Maps de Comptes

Les Maps sont des structures de données qui sont fréquemment utilisées en programmation pour associer une clé à une valeur quelconque. La clé et la valeur peuvent être de n'importe quel type. De plus, la clé sert d'identifiant pour une valeur donnée qui est sauvegardée. Ensuite, selon la clé donnée, elle nous permet d'insérer, de récupérer et de mettre à jour efficacement sa valeur.

Le modèle de compte Solana, comme nous le savons, exige que les données du programme et ses données d'état correspondantes soient stockées dans des comptes différents. Ces comptes ont une adresse associée. Ce qui, en soi, fait office de map ! Découvrez le modèle de compte de Solana ici.

Il serait donc logique de stocker vos valeurs dans des comptes distincts, dont l'adresse serait la clé nécessaire pour récupérer la valeur. Mais cela soulève quelques problèmes, tels que :

• Les adresses mentionnées ci-dessus ne seront très probablement pas des clés idéales, dont vous pourriez vous souvenir et récupérer la valeur requise.

• Les adresses mentionnées ci-dessus font référence à des clés publiques de différentes Paires de Clés, où chaque clé publique (ou adresse) est associée à une clé privée. Cette clé privée serait nécessaire pour signer différentes instructions si et quand cela est nécessaire, ce qui nous obligerait à stocker la clé privée quelque part, ce qui n'est absolument pas recommandé !

Cela présente un problème auquel de nombreux développeurs Solana sont confrontés, à savoir l'implémentation d'une logique de type Map dans leurs programmes. Voyons comment nous pourrions aborder ce problème.

Dérivation des PDAs

PDA signifie Program Derived Address (Adresse Dérivée du Programme) et sont, en bref, des adresses dérivées d'un ensemble de seeds et d'un identifiant de programme (ou adresse).

La particularité des PDAs est que ces adresses ne sont pas associées à une clé privée. Cela est dû au fait que ces adresses ne se trouvent pas sur la courbe ED25519. Par conséquent, seul le programme, dont cette adresse a été dérivée, peut signer une instruction avec la clé, pourvu que les seeds soient également fournies. Plus d'informations à ce sujet ici.

Maintenant que nous avons une idée de ce que sont les PDAs, utilisons-les pour mapper quelques comptes ! Nous allons prendre l'exemple d'un programme de Blog pour montrer comment cela pourrait être mis en œuvre.

Dans ce programme de Blog, nous souhaitons que chaque Utilisateur ait un seul Blog. Ce blog peut avoir un nombre quelconque de "Posts". Cela signifie que nous mappons chaque utilisateur à un blog, et que chaque post est mappé à un certain blog.

En bref, il existe une correspondance "1:1" entre un utilisateur et son blog, et une correspondance "1:N" entre un blog et ses articles.

Pour la correspondance 1:1, nous voudrions que l'adresse d'un blog soit dérivée uniquement de son utilisateur, ce qui nous permettrait de retrouver un blog, étant donné son autorité (ou utilisateur). Ainsi, les seeds d'un blog seraient constituées de sa clé d'autorité, et éventuellement d'un préfixe "blog" pour servir d'identifiant de type.

Pour la correspondance 1:N, nous voudrions que l'adresse de chaque post soit dérivée non seulement du blog auquel il est associé, mais aussi d'un autre identifiant qui nous permet de faire la différence entre un nombre N de posts de blog. Dans l'exemple ci-dessous, l'adresse de chaque post est dérivée de la clé du blog, d'un slug pour identifier chaque post, et d'un préfixe "post" qui sert d'identifiant de type.

Le code est le suivant :

Press </> button to view full source

use anchor_lang::prelude::*;

declare_id!("2vD2HBhLnkcYcKxnxLjFYXokHdcsgJnyEXGnSpAX376e");

#[program]
pub mod mapping_pda {
    use super::*;
    pub fn initialize_blog(ctx: Context<InitializeBlog>, _blog_account_bump: u8, blog: Blog) -> ProgramResult {
        ctx.accounts.blog_account.set_inner(blog);
        Ok(())
    }

    pub fn create_post(ctx: Context<CreatePost>, _post_account_bump: u8, post: Post) -> ProgramResult {
        if (post.title.len() > 20) || (post.content.len() > 50) {
            return Err(ErrorCode::InvalidContentOrTitle.into());
        }

        ctx.accounts.post_account.set_inner(post);
        ctx.accounts.blog_account.post_count += 1;

        Ok(())
    }
}

#[derive(Accounts)]
#[instruction(blog_account_bump: u8)]
pub struct InitializeBlog<'info> {
    #[account(
        init,
        seeds = [
            b"blog".as_ref(),
            authority.key().as_ref()
        ],
        bump = blog_account_bump,
        payer = authority,
        space = Blog::LEN
    )]
    pub blog_account: Account<'info, Blog>,

    #[account(mut)]
    pub authority: Signer<'info>,

    pub system_program: Program<'info, System>
}

#[derive(Accounts)]
#[instruction(post_account_bump: u8, post: Post)]
pub struct CreatePost<'info> {
    #[account(mut, has_one = authority)]
    pub blog_account: Account<'info, Blog>,

    #[account(
        init,
        seeds = [
            b"post".as_ref(),
            blog_account.key().as_ref(),
            post.slug.as_ref(),
        ],
        bump = post_account_bump,
        payer = authority,
        space = Post::LEN
    )]
    pub post_account: Account<'info, Post>,

    #[account(mut)]
    pub authority: Signer<'info>,
    
    pub system_program: Program<'info, System>
}

#[account]
pub struct Blog {
    pub authority: Pubkey,
    pub bump: u8,
    pub post_count: u8,
}

#[account]
pub struct Post {
    pub author: Pubkey,
    pub slug: String, // 10 characters max
    pub title: String, // 20 characters max
    pub content: String // 50 characters max
}

impl Blog {
    const LEN: usize = 8 + 32 + 1 + (4 + (10 * 32));
}

impl Post {
    const LEN: usize = 8 + 32 + 32 + (4 + 10) + (4 + 20) + (4 + 50); 
}

#[error]
pub enum ErrorCode {
    #[msg("Invalid Content or Title.")]
    InvalidContentOrTitle,
}

#[derive(Accounts)]
#[instruction(blog_account_bump: u8)]
pub struct InitializeBlog<'info> {
    #[account(
        init,
        seeds = [
            b"blog".as_ref(),
            authority.key().as_ref()
        ],
        bump = blog_account_bump,
        payer = authority,
        space = Blog::LEN
    )]
    pub blog_account: Account<'info, Blog>,

    #[account(mut)]
    pub authority: Signer<'info>,

    pub system_program: Program<'info, System>
}

#[derive(Accounts)]
#[instruction(post_account_bump: u8, post: Post)]
pub struct CreatePost<'info> {
    #[account(mut, has_one = authority)]
    pub blog_account: Account<'info, Blog>,

    #[account(
        init,
        seeds = [
            b"post".as_ref(),
            blog_account.key().as_ref(),
            post.slug.as_ref(),
        ],
        bump = post_account_bump,
        payer = authority,
        space = Post::LEN
    )]
    pub post_account: Account<'info, Post>,

    #[account(mut)]
    pub authority: Signer<'info>,
    
    pub system_program: Program<'info, System>
}

use std::convert::TryInto;
use borsh::{BorshDeserialize, BorshSerialize};
use solana_program::{
    sysvar::{rent::Rent, Sysvar},
    borsh::try_from_slice_unchecked,
    account_info::{AccountInfo, next_account_info},
    entrypoint,
    entrypoint::ProgramResult, 
    pubkey::Pubkey, 
    msg,
    program_error::ProgramError, system_instruction, program::invoke_signed,
};
use thiserror::Error;


entrypoint!(process_instruction);
fn process_instruction(
    program_id: &Pubkey,
    accounts: &[AccountInfo],
    instruction_data: &[u8],
) -> ProgramResult {
    Processor::process(program_id, accounts, instruction_data)
}

pub enum BlogInstruction {

    /// Accounts expected:
    /// 
    /// 0. `[signer]` User account who is creating the blog
    /// 1. `[writable]` Blog account derived from PDA
    /// 2. `[]` The System Program
    InitBlog {},

    /// Accounts expected:
    /// 
    /// 0. `[signer]` User account who is creating the post
    /// 1. `[writable]` Blog account for which post is being created
    /// 2. `[writable]` Post account derived from PDA
    /// 3. `[]` System Program
    CreatePost {
        slug: String,
        title: String,
        content: String,
    }
}

pub struct Processor;
impl Processor {
    pub fn process(program_id: &Pubkey, accounts: &[AccountInfo], instruction_data: &[u8]) -> ProgramResult {
        
        let instruction = BlogInstruction::unpack(instruction_data)?;

        match instruction {
            BlogInstruction::InitBlog {} => {
                msg!("Instruction: InitBlog");
                Self::process_init_blog(accounts, program_id)
            },
            BlogInstruction::CreatePost { slug, title, content} => {
                msg!("Instruction: CreatePost");
                Self::process_create_post(accounts, slug, title, content, program_id)
            }
        }
    }

    fn process_create_post(
        accounts: &[AccountInfo],
        slug: String,
        title: String,
        content: String,
        program_id: &Pubkey
    ) -> ProgramResult {
        if slug.len() > 10 || content.len() > 20 || title.len() > 50 {
            return Err(BlogError::InvalidPostData.into())
        }

        let account_info_iter = &mut accounts.iter();

        let authority_account = next_account_info(account_info_iter)?;
        let blog_account = next_account_info(account_info_iter)?;
        let post_account = next_account_info(account_info_iter)?;
        let system_program = next_account_info(account_info_iter)?;

        if !authority_account.is_signer {
            return Err(ProgramError::MissingRequiredSignature);
        }

        let (blog_pda, _blog_bump) = Pubkey::find_program_address(
            &[b"blog".as_ref(), authority_account.key.as_ref()],
            program_id
        );
        if blog_pda != *blog_account.key || !blog_account.is_writable || blog_account.data_is_empty() {
            return Err(BlogError::InvalidBlogAccount.into())
        }

        let (post_pda, post_bump) = Pubkey::find_program_address(
            &[b"post".as_ref(), slug.as_ref(), authority_account.key.as_ref()],
            program_id
        );
        if post_pda != *post_account.key {
            return Err(BlogError::InvalidPostAccount.into())
        }

        let post_len: usize = 32 + 32 + 1 + (4 + slug.len()) + (4 + title.len()) + (4 + content.len());

        let rent = Rent::get()?;
        let rent_lamports = rent.minimum_balance(post_len);

        let create_post_pda_ix = &system_instruction::create_account(
            authority_account.key,
            post_account.key,
            rent_lamports,
            post_len.try_into().unwrap(),
            program_id
        );
        msg!("Creating post account!");
        invoke_signed(
            create_post_pda_ix, 
            &[
                authority_account.clone(),
                post_account.clone(),
                system_program.clone()
            ],
            &[&[
                b"post".as_ref(),
                slug.as_ref(),
                authority_account.key.as_ref(),
                &[post_bump]
            ]]
        )?;

        let mut post_account_state = try_from_slice_unchecked::<Post>(&post_account.data.borrow()).unwrap();
        post_account_state.author = *authority_account.key;
        post_account_state.blog = *blog_account.key;
        post_account_state.bump = post_bump;
        post_account_state.slug = slug;
        post_account_state.title = title;
        post_account_state.content = content;

        msg!("Serializing Post data");
        post_account_state.serialize(&mut &mut post_account.data.borrow_mut()[..])?;


        let mut blog_account_state = Blog::try_from_slice(&blog_account.data.borrow())?;
        blog_account_state.post_count += 1;

        msg!("Serializing Blog data");
        blog_account_state.serialize(&mut &mut blog_account.data.borrow_mut()[..])?;

        Ok(())
    }

    fn process_init_blog(
        accounts: &[AccountInfo],
        program_id: &Pubkey
    ) -> ProgramResult {
        let account_info_iter = &mut accounts.iter();
        
        let authority_account = next_account_info(account_info_iter)?;
        let blog_account = next_account_info(account_info_iter)?;
        let system_program = next_account_info(account_info_iter)?;

        if !authority_account.is_signer {
            return Err(ProgramError::MissingRequiredSignature);
        }

        let (blog_pda, blog_bump) = Pubkey::find_program_address(
            &[b"blog".as_ref(), authority_account.key.as_ref()],
            program_id 
        );
        if blog_pda != *blog_account.key {
            return Err(BlogError::InvalidBlogAccount.into())
        }

        let rent = Rent::get()?;
        let rent_lamports = rent.minimum_balance(Blog::LEN);
        
        let create_blog_pda_ix = &system_instruction::create_account(
            authority_account.key,
            blog_account.key,
            rent_lamports,
            Blog::LEN.try_into().unwrap(),
            program_id
        );
        msg!("Creating blog account!");
        invoke_signed(
            create_blog_pda_ix, 
            &[
                authority_account.clone(),
                blog_account.clone(),
                system_program.clone()
            ],
            &[&[
                b"blog".as_ref(),
                authority_account.key.as_ref(),
                &[blog_bump]
            ]]
        )?;

        let mut blog_account_state = Blog::try_from_slice(&blog_account.data.borrow())?;
        blog_account_state.authority = *authority_account.key;
        blog_account_state.bump = blog_bump;
        blog_account_state.post_count = 0;
        blog_account_state.serialize(&mut &mut blog_account.data.borrow_mut()[..])?;
        

        Ok(())
    }
}



#[derive(BorshDeserialize, Debug)]
struct PostIxPayload {
    slug: String,
    title: String,
    content: String
}


impl BlogInstruction {
    pub fn unpack(input: &[u8]) -> Result<Self, ProgramError> {
        let (variant, rest) = input.split_first().ok_or(BlogError::InvalidInstruction)?;
        let payload = PostIxPayload::try_from_slice(rest).unwrap();

        Ok(match variant {
            0 => Self::InitBlog {},
            1 => Self::CreatePost {
                slug: payload.slug,
                title: payload.title,
                content: payload.content
            },
            _ => return Err(BlogError::InvalidInstruction.into()),
        })
    }
}

#[derive(BorshSerialize, BorshDeserialize, Debug, Clone)]
pub struct Blog {
    pub authority: Pubkey,
    pub bump: u8,
    pub post_count: u8 // 10 posts max
}

#[derive(BorshSerialize, BorshDeserialize, Debug, Clone)]
pub struct Post {
    pub author: Pubkey,
    pub blog: Pubkey,
    pub bump: u8,
    pub slug: String, // 10 chars max
    pub title: String, // 20 chars max
    pub content: String, // 50 chars max
}

impl Blog {
    pub const LEN: usize = 32 + 1 + 1;
}

#[derive(Error, Debug, Copy, Clone)]
pub enum BlogError {
    #[error("Invalid Instruction")]
    InvalidInstruction,

    #[error("Invalid Blog Account")]
    InvalidBlogAccount,

    #[error("Invalid Post Account")]
    InvalidPostAccount,

    #[error("Invalid Post Data")]
    InvalidPostData,

    #[error("Account not Writable")]
    AccountNotWritable,
}

impl From<BlogError> for ProgramError {
    fn from(e: BlogError) -> Self {
        return ProgramError::Custom(e as u32);
    }
}

fn process_create_post(
    accounts: &[AccountInfo],
    slug: String,
    title: String,
    content: String,
    program_id: &Pubkey
) -> ProgramResult {
    if slug.len() > 10 || content.len() > 20 || title.len() > 50 {
        return Err(BlogError::InvalidPostData.into())
    }

    let account_info_iter = &mut accounts.iter();

    let authority_account = next_account_info(account_info_iter)?;
    let blog_account = next_account_info(account_info_iter)?;
    let post_account = next_account_info(account_info_iter)?;
    let system_program = next_account_info(account_info_iter)?;

    if !authority_account.is_signer {
        return Err(ProgramError::MissingRequiredSignature);
    }

    let (blog_pda, _blog_bump) = Pubkey::find_program_address(
        &[b"blog".as_ref(), authority_account.key.as_ref()],
        program_id
    );
    if blog_pda != *blog_account.key || !blog_account.is_writable || blog_account.data_is_empty() {
        return Err(BlogError::InvalidBlogAccount.into())
    }

    let (post_pda, post_bump) = Pubkey::find_program_address(
        &[b"post".as_ref(), slug.as_ref(), authority_account.key.as_ref()],
        program_id
    );
    if post_pda != *post_account.key {
        return Err(BlogError::InvalidPostAccount.into())
    }

    let post_len: usize = 32 + 32 + 1 + (4 + slug.len()) + (4 + title.len()) + (4 + content.len());

    let rent = Rent::get()?;
    let rent_lamports = rent.minimum_balance(post_len);

    let create_post_pda_ix = &system_instruction::create_account(
        authority_account.key,
        post_account.key,
        rent_lamports,
        post_len.try_into().unwrap(),
        program_id
    );
    msg!("Creating post account!");
    invoke_signed(
        create_post_pda_ix, 
        &[
            authority_account.clone(),
            post_account.clone(),
            system_program.clone()
        ],
        &[&[
            b"post".as_ref(),
            slug.as_ref(),
            authority_account.key.as_ref(),
            &[post_bump]
        ]]
    )?;

    let mut post_account_state = try_from_slice_unchecked::<Post>(&post_account.data.borrow()).unwrap();
    post_account_state.author = *authority_account.key;
    post_account_state.blog = *blog_account.key;
    post_account_state.bump = post_bump;
    post_account_state.slug = slug;
    post_account_state.title = title;
    post_account_state.content = content;

    msg!("Serializing Post data");
    post_account_state.serialize(&mut &mut post_account.data.borrow_mut()[..])?;


    let mut blog_account_state = Blog::try_from_slice(&blog_account.data.borrow())?;
    blog_account_state.post_count += 1;

    msg!("Serializing Blog data");
    blog_account_state.serialize(&mut &mut blog_account.data.borrow_mut()[..])?;

    Ok(())
}

fn process_init_blog(
    accounts: &[AccountInfo],
    program_id: &Pubkey
) -> ProgramResult {
    let account_info_iter = &mut accounts.iter();
    
    let authority_account = next_account_info(account_info_iter)?;
    let blog_account = next_account_info(account_info_iter)?;
    let system_program = next_account_info(account_info_iter)?;

    if !authority_account.is_signer {
        return Err(ProgramError::MissingRequiredSignature);
    }

    let (blog_pda, blog_bump) = Pubkey::find_program_address(
        &[b"blog".as_ref(), authority_account.key.as_ref()],
        program_id 
    );
    if blog_pda != *blog_account.key {
        return Err(BlogError::InvalidBlogAccount.into())
    }

    let rent = Rent::get()?;
    let rent_lamports = rent.minimum_balance(Blog::LEN);
    
    let create_blog_pda_ix = &system_instruction::create_account(
        authority_account.key,
        blog_account.key,
        rent_lamports,
        Blog::LEN.try_into().unwrap(),
        program_id
    );
    msg!("Creating blog account!");
    invoke_signed(
        create_blog_pda_ix, 
        &[
            authority_account.clone(),
            blog_account.clone(),
            system_program.clone()
        ],
        &[&[
            b"blog".as_ref(),
            authority_account.key.as_ref(),
            &[blog_bump]
        ]]
    )?;

    let mut blog_account_state = Blog::try_from_slice(&blog_account.data.borrow())?;
    blog_account_state.authority = *authority_account.key;
    blog_account_state.bump = blog_bump;
    blog_account_state.post_count = 0;
    blog_account_state.serialize(&mut &mut blog_account.data.borrow_mut()[..])?;
    

    Ok(())
}

Côté client, vous pouvez utiliser PublicKey.findProgramAddress() pour obtenir les adresses de compte Blog et Post nécessaires, que vous pouvez ensuite passer dans connection.getAccountInfo() pour récupérer les données du compte. Un exemple est présenté ci-dessous :

Press </> button to view full source

import * as borsh from "@project-serum/borsh";
import { PublicKey } from "@solana/web3.js";

export const BLOG_ACCOUNT_DATA_LAYOUT = borsh.struct([
  borsh.publicKey("authorityPubkey"),
  borsh.u8("bump"),
  borsh.u8("postCount"),
]);

export const POST_ACCOUNT_DATA_LAYOUT = borsh.struct([
  borsh.publicKey("author"),
  borsh.publicKey("blog"),
  borsh.u8("bump"),
  borsh.str("slug"),
  borsh.str("title"),
  borsh.str("content"),
]);

async () => {
  const connection = new Connection("http://localhost:8899", "confirmed");

  const [blogAccount] = await PublicKey.findProgramAddress(
    [Buffer.from("blog"), user.publicKey.toBuffer()],
    MY_PROGRAM_ID
  );

  const [postAccount] = await PublicKey.findProgramAddress(
    [Buffer.from("post"), Buffer.from("slug-1"), user.publicKey.toBuffer()],
    MY_PROGRAM_ID
  );

  const blogAccountInfo = await connection.getAccountInfo(blogAccount);
  const blogAccountState = BLOG_ACCOUNT_DATA_LAYOUT.decode(
    blogAccountInfo.data
  );
  console.log("Blog account state: ", blogAccountState);

  const postAccountInfo = await connection.getAccountInfo(postAccount);
  const postAccountState = POST_ACCOUNT_DATA_LAYOUT.decode(
    postAccountInfo.data
  );
  console.log("Post account state: ", postAccountState);
};

async () => {
  const connection = new Connection("http://localhost:8899", "confirmed");

  const [blogAccount] = await PublicKey.findProgramAddress(
    [Buffer.from("blog"), user.publicKey.toBuffer()],
    MY_PROGRAM_ID
  );

  const [postAccount] = await PublicKey.findProgramAddress(
    [Buffer.from("post"), Buffer.from("slug-1"), user.publicKey.toBuffer()],
    MY_PROGRAM_ID
  );

  const blogAccountInfo = await connection.getAccountInfo(blogAccount);
  const blogAccountState = BLOG_ACCOUNT_DATA_LAYOUT.decode(
    blogAccountInfo.data
  );
  console.log("Blog account state: ", blogAccountState);

  const postAccountInfo = await connection.getAccountInfo(postAccount);
  const postAccountState = POST_ACCOUNT_DATA_LAYOUT.decode(
    postAccountInfo.data
  );
  console.log("Post account state: ", postAccountState);
};

Compte de Map Unique

Une autre façon d'implémenter le mappage serait d'avoir une structure de données BTreeMap explicitement stockée dans un compte unique. L'adresse de ce compte peut être un PDA ou la clé publique d'une Paire de Clés générée.

Cette méthode de mappage des comptes n'est pas idéale pour les raisons suivantes :

• Vous devrez d'abord initialiser le compte stockant le BTreeMap, avant de pouvoir y insérer les paires clé-valeur nécessaires. Ensuite, vous devrez également stocker l'adresse de ce compte quelque part, afin de la mettre à jour à chaque fois.

• Il y a des limites de mémoire pour un compte. En effet, un compte peut avoir une taille maximale de 10 megabytes ce qui empêche le BTreeMap de stocker un grand nombre de paires clé-valeur.

Ainsi, après avoir étudié votre cas d'utilisation, vous pouvez mettre en œuvre cette méthode comme indiqué ci-dessous :

Press </> button to view full source

use std::{collections::BTreeMap};
use thiserror::Error;
use borsh::{BorshSerialize, BorshDeserialize};
use num_traits::FromPrimitive;
use solana_program::{sysvar::{rent::Rent, Sysvar}, entrypoint, entrypoint::ProgramResult, pubkey::Pubkey, account_info::{AccountInfo, next_account_info}, program_error::ProgramError, system_instruction, msg, program::{invoke_signed}, borsh::try_from_slice_unchecked};

entrypoint!(process_instruction);

fn process_instruction(
    program_id: &Pubkey,
    accounts: &[AccountInfo],
    instruction_data: &[u8],
) -> ProgramResult {
    msg!("instruction_data: {:?}", instruction_data);
    Processor::process(program_id, accounts, instruction_data)
}

pub struct Processor;

impl Processor {
    pub fn process(
        program_id: &Pubkey,
        accounts: &[AccountInfo],
        instruction_data: &[u8]
    ) -> ProgramResult {
        let instruction = FromPrimitive::from_u8(instruction_data[0]).ok_or(ProgramError::InvalidInstructionData)?;

        match instruction {
            0 => {
                msg!("Initializing map!");
                Self::process_init_map(accounts, program_id)?;
            },
            1 => {
                msg!("Inserting entry!");
                Self::process_insert_entry(accounts, program_id)?;
            },
            _ => {
                return Err(ProgramError::InvalidInstructionData)
            }
        }
        Ok(())
    }

    fn process_init_map(accounts: &[AccountInfo], program_id: &Pubkey) -> ProgramResult {
        let account_info_iter = &mut accounts.iter();

        let authority_account = next_account_info(account_info_iter)?;
        let map_account = next_account_info(account_info_iter)?;
        let system_program = next_account_info(account_info_iter)?;

        if !authority_account.is_signer {
            return Err(ProgramError::MissingRequiredSignature)
        }

        let (map_pda, map_bump) = Pubkey::find_program_address(
            &[b"map".as_ref()],
            program_id
        );

        if map_pda != *map_account.key || !map_account.is_writable || !map_account.data_is_empty() {
            return Err(BlogError::InvalidMapAccount.into())
        }

        let rent = Rent::get()?;
        let rent_lamports = rent.minimum_balance(MapAccount::LEN);

        let create_map_ix = &system_instruction::create_account(
            authority_account.key, 
            map_account.key, 
            rent_lamports, 
            MapAccount::LEN.try_into().unwrap(), 
            program_id
        );

        msg!("Creating MapAccount account");
        invoke_signed(
            create_map_ix, 
            &[
                authority_account.clone(),
                map_account.clone(),
                system_program.clone()
            ],
            &[&[
                b"map".as_ref(),
                &[map_bump]
            ]]
        )?;

        msg!("Deserializing MapAccount account");
        let mut map_state = try_from_slice_unchecked::<MapAccount>(&map_account.data.borrow()).unwrap();
        let empty_map: BTreeMap<Pubkey, Pubkey> = BTreeMap::new();

        map_state.is_initialized = 1;
        map_state.map = empty_map;

        msg!("Serializing MapAccount account");
        map_state.serialize(&mut &mut map_account.data.borrow_mut()[..])?;

        Ok(())
    }

    fn process_insert_entry(accounts: &[AccountInfo], program_id: &Pubkey) -> ProgramResult {
        
        let account_info_iter = &mut accounts.iter();

        let a_account = next_account_info(account_info_iter)?;
        let b_account = next_account_info(account_info_iter)?;
        let map_account = next_account_info(account_info_iter)?;

        if !a_account.is_signer {
            return Err(ProgramError::MissingRequiredSignature)
        }

        if map_account.data.borrow()[0] == 0 || *map_account.owner != *program_id {
            return Err(BlogError::InvalidMapAccount.into())
        }

        msg!("Deserializing MapAccount account");
        let mut map_state = try_from_slice_unchecked::<MapAccount>(&map_account.data.borrow())?;

        if map_state.map.contains_key(a_account.key) {
            return Err(BlogError::AccountAlreadyHasEntry.into())
        }

        map_state.map.insert(*a_account.key, *b_account.key);
        
        msg!("Serializing MapAccount account");
        map_state.serialize(&mut &mut map_account.data.borrow_mut()[..])?;

        Ok(())
    }
}

#[derive(BorshSerialize, BorshDeserialize, Clone, Debug)]
pub struct MapAccount {
    pub is_initialized: u8,
    pub map: BTreeMap<Pubkey, Pubkey> // 100
}

impl MapAccount {
    const LEN: usize = 1 + (4 + (10 * 64)); // 10 user -> blog
}

#[derive(Error, Debug, Copy, Clone)]
pub enum BlogError {
    #[error("Invalid MapAccount account")]
    InvalidMapAccount,

    #[error("Invalid Blog account")]
    InvalidBlogAccount,

    #[error("Account already has entry in Map")]
    AccountAlreadyHasEntry,
}

impl From<BlogError> for ProgramError {
    fn from(e: BlogError) -> Self {
        return ProgramError::Custom(e as u32);
    }
}

fn process_init_map(accounts: &[AccountInfo], program_id: &Pubkey) -> ProgramResult {
    let account_info_iter = &mut accounts.iter();

    let authority_account = next_account_info(account_info_iter)?;
    let map_account = next_account_info(account_info_iter)?;
    let system_program = next_account_info(account_info_iter)?;

    if !authority_account.is_signer {
        return Err(ProgramError::MissingRequiredSignature)
    }

    let (map_pda, map_bump) = Pubkey::find_program_address(
        &[b"map".as_ref()],
        program_id
    );

    if map_pda != *map_account.key || !map_account.is_writable || !map_account.data_is_empty() {
        return Err(BlogError::InvalidMapAccount.into())
    }

    let rent = Rent::get()?;
    let rent_lamports = rent.minimum_balance(MapAccount::LEN);

    let create_map_ix = &system_instruction::create_account(
        authority_account.key, 
        map_account.key, 
        rent_lamports, 
        MapAccount::LEN.try_into().unwrap(), 
        program_id
    );

    msg!("Creating MapAccount account");
    invoke_signed(
        create_map_ix, 
        &[
            authority_account.clone(),
            map_account.clone(),
            system_program.clone()
        ],
        &[&[
            b"map".as_ref(),
            &[map_bump]
        ]]
    )?;

    msg!("Deserializing MapAccount account");
    let mut map_state = try_from_slice_unchecked::<MapAccount>(&map_account.data.borrow()).unwrap();
    let empty_map: BTreeMap<Pubkey, Pubkey> = BTreeMap::new();

    map_state.is_initialized = 1;
    map_state.map = empty_map;

    msg!("Serializing MapAccount account");
    map_state.serialize(&mut &mut map_account.data.borrow_mut()[..])?;

    Ok(())
}

fn process_insert_entry(accounts: &[AccountInfo], program_id: &Pubkey) -> ProgramResult {
    
    let account_info_iter = &mut accounts.iter();

    let a_account = next_account_info(account_info_iter)?;
    let b_account = next_account_info(account_info_iter)?;
    let map_account = next_account_info(account_info_iter)?;

    if !a_account.is_signer {
        return Err(ProgramError::MissingRequiredSignature)
    }

    if map_account.data.borrow()[0] == 0 || *map_account.owner != *program_id {
        return Err(BlogError::InvalidMapAccount.into())
    }

    msg!("Deserializing MapAccount account");
    let mut map_state = try_from_slice_unchecked::<MapAccount>(&map_account.data.borrow())?;

    if map_state.map.contains_key(a_account.key) {
        return Err(BlogError::AccountAlreadyHasEntry.into())
    }

    map_state.map.insert(*a_account.key, *b_account.key);
    
    msg!("Serializing MapAccount account");
    map_state.serialize(&mut &mut map_account.data.borrow_mut()[..])?;

    Ok(())
}

Le code côté client pour tester le programme ci-dessus ressemblerait à quelque chose comme indiqué ci-dessous :

Press </> button to view full source

import {
  Connection,
  Keypair,
  LAMPORTS_PER_SOL,
  PublicKey,
  SystemProgram,
  Transaction,
  TransactionInstruction,
} from "@solana/web3.js";

import * as borsh from "@project-serum/borsh";

const MY_PROGRAM_ID = new PublicKey(
  "FwcG3yKuAkCfX68q9GPykNWDaaPjdZFaR1Tgr8qSxaEa"
);

const MAP_DATA_LAYOUT = borsh.struct([
  borsh.u8("is_initialized"),
  borsh.map(borsh.publicKey("user_a"), borsh.publicKey("user_b"), "blogs"),
]);

async () => {
  const connection = new Connection("http://localhost:8899", "confirmed");

  const userA = Keypair.generate();
  const userB = Keypair.generate();
  const userC = Keypair.generate();

  const [mapKey] = await PublicKey.findProgramAddress(
    [Buffer.from("map")],
    MY_PROGRAM_ID
  );

  const airdropASig = await connection.requestAirdrop(
    userA.publicKey,
    5 * LAMPORTS_PER_SOL
  );
  const airdropBSig = await connection.requestAirdrop(
    userB.publicKey,
    5 * LAMPORTS_PER_SOL
  );
  const airdropCSig = await connection.requestAirdrop(
    userC.publicKey,
    5 * LAMPORTS_PER_SOL
  );
  const promiseA = connection.confirmTransaction(airdropASig);
  const promiseB = connection.confirmTransaction(airdropBSig);
  const promiseC = connection.confirmTransaction(airdropCSig);

  await Promise.all([promiseA, promiseB, promiseC]);

  const initMapIx = new TransactionInstruction({
    programId: MY_PROGRAM_ID,
    keys: [
      {
        pubkey: userA.publicKey,
        isSigner: true,
        isWritable: true,
      },
      {
        pubkey: mapKey,
        isSigner: false,
        isWritable: true,
      },
      {
        pubkey: SystemProgram.programId,
        isSigner: false,
        isWritable: false,
      },
    ],
    data: Buffer.from(Uint8Array.of(0)),
  });

  const insertABIx = new TransactionInstruction({
    programId: MY_PROGRAM_ID,
    keys: [
      {
        pubkey: userA.publicKey,
        isSigner: true,
        isWritable: true,
      },
      {
        pubkey: userB.publicKey,
        isSigner: false,
        isWritable: false,
      },
      {
        pubkey: mapKey,
        isSigner: false,
        isWritable: true,
      },
    ],
    data: Buffer.from(Uint8Array.of(1)),
  });

  const insertBCIx = new TransactionInstruction({
    programId: MY_PROGRAM_ID,
    keys: [
      {
        pubkey: userB.publicKey,
        isSigner: true,
        isWritable: true,
      },
      {
        pubkey: userC.publicKey,
        isSigner: false,
        isWritable: false,
      },
      {
        pubkey: mapKey,
        isSigner: false,
        isWritable: true,
      },
    ],
    data: Buffer.from(Uint8Array.of(1)),
  });

  const insertCAIx = new TransactionInstruction({
    programId: MY_PROGRAM_ID,
    keys: [
      {
        pubkey: userC.publicKey,
        isSigner: true,
        isWritable: true,
      },
      {
        pubkey: userA.publicKey,
        isSigner: false,
        isWritable: false,
      },
      {
        pubkey: mapKey,
        isSigner: false,
        isWritable: true,
      },
    ],
    data: Buffer.from(Uint8Array.of(1)),
  });

  const tx = new Transaction();
  tx.add(initMapIx);
  tx.add(insertABIx);
  tx.add(insertBCIx);
  tx.add(insertCAIx);

  const sig = await connection.sendTransaction(tx, [userA, userB, userC], {
    skipPreflight: false,
    preflightCommitment: "confirmed",
  });
  await connection.confirmTransaction(sig);

  const mapAccount = await connection.getAccountInfo(mapKey);
  const mapData = MAP_DATA_LAYOUT.decode(mapAccount.data);
  console.log("MapData: ", mapData);
};

const insertABIx = new TransactionInstruction({
  programId: MY_PROGRAM_ID,
  keys: [
    {
      pubkey: userA.publicKey,
      isSigner: true,
      isWritable: true,
    },
    {
      pubkey: userB.publicKey,
      isSigner: false,
      isWritable: false,
    },
    {
      pubkey: mapKey,
      isSigner: false,
      isWritable: true,
    },
  ],
  data: Buffer.from(Uint8Array.of(1)),
});

const insertBCIx = new TransactionInstruction({
  programId: MY_PROGRAM_ID,
  keys: [
    {
      pubkey: userB.publicKey,
      isSigner: true,
      isWritable: true,
    },
    {
      pubkey: userC.publicKey,
      isSigner: false,
      isWritable: false,
    },
    {
      pubkey: mapKey,
      isSigner: false,
      isWritable: true,
    },
  ],
  data: Buffer.from(Uint8Array.of(1)),
});

const insertCAIx = new TransactionInstruction({
  programId: MY_PROGRAM_ID,
  keys: [
    {
      pubkey: userC.publicKey,
      isSigner: true,
      isWritable: true,
    },
    {
      pubkey: userA.publicKey,
      isSigner: false,
      isWritable: false,
    },
    {
      pubkey: mapKey,
      isSigner: false,
      isWritable: true,
    },
  ],
  data: Buffer.from(Uint8Array.of(1)),
});

const tx = new Transaction();
tx.add(initMapIx);
tx.add(insertABIx);
tx.add(insertBCIx);
tx.add(insertCAIx);