//! Sub-phase 3b integration tests for the advanced-mode SQL
//! `INSERT` surface (ADR-0033 §1).
//!
//! Covers:
//! - Worker round-trip: a validated `INSERT` runs against the
//!   database, returns the affected-row count, and re-persists the
//!   target table's CSV (ADR-0030 §11).
//! - Single-row, multi-row, explicit-column-list, and full-arity
//!   (no column list) forms.
//! - `history.log` records the literal submitted line.
//! - A failing INSERT (PK conflict) rolls back and does NOT
//!   re-persist the CSV.
//! - Parse path: `parse_command` (advanced mode) lowers the dev
//!   `sqlinsert` scaffold to `Command::SqlInsert`, reconstructing
//!   valid `insert …` SQL and extracting the target table.
//! - `__rdbms_*` target tables are rejected at the grammar layer.
//!
//! The dev `sqlinsert` entry word keeps the SQL INSERT path
//! isolated from the DSL `insert` word until sub-phase 3j; the
//! worker-level tests call `db.run_sql_insert` directly with the
//! real reconstructed SQL.

use rdbms_playground::db::Database;
use rdbms_playground::dsl::{ColumnSpec, Command, Type, parse_command};
use rdbms_playground::persistence::Persistence;
use rdbms_playground::project;

fn rt() -> tokio::runtime::Runtime {
    tokio::runtime::Builder::new_current_thread()
        .enable_all()
        .build()
        .expect("tokio rt")
}

fn open_project_db() -> (project::Project, Database, tempfile::TempDir) {
    let dir = tempfile::tempdir().expect("create tempdir");
    let project =
        project::open_or_create(None, Some(dir.path())).expect("open or create project");
    let persistence = Persistence::new(project.path().to_path_buf());
    let db = Database::open_with_persistence(project.db_path(), persistence)
        .expect("open db with persistence");
    (project, db, dir)
}

fn read_csv(project: &project::Project, table: &str) -> Option<String> {
    std::fs::read_to_string(project.path().join("data").join(format!("{table}.csv"))).ok()
}

/// Create a two-column table `T(a int pk, b text)` — no
/// auto-generated columns, so 3b's explicit-values requirement is
/// satisfied by every INSERT below.
fn create_t(db: &Database, rt: &tokio::runtime::Runtime) {
    rt.block_on(db.create_table(
        "T".to_string(),
        vec![
            ColumnSpec::new("a", Type::Int),
            ColumnSpec::new("b", Type::Text),
        ],
        vec!["a".to_string()],
        None,
    ))
    .expect("create table T");
}

#[test]
fn single_row_insert_persists_and_counts() {
    let (project, db, _dir) = open_project_db();
    let rt = rt();
    create_t(&db, &rt);
    let result = rt
        .block_on(db.run_sql_insert(
            "insert into T (a, b) values (1, 'Ada')".to_string(),
            Some("insert into T (a, b) values (1, 'Ada')".to_string()),
            "T".to_string(),
        ))
        .expect("insert runs");
    assert_eq!(result.rows_affected, 1, "one row inserted");
    let csv = read_csv(&project, "T").expect("T.csv written after insert");
    assert!(csv.contains("Ada"), "CSV reflects the inserted row: {csv:?}");
}

#[test]
fn multi_row_insert_persists_both_rows() {
    let (project, db, _dir) = open_project_db();
    let rt = rt();
    create_t(&db, &rt);
    let result = rt
        .block_on(db.run_sql_insert(
            "insert into T (a, b) values (1, 'first'), (2, 'second')".to_string(),
            None,
            "T".to_string(),
        ))
        .expect("multi-row insert runs");
    assert_eq!(result.rows_affected, 2, "two rows inserted");
    let csv = read_csv(&project, "T").expect("T.csv written");
    assert!(
        csv.contains("first") && csv.contains("second"),
        "CSV reflects both inserted rows: {csv:?}",
    );
}

#[test]
fn no_column_list_full_arity_insert_persists() {
    let (project, db, _dir) = open_project_db();
    let rt = rt();
    create_t(&db, &rt);
    let result = rt
        .block_on(db.run_sql_insert(
            "insert into T values (7, 'full-arity')".to_string(),
            None,
            "T".to_string(),
        ))
        .expect("full-arity insert runs");
    assert_eq!(result.rows_affected, 1);
    let csv = read_csv(&project, "T").expect("T.csv written");
    assert!(csv.contains("full-arity"), "CSV reflects the row: {csv:?}");
}

#[test]
fn insert_appends_literal_line_to_history() {
    let (project, db, _dir) = open_project_db();
    let rt = rt();
    create_t(&db, &rt);
    // ADR-0030 §11: the literal submitted line lands in history.log.
    let source = "insert into T (a, b) values (1, 'logged')";
    rt.block_on(db.run_sql_insert(
        "insert into T (a, b) values (1, 'logged')".to_string(),
        Some(source.to_string()),
        "T".to_string(),
    ))
    .expect("insert runs");
    let body = std::fs::read_to_string(project.path().join("history.log"))
        .expect("history.log present after an INSERT");
    assert!(
        body.contains(source),
        "history.log records the literal INSERT line: {body:?}",
    );
}

#[test]
fn failed_insert_rolls_back_and_does_not_repersist() {
    let (project, db, _dir) = open_project_db();
    let rt = rt();
    create_t(&db, &rt);
    // First insert succeeds and persists.
    rt.block_on(db.run_sql_insert(
        "insert into T (a, b) values (1, 'kept')".to_string(),
        None,
        "T".to_string(),
    ))
    .expect("first insert runs");
    // Second insert violates the primary key — it must fail and
    // leave persistence untouched (the transaction rolls back
    // before finalize_persistence).
    let outcome = rt.block_on(db.run_sql_insert(
        "insert into T (a, b) values (1, 'discarded')".to_string(),
        None,
        "T".to_string(),
    ));
    assert!(outcome.is_err(), "duplicate PK must fail: {outcome:?}");
    let csv = read_csv(&project, "T").expect("T.csv still present");
    assert!(
        csv.contains("kept") && !csv.contains("discarded"),
        "failed insert must not be persisted: {csv:?}",
    );
}

#[test]
fn failed_multi_row_insert_is_atomic() {
    // ADR-0033 §3b DA gate: a multi-row INSERT whose later tuple
    // violates a constraint fails as one statement — no partial
    // rows land, and the CSV is not rewritten.
    let (project, db, _dir) = open_project_db();
    let rt = rt();
    create_t(&db, &rt);
    rt.block_on(db.run_sql_insert(
        "insert into T (a, b) values (1, 'existing')".to_string(),
        None,
        "T".to_string(),
    ))
    .expect("seed row");
    // Row (2,…) is new but (1,…) collides on the PK — the whole
    // statement must fail with neither tuple applied.
    let outcome = rt.block_on(db.run_sql_insert(
        "insert into T (a, b) values (2, 'fresh'), (1, 'collides')".to_string(),
        None,
        "T".to_string(),
    ));
    assert!(outcome.is_err(), "multi-row PK conflict must fail: {outcome:?}");
    let csv = read_csv(&project, "T").expect("T.csv still present");
    assert!(
        csv.contains("existing") && !csv.contains("fresh") && !csv.contains("collides"),
        "no tuple from the failed multi-row insert may land: {csv:?}",
    );
}

#[test]
fn parse_path_lowers_sqlinsert_scaffold_to_command() {
    // Advanced-mode parse of the dev scaffold reconstructs valid
    // `insert …` SQL and extracts the target table.
    let command = parse_command("sqlinsert into Orders (id, total) values (1, 99.5)")
        .expect("sqlinsert parses in advanced mode");
    match command {
        Command::SqlInsert { sql, target_table } => {
            assert_eq!(sql, "insert into Orders (id, total) values (1, 99.5)");
            assert_eq!(target_table, "Orders");
        }
        other => panic!("expected Command::SqlInsert, got {other:?}"),
    }
}

#[test]
fn parse_path_rejects_internal_target_table() {
    let result = parse_command("sqlinsert into __rdbms_playground_columns values (1)");
    assert!(
        result.is_err(),
        "an internal `__rdbms_*` target must be rejected: {result:?}",
    );
}