// Copyright 2024, Linaro Limited // Author(s): Manos Pitsidianakis // SPDX-License-Identifier: GPL-2.0-or-later // // PL011 QEMU Device Model // // This library implements a device model for the PrimeCell® UART (PL011) // device in QEMU. // #![doc = include_str!("../README.md")] //! # Library crate //! //! See [`PL011State`](crate::device::PL011State) for the device model type and //! the [`registers`] module for register types. #![deny( rustdoc::broken_intra_doc_links, rustdoc::redundant_explicit_links, clippy::correctness, clippy::suspicious, clippy::complexity, clippy::perf, clippy::cargo, clippy::nursery, clippy::style, // restriction group clippy::dbg_macro, clippy::as_underscore, clippy::assertions_on_result_states, // pedantic group clippy::doc_markdown, clippy::borrow_as_ptr, clippy::cast_lossless, clippy::option_if_let_else, clippy::missing_const_for_fn, clippy::cognitive_complexity, clippy::missing_safety_doc, )] #![allow(clippy::result_unit_err)] extern crate bilge; extern crate bilge_impl; extern crate qemu_api; pub mod device; pub mod device_class; pub mod memory_ops; pub const TYPE_PL011: &::core::ffi::CStr = c"pl011"; /// Offset of each register from the base memory address of the device. /// /// # Source /// ARM DDI 0183G, Table 3-1 p.3-3 #[doc(alias = "offset")] #[allow(non_camel_case_types)] #[repr(u64)] #[derive(Debug)] pub enum RegisterOffset { /// Data Register /// /// A write to this register initiates the actual data transmission #[doc(alias = "UARTDR")] DR = 0x000, /// Receive Status Register or Error Clear Register #[doc(alias = "UARTRSR")] #[doc(alias = "UARTECR")] RSR = 0x004, /// Flag Register /// /// A read of this register shows if transmission is complete #[doc(alias = "UARTFR")] FR = 0x018, /// Fractional Baud Rate Register /// /// responsible for baud rate speed #[doc(alias = "UARTFBRD")] FBRD = 0x028, /// `IrDA` Low-Power Counter Register #[doc(alias = "UARTILPR")] ILPR = 0x020, /// Integer Baud Rate Register /// /// Responsible for baud rate speed #[doc(alias = "UARTIBRD")] IBRD = 0x024, /// line control register (data frame format) #[doc(alias = "UARTLCR_H")] LCR_H = 0x02C, /// Toggle UART, transmission or reception #[doc(alias = "UARTCR")] CR = 0x030, /// Interrupt FIFO Level Select Register #[doc(alias = "UARTIFLS")] FLS = 0x034, /// Interrupt Mask Set/Clear Register #[doc(alias = "UARTIMSC")] IMSC = 0x038, /// Raw Interrupt Status Register #[doc(alias = "UARTRIS")] RIS = 0x03C, /// Masked Interrupt Status Register #[doc(alias = "UARTMIS")] MIS = 0x040, /// Interrupt Clear Register #[doc(alias = "UARTICR")] ICR = 0x044, /// DMA control Register #[doc(alias = "UARTDMACR")] DMACR = 0x048, ///// Reserved, offsets `0x04C` to `0x07C`. //Reserved = 0x04C, } impl core::convert::TryFrom for RegisterOffset { type Error = u64; fn try_from(value: u64) -> Result { macro_rules! case { ($($discriminant:ident),*$(,)*) => { /* check that matching on all macro arguments compiles, which means we are not * missing any enum value; if the type definition ever changes this will stop * compiling. */ const fn _assert_exhaustive(val: RegisterOffset) { match val { $(RegisterOffset::$discriminant => (),)* } } match value { $(x if x == Self::$discriminant as u64 => Ok(Self::$discriminant),)* _ => Err(value), } } } case! { DR, RSR, FR, FBRD, ILPR, IBRD, LCR_H, CR, FLS, IMSC, RIS, MIS, ICR, DMACR } } } pub mod registers { //! Device registers exposed as typed structs which are backed by arbitrary //! integer bitmaps. [`Data`], [`Control`], [`LineControl`], etc. //! //! All PL011 registers are essentially 32-bit wide, but are typed here as //! bitmaps with only the necessary width. That is, if a struct bitmap //! in this module is for example 16 bits long, it should be conceived //! as a 32-bit register where the unmentioned higher bits are always //! unused thus treated as zero when read or written. use bilge::prelude::*; // TODO: FIFO Mode has different semantics /// Data Register, `UARTDR` /// /// The `UARTDR` register is the data register. /// /// For words to be transmitted: /// /// - if the FIFOs are enabled, data written to this location is pushed onto /// the transmit /// FIFO /// - if the FIFOs are not enabled, data is stored in the transmitter /// holding register (the /// bottom word of the transmit FIFO). /// /// The write operation initiates transmission from the UART. The data is /// prefixed with a start bit, appended with the appropriate parity bit /// (if parity is enabled), and a stop bit. The resultant word is then /// transmitted. /// /// For received words: /// /// - if the FIFOs are enabled, the data byte and the 4-bit status (break, /// frame, parity, /// and overrun) is pushed onto the 12-bit wide receive FIFO /// - if the FIFOs are not enabled, the data byte and status are stored in /// the receiving /// holding register (the bottom word of the receive FIFO). /// /// The received data byte is read by performing reads from the `UARTDR` /// register along with the corresponding status information. The status /// information can also be read by a read of the `UARTRSR/UARTECR` /// register. /// /// # Note /// /// You must disable the UART before any of the control registers are /// reprogrammed. When the UART is disabled in the middle of /// transmission or reception, it completes the current character before /// stopping. /// /// # Source /// ARM DDI 0183G 3.3.1 Data Register, UARTDR #[bitsize(16)] #[derive(Clone, Copy, DebugBits, FromBits)] #[doc(alias = "UARTDR")] pub struct Data { _reserved: u4, pub data: u8, pub framing_error: bool, pub parity_error: bool, pub break_error: bool, pub overrun_error: bool, } // TODO: FIFO Mode has different semantics /// Receive Status Register / Error Clear Register, `UARTRSR/UARTECR` /// /// The UARTRSR/UARTECR register is the receive status register/error clear /// register. Receive status can also be read from the `UARTRSR` /// register. If the status is read from this register, then the status /// information for break, framing and parity corresponds to the /// data character read from the [Data register](Data), `UARTDR` prior to /// reading the UARTRSR register. The status information for overrun is /// set immediately when an overrun condition occurs. /// /// /// # Note /// The received data character must be read first from the [Data /// Register](Data), `UARTDR` before reading the error status associated /// with that data character from the `UARTRSR` register. This read /// sequence cannot be reversed, because the `UARTRSR` register is /// updated only when a read occurs from the `UARTDR` register. However, /// the status information can also be obtained by reading the `UARTDR` /// register /// /// # Source /// ARM DDI 0183G 3.3.2 Receive Status Register/Error Clear Register, /// UARTRSR/UARTECR #[bitsize(8)] #[derive(Clone, Copy, DebugBits, FromBits)] pub struct ReceiveStatusErrorClear { pub framing_error: bool, pub parity_error: bool, pub break_error: bool, pub overrun_error: bool, _reserved_unpredictable: u4, } impl ReceiveStatusErrorClear { pub fn reset(&mut self) { // All the bits are cleared to 0 on reset. *self = 0.into(); } } impl Default for ReceiveStatusErrorClear { fn default() -> Self { 0.into() } } #[bitsize(16)] #[derive(Clone, Copy, DebugBits, FromBits)] /// Flag Register, `UARTFR` #[doc(alias = "UARTFR")] pub struct Flags { /// CTS Clear to send. This bit is the complement of the UART clear to /// send, `nUARTCTS`, modem status input. That is, the bit is 1 /// when `nUARTCTS` is LOW. pub clear_to_send: bool, /// DSR Data set ready. This bit is the complement of the UART data set /// ready, `nUARTDSR`, modem status input. That is, the bit is 1 when /// `nUARTDSR` is LOW. pub data_set_ready: bool, /// DCD Data carrier detect. This bit is the complement of the UART data /// carrier detect, `nUARTDCD`, modem status input. That is, the bit is /// 1 when `nUARTDCD` is LOW. pub data_carrier_detect: bool, /// BUSY UART busy. If this bit is set to 1, the UART is busy /// transmitting data. This bit remains set until the complete /// byte, including all the stop bits, has been sent from the /// shift register. This bit is set as soon as the transmit FIFO /// becomes non-empty, regardless of whether the UART is enabled /// or not. pub busy: bool, /// RXFE Receive FIFO empty. The meaning of this bit depends on the /// state of the FEN bit in the UARTLCR_H register. If the FIFO /// is disabled, this bit is set when the receive holding /// register is empty. If the FIFO is enabled, the RXFE bit is /// set when the receive FIFO is empty. pub receive_fifo_empty: bool, /// TXFF Transmit FIFO full. The meaning of this bit depends on the /// state of the FEN bit in the UARTLCR_H register. If the FIFO /// is disabled, this bit is set when the transmit holding /// register is full. If the FIFO is enabled, the TXFF bit is /// set when the transmit FIFO is full. pub transmit_fifo_full: bool, /// RXFF Receive FIFO full. The meaning of this bit depends on the state /// of the FEN bit in the UARTLCR_H register. If the FIFO is /// disabled, this bit is set when the receive holding register /// is full. If the FIFO is enabled, the RXFF bit is set when /// the receive FIFO is full. pub receive_fifo_full: bool, /// Transmit FIFO empty. The meaning of this bit depends on the state of /// the FEN bit in the [Line Control register](LineControl), /// `UARTLCR_H`. If the FIFO is disabled, this bit is set when the /// transmit holding register is empty. If the FIFO is enabled, /// the TXFE bit is set when the transmit FIFO is empty. This /// bit does not indicate if there is data in the transmit shift /// register. pub transmit_fifo_empty: bool, /// `RI`, is `true` when `nUARTRI` is `LOW`. pub ring_indicator: bool, _reserved_zero_no_modify: u7, } impl Flags { pub fn reset(&mut self) { // After reset TXFF, RXFF, and BUSY are 0, and TXFE and RXFE are 1 self.set_receive_fifo_full(false); self.set_transmit_fifo_full(false); self.set_busy(false); self.set_receive_fifo_empty(true); self.set_transmit_fifo_empty(true); } } impl Default for Flags { fn default() -> Self { let mut ret: Self = 0.into(); ret.reset(); ret } } #[bitsize(16)] #[derive(Clone, Copy, DebugBits, FromBits)] /// Line Control Register, `UARTLCR_H` #[doc(alias = "UARTLCR_H")] pub struct LineControl { /// 15:8 - Reserved, do not modify, read as zero. _reserved_zero_no_modify: u8, /// 7 SPS Stick parity select. /// 0 = stick parity is disabled /// 1 = either: /// • if the EPS bit is 0 then the parity bit is transmitted and checked /// as a 1 • if the EPS bit is 1 then the parity bit is /// transmitted and checked as a 0. This bit has no effect when /// the PEN bit disables parity checking and generation. See Table 3-11 /// on page 3-14 for the parity truth table. pub sticky_parity: bool, /// WLEN Word length. These bits indicate the number of data bits /// transmitted or received in a frame as follows: b11 = 8 bits /// b10 = 7 bits /// b01 = 6 bits /// b00 = 5 bits. pub word_length: WordLength, /// FEN Enable FIFOs: /// 0 = FIFOs are disabled (character mode) that is, the FIFOs become /// 1-byte-deep holding registers 1 = transmit and receive FIFO /// buffers are enabled (FIFO mode). pub fifos_enabled: Mode, /// 3 STP2 Two stop bits select. If this bit is set to 1, two stop bits /// are transmitted at the end of the frame. The receive /// logic does not check for two stop bits being received. pub two_stops_bits: bool, /// EPS Even parity select. Controls the type of parity the UART uses /// during transmission and reception: /// - 0 = odd parity. The UART generates or checks for an odd number of /// 1s in the data and parity bits. /// - 1 = even parity. The UART generates or checks for an even number /// of 1s in the data and parity bits. /// This bit has no effect when the `PEN` bit disables parity checking /// and generation. See Table 3-11 on page 3-14 for the parity /// truth table. pub parity: Parity, /// 1 PEN Parity enable: /// /// - 0 = parity is disabled and no parity bit added to the data frame /// - 1 = parity checking and generation is enabled. /// /// See Table 3-11 on page 3-14 for the parity truth table. pub parity_enabled: bool, /// BRK Send break. /// /// If this bit is set to `1`, a low-level is continually output on the /// `UARTTXD` output, after completing transmission of the /// current character. For the proper execution of the break command, /// the software must set this bit for at least two complete /// frames. For normal use, this bit must be cleared to `0`. pub send_break: bool, } impl LineControl { pub fn reset(&mut self) { // All the bits are cleared to 0 when reset. *self = 0.into(); } } impl Default for LineControl { fn default() -> Self { 0.into() } } #[bitsize(1)] #[derive(Clone, Copy, Debug, Eq, FromBits, PartialEq)] /// `EPS` "Even parity select", field of [Line Control /// register](LineControl). pub enum Parity { /// - 0 = odd parity. The UART generates or checks for an odd number of /// 1s in the data and parity bits. Odd = 0, /// - 1 = even parity. The UART generates or checks for an even number /// of 1s in the data and parity bits. Even = 1, } #[bitsize(1)] #[derive(Clone, Copy, Debug, Eq, FromBits, PartialEq)] /// `FEN` "Enable FIFOs" or Device mode, field of [Line Control /// register](LineControl). pub enum Mode { /// 0 = FIFOs are disabled (character mode) that is, the FIFOs become /// 1-byte-deep holding registers Character = 0, /// 1 = transmit and receive FIFO buffers are enabled (FIFO mode). FIFO = 1, } impl From for bool { fn from(val: Mode) -> Self { matches!(val, Mode::FIFO) } } #[bitsize(2)] #[derive(Clone, Copy, Debug, Eq, FromBits, PartialEq)] /// `WLEN` Word length, field of [Line Control register](LineControl). /// /// These bits indicate the number of data bits transmitted or received in a /// frame as follows: pub enum WordLength { /// b11 = 8 bits _8Bits = 0b11, /// b10 = 7 bits _7Bits = 0b10, /// b01 = 6 bits _6Bits = 0b01, /// b00 = 5 bits. _5Bits = 0b00, } /// Control Register, `UARTCR` /// /// The `UARTCR` register is the control register. All the bits are cleared /// to `0` on reset except for bits `9` and `8` that are set to `1`. /// /// # Source /// ARM DDI 0183G, 3.3.8 Control Register, `UARTCR`, Table 3-12 #[bitsize(16)] #[doc(alias = "UARTCR")] #[derive(Clone, Copy, DebugBits, FromBits)] pub struct Control { /// `UARTEN` UART enable: 0 = UART is disabled. If the UART is disabled /// in the middle of transmission or reception, it completes the current /// character before stopping. 1 = the UART is enabled. Data /// transmission and reception occurs for either UART signals or SIR /// signals depending on the setting of the SIREN bit. pub enable_uart: bool, /// `SIREN` `SIR` enable: 0 = IrDA SIR ENDEC is disabled. `nSIROUT` /// remains LOW (no light pulse generated), and signal transitions on /// SIRIN have no effect. 1 = IrDA SIR ENDEC is enabled. Data is /// transmitted and received on nSIROUT and SIRIN. UARTTXD remains HIGH, /// in the marking state. Signal transitions on UARTRXD or modem status /// inputs have no effect. This bit has no effect if the UARTEN bit /// disables the UART. pub enable_sir: bool, /// `SIRLP` SIR low-power IrDA mode. This bit selects the IrDA encoding /// mode. If this bit is cleared to 0, low-level bits are transmitted as /// an active high pulse with a width of 3/ 16th of the bit period. If /// this bit is set to 1, low-level bits are transmitted with a pulse /// width that is 3 times the period of the IrLPBaud16 input signal, /// regardless of the selected bit rate. Setting this bit uses less /// power, but might reduce transmission distances. pub sir_lowpower_irda_mode: u1, /// Reserved, do not modify, read as zero. _reserved_zero_no_modify: u4, /// `LBE` Loopback enable. If this bit is set to 1 and the SIREN bit is /// set to 1 and the SIRTEST bit in the Test Control register, UARTTCR /// on page 4-5 is set to 1, then the nSIROUT path is inverted, and fed /// through to the SIRIN path. The SIRTEST bit in the test register must /// be set to 1 to override the normal half-duplex SIR operation. This /// must be the requirement for accessing the test registers during /// normal operation, and SIRTEST must be cleared to 0 when loopback /// testing is finished. This feature reduces the amount of external /// coupling required during system test. If this bit is set to 1, and /// the SIRTEST bit is set to 0, the UARTTXD path is fed through to the /// UARTRXD path. In either SIR mode or UART mode, when this bit is set, /// the modem outputs are also fed through to the modem inputs. This bit /// is cleared to 0 on reset, to disable loopback. pub enable_loopback: bool, /// `TXE` Transmit enable. If this bit is set to 1, the transmit section /// of the UART is enabled. Data transmission occurs for either UART /// signals, or SIR signals depending on the setting of the SIREN bit. /// When the UART is disabled in the middle of transmission, it /// completes the current character before stopping. pub enable_transmit: bool, /// `RXE` Receive enable. If this bit is set to 1, the receive section /// of the UART is enabled. Data reception occurs for either UART /// signals or SIR signals depending on the setting of the SIREN bit. /// When the UART is disabled in the middle of reception, it completes /// the current character before stopping. pub enable_receive: bool, /// `DTR` Data transmit ready. This bit is the complement of the UART /// data transmit ready, `nUARTDTR`, modem status output. That is, when /// the bit is programmed to a 1 then `nUARTDTR` is LOW. pub data_transmit_ready: bool, /// `RTS` Request to send. This bit is the complement of the UART /// request to send, `nUARTRTS`, modem status output. That is, when the /// bit is programmed to a 1 then `nUARTRTS` is LOW. pub request_to_send: bool, /// `Out1` This bit is the complement of the UART Out1 (`nUARTOut1`) /// modem status output. That is, when the bit is programmed to a 1 the /// output is 0. For DTE this can be used as Data Carrier Detect (DCD). pub out_1: bool, /// `Out2` This bit is the complement of the UART Out2 (`nUARTOut2`) /// modem status output. That is, when the bit is programmed to a 1, the /// output is 0. For DTE this can be used as Ring Indicator (RI). pub out_2: bool, /// `RTSEn` RTS hardware flow control enable. If this bit is set to 1, /// RTS hardware flow control is enabled. Data is only requested when /// there is space in the receive FIFO for it to be received. pub rts_hardware_flow_control_enable: bool, /// `CTSEn` CTS hardware flow control enable. If this bit is set to 1, /// CTS hardware flow control is enabled. Data is only transmitted when /// the `nUARTCTS` signal is asserted. pub cts_hardware_flow_control_enable: bool, } impl Control { pub fn reset(&mut self) { *self = 0.into(); self.set_enable_receive(true); self.set_enable_transmit(true); } } impl Default for Control { fn default() -> Self { let mut ret: Self = 0.into(); ret.reset(); ret } } /// Interrupt status bits in UARTRIS, UARTMIS, UARTIMSC pub const INT_OE: u32 = 1 << 10; pub const INT_BE: u32 = 1 << 9; pub const INT_PE: u32 = 1 << 8; pub const INT_FE: u32 = 1 << 7; pub const INT_RT: u32 = 1 << 6; pub const INT_TX: u32 = 1 << 5; pub const INT_RX: u32 = 1 << 4; pub const INT_DSR: u32 = 1 << 3; pub const INT_DCD: u32 = 1 << 2; pub const INT_CTS: u32 = 1 << 1; pub const INT_RI: u32 = 1 << 0; pub const INT_E: u32 = INT_OE | INT_BE | INT_PE | INT_FE; pub const INT_MS: u32 = INT_RI | INT_DSR | INT_DCD | INT_CTS; #[repr(u32)] pub enum Interrupt { OE = 1 << 10, BE = 1 << 9, PE = 1 << 8, FE = 1 << 7, RT = 1 << 6, TX = 1 << 5, RX = 1 << 4, DSR = 1 << 3, DCD = 1 << 2, CTS = 1 << 1, RI = 1 << 0, } impl Interrupt { pub const E: u32 = INT_OE | INT_BE | INT_PE | INT_FE; pub const MS: u32 = INT_RI | INT_DSR | INT_DCD | INT_CTS; } } // TODO: You must disable the UART before any of the control registers are // reprogrammed. When the UART is disabled in the middle of transmission or // reception, it completes the current character before stopping