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+---
+language: Tact
+filename: tact.tc
+contributors:
+  - ["Tal Kol", "https://www.orbs.com/"]
+  - ["Kirill Malev", "https://fslabs.io"]
+---
+
+Tact language is used to program smart contracts on the
+[The Open Network](https://ton.org) blockchain. Contract logic is executed in
+TVM, the stack-based TON Virtual Machine.
+
+Tact is a statically typed, but language was designed to be friendly for
+developers with JS and Python background.
+
+This page is based on [Tact-by-Example](https://tact-by-example.org/).
+You can use this resource to play around with contracts and check out
+the interactive features.
+
+# Basic syntax, function definition
+
+```c
+// Single line comment
+
+ // This is a multi-line comment
+  // this is a comment in the comment
+
+    get fun greeting(): String {
+    // This is a function that returns "hello world" message
+    // Return type is specified after a colon :
+        return "hello world";
+    }
+```
+
+# A Simple Counter contract
+
+This is a simple counter contract that allows users to increment its value.
+
+This contract has a state variable `val` that persists between contract calls
+
+- the counter value. When persisted, this variable is encoded as `uint32` -
+ a 32-bit unsigned integer. Contracts pay rent in proportion to the amount
+ of persistent space they consume, so compact representations are encouraged.
+
+State variables should be initialized in `init()` that runs on deployment of
+the contract.
+
+## Messages
+
+The actor model is a model of concurrent computation and is at the heart of TON
+smart contracts. Each smart contract can process one message at a time, change
+its own state, or send one or several messages. Processing of the message
+occurs in one transaction, that is, it cannot be interrupted. Messages to one
+contract are processed consequently one by one. As a result, the execution of
+each transaction is local and can be parallelized at the blockchain level,
+which allows for on-demand throughput horizontal scaling and hosting an
+unlimited number of users and transactions.
+
+## Receiving messages
+
+This contract can receive messages from users. Unlike getters that are just
+read-only, messages can do write operations and change the contract's
+persistent state. Incoming messages are processed in receive() methods as
+transactions and cost gas for the sender.
+
+After deploying the contract, send the increment message by pressing the Send
+increment button in order to increase the counter value by one. Afterwards,
+call the getter value() to see that the value indeed changed.
+
+```c
+contract Counter {
+// Tact allows to create a contract
+    // persistent state variable of type Int to hold the counter value
+    val: Int as uint32;
+ 
+    // initialize the state variable when contract is deployed
+    init() {
+        self.val = 0;
+    }
+ 
+    // handler for incoming increment messages that change the state
+    receive("increment") {
+        self.val = self.val + 1;
+    }
+ 
+    // read-only getter for querying the counter value
+    get fun value(): Int {
+        return self.val;
+    }
+}
+```
+
+# The Deployable Trait
+
+Tact doesn't support classical class inheritance, but contracts can implement
+traits. One of the commonly used traits is `Deployable`. It implements a simple
+receiver for the Deploy message which helps deploy contracts in a standard way.
+
+All contracts are deployed by sending them a message. This can be any message,
+but best practice is to designate the special `Deploy` 
+message for this purpose.
+
+This message has a single field, `queryId`, which is provided by the deployer
+(normally zero). If the deploy succeeds, the contract will reply with the
+message `DeployOk` and echo the same `queryId` in the response.
+
+If you're using Tact's [auto-generated](https://docs.tact-lang.org/tools/typescript#tact-contract-in-typescript) TypeScript
+classes to deploy, sending the deploy message should look like:
+
+```c
+const msg = { $$type: "Deploy", queryId: 0n };
+ await contract.send(sender, { value: toNano(1) }, msg);
+```
+
+You can see the implementation of the trait [here](https://github.com/tact-lang/tact/blob/main/stdlib/libs/deploy.tact).
+Notice that the file deploy.tact needs to be imported from the standard
+library using the import keyword.
+
+```c
+// this trait has to be imported
+import "@stdlib/deploy";
+
+// the Deployable trait adds a default receiver for the "Deploy" message
+contract Counter with Deployable {
+ 
+    val: Int as uint32;
+ 
+    init() {
+        self.val = 0;
+    }
+ 
+    receive("increment") {
+        self.val = self.val + 1;
+    }
+ 
+    get fun value(): Int {
+        return self.val;
+    }
+}
+```
+
+# Integers
+
+Tact supports a number of primitive data types that are tailored for
+smart contract use.
+
+`Int` is the primary number type. Math in smart contracts is always done
+with integers and never with floating points since floats are [unpredictable](https://learn.microsoft.com/en-us/cpp/build/why-floating-point-numbers-may-lose-precision).
+
+The runtime type `Int` is always 257-bit signed, so all runtime calculations
+are done at 257-bit. This should be large enough for pretty much anything you
+need as it's large enough to hold the number of atoms in the universe.
+
+Persistent state variables can be initialized inline or inside `init()`.
+If you forget to initialize a state variable, the code will not compile.
+
+## State costs
+
+When encoding `Int` to persistent state, we will usually use smaller
+representations than 257-bit to reduce storage cost.
+The persistent state size is specified in every declaration of
+a state variable after the `as` keyword.
+
+Storing 1000 257-bit integers in state [costs](https://ton.org/docs/develop/smart-contracts/fees#how-to-calculate-fees) about 
+0.184 TON per year. Storing 1000 32-bit integers only costs
+0.023 TON per year by comparison.
+
+```c
+import "@stdlib/deploy";
+
+contract Integers with Deployable {
+ 
+    // contract persistent state variables
+    // integers can be persisted in state in various sizes
+    // range -2^256 to 2^256 - 1 (takes 257 bit = 32 bytes + 1 bit)
+    i1: Int as int257 = 3001;   
+    i2: Int as uint256;         // range 0 to 2^256 - 1 (takes 256 bit = 32 bytes)
+    // range -2^255 to 2^255 - 1 (takes 256 bit = 32 bytes)
+    i3: Int as int256 = 17;
+    i4: Int as uint128;         // range 0 to 2^128 - 1 (takes 128 bit = 16 bytes)
+    // range -2^127 to 2^127 - 1 (takes 128 bit = 16 bytes)
+    i5: Int as int128;          
+    i6: Int as coins;           // range 0 to 2^120 - 1 (takes 120 bit = 15 bytes)
+    // range 0 to 18,446,744,073,709,551,615 (takes 64 bit = 8 bytes)
+    i7: Int as uint64 = 0x1c4a; 
+    // range -9,223,372,036,854,775,808 to 9,223,372,036,854,775,807
+    // (takes 64 bit = 8 bytes)
+    i8: Int as int64 = -203;    
+    i9: Int as uint32 = 0;      // range 0 to 4,294,967,295 (takes 32 bit = 4 bytes)
+    // range -2,147,483,648 to 2,147,483,647 (takes 32 bit = 4 bytes)
+    i10: Int as int32 = 0;      
+    i11: Int as uint16 = 0;     // range 0 to 65,535 (takes 16 bit = 2 bytes)
+    i12: Int as int16 = 0;      // range -32,768 to 32,767 (takes 16 bit = 2 bytes)
+    i13: Int as uint8 = 0;      // range 0 to 255 (takes 8 bit = 1 byte)
+    i14: Int as int8 = 0;       // range -128 to 127 (takes 8 bit = 1 byte)
+
+    init() {
+        // we can define numbers in hex (base 16)
+        self.i2 = 0x83dfd552e6372; 
+        self.i4 = 1507998500293440234999; // we can define numbers in decimal
+        self.i5 = pow(10, 9);   // this is 10^9 = 1,000,000,000
+        self.i6 = ton("1.23");  // easy to read coin balances
+        //  (coins type is nano-tons, like cents, just with 9 decimals)
+    }
+
+    receive("show all") {
+        dump(self.i1);
+        dump(self.i2);
+        dump(self.i3);
+        dump(self.i4);
+        dump(self.i5);
+        dump(self.i6);
+        dump(self.i7);
+        dump(self.i8);
+    }
+
+    get fun result(): Int {
+        return self.i1;
+    }
+}
+```
+
+## Additional resources
+
+- [TON Documentation](https://ton.org/docs/#/)
+- [Tact Docs](https://docs.tact-lang.org/)
+- [Community portal](https://society.ton.org)
+- [Blockchain portal](https://ton.org)
+- [Stackoverflow](https://stackoverflow.com/questions/tagged/ton)
+
+## Social
+- [Tact community](https://t.me/tactlang)
+- [Developer community](https://t.me/tondev_eng)
+- [TON Learn](https://t.me/ton_learn)
+- [Tondev News](https://t.me/tondevnews)
+
+## Useful blogposts
+
+- [Setting up a TON Development Environment](https://society.ton.org/setting-up-a-ton-development-environment)
+- [Hello World on TON](https://society.ton.org/ton-hello-world-step-by-step-guide-for-writing-your-first-smart-contract-in-func)
+
+## Future To Dos
+
+- Add smart contracts examples
+- Add more links to documentations
+
+This file is based on [Tact By Example](https://tact-by-example.org/04-decimal-point).
+
+P.S. If by any chance you're familiar with [Forth](https://learnxinyminutes.com/docs/forth/),
+you can also take a look at [Fift](https://ton-blockchain.github.io/docs/fiftbase.pdf).