1 // Copyright 2024, Linaro Limited 2 // Author(s): Manos Pitsidianakis <manos.pitsidianakis@linaro.org> 3 // SPDX-License-Identifier: GPL-2.0-or-later 4 5 use core::ptr::{addr_of, addr_of_mut, NonNull}; 6 use std::{ 7 ffi::CStr, 8 os::raw::{c_int, c_void}, 9 }; 10 11 use qemu_api::{ 12 bindings::{ 13 error_fatal, hwaddr, memory_region_init_io, qdev_prop_set_chr, qemu_chr_fe_accept_input, 14 qemu_chr_fe_ioctl, qemu_chr_fe_set_handlers, qemu_chr_fe_write_all, qemu_irq, 15 sysbus_connect_irq, sysbus_mmio_map, sysbus_realize, CharBackend, Chardev, MemoryRegion, 16 QEMUChrEvent, CHR_IOCTL_SERIAL_SET_BREAK, 17 }, 18 c_str, impl_vmstate_forward, 19 irq::InterruptSource, 20 prelude::*, 21 qdev::{Clock, ClockEvent, DeviceImpl, DeviceState, Property}, 22 qom::{ClassInitImpl, ObjectImpl, Owned, ParentField}, 23 sysbus::{SysBusDevice, SysBusDeviceClass}, 24 vmstate::VMStateDescription, 25 }; 26 27 use crate::{ 28 device_class, 29 memory_ops::PL011_OPS, 30 registers::{self, Interrupt}, 31 RegisterOffset, 32 }; 33 34 /// Integer Baud Rate Divider, `UARTIBRD` 35 const IBRD_MASK: u32 = 0xffff; 36 37 /// Fractional Baud Rate Divider, `UARTFBRD` 38 const FBRD_MASK: u32 = 0x3f; 39 40 /// QEMU sourced constant. 41 pub const PL011_FIFO_DEPTH: u32 = 16; 42 43 #[derive(Clone, Copy)] 44 struct DeviceId(&'static [u8; 8]); 45 46 impl std::ops::Index<hwaddr> for DeviceId { 47 type Output = u8; 48 49 fn index(&self, idx: hwaddr) -> &Self::Output { 50 &self.0[idx as usize] 51 } 52 } 53 54 impl DeviceId { 55 const ARM: Self = Self(&[0x11, 0x10, 0x14, 0x00, 0x0d, 0xf0, 0x05, 0xb1]); 56 const LUMINARY: Self = Self(&[0x11, 0x00, 0x18, 0x01, 0x0d, 0xf0, 0x05, 0xb1]); 57 } 58 59 // FIFOs use 32-bit indices instead of usize, for compatibility with 60 // the migration stream produced by the C version of this device. 61 #[repr(transparent)] 62 #[derive(Debug, Default)] 63 pub struct Fifo([registers::Data; PL011_FIFO_DEPTH as usize]); 64 impl_vmstate_forward!(Fifo); 65 66 impl Fifo { 67 const fn len(&self) -> u32 { 68 self.0.len() as u32 69 } 70 } 71 72 impl std::ops::IndexMut<u32> for Fifo { 73 fn index_mut(&mut self, idx: u32) -> &mut Self::Output { 74 &mut self.0[idx as usize] 75 } 76 } 77 78 impl std::ops::Index<u32> for Fifo { 79 type Output = registers::Data; 80 81 fn index(&self, idx: u32) -> &Self::Output { 82 &self.0[idx as usize] 83 } 84 } 85 86 #[repr(C)] 87 #[derive(Debug, Default, qemu_api_macros::offsets)] 88 pub struct PL011Registers { 89 #[doc(alias = "fr")] 90 pub flags: registers::Flags, 91 #[doc(alias = "lcr")] 92 pub line_control: registers::LineControl, 93 #[doc(alias = "rsr")] 94 pub receive_status_error_clear: registers::ReceiveStatusErrorClear, 95 #[doc(alias = "cr")] 96 pub control: registers::Control, 97 pub dmacr: u32, 98 pub int_enabled: u32, 99 pub int_level: u32, 100 pub read_fifo: Fifo, 101 pub ilpr: u32, 102 pub ibrd: u32, 103 pub fbrd: u32, 104 pub ifl: u32, 105 pub read_pos: u32, 106 pub read_count: u32, 107 pub read_trigger: u32, 108 } 109 110 #[repr(C)] 111 #[derive(qemu_api_macros::Object, qemu_api_macros::offsets)] 112 /// PL011 Device Model in QEMU 113 pub struct PL011State { 114 pub parent_obj: ParentField<SysBusDevice>, 115 pub iomem: MemoryRegion, 116 #[doc(alias = "chr")] 117 pub char_backend: CharBackend, 118 pub regs: BqlRefCell<PL011Registers>, 119 /// QEMU interrupts 120 /// 121 /// ```text 122 /// * sysbus MMIO region 0: device registers 123 /// * sysbus IRQ 0: `UARTINTR` (combined interrupt line) 124 /// * sysbus IRQ 1: `UARTRXINTR` (receive FIFO interrupt line) 125 /// * sysbus IRQ 2: `UARTTXINTR` (transmit FIFO interrupt line) 126 /// * sysbus IRQ 3: `UARTRTINTR` (receive timeout interrupt line) 127 /// * sysbus IRQ 4: `UARTMSINTR` (momem status interrupt line) 128 /// * sysbus IRQ 5: `UARTEINTR` (error interrupt line) 129 /// ``` 130 #[doc(alias = "irq")] 131 pub interrupts: [InterruptSource; IRQMASK.len()], 132 #[doc(alias = "clk")] 133 pub clock: Owned<Clock>, 134 #[doc(alias = "migrate_clk")] 135 pub migrate_clock: bool, 136 } 137 138 qom_isa!(PL011State : SysBusDevice, DeviceState, Object); 139 140 #[repr(C)] 141 pub struct PL011Class { 142 parent_class: <SysBusDevice as ObjectType>::Class, 143 /// The byte string that identifies the device. 144 device_id: DeviceId, 145 } 146 147 unsafe impl ObjectType for PL011State { 148 type Class = PL011Class; 149 const TYPE_NAME: &'static CStr = crate::TYPE_PL011; 150 } 151 152 impl ClassInitImpl<PL011Class> for PL011State { 153 fn class_init(klass: &mut PL011Class) { 154 klass.device_id = DeviceId::ARM; 155 <Self as ClassInitImpl<SysBusDeviceClass>>::class_init(&mut klass.parent_class); 156 } 157 } 158 159 impl ObjectImpl for PL011State { 160 type ParentType = SysBusDevice; 161 162 const INSTANCE_INIT: Option<unsafe fn(&mut Self)> = Some(Self::init); 163 const INSTANCE_POST_INIT: Option<fn(&Self)> = Some(Self::post_init); 164 } 165 166 impl DeviceImpl for PL011State { 167 fn properties() -> &'static [Property] { 168 &device_class::PL011_PROPERTIES 169 } 170 fn vmsd() -> Option<&'static VMStateDescription> { 171 Some(&device_class::VMSTATE_PL011) 172 } 173 const REALIZE: Option<fn(&Self)> = Some(Self::realize); 174 const RESET: Option<fn(&Self)> = Some(Self::reset); 175 } 176 177 impl PL011Registers { 178 pub(self) fn read(&mut self, offset: RegisterOffset) -> (bool, u32) { 179 use RegisterOffset::*; 180 181 let mut update = false; 182 let result = match offset { 183 DR => { 184 self.flags.set_receive_fifo_full(false); 185 let c = self.read_fifo[self.read_pos]; 186 if self.read_count > 0 { 187 self.read_count -= 1; 188 self.read_pos = (self.read_pos + 1) & (self.fifo_depth() - 1); 189 } 190 if self.read_count == 0 { 191 self.flags.set_receive_fifo_empty(true); 192 } 193 if self.read_count + 1 == self.read_trigger { 194 self.int_level &= !Interrupt::RX.0; 195 } 196 // Update error bits. 197 self.receive_status_error_clear.set_from_data(c); 198 // Must call qemu_chr_fe_accept_input 199 update = true; 200 u32::from(c) 201 } 202 RSR => u32::from(self.receive_status_error_clear), 203 FR => u32::from(self.flags), 204 FBRD => self.fbrd, 205 ILPR => self.ilpr, 206 IBRD => self.ibrd, 207 LCR_H => u32::from(self.line_control), 208 CR => u32::from(self.control), 209 FLS => self.ifl, 210 IMSC => self.int_enabled, 211 RIS => self.int_level, 212 MIS => self.int_level & self.int_enabled, 213 ICR => { 214 // "The UARTICR Register is the interrupt clear register and is write-only" 215 // Source: ARM DDI 0183G 3.3.13 Interrupt Clear Register, UARTICR 216 0 217 } 218 DMACR => self.dmacr, 219 }; 220 (update, result) 221 } 222 223 pub(self) fn write( 224 &mut self, 225 offset: RegisterOffset, 226 value: u32, 227 char_backend: *mut CharBackend, 228 ) -> bool { 229 // eprintln!("write offset {offset} value {value}"); 230 use RegisterOffset::*; 231 match offset { 232 DR => { 233 // interrupts always checked 234 let _ = self.loopback_tx(value); 235 self.int_level |= Interrupt::TX.0; 236 return true; 237 } 238 RSR => { 239 self.receive_status_error_clear = 0.into(); 240 } 241 FR => { 242 // flag writes are ignored 243 } 244 ILPR => { 245 self.ilpr = value; 246 } 247 IBRD => { 248 self.ibrd = value; 249 } 250 FBRD => { 251 self.fbrd = value; 252 } 253 LCR_H => { 254 let new_val: registers::LineControl = value.into(); 255 // Reset the FIFO state on FIFO enable or disable 256 if self.line_control.fifos_enabled() != new_val.fifos_enabled() { 257 self.reset_rx_fifo(); 258 self.reset_tx_fifo(); 259 } 260 let update = (self.line_control.send_break() != new_val.send_break()) && { 261 let mut break_enable: c_int = new_val.send_break().into(); 262 // SAFETY: self.char_backend is a valid CharBackend instance after it's been 263 // initialized in realize(). 264 unsafe { 265 qemu_chr_fe_ioctl( 266 char_backend, 267 CHR_IOCTL_SERIAL_SET_BREAK as i32, 268 addr_of_mut!(break_enable).cast::<c_void>(), 269 ); 270 } 271 self.loopback_break(break_enable > 0) 272 }; 273 self.line_control = new_val; 274 self.set_read_trigger(); 275 return update; 276 } 277 CR => { 278 // ??? Need to implement the enable bit. 279 self.control = value.into(); 280 return self.loopback_mdmctrl(); 281 } 282 FLS => { 283 self.ifl = value; 284 self.set_read_trigger(); 285 } 286 IMSC => { 287 self.int_enabled = value; 288 return true; 289 } 290 RIS => {} 291 MIS => {} 292 ICR => { 293 self.int_level &= !value; 294 return true; 295 } 296 DMACR => { 297 self.dmacr = value; 298 if value & 3 > 0 { 299 // qemu_log_mask(LOG_UNIMP, "pl011: DMA not implemented\n"); 300 eprintln!("pl011: DMA not implemented"); 301 } 302 } 303 } 304 false 305 } 306 307 #[inline] 308 #[must_use] 309 fn loopback_tx(&mut self, value: u32) -> bool { 310 // Caveat: 311 // 312 // In real hardware, TX loopback happens at the serial-bit level 313 // and then reassembled by the RX logics back into bytes and placed 314 // into the RX fifo. That is, loopback happens after TX fifo. 315 // 316 // Because the real hardware TX fifo is time-drained at the frame 317 // rate governed by the configured serial format, some loopback 318 // bytes in TX fifo may still be able to get into the RX fifo 319 // that could be full at times while being drained at software 320 // pace. 321 // 322 // In such scenario, the RX draining pace is the major factor 323 // deciding which loopback bytes get into the RX fifo, unless 324 // hardware flow-control is enabled. 325 // 326 // For simplicity, the above described is not emulated. 327 self.loopback_enabled() && self.put_fifo(value) 328 } 329 330 #[must_use] 331 fn loopback_mdmctrl(&mut self) -> bool { 332 if !self.loopback_enabled() { 333 return false; 334 } 335 336 /* 337 * Loopback software-driven modem control outputs to modem status inputs: 338 * FR.RI <= CR.Out2 339 * FR.DCD <= CR.Out1 340 * FR.CTS <= CR.RTS 341 * FR.DSR <= CR.DTR 342 * 343 * The loopback happens immediately even if this call is triggered 344 * by setting only CR.LBE. 345 * 346 * CTS/RTS updates due to enabled hardware flow controls are not 347 * dealt with here. 348 */ 349 350 self.flags.set_ring_indicator(self.control.out_2()); 351 self.flags.set_data_carrier_detect(self.control.out_1()); 352 self.flags.set_clear_to_send(self.control.request_to_send()); 353 self.flags 354 .set_data_set_ready(self.control.data_transmit_ready()); 355 356 // Change interrupts based on updated FR 357 let mut il = self.int_level; 358 359 il &= !Interrupt::MS.0; 360 361 if self.flags.data_set_ready() { 362 il |= Interrupt::DSR.0; 363 } 364 if self.flags.data_carrier_detect() { 365 il |= Interrupt::DCD.0; 366 } 367 if self.flags.clear_to_send() { 368 il |= Interrupt::CTS.0; 369 } 370 if self.flags.ring_indicator() { 371 il |= Interrupt::RI.0; 372 } 373 self.int_level = il; 374 true 375 } 376 377 fn loopback_break(&mut self, enable: bool) -> bool { 378 enable && self.loopback_tx(registers::Data::BREAK.into()) 379 } 380 381 fn set_read_trigger(&mut self) { 382 self.read_trigger = 1; 383 } 384 385 pub fn reset(&mut self) { 386 self.line_control.reset(); 387 self.receive_status_error_clear.reset(); 388 self.dmacr = 0; 389 self.int_enabled = 0; 390 self.int_level = 0; 391 self.ilpr = 0; 392 self.ibrd = 0; 393 self.fbrd = 0; 394 self.read_trigger = 1; 395 self.ifl = 0x12; 396 self.control.reset(); 397 self.flags.reset(); 398 self.reset_rx_fifo(); 399 self.reset_tx_fifo(); 400 } 401 402 pub fn reset_rx_fifo(&mut self) { 403 self.read_count = 0; 404 self.read_pos = 0; 405 406 // Reset FIFO flags 407 self.flags.set_receive_fifo_full(false); 408 self.flags.set_receive_fifo_empty(true); 409 } 410 411 pub fn reset_tx_fifo(&mut self) { 412 // Reset FIFO flags 413 self.flags.set_transmit_fifo_full(false); 414 self.flags.set_transmit_fifo_empty(true); 415 } 416 417 #[inline] 418 pub fn fifo_enabled(&self) -> bool { 419 self.line_control.fifos_enabled() == registers::Mode::FIFO 420 } 421 422 #[inline] 423 pub fn loopback_enabled(&self) -> bool { 424 self.control.enable_loopback() 425 } 426 427 #[inline] 428 pub fn fifo_depth(&self) -> u32 { 429 // Note: FIFO depth is expected to be power-of-2 430 if self.fifo_enabled() { 431 return PL011_FIFO_DEPTH; 432 } 433 1 434 } 435 436 #[must_use] 437 pub fn put_fifo(&mut self, value: u32) -> bool { 438 let depth = self.fifo_depth(); 439 assert!(depth > 0); 440 let slot = (self.read_pos + self.read_count) & (depth - 1); 441 self.read_fifo[slot] = registers::Data::from(value); 442 self.read_count += 1; 443 self.flags.set_receive_fifo_empty(false); 444 if self.read_count == depth { 445 self.flags.set_receive_fifo_full(true); 446 } 447 448 if self.read_count == self.read_trigger { 449 self.int_level |= Interrupt::RX.0; 450 return true; 451 } 452 false 453 } 454 455 pub fn post_load(&mut self) -> Result<(), ()> { 456 /* Sanity-check input state */ 457 if self.read_pos >= self.read_fifo.len() || self.read_count > self.read_fifo.len() { 458 return Err(()); 459 } 460 461 if !self.fifo_enabled() && self.read_count > 0 && self.read_pos > 0 { 462 // Older versions of PL011 didn't ensure that the single 463 // character in the FIFO in FIFO-disabled mode is in 464 // element 0 of the array; convert to follow the current 465 // code's assumptions. 466 self.read_fifo[0] = self.read_fifo[self.read_pos]; 467 self.read_pos = 0; 468 } 469 470 self.ibrd &= IBRD_MASK; 471 self.fbrd &= FBRD_MASK; 472 473 Ok(()) 474 } 475 } 476 477 impl PL011State { 478 /// Initializes a pre-allocated, unitialized instance of `PL011State`. 479 /// 480 /// # Safety 481 /// 482 /// `self` must point to a correctly sized and aligned location for the 483 /// `PL011State` type. It must not be called more than once on the same 484 /// location/instance. All its fields are expected to hold unitialized 485 /// values with the sole exception of `parent_obj`. 486 unsafe fn init(&mut self) { 487 // SAFETY: 488 // 489 // self and self.iomem are guaranteed to be valid at this point since callers 490 // must make sure the `self` reference is valid. 491 unsafe { 492 memory_region_init_io( 493 addr_of_mut!(self.iomem), 494 addr_of_mut!(*self).cast::<Object>(), 495 &PL011_OPS, 496 addr_of_mut!(*self).cast::<c_void>(), 497 Self::TYPE_NAME.as_ptr(), 498 0x1000, 499 ); 500 } 501 502 self.regs = Default::default(); 503 504 // SAFETY: 505 // 506 // self.clock is not initialized at this point; but since `Owned<_>` is 507 // not Drop, we can overwrite the undefined value without side effects; 508 // it's not sound but, because for all PL011State instances are created 509 // by QOM code which calls this function to initialize the fields, at 510 // leastno code is able to access an invalid self.clock value. 511 self.clock = self.init_clock_in("clk", &Self::clock_update, ClockEvent::ClockUpdate); 512 } 513 514 const fn clock_update(&self, _event: ClockEvent) { 515 /* pl011_trace_baudrate_change(s); */ 516 } 517 518 fn post_init(&self) { 519 self.init_mmio(&self.iomem); 520 for irq in self.interrupts.iter() { 521 self.init_irq(irq); 522 } 523 } 524 525 pub fn read(&mut self, offset: hwaddr, _size: u32) -> u64 { 526 match RegisterOffset::try_from(offset) { 527 Err(v) if (0x3f8..0x400).contains(&(v >> 2)) => { 528 let device_id = self.get_class().device_id; 529 u64::from(device_id[(offset - 0xfe0) >> 2]) 530 } 531 Err(_) => { 532 // qemu_log_mask(LOG_GUEST_ERROR, "pl011_read: Bad offset 0x%x\n", (int)offset); 533 0 534 } 535 Ok(field) => { 536 let (update_irq, result) = self.regs.borrow_mut().read(field); 537 if update_irq { 538 self.update(); 539 unsafe { 540 qemu_chr_fe_accept_input(&mut self.char_backend); 541 } 542 } 543 result.into() 544 } 545 } 546 } 547 548 pub fn write(&mut self, offset: hwaddr, value: u64) { 549 let mut update_irq = false; 550 if let Ok(field) = RegisterOffset::try_from(offset) { 551 // qemu_chr_fe_write_all() calls into the can_receive 552 // callback, so handle writes before entering PL011Registers. 553 if field == RegisterOffset::DR { 554 // ??? Check if transmitter is enabled. 555 let ch: u8 = value as u8; 556 // SAFETY: char_backend is a valid CharBackend instance after it's been 557 // initialized in realize(). 558 // XXX this blocks entire thread. Rewrite to use 559 // qemu_chr_fe_write and background I/O callbacks 560 unsafe { 561 qemu_chr_fe_write_all(&mut self.char_backend, &ch, 1); 562 } 563 } 564 565 update_irq = self 566 .regs 567 .borrow_mut() 568 .write(field, value as u32, &mut self.char_backend); 569 } else { 570 eprintln!("write bad offset {offset} value {value}"); 571 } 572 if update_irq { 573 self.update(); 574 } 575 } 576 577 pub fn can_receive(&self) -> bool { 578 // trace_pl011_can_receive(s->lcr, s->read_count, r); 579 let regs = self.regs.borrow(); 580 regs.read_count < regs.fifo_depth() 581 } 582 583 pub fn receive(&self, ch: u32) { 584 let mut regs = self.regs.borrow_mut(); 585 let update_irq = !regs.loopback_enabled() && regs.put_fifo(ch); 586 // Release the BqlRefCell before calling self.update() 587 drop(regs); 588 589 if update_irq { 590 self.update(); 591 } 592 } 593 594 pub fn event(&self, event: QEMUChrEvent) { 595 let mut update_irq = false; 596 let mut regs = self.regs.borrow_mut(); 597 if event == QEMUChrEvent::CHR_EVENT_BREAK && !regs.loopback_enabled() { 598 update_irq = regs.put_fifo(registers::Data::BREAK.into()); 599 } 600 // Release the BqlRefCell before calling self.update() 601 drop(regs); 602 603 if update_irq { 604 self.update() 605 } 606 } 607 608 pub fn realize(&self) { 609 // SAFETY: self.char_backend has the correct size and alignment for a 610 // CharBackend object, and its callbacks are of the correct types. 611 unsafe { 612 qemu_chr_fe_set_handlers( 613 addr_of!(self.char_backend) as *mut CharBackend, 614 Some(pl011_can_receive), 615 Some(pl011_receive), 616 Some(pl011_event), 617 None, 618 addr_of!(*self).cast::<c_void>() as *mut c_void, 619 core::ptr::null_mut(), 620 true, 621 ); 622 } 623 } 624 625 pub fn reset(&self) { 626 self.regs.borrow_mut().reset(); 627 } 628 629 pub fn update(&self) { 630 let regs = self.regs.borrow(); 631 let flags = regs.int_level & regs.int_enabled; 632 for (irq, i) in self.interrupts.iter().zip(IRQMASK) { 633 irq.set(flags & i != 0); 634 } 635 } 636 637 pub fn post_load(&self, _version_id: u32) -> Result<(), ()> { 638 self.regs.borrow_mut().post_load() 639 } 640 } 641 642 /// Which bits in the interrupt status matter for each outbound IRQ line ? 643 const IRQMASK: [u32; 6] = [ 644 /* combined IRQ */ 645 Interrupt::E.0 | Interrupt::MS.0 | Interrupt::RT.0 | Interrupt::TX.0 | Interrupt::RX.0, 646 Interrupt::RX.0, 647 Interrupt::TX.0, 648 Interrupt::RT.0, 649 Interrupt::MS.0, 650 Interrupt::E.0, 651 ]; 652 653 /// # Safety 654 /// 655 /// We expect the FFI user of this function to pass a valid pointer, that has 656 /// the same size as [`PL011State`]. We also expect the device is 657 /// readable/writeable from one thread at any time. 658 pub unsafe extern "C" fn pl011_can_receive(opaque: *mut c_void) -> c_int { 659 let state = NonNull::new(opaque).unwrap().cast::<PL011State>(); 660 unsafe { state.as_ref().can_receive().into() } 661 } 662 663 /// # Safety 664 /// 665 /// We expect the FFI user of this function to pass a valid pointer, that has 666 /// the same size as [`PL011State`]. We also expect the device is 667 /// readable/writeable from one thread at any time. 668 /// 669 /// The buffer and size arguments must also be valid. 670 pub unsafe extern "C" fn pl011_receive(opaque: *mut c_void, buf: *const u8, size: c_int) { 671 let state = NonNull::new(opaque).unwrap().cast::<PL011State>(); 672 unsafe { 673 if size > 0 { 674 debug_assert!(!buf.is_null()); 675 state.as_ref().receive(u32::from(buf.read_volatile())); 676 } 677 } 678 } 679 680 /// # Safety 681 /// 682 /// We expect the FFI user of this function to pass a valid pointer, that has 683 /// the same size as [`PL011State`]. We also expect the device is 684 /// readable/writeable from one thread at any time. 685 pub unsafe extern "C" fn pl011_event(opaque: *mut c_void, event: QEMUChrEvent) { 686 let state = NonNull::new(opaque).unwrap().cast::<PL011State>(); 687 unsafe { state.as_ref().event(event) } 688 } 689 690 /// # Safety 691 /// 692 /// We expect the FFI user of this function to pass a valid pointer for `chr`. 693 #[no_mangle] 694 pub unsafe extern "C" fn pl011_create( 695 addr: u64, 696 irq: qemu_irq, 697 chr: *mut Chardev, 698 ) -> *mut DeviceState { 699 let pl011 = PL011State::new(); 700 unsafe { 701 let dev = pl011.as_mut_ptr::<DeviceState>(); 702 qdev_prop_set_chr(dev, c_str!("chardev").as_ptr(), chr); 703 704 let sysbus = pl011.as_mut_ptr::<SysBusDevice>(); 705 sysbus_realize(sysbus, addr_of_mut!(error_fatal)); 706 sysbus_mmio_map(sysbus, 0, addr); 707 sysbus_connect_irq(sysbus, 0, irq); 708 709 // return the pointer, which is kept alive by the QOM tree; drop owned ref 710 pl011.as_mut_ptr() 711 } 712 } 713 714 #[repr(C)] 715 #[derive(qemu_api_macros::Object)] 716 /// PL011 Luminary device model. 717 pub struct PL011Luminary { 718 parent_obj: ParentField<PL011State>, 719 } 720 721 impl ClassInitImpl<PL011Class> for PL011Luminary { 722 fn class_init(klass: &mut PL011Class) { 723 klass.device_id = DeviceId::LUMINARY; 724 <Self as ClassInitImpl<SysBusDeviceClass>>::class_init(&mut klass.parent_class); 725 } 726 } 727 728 qom_isa!(PL011Luminary : PL011State, SysBusDevice, DeviceState, Object); 729 730 unsafe impl ObjectType for PL011Luminary { 731 type Class = <PL011State as ObjectType>::Class; 732 const TYPE_NAME: &'static CStr = crate::TYPE_PL011_LUMINARY; 733 } 734 735 impl ObjectImpl for PL011Luminary { 736 type ParentType = PL011State; 737 } 738 739 impl DeviceImpl for PL011Luminary {} 740