e20496e6372656d656e74696e672062792031 ("Storage key already set. Incrementing by 1") 277 CONVERT Buffer (30) 279 PUSH1 280 PACK 281 STLOC3 282 PUSHDATA1 696e666f ("info") 288 LDLOC3 289 SWAP 290 SYSCALL System.Runtime.Notify (95016f61) 295 NOP 296 LDLOC1 297 CONVERT Integer (21) 299 PUSH1 300 ADD 301 STLOC1 302 LDLOC0 303 PUSHDATA1 746573742d73746f726167652d6b6579 ("test-storage-key") 321 LDLOC1 322 REVERSE3 323 SYSCALL System.Storage.Put (e63f1884) 328 NOP 329 PUSHDATA1 4e65772076616c7565207772697474656e20696e746f2073746f72616765 ("New value written into storage") 361 CONVERT Buffer (30) 363 PUSH1 364 PACK 365 STLOC4 366 PUSHDATA1 696e666f ("info") 372 LDLOC4 373 SWAP 374 SYSCALL System.Runtime.Notify (95016f61) 379 NOP 380 LDLOC1 381 RET ``` #### Neo Smart Contract Debugger support It's possible to debug contracts written in Go using standard [Neo Smart Contract Debugger](https://github.com/neo-project/neo-debugger/) which is a part of [Neo Blockchain Toolkit](https://github.com/neo-project/neo-blockchain-toolkit/). To do that you need to generate debug information using `--debug` option, like this: ``` $ ./bin/neo-go contract compile -i contract.go -c contract.yml -m contract.manifest.json -o contract.nef --debug contract.debug.json ``` This file can then be used by debugger and set up to work just like for any other supported language. ### Deploying Deploying a contract to blockchain with neo-go requires both NEF and JSON manifest generated by the compiler from a configuration file provided in YAML format. To create contract manifest, pass a YAML file with `-c` parameter and specify the manifest output file with `-m`: ``` ./bin/neo-go contract compile -i contract.go -c config.yml -m contract.manifest.json ``` Example of such YAML file contents: ``` name: Contract safemethods: [] supportedstandards: [] events: - name: info parameters: - name: message type: String ``` Then, the manifest can be passed to the `deploy` command via `-m` option: ``` $ ./bin/neo-go contract deploy -i contract.nef -m contract.manifest.json -r http://localhost:20331 -w wallet.json ``` Deployment works via an RPC server, an address of which is passed via `-r` option, and should be signed using a wallet from `-w` option. More details can be found in `deploy` command help. #### Config file Configuration file contains following options: | Parameter | Description | Example | | --- | --- | --- | | `name` | Contract name in the manifest. | `"My awesome contract"` | `safemethods` | List of methods which don't change contract state, don't emit notifications and are available for anyone to call. | `["balanceOf", "decimals"]` | `supportedstandards` | List of standards this contract implements. For example, `NEP-11` or `NEP-17` token standard. This will enable additional checks in compiler. The check can be disabled with `--no-standards` flag. | `["NEP-17"]` | `events` | Notifications emitted by this contract. | See [Events](#Events). | | `permissions` | Foreign calls allowed for this contract. | See [Permissions](#Permissions). | | `overloads` | Custom method names for this contract. | See [Overloads](#Overloads). | ##### Events Each event must have a name and 0 or more parameters. Parameters are specified using their name and type. Both event and parameter names must be strings. Parameter type can be one of the following: Type in code | Type in config file --- | --- `bool` | `Boolean` `int`, `int64` etc.| `Integer` `[]byte` | `ByteArray` `string` | `String` Any non-byte slice `[]T`| `Array` `map[K]V` | `Map` `interop.Hash160` | `Hash160` `interop.Hash256` | `Hash256` `interop.Interface` | `InteropInterface` `interop.PublicKey` | `PublicKey` `interop.Signature` | `Signature` anything else | `Any` `interop.*` types are defined as aliases in `github.com/nspcc-dev/neo-go/pkg/interop` module with the sole purpose of correct manifest generation. As an example, consider `Transfer` event from `NEP-17` standard: ``` - name: Transfer parameters: - name: from type: Hash160 - name: to type: Hash160 - name: amount type: Integer ``` By default, compiler performs some sanity checks. Most of the time it will report missing events and/or parameter type mismatch. It isn't prohibited to use a variable as an event name in code, but it will prevent the compiler from analyzing the event. It is better to use either constant or string literal. It isn't prohibited to use ellipsis expression as an event arguments, but it will also prevent the compiler from analyzing the event. It is better to provide arguments directly without `...`. The type conversion code will be emitted for checked events, it will cast argument types to ones specified in the contract manifest. These checks and conversion can be disabled with `--no-events` flag. ##### Permissions Each permission specifies contracts and methods allowed for this permission. If a contract is not specified in a rule, specified set of methods can be called on any contract. By default, no calls are allowed. The simplest permission is to allow everything: ``` - methods: '*' ``` Another common case is to allow calling `onNEP17Payment`, which is necessary for most of the NEP-17 token implementations: ``` - methods: ["onNEP17Payment"] ``` In addition to `methods`, permission can have one of these fields: 1. `hash` contains hash and restricts a set of contracts to a single contract. 2. `group` contains public key and restricts a set of contracts to those that have the corresponding group in their manifest. Consider an example: ``` - methods: ["onNEP17Payment"] - hash: fffdc93764dbaddd97c48f252a53ea4643faa3fd methods: ["start", "stop"] - group: 03184b018d6b2bc093e535519732b3fd3f7551c8cffaf4621dd5a0b89482ca66c9 methods: ["update"] ``` This set of permissions allows calling: - `onNEP17Payment` method of any contract - `start` and `stop` methods of contract with hash `fffdc93764dbaddd97c48f252a53ea4643faa3fd` - `update` method of contract in group with public key `03184b018d6b2bc093e535519732b3fd3f7551c8cffaf4621dd5a0b89482ca66c9` Also note that a native contract must be included here too. For example, if your contract transfers NEO/GAS or gets some info from the `Ledger` contract, all of these calls must be allowed in permissions. The compiler does its best to ensure that correct permissions are specified in the config. Incorrect permissions will result in runtime invocation failures. Using either constant or literal for contract hash and method will allow the compiler to perform more extensive analysis. This check can be disabled with `--no-permissions` flag. ##### Overloads NeoVM allows a contract to have multiple methods with the same name but different parameters number. Go lacks this feature, but this can be circumvented with `overloads` section. Essentially, it is a mapping from default contract method names to the new ones. ``` - overloads: oldName1: newName oldName2: newName ``` Since the use-case for this is to provide multiple implementations with the same ABI name, `newName` is required to be already present in the compiled contract. As an example, consider [`NEP-11` standard](https://github.com/neo-project/proposals/blob/master/nep-11.mediawiki#transfer). It requires a divisible NFT contract to have 2 `transfer` methods. To achieve this, we might implement `Transfer` and `TransferDivisible` and specify the emitted name in the config: ``` - overloads: transferDivisible:transfer ``` #### Manifest file Any contract can be included in a group identified by a public key which is used in [permissions](#Permissions). This is achieved with `manifest add-group` command. ``` ./bin/neo-go contract manifest add-group -n contract.nef -m contract.manifest.json --sender --wallet /path/to/wallet.json --account ``` It accepts contract `.nef` and manifest files emitted by `compile` command as well as sender and signer accounts. `--sender` is the account that will send deploy transaction later (not necessarily in wallet). `--account` is the wallet account which signs contract hash using group private key. #### Neo Express support It's possible to deploy contracts written in Go using [Neo Express](https://github.com/neo-project/neo-express), which is a part of [Neo Blockchain Toolkit](https://github.com/neo-project/neo-blockchain-toolkit/). To do that, you need to generate a different metadata file using YAML written for deployment with neo-go. It's done in the same step with compilation via `--config` input parameter and `--abi` output parameter, combined with debug support the command line will look like this: ``` $ ./bin/neo-go contract compile -i contract.go --config contract.yml -o contract.nef --debug contract.debug.json --abi contract.abi.json ``` This file can then be used by toolkit to deploy contract the same way contracts in other languages are deployed. ### Invoking You can import your contract into a standalone VM and run it there (see [VM documentation](vm.md) for more info), but that only works for simple contracts that don't use blockchain a lot. For more real contracts you need to deploy them first and then do test invocations and regular invocations with `contract testinvokefunction` and `contract invokefunction` commands (or their variants, see `contract` command help for more details. They all work via RPC, so it's a mandatory parameter. Example call (contract `f84d6a337fbc3d3a201d41da99e86b479e7a2554` with method `balanceOf` and method's parameter `AK2nJJpJr6o664CWJKi1QRXjqeic2zRp8y` using given RPC server and wallet and paying 0.00001 extra GAS for this transaction): ``` $ ./bin/neo-go contract invokefunction -r http://localhost:20331 -w my_wallet.json -g 0.00001 f84d6a337fbc3d3a201d41da99e86b479e7a2554 balanceOf AK2nJJpJr6o664CWJKi1QRXjqeic2zRp8y ``` ### Generating contract bindings To be able to use deployed contract from another contract one needs to have its interface definition (exported methods and hash). While it is possible to use generic contract.Call interop interface, it's not very convenient and efficient. NeoGo can autogenerate contract bindings in Go language for any deployed contract based on its manifest, it creates a Go source file with all of the contract's methods that then can be imported and used as a regular Go package. ``` $ ./bin/neo-go contract generate-wrapper --manifest manifest.json --out wrapper.go --hash 0x1b4357bff5a01bdf2a6581247cf9ed1e24629176 ``` Notice that some structured types can be omitted this way (when a function returns some structure it's just an "Array" type in the manifest with no internal details), but if the contract you're using is written in Go originally you can create a specific configuration file during compilation that will add this data for wrapper generator to use: ``` $ ./bin/neo-go contract compile -i contract.go --config contract.yml -o contract.nef --manifest manifest.json --bindings contract.bindings.yml $ ./bin/neo-go contract generate-wrapper --manifest manifest.json --config contract.bindings.yml --out wrapper.go --hash 0x1b4357bff5a01bdf2a6581247cf9ed1e24629176 ``` ### Generating RPC contract bindings To simplify interacting with the contract via RPC you can generate contract-specific RPC bindings with the "generate-rpcwrapper" command. If your contract is NEP-11 or NEP-17 that's autodetected and an appropriate package is included as well. Notice that the type data available in the manifest is limited, so in some cases the interface generated may use generic stackitem types. Iterators are not supported yet. ``` $ ./bin/neo-go contract generate-rpcwrapper --manifest manifest.json --out rpcwrapper.go --hash 0x1b4357bff5a01bdf2a6581247cf9ed1e24629176 ``` ## Smart contract examples Some examples are provided in the [examples directory](../examples). For more sophisticated real-world contracts written in Go check out [NeoFS contracts](https://github.com/nspcc-dev/neofs-contract/). ## How to report compiler bugs 1. Make a proper testcase (example testcases can be found in the tests folder) 2. Create an issue on Github 3. Make a PR with a reference to the created issue, containing the testcase that proves the bug 4. Either you fix the bug yourself or wait for patch that solves the problem