Add cross-interface consistency tests
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parent
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3 changed files with 617 additions and 4 deletions
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/*
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* This file is part of Sharenet.
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*
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* Sharenet is licensed under the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.
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*
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* You may obtain a copy of the license at:
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* https://creativecommons.org/licenses/by-nc-sa/4.0/
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*
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* Copyright (c) 2024 Continuist <continuist02@gmail.com>
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*/
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use application::{Service, UseCase};
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use domain::{CreateProduct, CreateUser, Product, UpdateProduct, UpdateUser, User};
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use memory::{InMemoryUserRepository, InMemoryProductRepository};
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use postgres::{PostgresUserRepository, PostgresProductRepository};
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use sqlx::PgPool;
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use sqlx::postgres::PgPoolOptions;
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use std::env;
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use uuid::Uuid;
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use serial_test::serial;
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// Helper functions for test setup
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async fn setup_test_db() -> PgPool {
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// Explicitly set DATABASE_URL to use sharenet_test database
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std::env::set_var("DATABASE_URL", "postgres://postgres:password@localhost:5432/sharenet_test");
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let database_url = env::var("DATABASE_URL")
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.unwrap_or_else(|_| "postgres://postgres:password@localhost:5432/sharenet_test".to_string());
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let pool = PgPoolOptions::new()
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.max_connections(5)
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.connect(&database_url)
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.await
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.expect("Failed to connect to test database");
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sqlx::migrate!("../../migrations")
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.run(&pool)
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.await
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.expect("Failed to run migrations");
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cleanup_test_data(&pool).await;
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pool
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}
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async fn cleanup_test_data(pool: &PgPool) {
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let mut tx = pool.begin().await.expect("Failed to begin transaction");
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sqlx::query("TRUNCATE TABLE products, users RESTART IDENTITY CASCADE").execute(&mut *tx).await.expect("Failed to truncate tables");
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tx.commit().await.expect("Failed to commit cleanup transaction");
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// Assert tables are empty
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let users_count: (i64,) = sqlx::query_as("SELECT COUNT(*) FROM users").fetch_one(pool).await.expect("Failed to count users");
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let products_count: (i64,) = sqlx::query_as("SELECT COUNT(*) FROM products").fetch_one(pool).await.expect("Failed to count products");
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assert_eq!(users_count.0, 0, "Users table not empty after cleanup");
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assert_eq!(products_count.0, 0, "Products table not empty after cleanup");
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}
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fn unique_test_data(prefix: &str) -> (String, String) {
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let id = Uuid::new_v4().to_string();
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(format!("{}_{}", prefix, id), format!("{}_{}@example.com", prefix, id))
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}
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// Test data structures for comparison
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#[derive(Debug, PartialEq, Clone)]
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struct UserData {
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username: String,
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email: String,
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}
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impl From<&User> for UserData {
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fn from(user: &User) -> Self {
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Self {
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username: user.username().to_string(),
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email: user.email().to_string(),
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}
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}
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}
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#[derive(Debug, PartialEq, Clone)]
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struct ProductData {
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name: String,
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description: String,
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}
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impl From<&Product> for ProductData {
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fn from(product: &Product) -> Self {
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Self {
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name: product.name().to_string(),
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description: product.description().to_string(),
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}
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}
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}
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// Helper function to compare user lists (ignoring IDs and timestamps)
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fn compare_user_lists(users1: &[User], users2: &[User]) {
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let data1: Vec<UserData> = users1.iter().map(UserData::from).collect();
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let data2: Vec<UserData> = users2.iter().map(UserData::from).collect();
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assert_eq!(data1.len(), data2.len(), "User count mismatch");
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// Sort by username for consistent comparison
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let mut sorted1 = data1.clone();
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let mut sorted2 = data2.clone();
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sorted1.sort_by(|a, b| a.username.cmp(&b.username));
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sorted2.sort_by(|a, b| a.username.cmp(&b.username));
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assert_eq!(sorted1, sorted2, "User data mismatch");
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}
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// Helper function to compare product lists (ignoring IDs and timestamps)
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fn compare_product_lists(products1: &[Product], products2: &[Product]) {
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let data1: Vec<ProductData> = products1.iter().map(ProductData::from).collect();
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let data2: Vec<ProductData> = products2.iter().map(ProductData::from).collect();
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assert_eq!(data1.len(), data2.len(), "Product count mismatch");
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// Sort by name for consistent comparison
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let mut sorted1 = data1.clone();
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let mut sorted2 = data2.clone();
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sorted1.sort_by(|a, b| a.name.cmp(&b.name));
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sorted2.sort_by(|a, b| a.name.cmp(&b.name));
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assert_eq!(sorted1, sorted2, "Product data mismatch");
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}
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// Helper function to create services for different interfaces
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fn create_memory_services() -> (Service<User, InMemoryUserRepository>, Service<Product, InMemoryProductRepository>) {
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let user_repo = InMemoryUserRepository::new();
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let product_repo = InMemoryProductRepository::new();
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let user_service = Service::new(user_repo);
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let product_service = Service::new(product_repo);
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(user_service, product_service)
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}
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fn create_postgres_services(pool: PgPool) -> (Service<User, PostgresUserRepository>, Service<Product, PostgresProductRepository>) {
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let user_repo = PostgresUserRepository::new(pool.clone());
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let product_repo = PostgresProductRepository::new(pool);
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let user_service = Service::new(user_repo);
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let product_service = Service::new(product_repo);
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(user_service, product_service)
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}
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#[tokio::test]
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#[serial]
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async fn test_api_cli_consistency_with_memory() {
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// Create services for both interfaces using memory backend
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let (api_user_service, api_product_service) = create_memory_services();
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let (cli_user_service, cli_product_service) = create_memory_services();
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// Test data
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let (username1, email1) = unique_test_data("api_cli_user1");
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let (username2, email2) = unique_test_data("api_cli_user2");
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let (name1, _) = unique_test_data("api_cli_product1");
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let (name2, _) = unique_test_data("api_cli_product2");
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// Test 1: Create users via API interface and capture state
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let create_user1 = CreateUser::new(username1.clone(), email1.clone()).unwrap();
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let create_user2 = CreateUser::new(username2.clone(), email2.clone()).unwrap();
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let api_user1 = api_user_service.create(create_user1.clone()).await.unwrap();
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let _api_user2 = api_user_service.create(create_user2.clone()).await.unwrap();
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let api_users_after_create = api_user_service.list().await.unwrap();
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assert_eq!(api_users_after_create.len(), 2);
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// Test 2: Create same users via CLI interface and compare
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let cli_user1 = cli_user_service.create(create_user1).await.unwrap();
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let _cli_user2 = cli_user_service.create(create_user2).await.unwrap();
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let cli_users_after_create = cli_user_service.list().await.unwrap();
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assert_eq!(cli_users_after_create.len(), 2);
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// Compare user data (ignoring IDs and timestamps)
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compare_user_lists(&api_users_after_create, &cli_users_after_create);
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// Test 3: Create products via API interface and capture state
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let create_product1 = CreateProduct::new(name1.clone(), "Description 1".to_string()).unwrap();
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let create_product2 = CreateProduct::new(name2.clone(), "Description 2".to_string()).unwrap();
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let api_product1 = api_product_service.create(create_product1.clone()).await.unwrap();
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let _api_product2 = api_product_service.create(create_product2.clone()).await.unwrap();
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let api_products_after_create = api_product_service.list().await.unwrap();
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assert_eq!(api_products_after_create.len(), 2);
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// Test 4: Create same products via CLI interface and compare
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let cli_product1 = cli_product_service.create(create_product1).await.unwrap();
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let _cli_product2 = cli_product_service.create(create_product2).await.unwrap();
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let cli_products_after_create = cli_product_service.list().await.unwrap();
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assert_eq!(cli_products_after_create.len(), 2);
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// Compare product data (ignoring IDs and timestamps)
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compare_product_lists(&api_products_after_create, &cli_products_after_create);
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// Test 5: Test that both interfaces can access the same data
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let api_retrieved_user = api_user_service.get(api_user1.id()).await.unwrap();
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let cli_retrieved_user = cli_user_service.get(cli_user1.id()).await.unwrap();
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assert_eq!(api_retrieved_user.username(), cli_retrieved_user.username());
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assert_eq!(api_retrieved_user.email(), cli_retrieved_user.email());
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let api_retrieved_product = api_product_service.get(api_product1.id()).await.unwrap();
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let cli_retrieved_product = cli_product_service.get(cli_product1.id()).await.unwrap();
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assert_eq!(api_retrieved_product.name(), cli_retrieved_product.name());
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assert_eq!(api_retrieved_product.description(), cli_retrieved_product.description());
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// Test 6: Test update consistency - update same user via both interfaces
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let update_user_data = UpdateUser::new(Some("updated_username".to_string()), Some("updated@example.com".to_string())).unwrap();
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let api_updated_user = api_user_service.update(api_user1.id(), update_user_data.clone()).await.unwrap();
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let cli_updated_user = cli_user_service.update(cli_user1.id(), update_user_data).await.unwrap();
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assert_eq!(api_updated_user.username(), cli_updated_user.username());
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assert_eq!(api_updated_user.email(), cli_updated_user.email());
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// Test 7: Test delete consistency
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api_user_service.delete(api_user1.id()).await.unwrap();
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cli_user_service.delete(cli_user1.id()).await.unwrap();
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let api_users_after_delete = api_user_service.list().await.unwrap();
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let cli_users_after_delete = cli_user_service.list().await.unwrap();
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assert_eq!(api_users_after_delete.len(), 1);
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assert_eq!(cli_users_after_delete.len(), 1);
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compare_user_lists(&api_users_after_delete, &cli_users_after_delete);
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}
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#[tokio::test]
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#[serial]
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async fn test_api_tui_consistency_with_memory() {
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// Create services for both interfaces using memory backend
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let (api_user_service, api_product_service) = create_memory_services();
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let (tui_user_service, tui_product_service) = create_memory_services();
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// Test data
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let (username1, email1) = unique_test_data("api_tui_user1");
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let (username2, email2) = unique_test_data("api_tui_user2");
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let (name1, _) = unique_test_data("api_tui_product1");
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let (name2, _) = unique_test_data("api_tui_product2");
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// Test 1: Create users via API interface and capture state
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let create_user1 = CreateUser::new(username1.clone(), email1.clone()).unwrap();
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let create_user2 = CreateUser::new(username2.clone(), email2.clone()).unwrap();
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let api_user1 = api_user_service.create(create_user1.clone()).await.unwrap();
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let _api_user2 = api_user_service.create(create_user2.clone()).await.unwrap();
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let api_users_after_create = api_user_service.list().await.unwrap();
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assert_eq!(api_users_after_create.len(), 2);
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// Test 2: Create same users via TUI interface and compare
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let tui_user1 = tui_user_service.create(create_user1).await.unwrap();
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let _tui_user2 = tui_user_service.create(create_user2).await.unwrap();
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let tui_users_after_create = tui_user_service.list().await.unwrap();
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assert_eq!(tui_users_after_create.len(), 2);
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// Compare user data (ignoring IDs and timestamps)
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compare_user_lists(&api_users_after_create, &tui_users_after_create);
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// Test 3: Create products via API interface and capture state
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let create_product1 = CreateProduct::new(name1.clone(), "Description 1".to_string()).unwrap();
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let create_product2 = CreateProduct::new(name2.clone(), "Description 2".to_string()).unwrap();
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let api_product1 = api_product_service.create(create_product1.clone()).await.unwrap();
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let _api_product2 = api_product_service.create(create_product2.clone()).await.unwrap();
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let api_products_after_create = api_product_service.list().await.unwrap();
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assert_eq!(api_products_after_create.len(), 2);
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// Test 4: Create same products via TUI interface and compare
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let tui_product1 = tui_product_service.create(create_product1).await.unwrap();
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let _tui_product2 = tui_product_service.create(create_product2).await.unwrap();
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let tui_products_after_create = tui_product_service.list().await.unwrap();
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assert_eq!(tui_products_after_create.len(), 2);
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// Compare product data (ignoring IDs and timestamps)
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compare_product_lists(&api_products_after_create, &tui_products_after_create);
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// Test 5: Test that both interfaces can access the same data
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let api_retrieved_user = api_user_service.get(api_user1.id()).await.unwrap();
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let tui_retrieved_user = tui_user_service.get(tui_user1.id()).await.unwrap();
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assert_eq!(api_retrieved_user.username(), tui_retrieved_user.username());
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assert_eq!(api_retrieved_user.email(), tui_retrieved_user.email());
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let api_retrieved_product = api_product_service.get(api_product1.id()).await.unwrap();
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let tui_retrieved_product = tui_product_service.get(tui_product1.id()).await.unwrap();
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assert_eq!(api_retrieved_product.name(), tui_retrieved_product.name());
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assert_eq!(api_retrieved_product.description(), tui_retrieved_product.description());
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// Test 6: Test update consistency - update same user via both interfaces
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let update_user_data = UpdateUser::new(Some("updated_username".to_string()), Some("updated@example.com".to_string())).unwrap();
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let api_updated_user = api_user_service.update(api_user1.id(), update_user_data.clone()).await.unwrap();
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let tui_updated_user = tui_user_service.update(tui_user1.id(), update_user_data).await.unwrap();
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assert_eq!(api_updated_user.username(), tui_updated_user.username());
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assert_eq!(api_updated_user.email(), tui_updated_user.email());
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// Test 7: Test delete consistency
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api_user_service.delete(api_user1.id()).await.unwrap();
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tui_user_service.delete(tui_user1.id()).await.unwrap();
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let api_users_after_delete = api_user_service.list().await.unwrap();
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let tui_users_after_delete = tui_user_service.list().await.unwrap();
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assert_eq!(api_users_after_delete.len(), 1);
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assert_eq!(tui_users_after_delete.len(), 1);
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compare_user_lists(&api_users_after_delete, &tui_users_after_delete);
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}
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#[tokio::test]
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#[serial]
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async fn test_cli_tui_consistency_with_memory() {
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// Create services for both interfaces using memory backend
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let (cli_user_service, cli_product_service) = create_memory_services();
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let (tui_user_service, tui_product_service) = create_memory_services();
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// Test data
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let (username1, email1) = unique_test_data("cli_tui_user1");
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let (username2, email2) = unique_test_data("cli_tui_user2");
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let (name1, _) = unique_test_data("cli_tui_product1");
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let (name2, _) = unique_test_data("cli_tui_product2");
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// Test 1: Create users via CLI interface and capture state
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let create_user1 = CreateUser::new(username1.clone(), email1.clone()).unwrap();
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let create_user2 = CreateUser::new(username2.clone(), email2.clone()).unwrap();
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let cli_user1 = cli_user_service.create(create_user1.clone()).await.unwrap();
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let _cli_user2 = cli_user_service.create(create_user2.clone()).await.unwrap();
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let cli_users_after_create = cli_user_service.list().await.unwrap();
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assert_eq!(cli_users_after_create.len(), 2);
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// Test 2: Create same users via TUI interface and compare
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let tui_user1 = tui_user_service.create(create_user1).await.unwrap();
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let _tui_user2 = tui_user_service.create(create_user2).await.unwrap();
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let tui_users_after_create = tui_user_service.list().await.unwrap();
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assert_eq!(tui_users_after_create.len(), 2);
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// Compare user data (ignoring IDs and timestamps)
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compare_user_lists(&cli_users_after_create, &tui_users_after_create);
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// Test 3: Create products via CLI interface and capture state
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let create_product1 = CreateProduct::new(name1.clone(), "Description 1".to_string()).unwrap();
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let create_product2 = CreateProduct::new(name2.clone(), "Description 2".to_string()).unwrap();
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let cli_product1 = cli_product_service.create(create_product1.clone()).await.unwrap();
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let _cli_product2 = cli_product_service.create(create_product2.clone()).await.unwrap();
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let cli_products_after_create = cli_product_service.list().await.unwrap();
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assert_eq!(cli_products_after_create.len(), 2);
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// Test 4: Create same products via TUI interface and compare
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let tui_product1 = tui_product_service.create(create_product1).await.unwrap();
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let _tui_product2 = tui_product_service.create(create_product2).await.unwrap();
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let tui_products_after_create = tui_product_service.list().await.unwrap();
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assert_eq!(tui_products_after_create.len(), 2);
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// Compare product data (ignoring IDs and timestamps)
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compare_product_lists(&cli_products_after_create, &tui_products_after_create);
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// Test 5: Test that both interfaces can access the same data
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let cli_retrieved_user = cli_user_service.get(cli_user1.id()).await.unwrap();
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let tui_retrieved_user = tui_user_service.get(tui_user1.id()).await.unwrap();
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assert_eq!(cli_retrieved_user.username(), tui_retrieved_user.username());
|
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assert_eq!(cli_retrieved_user.email(), tui_retrieved_user.email());
|
||||
|
||||
let cli_retrieved_product = cli_product_service.get(cli_product1.id()).await.unwrap();
|
||||
let tui_retrieved_product = tui_product_service.get(tui_product1.id()).await.unwrap();
|
||||
|
||||
assert_eq!(cli_retrieved_product.name(), tui_retrieved_product.name());
|
||||
assert_eq!(cli_retrieved_product.description(), tui_retrieved_product.description());
|
||||
|
||||
// Test 6: Test update consistency - update same user via both interfaces
|
||||
let update_user_data = UpdateUser::new(Some("updated_username".to_string()), Some("updated@example.com".to_string())).unwrap();
|
||||
|
||||
let cli_updated_user = cli_user_service.update(cli_user1.id(), update_user_data.clone()).await.unwrap();
|
||||
let tui_updated_user = tui_user_service.update(tui_user1.id(), update_user_data).await.unwrap();
|
||||
|
||||
assert_eq!(cli_updated_user.username(), tui_updated_user.username());
|
||||
assert_eq!(cli_updated_user.email(), tui_updated_user.email());
|
||||
|
||||
// Test 7: Test delete consistency
|
||||
cli_user_service.delete(cli_user1.id()).await.unwrap();
|
||||
tui_user_service.delete(tui_user1.id()).await.unwrap();
|
||||
|
||||
let cli_users_after_delete = cli_user_service.list().await.unwrap();
|
||||
let tui_users_after_delete = tui_user_service.list().await.unwrap();
|
||||
|
||||
assert_eq!(cli_users_after_delete.len(), 1);
|
||||
assert_eq!(tui_users_after_delete.len(), 1);
|
||||
compare_user_lists(&cli_users_after_delete, &tui_users_after_delete);
|
||||
}
|
||||
|
||||
#[tokio::test]
|
||||
#[serial]
|
||||
async fn test_api_cli_consistency_with_postgres() {
|
||||
let pool = setup_test_db().await;
|
||||
cleanup_test_data(&pool).await;
|
||||
|
||||
// Double-check that the database is empty
|
||||
let users_count: (i64,) = sqlx::query_as("SELECT COUNT(*) FROM users").fetch_one(&pool).await.expect("Failed to count users");
|
||||
let products_count: (i64,) = sqlx::query_as("SELECT COUNT(*) FROM products").fetch_one(&pool).await.expect("Failed to count products");
|
||||
println!("Database state before test: {} users, {} products", users_count.0, products_count.0);
|
||||
assert_eq!(users_count.0, 0, "Users table not empty before test");
|
||||
assert_eq!(products_count.0, 0, "Products table not empty before test");
|
||||
|
||||
// Test data
|
||||
let (username1, email1) = unique_test_data("api_cli_user1");
|
||||
let (username2, email2) = unique_test_data("api_cli_user2");
|
||||
let (name1, _) = unique_test_data("api_cli_product1");
|
||||
let (name2, _) = unique_test_data("api_cli_product2");
|
||||
|
||||
println!("Generated usernames: {}, {}", username1, username2);
|
||||
|
||||
// Test 1: Create users via API interface and capture state
|
||||
let (api_user_service, _api_product_service) = create_postgres_services(pool.clone());
|
||||
|
||||
let create_user1 = CreateUser::new(username1.clone(), email1.clone()).unwrap();
|
||||
let create_user2 = CreateUser::new(username2.clone(), email2.clone()).unwrap();
|
||||
|
||||
println!("Creating API user 1: {}", username1);
|
||||
let _api_user1 = api_user_service.create(create_user1.clone()).await.unwrap();
|
||||
println!("Creating API user 2: {}", username2);
|
||||
let _api_user2 = api_user_service.create(create_user2.clone()).await.unwrap();
|
||||
|
||||
let api_users_after_create = api_user_service.list().await.unwrap();
|
||||
assert_eq!(api_users_after_create.len(), 2);
|
||||
|
||||
// Test 2: Create same users via CLI interface and compare
|
||||
cleanup_test_data(&pool).await;
|
||||
let (cli_user_service, _cli_product_service) = create_postgres_services(pool.clone());
|
||||
|
||||
println!("Creating CLI user 1: {}", username1);
|
||||
let _cli_user1 = cli_user_service.create(create_user1).await.unwrap();
|
||||
println!("Creating CLI user 2: {}", username2);
|
||||
let _cli_user2 = cli_user_service.create(create_user2).await.unwrap();
|
||||
|
||||
let cli_users_after_create = cli_user_service.list().await.unwrap();
|
||||
assert_eq!(cli_users_after_create.len(), 2);
|
||||
|
||||
// Compare user data (ignoring IDs and timestamps)
|
||||
compare_user_lists(&api_users_after_create, &cli_users_after_create);
|
||||
|
||||
// Test 3: Create products via API interface and capture state
|
||||
cleanup_test_data(&pool).await;
|
||||
let (_api_user_service, api_product_service) = create_postgres_services(pool.clone());
|
||||
|
||||
let create_product1 = CreateProduct::new(name1.clone(), "Description 1".to_string()).unwrap();
|
||||
let create_product2 = CreateProduct::new(name2.clone(), "Description 2".to_string()).unwrap();
|
||||
|
||||
let _api_product1 = api_product_service.create(create_product1.clone()).await.unwrap();
|
||||
let _api_product2 = api_product_service.create(create_product2.clone()).await.unwrap();
|
||||
|
||||
let api_products_after_create = api_product_service.list().await.unwrap();
|
||||
assert_eq!(api_products_after_create.len(), 2);
|
||||
|
||||
// Test 4: Create same products via CLI interface and compare
|
||||
cleanup_test_data(&pool).await;
|
||||
let (_cli_user_service, cli_product_service) = create_postgres_services(pool.clone());
|
||||
|
||||
let _cli_product1 = cli_product_service.create(create_product1).await.unwrap();
|
||||
let _cli_product2 = cli_product_service.create(create_product2).await.unwrap();
|
||||
|
||||
let cli_products_after_create = cli_product_service.list().await.unwrap();
|
||||
assert_eq!(cli_products_after_create.len(), 2);
|
||||
|
||||
// Compare product data (ignoring IDs and timestamps)
|
||||
compare_product_lists(&api_products_after_create, &cli_products_after_create);
|
||||
|
||||
// Test 5: Test that both interfaces can access the same data (using shared database)
|
||||
cleanup_test_data(&pool).await;
|
||||
let (api_user_service, _api_product_service) = create_postgres_services(pool.clone());
|
||||
let (cli_user_service, _cli_product_service) = create_postgres_services(pool);
|
||||
|
||||
// Create a user via API
|
||||
let create_user = CreateUser::new(username1.clone(), email1.clone()).unwrap();
|
||||
let api_user = api_user_service.create(create_user).await.unwrap();
|
||||
|
||||
// Both services should be able to access the same user
|
||||
let api_retrieved_user = api_user_service.get(api_user.id()).await.unwrap();
|
||||
let cli_retrieved_user = cli_user_service.get(api_user.id()).await.unwrap();
|
||||
|
||||
assert_eq!(api_retrieved_user.username(), cli_retrieved_user.username());
|
||||
assert_eq!(api_retrieved_user.email(), cli_retrieved_user.email());
|
||||
|
||||
// Test 6: Test update consistency - update same user via both interfaces
|
||||
let update_user_data = UpdateUser::new(Some("updated_username".to_string()), Some("updated@example.com".to_string())).unwrap();
|
||||
|
||||
let api_updated_user = api_user_service.update(api_user.id(), update_user_data.clone()).await.unwrap();
|
||||
let cli_updated_user = cli_user_service.update(api_user.id(), update_user_data).await.unwrap();
|
||||
|
||||
assert_eq!(api_updated_user.username(), cli_updated_user.username());
|
||||
assert_eq!(api_updated_user.email(), cli_updated_user.email());
|
||||
|
||||
// Test 7: Test delete consistency
|
||||
api_user_service.delete(api_user.id()).await.unwrap();
|
||||
|
||||
// Both services should see the user as deleted
|
||||
let api_users_after_delete = api_user_service.list().await.unwrap();
|
||||
let cli_users_after_delete = cli_user_service.list().await.unwrap();
|
||||
|
||||
assert_eq!(api_users_after_delete.len(), 0);
|
||||
assert_eq!(cli_users_after_delete.len(), 0);
|
||||
}
|
||||
|
||||
#[tokio::test]
|
||||
#[serial]
|
||||
async fn test_error_handling_consistency_across_interfaces() {
|
||||
let pool = setup_test_db().await;
|
||||
|
||||
// Create services for all interfaces using PostgreSQL backend
|
||||
let (api_user_service, api_product_service) = create_postgres_services(pool.clone());
|
||||
let (cli_user_service, cli_product_service) = create_postgres_services(pool.clone());
|
||||
let (tui_user_service, tui_product_service) = create_postgres_services(pool);
|
||||
|
||||
// Test 1: Get non-existent user via all interfaces
|
||||
let non_existent_id = Uuid::new_v4();
|
||||
|
||||
let api_user_result = api_user_service.get(non_existent_id).await;
|
||||
let cli_user_result = cli_user_service.get(non_existent_id).await;
|
||||
let tui_user_result = tui_user_service.get(non_existent_id).await;
|
||||
|
||||
assert!(api_user_result.is_err());
|
||||
assert!(cli_user_result.is_err());
|
||||
assert!(tui_user_result.is_err());
|
||||
|
||||
// All should return the same error type
|
||||
assert!(matches!(api_user_result.unwrap_err(), application::ApplicationError::Domain(domain::DomainError::NotFound(_))));
|
||||
assert!(matches!(cli_user_result.unwrap_err(), application::ApplicationError::Domain(domain::DomainError::NotFound(_))));
|
||||
assert!(matches!(tui_user_result.unwrap_err(), application::ApplicationError::Domain(domain::DomainError::NotFound(_))));
|
||||
|
||||
// Test 2: Get non-existent product via all interfaces
|
||||
let api_product_result = api_product_service.get(non_existent_id).await;
|
||||
let cli_product_result = cli_product_service.get(non_existent_id).await;
|
||||
let tui_product_result = tui_product_service.get(non_existent_id).await;
|
||||
|
||||
assert!(api_product_result.is_err());
|
||||
assert!(cli_product_result.is_err());
|
||||
assert!(tui_product_result.is_err());
|
||||
|
||||
assert!(matches!(api_product_result.unwrap_err(), application::ApplicationError::Domain(domain::DomainError::NotFound(_))));
|
||||
assert!(matches!(cli_product_result.unwrap_err(), application::ApplicationError::Domain(domain::DomainError::NotFound(_))));
|
||||
assert!(matches!(tui_product_result.unwrap_err(), application::ApplicationError::Domain(domain::DomainError::NotFound(_))));
|
||||
|
||||
// Test 3: Update non-existent user via all interfaces
|
||||
let update_user_data = UpdateUser::new(Some("new_username".to_string()), None).unwrap();
|
||||
|
||||
let api_update_result = api_user_service.update(non_existent_id, update_user_data.clone()).await;
|
||||
let cli_update_result = cli_user_service.update(non_existent_id, update_user_data.clone()).await;
|
||||
let tui_update_result = tui_user_service.update(non_existent_id, update_user_data).await;
|
||||
|
||||
assert!(api_update_result.is_err());
|
||||
assert!(cli_update_result.is_err());
|
||||
assert!(tui_update_result.is_err());
|
||||
|
||||
assert!(matches!(api_update_result.unwrap_err(), application::ApplicationError::Domain(domain::DomainError::NotFound(_))));
|
||||
assert!(matches!(cli_update_result.unwrap_err(), application::ApplicationError::Domain(domain::DomainError::NotFound(_))));
|
||||
assert!(matches!(tui_update_result.unwrap_err(), application::ApplicationError::Domain(domain::DomainError::NotFound(_))));
|
||||
|
||||
// Test 4: Delete non-existent user via all interfaces
|
||||
let api_delete_result = api_user_service.delete(non_existent_id).await;
|
||||
let cli_delete_result = cli_user_service.delete(non_existent_id).await;
|
||||
let tui_delete_result = tui_user_service.delete(non_existent_id).await;
|
||||
|
||||
assert!(api_delete_result.is_err());
|
||||
assert!(cli_delete_result.is_err());
|
||||
assert!(tui_delete_result.is_err());
|
||||
|
||||
assert!(matches!(api_delete_result.unwrap_err(), application::ApplicationError::Domain(domain::DomainError::NotFound(_))));
|
||||
assert!(matches!(cli_delete_result.unwrap_err(), application::ApplicationError::Domain(domain::DomainError::NotFound(_))));
|
||||
assert!(matches!(tui_delete_result.unwrap_err(), application::ApplicationError::Domain(domain::DomainError::NotFound(_))));
|
||||
}
|
||||
|
||||
#[tokio::test]
|
||||
#[serial]
|
||||
async fn test_validation_consistency_across_interfaces() {
|
||||
// Test that all interfaces validate input consistently
|
||||
// This test doesn't need actual services since validation happens at the domain level
|
||||
|
||||
// Test 1: Create user with empty username
|
||||
let create_user_empty_username = CreateUser::new("".to_string(), "test@example.com".to_string());
|
||||
assert!(create_user_empty_username.is_err());
|
||||
assert!(matches!(create_user_empty_username.unwrap_err(), domain::DomainError::InvalidInput(_)));
|
||||
|
||||
// Test 2: Create product with empty name
|
||||
let create_product_empty_name = CreateProduct::new("".to_string(), "description".to_string());
|
||||
assert!(create_product_empty_name.is_err());
|
||||
assert!(matches!(create_product_empty_name.unwrap_err(), domain::DomainError::InvalidInput(_)));
|
||||
|
||||
// Test 3: Update user with empty username
|
||||
let update_user_empty_username = UpdateUser::new(Some("".to_string()), None);
|
||||
assert!(update_user_empty_username.is_err());
|
||||
assert!(matches!(update_user_empty_username.unwrap_err(), domain::DomainError::InvalidInput(_)));
|
||||
|
||||
// Test 4: Update product with empty name
|
||||
let update_product_empty_name = UpdateProduct::new(Some("".to_string()), None);
|
||||
assert!(update_product_empty_name.is_err());
|
||||
assert!(matches!(update_product_empty_name.unwrap_err(), domain::DomainError::InvalidInput(_)));
|
||||
}
|
||||
|
|
@ -21,6 +21,9 @@ use serial_test::serial;
|
|||
|
||||
// Helper functions for test setup
|
||||
async fn setup_test_db() -> PgPool {
|
||||
// Explicitly set DATABASE_URL to use sharenet_test database
|
||||
std::env::set_var("DATABASE_URL", "postgres://postgres:password@localhost:5432/sharenet_test");
|
||||
|
||||
let database_url = env::var("DATABASE_URL")
|
||||
.unwrap_or_else(|_| "postgres://postgres:password@localhost:5432/sharenet_test".to_string());
|
||||
let pool = PgPoolOptions::new()
|
||||
|
|
@ -38,14 +41,18 @@ async fn setup_test_db() -> PgPool {
|
|||
|
||||
async fn cleanup_test_data(pool: &PgPool) {
|
||||
let mut tx = pool.begin().await.expect("Failed to begin transaction");
|
||||
sqlx::query("DELETE FROM products").execute(&mut *tx).await.expect("Failed to delete products");
|
||||
sqlx::query("DELETE FROM users").execute(&mut *tx).await.expect("Failed to delete users");
|
||||
sqlx::query("TRUNCATE TABLE products, users RESTART IDENTITY CASCADE").execute(&mut *tx).await.expect("Failed to truncate tables");
|
||||
tx.commit().await.expect("Failed to commit cleanup transaction");
|
||||
// Assert tables are empty
|
||||
let users_count: (i64,) = sqlx::query_as("SELECT COUNT(*) FROM users").fetch_one(pool).await.expect("Failed to count users");
|
||||
let products_count: (i64,) = sqlx::query_as("SELECT COUNT(*) FROM products").fetch_one(pool).await.expect("Failed to count products");
|
||||
assert_eq!(users_count.0, 0, "Users table not empty after cleanup");
|
||||
assert_eq!(products_count.0, 0, "Products table not empty after cleanup");
|
||||
}
|
||||
|
||||
fn unique_test_data(prefix: &str) -> (String, String) {
|
||||
let id = Uuid::new_v4().to_string()[..8].to_string();
|
||||
(format!("{}_{}", prefix, id), format!("{}_test@example.com", prefix))
|
||||
let id = Uuid::new_v4().to_string();
|
||||
(format!("{}_{}", prefix, id), format!("{}_{}@example.com", prefix, id))
|
||||
}
|
||||
|
||||
// Test data structures for comparison
|
||||
|
|
|
|||
|
|
@ -16,6 +16,8 @@ pub mod cli_tests;
|
|||
#[cfg(test)]
|
||||
pub mod cross_repository_consistency_tests;
|
||||
#[cfg(test)]
|
||||
pub mod cross_interface_consistency_tests;
|
||||
#[cfg(test)]
|
||||
pub mod migration_tests;
|
||||
#[cfg(test)]
|
||||
pub mod performance_tests;
|
||||
|
|
|
|||
Loading…
Add table
Reference in a new issue