Reference documentation for the Uniswap v3 wrapper is located at https://docs.polywrap.io/uniswapv3/intro.
The Uniswap v3 wrapper is a Polywrap-compatible API providing the same features as Uniswap's JavaScript SDK, plus more. The wrapper is written in AssemblyScript and compiled to Web Assembly (WASM). Polywrap's JavaScript Client makes interfacing with the wrapper as easy as interfacing with any ordinary JavaScript SDK.
Polywrap wrappers are user-friendly, secure, scalable, and infinitely composable. They are designed to be seamlessly upgradeable and truly multi-platform. They are better SDK's.
While the first Polywrap Client is written in JavaScript, future clients will be written for languages like Rust, Python, and Kotlin. Once written, a wrapper can be used with any Polywrap Client.
Polywrap's core toolchain consists of a development environment for writing API's and a Client to interface with them.
The Polywrap Client handles URI resolution and API method invocations. It downloads and caches the API at runtime, loads a Web Assembly runtime, makes the requested API call, and returns the result in the Client's native language. All of this happens "under the hood". Users have a familiar development experience so they can focus on their applications.
Polywrap wrappers are written in a supported language--currently AssemblyScript and Rust--and compiled to WASM. Wrappers can interact with each other seamlessly, irrespective of their source language. Wrapper calls are stateless and sandboxed for unprecedented security. And they are fast!
Polywrap plugins are written in a Client's native language to extend the Client's functionality. Wrappers can interact with plugins as though they were wrappers, and the plugin development experience is similar to that of wrappers. However, plugins do not have wrappers' special qualities. Because WASM modules are sandboxed, wrappers cannot directly interact with the browser, the filesystem, or networks. Plugins were conceived to handle these tasks securely.
Polywrap is a new paradigm. Integrating a WASM module into an application used to be a clunky and complex effort. Polywrap makes the WASM user experience really good.
"Yeah, Poywrap is cool, but what about our traditional SDK?"
If something like this crossed your mind, we've got you covered. Porting a JavaScript SDK to a wrapper is fairly straightforward. This section describes how we did it for Uniswap.
When writing the Uniswap v3 wrapper, our goal was to provide the same user experience as the SDK. The wrapper provides feature-parity and the "business logic" is the same. We ported elements of the Uniswap SDK Core package as necessary to implement the v3 wrapper.
The best way to set up a Polywrap project is to start with one of the project templates available in the Polywrap CLI. The w3 create
command lets you bootstrap your project structure without effort.
The initial project setup includes a mutation
folder and a query
folder within src
, which correspond to the two types of modules a wrapper can have.
It also includes a web3api.yaml
manifest file, a web3api.build.yaml
build manifest file, and a web3api.meta.yaml
meta manaifest file. The web3api.yaml
manifest tells the Polywrap CLI what language your wrapper is in, where your module schemas are located, and more. Our web3api.yaml
looked like this:
format: 0.0.1-prealpha.5
build: ./web3api.build.yaml
meta: ./web3api.meta.yaml
language: wasm/assemblyscript
modules:
mutation:
schema: ./src/mutation/schema.graphql
module: ./src/mutation/index.ts
query:
schema: ./src/query/schema.graphql
module: ./src/query/index.ts
The build manifest lets you customize the build process. The meta manifest lets you add meta-data to your project, like a description and a link to your repo.
For the Uniswap v3 wrapper, we left the web3api.yaml
manifest and the build manifest unchanged. We added detail to the meta manifest much later, when wrapper development was largely complete.
We started by reading through the entire Uniswap v3 JavaScript SDK repo on GitHub to record all the types and methods we would reproduce, and to take note of their interactions. The interface of a Polywrap API is declared in a GraphQL schema. We wrote a schema type for each externally-facing class in the SDK, with properties that matched those in the class with public access. We wrote a method declaration in the schema for each externally-facing function and class method in the SDK. We even copied over the SDK's inline documentation to fill the schema with context.
#An abridged look at our schema
"""ERC20-compliant token or Ether"""
type Token {
"""Id of chain where token exists"""
chainId: ChainId!
"""Address of token's ERC20 contract"""
address: String!
"""Token description"""
currency: Currency!
}
type Query {
"""Returns true if the tokens are equivalent, false otherwise"""
tokenEquals(
tokenA: Token!
tokenB: Token!
): Boolean!
"""Returns true if the address of tokenA would precede the address of token B when sorted alphabetically"""
tokenSortsBefore(
tokenA: Token!
tokenB: Token!
): Boolean!
}
A wrapper can have two modules: a query
module and a mutation
module. Each module has its own schema that, along with a an optional common
schema for shared types, are combined at build time. The difference between mutations and queries is simple: mutations modify state--this typically means blockchain state in web3 applications--while queries do not. The Uniswap v3 SDK does not modify on-chain state, so all of its functionality was placed in the query
module schema.
The first draft of the Uniswap v3 wrapper's schema was written in just a few hours, though it was revised during development to fix mistakes and improve the user experience.
When porting an SDK, it's important to understand its project structure. The organization of the SDK's soure code can indicate how wrapper development should proceed. Development should allow for iterative changes and testing.
The Unsiwap v3 SDK can be mentally modularized into a roughly linear set of dependent components. We can start with the concept of a Token
, which is the component of a CurrencyAmount
and a Pool
. A Route
is a set of pools and currencies. A Trade
is constructed from two currency amounts and one or more routes. Based on this pattern, it made sense for us to start with Token
.
In Uniswap's JavaScript SDK, Token has properties like chainId
and address
, as well as two class methods: equals
and sortsBefore
.
// Methods found in the Token class in Uniswap's SDK Core package
public equals(other: Currency): boolean {
return other.isToken && this.chainId === other.chainId && this.address === other.address
}
public sortsBefore(other: Token): boolean {
invariant(this.chainId === other.chainId, 'CHAIN_IDS')
invariant(this.address !== other.address, 'ADDRESSES')
return this.address.toLowerCase() < other.address.toLowerCase()
}
Using the Polywrap CLI's codegen
command, we generated AssemblyScript classes corresponding to each type we defined in the schema. This was as simple as typing w3 codegen
. The classes work like TypeScript interfaces (statically typed JavaScript objects) that include some boilerplate serialization logic. When you declare a function in your schema that returns a custom type or accepts one as an argument, these generated classes are used as the AssemblyScript analogs.
The codegen
command simulatenously generates another flavor of AssemblyScript class: function inputs. An Input_*
class is generated for each function, where *
is the name of the function. The classes have properties corresponding to the arguments defined in the schema. These Input_*
classes are used as inputs to the functions declared in the GraphQL schema.
The Polywrap CLI places the generated files in directories named w3
, which can be found within each module folder (as declared in your web3api.yaml
manifest). From there you can implement and use them.
Once we generated the classes, we imported the generated types and implemented the functions just as we found them in the Uniswap SDK. The function signatures match the schema definitions we declared earlier.
// An abridged copy of src/query/token.ts in the Uniswap v3 wrapper
import {
Input_tokenEquals,
Input_tokenSortsBefore,
Token,
} from "./w3";
// Checks if the current instance is equal to another (has an identical chainId and address).
export function tokenEquals(input: Input_tokenEquals): boolean {
const tokenA: Token = input.tokenA;
const tokenB: Token = input.tokenB;
return tokenA.chainId == tokenB.chainId && tokenA.address == tokenB.address;
}
// Checks if the current instance sorts before another, by address.
export function tokenSortsBefore(input: Input_tokenSortsBefore): boolean {
const tokenA: Token = input.tokenA;
const tokenB: Token = input.tokenB;
const tokenAddress: string = tokenA.address.toLowerCase();
const otherAddress: string = tokenB.address.toLowerCase();
return tokenAddress.localeCompare(otherAddress) < 0;
}
After implementing the token functions, it was possible to build the project (after commenting out methods in the schema that had not yet been implemented) and write the first automated tests.
The Uniswap v3 wrapper imports external dependencies to help it with certain tasks. A wrapper can import other wrappers or plugins.
One of the most important dependencies we used is Polywrap's Ethereum plugin. The Ethereum plugin is based on the popular ethers.js
package. It can be used to prepare and send Ethereum transactions in much the same way.
Although the Uniswap v3 JavaScript SDK does not include methods that mutate state on the Ethereum blockchain, several of its functions do return encoded Ethereum transaction calldata that can be sent to Uniswap's on-chain smart contracts. The SDK uses ethers.js
to encode calldata. We can do the same with the Ethereum plugin.
Our src/query/schema.graphql
schema declares several imports at the top of the file. Among these is the Ethereum plugin, which is included in the Polywrap client by default.
#import { Query } into Ethereum from "w3://ens/ethereum.web3api.eth"
#import { Query } into SHA3 from "w3://ens/sha3.web3api.eth"
#import { Query } into ERC20 from "w3://ipfs/QmeiPWHe2ixfitcgjRwP5AaJD5R7DbsGhQNQwT4rFNyxx8"
#import { Query } into Subgraph from "w3://ipfs/QmcnrHegojMFqHkRhixazY67Zb9mSbMLv6sSxyDpUtnrQS"
#import { ChainId, TradeType, Currency, Token, Price, TokenAmount, Tick, Pool, FeeAmount, Route, TradeSwap, Trade, BestTradeOptions, Position, PermitOptions, FeeOptions, SwapOptions, MethodParameters, MintAmounts } from "../common/schema.graphql"
Wrappers and plugins are queried at URIs. When a user wants to call an API function with the Polywrap Client, they use a URI to tell the Client which API they are calling. The URI's are also used to import wrapper dependencies. Even though the Ethereum plugin is a JavaScript package that gets loaded into memory, it is still queried at a URI that is redirected and resolved to the in-memory instance.
Once imports are declared, we can run the codegen
command of the Polywrap CLI to generate imported modules and types. The imported module class includes all of the methods declared in its own GraphQL schema. If we want to know what's in it, we might look there first.
We used the Ethereum plugin's encodeFunction
method to encode calldata for Uniswap's Multicall smart contract.
// An abridged copy of src/query/routerUtils.ts in the Uniswap v3 wrapper
import {
Ethereum_Query,
Input_encodeMulticall,
} from "./w3";
export function encodeMulticall(input: Input_encodeMulticall): string {
const calldatas: string[] = input.calldatas;
return calldatas.length == 1
? calldatas[0]
: Ethereum_Query.encodeFunction({
method:
"function multicall(bytes[] calldata data) external payable returns (bytes[] memory results)",
args: ['["' + calldatas.join('", "') + '"]'],
}).unwrap();
}
Polywrap schemas support additional default types beyond those found in standard GraphQL. The BigInt
type is used in the Uniswap v3 wrapper to represent integers larger than 32 bits. Since Ethereum supports unsigned integers as large as 256 bits, we needed to support them as well.
"""An amount of a token"""
type TokenAmount {
"""Token"""
token: Token!
"""Raw amount of the token, not adjusted for the token's decimals"""
amount: BigInt!
}
The BigInt
type looks like a standard GraphQL type in the schema. In AssemblyScript, the type is received as an instance of the BigInt
class from in the as-bigint AssemblyScript package.
// compares two TokenAmount types for equality, returning true if they have the
// same token and same amount
export function tokenAmountEquals(input: Input_tokenAmountEquals): boolean {
const amtA: TokenAmount = input.tokenAmountA;
const amtB: TokenAmount = input.tokenAmountB;
return (
tokenEquals({ tokenA: amtA.token, tokenB: amtB.token }) &&
amtA.amount.eq(amtB.amount)
);
}
Other base schema types include BigNumber
, JSON
, and Map<T,U>
. These types, along with BigInt
, can be imported directly into AssemblyScript modules from the web3api/wasm
package.
We adapted all of the tests in Uniswap's SDK to work with the wrapper. This ensured that the wrapper met at least the same standards of quality the Uniswap team expected of their SDK. The Uniswap team tested their SDK with artificial data that allowed them to calculate the expected results and compare those results to the outputs of their code. We used the same test cases and expected the same results from our wrapper.
We also wrote tests based on real-world data, using a fork of the Ethereum Mainnet network, to compare the results of our wrapper queries with results produced by the SDK. This helped us test the wrapper with input of greater complexity.
We wrote automated tests using two different testing frameworks: as-pect
and jest
.
as-pect
is an AssemblyScript testing framework, and that is why we used it. Unit tests written in the native language of the wrapper can be used to test classes and functions that are written to support the main wrapper code. This reduces the layers of complexity that would be associated with testing only the functions declared in our GraphQL schema.
For example, we wrote a PriorityQueue
class to sort trades for the bestTradeExactIn
and bestTradeExactOut
functions. We used as-pect
to test it. This simplified testing and debugging forbestTradeExactIn
and bestTradeExactOut
.
We wrote many of our other tests in as-pect
as well, in part because it was straightforward to copy and paste test scripts from the Uniswap v3 SDK repo and adapt the syntax.
One quirk with as-pect
is that the following must be added to its configuration file to get it working with Polywrap.
imports: {
w3: {
__w3_invoke_args: () => {},
__w3_invoke_result: () => {},
__w3_invoke_error: () => {},
__w3_subinvoke: () => {},
__w3_subinvoke_result: () => {},
__w3_subinvoke_result_len: () => {},
__w3_subinvoke_error: () => {},
__w3_subinvoke_error_len: () => {},
__w3_abort: () => {},
}
},
Not all tests can be written in the wrapper's native language, nor should they be. Code that depends on other wrappers or plugins must be tested by making calls to the Polywrap Client. The Client coordinates inter-API communication.
We wrote many of our most important tests in the popular JavaScript framework jest
. Were we to write the Uniswap v3 wrapper again, we would actually use a lot less as-pect
and a lot more jest
.
One advantage of testing with jest
is that it requires developers to make calls in the same way users of their wrappers are likely to make them. A disadvantage is that it requires developers to set up the Polywrap client and a test environment, which is easy but takes more time.
Setting up the Client is easy if you only need the default plugins and plan to use a standard Polywrap test environment.
The @web3api/test-env-js
package includes functions for starting and stopping a Polywrap test environment programmatically. The test environment has the following:
- A standard Ganache Ethereum test chain at "http://localhost:8545"
- A Ganache Ethereum mainnet fork test chain at "http://localhost:8546"
- An IPFS node at * A Ganache Ethereum test chain at "http://localhost:5001"
It also sets up an ENS contract at initialization so you can build wrappers and deploy them to an ENS URI on your locally hosted testnet.
We created a helper function that takes some network information as inputs and returns a Client config.
export function getPlugins(ethereum: string, ipfs: string, ensAddress: string): ClientConfig {
return {
redirects: [],
plugins: [
{
uri: "w3://ens/ipfs.web3api.eth",
plugin: ipfsPlugin({ provider: ipfs }),
},
{
uri: "w3://ens/ens.web3api.eth",
plugin: ensPlugin({ addresses: { testnet: ensAddress } }),
},
{
uri: "w3://ens/ethereum.web3api.eth",
plugin: ethereumPlugin({
networks: {
testnet: {
provider: ethereum
},
MAINNET: {
provider: "http://localhost:8546" // Ganache mainnet fork
},
},
defaultNetwork: "testnet"
}),
},
],
};
}
And then we put some boilerplate code in each of our jest
test files to start the test environment, intantiate the client, build the api, and deploy it to the test environment's IPFS/ENS infrastructure.
import { ClientConfig, Web3ApiClient } from "@web3api/client-js";
import { buildAndDeployApi, initTestEnvironment, stopTestEnvironment } from "@web3api/test-env-js";
import { getPlugins } from "../testUtils";
describe('Wrapper Test', () => {
let client: Web3ApiClient;
let ensUri: string;
beforeAll(async () => {
// initialize test environment
const { ethereum: testEnvEtherem, ensAddress, ipfs } = await initTestEnvironment();
// get client
const config: ClientConfig = getPlugins(testEnvEtherem, ipfs, ensAddress);
client = new Web3ApiClient(config);
// deploy api
const apiPath: string = path.resolve(__dirname + "/../../../../");
const api = await buildAndDeployApi(apiPath, ipfs, ensAddress);
ensUri = `ens/testnet/${api.ensDomain}`;
});
afterAll(async () => {
await stopTestEnvironment();
});
The Polywrap CLI can automatically generate TypeScript types using the w3 app
command. The types mirror those declared in your GraphQL schema.
If you love brevity, we can also recommend writing functions that "wrap" your wrapper calls. This can make your tests a bit easier to read.
// This function lets us call the createRoute function in the Uniswap v3 wrapper with one line of code
export async function createRoute(client: Web3ApiClient, ensUri: string, pools: Pool[], inToken: Token, outToken: Token): Promise<Route> {
const query = await client.invoke<Route>({
uri: ensUri,
module: "query",
method: "createRoute",
input: {
pools,
inToken,
outToken,
},
});
if (query.error) {
throw query.error;
}
return query.data!;
}
// example usage
const route_0_1: Route = await createRoute(client, ensUri, [pool_0_1], token0, token1);
As a final touch, we generated ample documentation for the Uniswap v3 wrapper.
Polywrap's GraphQL parser can read documentation comments (comments with triple quotes) from the wrapper's GraphQL schema. Using this capability, Polywrap built a tool to help developers create documentation for their wrappers.
The Polywrap CLI will soon be able to use GraphQL schemas to automatically generate markdown that is compatible with popular documentation tools like Docusaurus. We tested the tool to generate the reference documentation found at https://docs.polywrap.io/uniswapv3/intro.