//! Create virtual tables. //! //! Follow these steps to create your own virtual table: //! 1. Write implemenation of `VTab` and `VTabCursor` traits. //! 2. Create an instance of the `Module` structure specialized for `VTab` impl. from step 1. //! 3. Register your `Module` structure using `Connection.create_module`. //! 4. Run a `CREATE VIRTUAL TABLE` command that specifies the new module in the `USING` clause. //! //! (See [SQLite doc](http://sqlite.org/vtab.html)) use std::borrow::Cow::{self, Borrowed, Owned}; use std::ffi::CString; use std::marker::PhantomData; use std::marker::Sync; use std::os::raw::{c_char, c_int, c_void}; use std::ptr; use std::slice; use context::set_result; use error::error_from_sqlite_code; use ffi; pub use ffi::{sqlite3_vtab, sqlite3_vtab_cursor}; use types::{FromSql, FromSqlError, ToSql, ValueRef}; use {str_to_cstring, Connection, Error, InnerConnection, Result}; // let conn: Connection = ...; // let mod: Module = ...; // VTab builder // conn.create_module("module", mod); // // conn.execute("CREATE VIRTUAL TABLE foo USING module(...)"); // \-> Module::xcreate // |-> let vtab: VTab = ...; // on the heap // \-> conn.declare_vtab("CREATE TABLE foo (...)"); // conn = Connection::open(...); // \-> Module::xconnect // |-> let vtab: VTab = ...; // on the heap // \-> conn.declare_vtab("CREATE TABLE foo (...)"); // // conn.close(); // \-> vtab.xdisconnect // conn.execute("DROP TABLE foo"); // \-> vtab.xDestroy // // let stmt = conn.prepare("SELECT ... FROM foo WHERE ..."); // \-> vtab.xbestindex // stmt.query().next(); // \-> vtab.xopen // |-> let cursor: VTabCursor = ...; // on the heap // |-> cursor.xfilter or xnext // |-> cursor.xeof // \-> if not eof { cursor.column or xrowid } else { cursor.xclose } // // db: *mut ffi::sqlite3 => VTabConnection // module: *const ffi::sqlite3_module => Module // aux: *mut c_void => Module::Aux // ffi::sqlite3_vtab => VTab // ffi::sqlite3_vtab_cursor => VTabCursor /// Virtual table module /// /// (See [SQLite doc](https://sqlite.org/c3ref/module.html)) #[repr(C)] pub struct Module { base: ffi::sqlite3_module, phantom: PhantomData, } unsafe impl Sync for Module {} /// Create a read-only virtual table implementation. /// /// Step 2 of [Creating New Virtual Table Implementations](https://sqlite.org/vtab.html#creating_new_virtual_table_implementations). pub fn read_only_module(version: c_int) -> Module { // The xConnect and xCreate methods do the same thing, but they must be // different so that the virtual table is not an eponymous virtual table. let ffi_module = ffi::sqlite3_module { iVersion: version, xCreate: Some(rust_create::), xConnect: Some(rust_connect::), xBestIndex: Some(rust_best_index::), xDisconnect: Some(rust_disconnect::), xDestroy: Some(rust_destroy::), xOpen: Some(rust_open::), xClose: Some(rust_close::), xFilter: Some(rust_filter::), xNext: Some(rust_next::), xEof: Some(rust_eof::), xColumn: Some(rust_column::), xRowid: Some(rust_rowid::), xUpdate: None, xBegin: None, xSync: None, xCommit: None, xRollback: None, xFindFunction: None, xRename: None, xSavepoint: None, xRelease: None, xRollbackTo: None, }; Module { base: ffi_module, phantom: PhantomData::, } } /// Create an eponymous only virtual table implementation. /// /// Step 2 of [Creating New Virtual Table Implementations](https://sqlite.org/vtab.html#creating_new_virtual_table_implementations). pub fn eponymous_only_module(version: c_int) -> Module { // A virtual table is eponymous if its xCreate method is the exact same function as the xConnect method // For eponymous-only virtual tables, the xCreate method is NULL let ffi_module = ffi::sqlite3_module { iVersion: version, xCreate: None, xConnect: Some(rust_connect::), xBestIndex: Some(rust_best_index::), xDisconnect: Some(rust_disconnect::), xDestroy: None, xOpen: Some(rust_open::), xClose: Some(rust_close::), xFilter: Some(rust_filter::), xNext: Some(rust_next::), xEof: Some(rust_eof::), xColumn: Some(rust_column::), xRowid: Some(rust_rowid::), xUpdate: None, xBegin: None, xSync: None, xCommit: None, xRollback: None, xFindFunction: None, xRename: None, xSavepoint: None, xRelease: None, xRollbackTo: None, }; Module { base: ffi_module, phantom: PhantomData::, } } pub struct VTabConnection(*mut ffi::sqlite3); impl VTabConnection { /// Get access to the underlying SQLite database connection handle. /// /// # Warning /// /// You should not need to use this function. If you do need to, please [open an issue /// on the rusqlite repository](https://github.com/jgallagher/rusqlite/issues) and describe /// your use case. This function is unsafe because it gives you raw access to the SQLite /// connection, and what you do with it could impact the safety of this `Connection`. pub unsafe fn handle(&mut self) -> *mut ffi::sqlite3 { self.0 } } /// Virtual table instance trait. /// /// Implementations must be like: /// ```rust,ignore /// #[repr(C)] /// struct MyTab { /// /// Base class. Must be first /// base: ffi::sqlite3_vtab, /// /* Virtual table implementations will typically add additional fields */ /// } /// ``` /// /// (See [SQLite doc](https://sqlite.org/c3ref/vtab.html)) pub trait VTab: Sized { type Aux; type Cursor: VTabCursor; /// Create a new instance of a virtual table in response to a CREATE VIRTUAL TABLE statement. /// The `db` parameter is a pointer to the SQLite database connection that is executing /// the CREATE VIRTUAL TABLE statement. /// /// Unused by eponymous virtual table. Call `connect` by default. /// (See [SQLite doc](https://sqlite.org/vtab.html#the_xcreate_method)) fn create( db: &mut VTabConnection, aux: Option<&Self::Aux>, args: &[&[u8]], ) -> Result<(String, Self)> { Self::connect(db, aux, args) } /// Destroy the underlying table implementation. This method undoes the work of `create`. /// /// Unused by eponymous virtual table. Do nothing by default. /// (See [SQLite doc](https://sqlite.org/vtab.html#the_xdestroy_method)) fn destroy(&self) -> Result<()> { Ok(()) } /// Similar to `create`. The difference is that `connect` is called to establish a new connection /// to an _existing_ virtual table whereas `create` is called to create a new virtual table from scratch. /// /// (See [SQLite doc](https://sqlite.org/vtab.html#the_xconnect_method)) fn connect( db: &mut VTabConnection, aux: Option<&Self::Aux>, args: &[&[u8]], ) -> Result<(String, Self)>; /// Determine the best way to access the virtual table. /// (See [SQLite doc](https://sqlite.org/vtab.html#the_xbestindex_method)) fn best_index(&self, info: &mut IndexInfo) -> Result<()>; /// Create a new cursor used for accessing a virtual table. /// (See [SQLite doc](https://sqlite.org/vtab.html#the_xopen_method)) fn open(&self) -> Result; } bitflags! { #[doc = "Index constraint operator."] #[repr(C)] pub struct IndexConstraintOp: ::std::os::raw::c_uchar { const SQLITE_INDEX_CONSTRAINT_EQ = 2; const SQLITE_INDEX_CONSTRAINT_GT = 4; const SQLITE_INDEX_CONSTRAINT_LE = 8; const SQLITE_INDEX_CONSTRAINT_LT = 16; const SQLITE_INDEX_CONSTRAINT_GE = 32; const SQLITE_INDEX_CONSTRAINT_MATCH = 64; } } /// Pass information into and receive the reply from the `VTab.best_index` method. /// /// (See [SQLite doc](http://sqlite.org/c3ref/index_info.html)) pub struct IndexInfo(*mut ffi::sqlite3_index_info); impl IndexInfo { /// Record WHERE clause constraints. pub fn constraints(&self) -> IndexConstraintIter { let constraints = unsafe { slice::from_raw_parts((*self.0).aConstraint, (*self.0).nConstraint as usize) }; IndexConstraintIter { iter: constraints.iter(), } } /// Information about the ORDER BY clause. pub fn order_bys(&self) -> OrderByIter { let order_bys = unsafe { slice::from_raw_parts((*self.0).aOrderBy, (*self.0).nOrderBy as usize) }; OrderByIter { iter: order_bys.iter(), } } /// Number of terms in the ORDER BY clause pub fn num_of_order_by(&self) -> usize { unsafe { (*self.0).nOrderBy as usize } } pub fn constraint_usage(&mut self, constraint_idx: usize) -> IndexConstraintUsage { let constraint_usages = unsafe { slice::from_raw_parts_mut((*self.0).aConstraintUsage, (*self.0).nConstraint as usize) }; IndexConstraintUsage(&mut constraint_usages[constraint_idx]) } /// Number used to identify the index pub fn set_idx_num(&mut self, idx_num: c_int) { unsafe { (*self.0).idxNum = idx_num; } } /// True if output is already ordered pub fn set_order_by_consumed(&mut self, order_by_consumed: bool) { unsafe { (*self.0).orderByConsumed = if order_by_consumed { 1 } else { 0 }; } } /// Estimated cost of using this index pub fn set_estimated_cost(&mut self, estimated_ost: f64) { unsafe { (*self.0).estimatedCost = estimated_ost; } } /// Estimated number of rows returned #[cfg(feature = "bundled")] // SQLite >= 3.8.2 pub fn set_estimated_rows(&mut self, estimated_rows: i64) { unsafe { (*self.0).estimatedRows = estimated_rows; } } } pub struct IndexConstraintIter<'a> { iter: slice::Iter<'a, ffi::sqlite3_index_constraint>, } impl<'a> Iterator for IndexConstraintIter<'a> { type Item = IndexConstraint<'a>; fn next(&mut self) -> Option> { self.iter.next().map(|raw| IndexConstraint(raw)) } fn size_hint(&self) -> (usize, Option) { self.iter.size_hint() } } /// WHERE clause constraint pub struct IndexConstraint<'a>(&'a ffi::sqlite3_index_constraint); impl<'a> IndexConstraint<'a> { /// Column constrained. -1 for ROWID pub fn column(&self) -> c_int { self.0.iColumn } /// Constraint operator pub fn operator(&self) -> IndexConstraintOp { IndexConstraintOp::from_bits_truncate(self.0.op) } /// True if this constraint is usable pub fn is_usable(&self) -> bool { self.0.usable != 0 } } /// Information about what parameters to pass to `VTabCursor.filter`. pub struct IndexConstraintUsage<'a>(&'a mut ffi::sqlite3_index_constraint_usage); impl<'a> IndexConstraintUsage<'a> { /// if `argv_index` > 0, constraint is part of argv to `VTabCursor.filter` pub fn set_argv_index(&mut self, argv_index: c_int) { self.0.argvIndex = argv_index; } /// if `omit`, do not code a test for this constraint pub fn set_omit(&mut self, omit: bool) { self.0.omit = if omit { 1 } else { 0 }; } } pub struct OrderByIter<'a> { iter: slice::Iter<'a, ffi::sqlite3_index_info_sqlite3_index_orderby>, } impl<'a> Iterator for OrderByIter<'a> { type Item = OrderBy<'a>; fn next(&mut self) -> Option> { self.iter.next().map(|raw| OrderBy(raw)) } fn size_hint(&self) -> (usize, Option) { self.iter.size_hint() } } /// A column of the ORDER BY clause. pub struct OrderBy<'a>(&'a ffi::sqlite3_index_info_sqlite3_index_orderby); impl<'a> OrderBy<'a> { /// Column number pub fn column(&self) -> c_int { self.0.iColumn } /// True for DESC. False for ASC. pub fn is_order_by_desc(&self) -> bool { self.0.desc != 0 } } /// Virtual table cursor trait. /// /// Implementations must be like: /// ```rust,ignore /// #[repr(C)] /// struct MyTabCursor { /// /// Base class. Must be first /// base: ffi::sqlite3_vtab_cursor, /// /* Virtual table implementations will typically add additional fields */ /// } /// ``` /// /// (See [SQLite doc](https://sqlite.org/c3ref/vtab_cursor.html)) pub trait VTabCursor: Sized { type Table: VTab; /// Begin a search of a virtual table. /// (See [SQLite doc](https://sqlite.org/vtab.html#the_xfilter_method)) fn filter(&mut self, idx_num: c_int, idx_str: Option<&str>, args: &Values) -> Result<()>; /// Advance cursor to the next row of a result set initiated by `filter`. /// (See [SQLite doc](https://sqlite.org/vtab.html#the_xnext_method)) fn next(&mut self) -> Result<()>; /// Must return `false` if the cursor currently points to a valid row of data, /// or `true` otherwise. /// (See [SQLite doc](https://sqlite.org/vtab.html#the_xeof_method)) fn eof(&self) -> bool; /// Find the value for the `i`-th column of the current row. /// `i` is zero-based so the first column is numbered 0. /// May return its result back to SQLite using one of the specified `ctx`. /// (See [SQLite doc](https://sqlite.org/vtab.html#the_xcolumn_method)) fn column(&self, ctx: &mut Context, i: c_int) -> Result<()>; /// Return the rowid of row that the cursor is currently pointing at. /// (See [SQLite doc](https://sqlite.org/vtab.html#the_xrowid_method)) fn rowid(&self) -> Result; } /// Context is used by `VTabCursor.column`` to specify the cell value. pub struct Context(*mut ffi::sqlite3_context); impl Context { pub fn set_result(&mut self, value: &T) -> Result<()> { let t = value.to_sql()?; unsafe { set_result(self.0, &t) }; Ok(()) } } /// Wrapper to `VTabCursor.filter` arguments, the values requested by `VTab.best_index`. pub struct Values<'a> { args: &'a [*mut ffi::sqlite3_value], } impl<'a> Values<'a> { pub fn len(&self) -> usize { self.args.len() } pub fn is_empty(&self) -> bool { self.args.is_empty() } pub fn get(&self, idx: usize) -> Result { let arg = self.args[idx]; let value = unsafe { ValueRef::from_value(arg) }; FromSql::column_result(value).map_err(|err| match err { FromSqlError::InvalidType => Error::InvalidFilterParameterType(idx, value.data_type()), FromSqlError::Other(err) => { Error::FromSqlConversionFailure(idx, value.data_type(), err) } FromSqlError::OutOfRange(i) => Error::IntegralValueOutOfRange(idx, i), }) } // `sqlite3_value_type` returns `SQLITE_NULL` for pointer. // So it seems not possible to enhance `ValueRef::from_value`. #[cfg(feature = "array")] pub fn get_array(&self, idx: usize) -> Result> { use types::Value; let arg = self.args[idx]; let ptr = unsafe { ffi::sqlite3_value_pointer(arg, array::ARRAY_TYPE) }; if ptr.is_null() { Ok(None) } else { Ok(Some(unsafe { array::Array::from_raw(ptr as *const Vec) })) } } pub fn iter(&self) -> ValueIter { ValueIter { iter: self.args.iter(), } } } impl<'a> IntoIterator for &'a Values<'a> { type Item = ValueRef<'a>; type IntoIter = ValueIter<'a>; fn into_iter(self) -> ValueIter<'a> { self.iter() } } pub struct ValueIter<'a> { iter: slice::Iter<'a, *mut ffi::sqlite3_value>, } impl<'a> Iterator for ValueIter<'a> { type Item = ValueRef<'a>; fn next(&mut self) -> Option> { self.iter .next() .map(|&raw| unsafe { ValueRef::from_value(raw) }) } fn size_hint(&self) -> (usize, Option) { self.iter.size_hint() } } impl Connection { /// Register a virtual table implementation. /// /// Step 3 of [Creating New Virtual Table Implementations](https://sqlite.org/vtab.html#creating_new_virtual_table_implementations). pub fn create_module( &self, module_name: &str, module: &Module, aux: Option, ) -> Result<()> { self.db.borrow_mut().create_module(module_name, module, aux) } } impl InnerConnection { fn create_module( &mut self, module_name: &str, module: &Module, aux: Option, ) -> Result<()> { let c_name = try!(str_to_cstring(module_name)); let r = match aux { Some(aux) => { let boxed_aux: *mut T::Aux = Box::into_raw(Box::new(aux)); unsafe { ffi::sqlite3_create_module_v2( self.db(), c_name.as_ptr(), &module.base, boxed_aux as *mut c_void, Some(free_boxed_value::), ) } } None => unsafe { ffi::sqlite3_create_module_v2( self.db(), c_name.as_ptr(), &module.base, ptr::null_mut(), None, ) }, }; self.decode_result(r) } } /// Escape double-quote (`"`) character occurences by doubling them (`""`). pub fn escape_double_quote(identifier: &str) -> Cow { if identifier.contains('"') { // escape quote by doubling them Owned(identifier.replace("\"", "\"\"")) } else { Borrowed(identifier) } } /// Dequote string pub fn dequote(s: &str) -> &str { if s.len() < 2 { return s; } match s.bytes().next() { Some(b) if b == b'"' || b == b'\'' => match s.bytes().rev().next() { Some(e) if e == b => &s[1..s.len() - 1], _ => s, }, _ => s, } } /// The boolean can be one of: /// ```text /// 1 yes true on /// 0 no false off /// ``` pub fn parse_boolean(s: &str) -> Option { if s.eq_ignore_ascii_case("yes") || s.eq_ignore_ascii_case("on") || s.eq_ignore_ascii_case("true") || s.eq("1") { Some(true) } else if s.eq_ignore_ascii_case("no") || s.eq_ignore_ascii_case("off") || s.eq_ignore_ascii_case("false") || s.eq("0") { Some(false) } else { None } } // FIXME copy/paste from function.rs unsafe extern "C" fn free_boxed_value(p: *mut c_void) { let _: Box = Box::from_raw(p as *mut T); } unsafe extern "C" fn rust_create( db: *mut ffi::sqlite3, aux: *mut c_void, argc: c_int, argv: *const *const c_char, pp_vtab: *mut *mut ffi::sqlite3_vtab, err_msg: *mut *mut c_char, ) -> c_int where T: VTab, { use std::error::Error as StdError; use std::ffi::CStr; use std::slice; let mut conn = VTabConnection(db); let aux = aux as *mut T::Aux; let args = slice::from_raw_parts(argv, argc as usize); let vec = args .iter() .map(|&cs| CStr::from_ptr(cs).to_bytes()) // FIXME .to_str() -> Result<&str, Utf8Error> .collect::>(); match T::create(&mut conn, aux.as_ref(), &vec[..]) { Ok((sql, vtab)) => match ::std::ffi::CString::new(sql) { Ok(c_sql) => { let rc = ffi::sqlite3_declare_vtab(db, c_sql.as_ptr()); if rc == ffi::SQLITE_OK { let boxed_vtab: *mut T = Box::into_raw(Box::new(vtab)); *pp_vtab = boxed_vtab as *mut ffi::sqlite3_vtab; ffi::SQLITE_OK } else { let err = error_from_sqlite_code(rc, None); *err_msg = mprintf(err.description()); rc } } Err(err) => { *err_msg = mprintf(err.description()); ffi::SQLITE_ERROR } }, Err(Error::SqliteFailure(err, s)) => { if let Some(s) = s { *err_msg = mprintf(&s); } err.extended_code } Err(err) => { *err_msg = mprintf(err.description()); ffi::SQLITE_ERROR } } } unsafe extern "C" fn rust_connect( db: *mut ffi::sqlite3, aux: *mut c_void, argc: c_int, argv: *const *const c_char, pp_vtab: *mut *mut ffi::sqlite3_vtab, err_msg: *mut *mut c_char, ) -> c_int where T: VTab, { use std::error::Error as StdError; use std::ffi::CStr; use std::slice; let mut conn = VTabConnection(db); let aux = aux as *mut T::Aux; let args = slice::from_raw_parts(argv, argc as usize); let vec = args .iter() .map(|&cs| CStr::from_ptr(cs).to_bytes()) // FIXME .to_str() -> Result<&str, Utf8Error> .collect::>(); match T::connect(&mut conn, aux.as_ref(), &vec[..]) { Ok((sql, vtab)) => match ::std::ffi::CString::new(sql) { Ok(c_sql) => { let rc = ffi::sqlite3_declare_vtab(db, c_sql.as_ptr()); if rc == ffi::SQLITE_OK { let boxed_vtab: *mut T = Box::into_raw(Box::new(vtab)); *pp_vtab = boxed_vtab as *mut ffi::sqlite3_vtab; ffi::SQLITE_OK } else { let err = error_from_sqlite_code(rc, None); *err_msg = mprintf(err.description()); rc } } Err(err) => { *err_msg = mprintf(err.description()); ffi::SQLITE_ERROR } }, Err(Error::SqliteFailure(err, s)) => { if let Some(s) = s { *err_msg = mprintf(&s); } err.extended_code } Err(err) => { *err_msg = mprintf(err.description()); ffi::SQLITE_ERROR } } } unsafe extern "C" fn rust_best_index( vtab: *mut ffi::sqlite3_vtab, info: *mut ffi::sqlite3_index_info, ) -> c_int where T: VTab, { use std::error::Error as StdError; let vt = vtab as *mut T; let mut idx_info = IndexInfo(info); match (*vt).best_index(&mut idx_info) { Ok(_) => ffi::SQLITE_OK, Err(Error::SqliteFailure(err, s)) => { if let Some(err_msg) = s { set_err_msg(vtab, &err_msg); } err.extended_code } Err(err) => { set_err_msg(vtab, err.description()); ffi::SQLITE_ERROR } } } unsafe extern "C" fn rust_disconnect(vtab: *mut ffi::sqlite3_vtab) -> c_int where T: VTab, { if vtab.is_null() { return ffi::SQLITE_OK; } let vtab = vtab as *mut T; let _: Box = Box::from_raw(vtab); ffi::SQLITE_OK } unsafe extern "C" fn rust_destroy(vtab: *mut ffi::sqlite3_vtab) -> c_int where T: VTab, { use std::error::Error as StdError; if vtab.is_null() { return ffi::SQLITE_OK; } let vt = vtab as *mut T; match (*vt).destroy() { Ok(_) => { let _: Box = Box::from_raw(vt); ffi::SQLITE_OK } Err(Error::SqliteFailure(err, s)) => { if let Some(err_msg) = s { set_err_msg(vtab, &err_msg); } err.extended_code } Err(err) => { set_err_msg(vtab, err.description()); ffi::SQLITE_ERROR } } } unsafe extern "C" fn rust_open( vtab: *mut ffi::sqlite3_vtab, pp_cursor: *mut *mut ffi::sqlite3_vtab_cursor, ) -> c_int where T: VTab, { use std::error::Error as StdError; let vt = vtab as *mut T; match (*vt).open() { Ok(cursor) => { let boxed_cursor: *mut T::Cursor = Box::into_raw(Box::new(cursor)); *pp_cursor = boxed_cursor as *mut ffi::sqlite3_vtab_cursor; ffi::SQLITE_OK } Err(Error::SqliteFailure(err, s)) => { if let Some(err_msg) = s { set_err_msg(vtab, &err_msg); } err.extended_code } Err(err) => { set_err_msg(vtab, err.description()); ffi::SQLITE_ERROR } } } unsafe extern "C" fn rust_close(cursor: *mut ffi::sqlite3_vtab_cursor) -> c_int where C: VTabCursor, { let cr = cursor as *mut C; let _: Box = Box::from_raw(cr); ffi::SQLITE_OK } unsafe extern "C" fn rust_filter( cursor: *mut ffi::sqlite3_vtab_cursor, idx_num: c_int, idx_str: *const c_char, argc: c_int, argv: *mut *mut ffi::sqlite3_value, ) -> c_int where C: VTabCursor, { use std::ffi::CStr; use std::slice; use std::str; let idx_name = if idx_str.is_null() { None } else { let c_slice = CStr::from_ptr(idx_str).to_bytes(); Some(str::from_utf8_unchecked(c_slice)) }; let args = slice::from_raw_parts_mut(argv, argc as usize); let values = Values { args }; let cr = cursor as *mut C; cursor_error(cursor, (*cr).filter(idx_num, idx_name, &values)) } unsafe extern "C" fn rust_next(cursor: *mut ffi::sqlite3_vtab_cursor) -> c_int where C: VTabCursor, { let cr = cursor as *mut C; cursor_error(cursor, (*cr).next()) } unsafe extern "C" fn rust_eof(cursor: *mut ffi::sqlite3_vtab_cursor) -> c_int where C: VTabCursor, { let cr = cursor as *mut C; (*cr).eof() as c_int } unsafe extern "C" fn rust_column( cursor: *mut ffi::sqlite3_vtab_cursor, ctx: *mut ffi::sqlite3_context, i: c_int, ) -> c_int where C: VTabCursor, { let cr = cursor as *mut C; let mut ctxt = Context(ctx); result_error(ctx, (*cr).column(&mut ctxt, i)) } unsafe extern "C" fn rust_rowid( cursor: *mut ffi::sqlite3_vtab_cursor, p_rowid: *mut ffi::sqlite3_int64, ) -> c_int where C: VTabCursor, { let cr = cursor as *mut C; match (*cr).rowid() { Ok(rowid) => { *p_rowid = rowid; ffi::SQLITE_OK } err => cursor_error(cursor, err), } } /// Virtual table cursors can set an error message by assigning a string to `zErrMsg`. unsafe fn cursor_error(cursor: *mut ffi::sqlite3_vtab_cursor, result: Result) -> c_int { use std::error::Error as StdError; match result { Ok(_) => ffi::SQLITE_OK, Err(Error::SqliteFailure(err, s)) => { if let Some(err_msg) = s { set_err_msg((*cursor).pVtab, &err_msg); } err.extended_code } Err(err) => { set_err_msg((*cursor).pVtab, err.description()); ffi::SQLITE_ERROR } } } /// Virtual tables methods can set an error message by assigning a string to `zErrMsg`. unsafe fn set_err_msg(vtab: *mut ffi::sqlite3_vtab, err_msg: &str) { if !(*vtab).zErrMsg.is_null() { ffi::sqlite3_free((*vtab).zErrMsg as *mut c_void); } (*vtab).zErrMsg = mprintf(err_msg); } /// To raise an error, the `column` method should use this method to set the error message /// and return the error code. unsafe fn result_error(ctx: *mut ffi::sqlite3_context, result: Result) -> c_int { use std::error::Error as StdError; match result { Ok(_) => ffi::SQLITE_OK, Err(Error::SqliteFailure(err, s)) => { match err.extended_code { ffi::SQLITE_TOOBIG => { ffi::sqlite3_result_error_toobig(ctx); } ffi::SQLITE_NOMEM => { ffi::sqlite3_result_error_nomem(ctx); } code => { ffi::sqlite3_result_error_code(ctx, code); if let Some(Ok(cstr)) = s.map(|s| str_to_cstring(&s)) { ffi::sqlite3_result_error(ctx, cstr.as_ptr(), -1); } } }; err.extended_code } Err(err) => { ffi::sqlite3_result_error_code(ctx, ffi::SQLITE_ERROR); if let Ok(cstr) = str_to_cstring(err.description()) { ffi::sqlite3_result_error(ctx, cstr.as_ptr(), -1); } ffi::SQLITE_ERROR } } } // Space to hold this error message string must be obtained // from an SQLite memory allocation function. fn mprintf(err_msg: &str) -> *mut c_char { let c_format = CString::new("%s").unwrap(); let c_err = CString::new(err_msg).unwrap(); unsafe { ffi::sqlite3_mprintf(c_format.as_ptr(), c_err.as_ptr()) } } #[cfg(feature = "array")] pub mod array; #[cfg(feature = "csvtab")] pub mod csvtab; #[cfg(feature = "bundled")] pub mod series; // SQLite >= 3.9.0 #[cfg(test)] mod test { #[test] fn test_dequote() { assert_eq!("", super::dequote("")); assert_eq!("'", super::dequote("'")); assert_eq!("\"", super::dequote("\"")); assert_eq!("'\"", super::dequote("'\"")); assert_eq!("", super::dequote("''")); assert_eq!("", super::dequote("\"\"")); assert_eq!("x", super::dequote("'x'")); assert_eq!("x", super::dequote("\"x\"")); assert_eq!("x", super::dequote("x")); } #[test] fn test_parse_boolean() { assert_eq!(None, super::parse_boolean("")); assert_eq!(Some(true), super::parse_boolean("1")); assert_eq!(Some(true), super::parse_boolean("yes")); assert_eq!(Some(true), super::parse_boolean("on")); assert_eq!(Some(true), super::parse_boolean("true")); assert_eq!(Some(false), super::parse_boolean("0")); assert_eq!(Some(false), super::parse_boolean("no")); assert_eq!(Some(false), super::parse_boolean("off")); assert_eq!(Some(false), super::parse_boolean("false")); } }