1 use crate::{ 2 alloc::string::ToString, 3 arch::{io::PortIOArch, CurrentPortIOArch}, 4 driver::acpi::{ 5 acpi_manager, 6 pmtmr::{ACPI_PM_MASK, PMTMR_TICKS_PER_SEC}, 7 }, 8 libs::spinlock::SpinLock, 9 time::{ 10 clocksource::{Clocksource, ClocksourceData, ClocksourceFlags, ClocksourceMask, CycleNum}, 11 PIT_TICK_RATE, 12 }, 13 }; 14 use acpi::fadt::Fadt; 15 use alloc::sync::{Arc, Weak}; 16 use core::intrinsics::unlikely; 17 use core::sync::atomic::{AtomicU32, Ordering}; 18 use system_error::SystemError; 19 20 // 参考:https://code.dragonos.org.cn/xref/linux-6.6.21/drivers/clocksource/acpi_pm.c 21 22 /// acpi_pmtmr所在的I/O端口 23 pub static mut PMTMR_IO_PORT: AtomicU32 = AtomicU32::new(0); 24 25 /// # 读取acpi_pmtmr当前值,并对齐进行掩码操作 26 #[inline(always)] 27 fn read_pmtmr() -> u32 { 28 return unsafe { CurrentPortIOArch::in32(PMTMR_IO_PORT.load(Ordering::SeqCst) as u16) } 29 & ACPI_PM_MASK as u32; 30 } 31 32 //参考: https://code.dragonos.org.cn/xref/linux-6.6.21/drivers/clocksource/acpi_pm.c#41 33 /// # 读取acpi_pmtmr的值,并进行多次读取以保证获取正确的值 34 /// 35 /// ## 返回值 36 /// - u32: 读取到的acpi_pmtmr值 37 pub fn acpi_pm_read_verified() -> u32 { 38 let mut v2: u32; 39 40 // 因为某些损坏芯片组(如ICH4、PIIX4和PIIX4E)可能导致APCI PM时钟源未锁存 41 // 因此需要多次读取以保证获取正确的值 42 loop { 43 let v1 = read_pmtmr(); 44 v2 = read_pmtmr(); 45 let v3 = read_pmtmr(); 46 47 if !(unlikely((v2 > v3 || v1 < v3) && v1 > v2 || v1 < v3 && v2 > v3)) { 48 break; 49 } 50 } 51 52 return v2; 53 } 54 55 /// # 作为时钟源的读取函数 56 /// 57 /// ## 返回值 58 /// - u64: acpi_pmtmr的当前值 59 fn acpi_pm_read() -> u64 { 60 return read_pmtmr() as u64; 61 } 62 63 pub static mut CLOCKSOURCE_ACPI_PM: Option<Arc<Acpipm>> = None; 64 65 pub fn clocksource_acpi_pm() -> Arc<Acpipm> { 66 return unsafe { CLOCKSOURCE_ACPI_PM.as_ref().unwrap().clone() }; 67 } 68 69 #[derive(Debug)] 70 pub struct Acpipm(SpinLock<InnerAcpipm>); 71 72 #[derive(Debug)] 73 struct InnerAcpipm { 74 data: ClocksourceData, 75 self_reaf: Weak<Acpipm>, 76 } 77 78 impl Acpipm { 79 pub fn new() -> Arc<Self> { 80 let data = ClocksourceData { 81 name: "acpi_pm".to_string(), 82 rating: 200, 83 mask: ClocksourceMask::new(ACPI_PM_MASK), 84 mult: 0, 85 shift: 0, 86 max_idle_ns: Default::default(), 87 flags: ClocksourceFlags::CLOCK_SOURCE_IS_CONTINUOUS, 88 watchdog_last: CycleNum::new(0), 89 uncertainty_margin: 0, 90 maxadj: 0, 91 }; 92 let acpi_pm = Arc::new(Acpipm(SpinLock::new(InnerAcpipm { 93 data, 94 self_reaf: Default::default(), 95 }))); 96 acpi_pm.0.lock().self_reaf = Arc::downgrade(&acpi_pm); 97 98 return acpi_pm; 99 } 100 } 101 102 impl Clocksource for Acpipm { 103 fn read(&self) -> CycleNum { 104 return CycleNum::new(acpi_pm_read()); 105 } 106 107 fn clocksource_data(&self) -> ClocksourceData { 108 let inner = self.0.lock_irqsave(); 109 return inner.data.clone(); 110 } 111 112 fn clocksource(&self) -> Arc<dyn Clocksource> { 113 return self.0.lock_irqsave().self_reaf.upgrade().unwrap(); 114 } 115 116 fn update_clocksource_data(&self, data: ClocksourceData) -> Result<(), SystemError> { 117 let d = &mut self.0.lock_irqsave().data; 118 d.set_flags(data.flags); 119 d.set_mask(data.mask); 120 d.set_max_idle_ns(data.max_idle_ns); 121 d.set_mult(data.mult); 122 d.set_name(data.name); 123 d.set_rating(data.rating); 124 d.set_shift(data.shift); 125 d.watchdog_last = data.watchdog_last; 126 return Ok(()); 127 } 128 } 129 130 // 参考:https://code.dragonos.org.cn/xref/linux-6.6.21/arch/x86/include/asm/mach_timer.h?fi=mach_prepare_counter 131 #[allow(dead_code)] 132 pub const CALIBRATE_TIME_MSEC: u64 = 30; 133 pub const CALIBRATE_LATCH: u64 = (PIT_TICK_RATE * CALIBRATE_TIME_MSEC + 1000 / 2) / 1000; 134 135 #[inline(always)] 136 #[allow(dead_code)] 137 pub fn mach_prepare_counter() { 138 unsafe { 139 // 将Gate位设置为高电平,从而禁用扬声器 140 CurrentPortIOArch::out8(0x61, (CurrentPortIOArch::in8(0x61) & !0x02) | 0x01); 141 142 // 针对计数器/定时器控制器的通道2进行配置,设置为模式0,二进制计数 143 CurrentPortIOArch::out8(0x43, 0xb0); 144 CurrentPortIOArch::out8(0x42, (CALIBRATE_LATCH & 0xff) as u8); 145 CurrentPortIOArch::out8(0x42, (CALIBRATE_LATCH >> 8) as u8); 146 } 147 } 148 149 #[allow(dead_code)] 150 pub fn mach_countup(count: &mut u32) { 151 let mut tmp: u32 = 0; 152 loop { 153 tmp += 1; 154 if (unsafe { CurrentPortIOArch::in8(0x61) } & 0x20) != 0 { 155 break; 156 } 157 } 158 *count = tmp; 159 } 160 161 #[allow(dead_code)] 162 const PMTMR_EXPECTED_RATE: u64 = 163 (CALIBRATE_LATCH * (PMTMR_TICKS_PER_SEC >> 10)) / (PIT_TICK_RATE >> 10); 164 165 /// # 验证ACPI PM Timer的运行速率是否在预期范围内(在x86_64架构以外的情况下验证) 166 /// 167 /// ## 返回值 168 /// - i32:如果为0则表示在预期范围内,否则不在 169 #[cfg(not(target_arch = "x86_64"))] 170 fn verify_pmtmr_rate() -> bool { 171 let mut count: u32 = 0; 172 173 mach_prepare_counter(); 174 let value1 = clocksource_acpi_pm().read().data(); 175 mach_countup(&mut count); 176 let value2 = clocksource_acpi_pm().read().data(); 177 let delta = (value2 - value1) & ACPI_PM_MASK; 178 179 if (delta < (PMTMR_EXPECTED_RATE * 19) / 20) || (delta > (PMTMR_EXPECTED_RATE * 21) / 20) { 180 kinfo!( 181 "PM Timer running at invalid rate: {}", 182 100 * delta / PMTMR_EXPECTED_RATE 183 ); 184 return false; 185 } 186 187 return true; 188 } 189 #[cfg(target_arch = "x86_64")] 190 fn verify_pmtmr_rate() -> bool { 191 return true; 192 } 193 194 const ACPI_PM_MONOTONIC_CHECKS: u32 = 10; 195 const ACPI_PM_READ_CHECKS: u32 = 10000; 196 197 /// # 解析fadt 198 fn find_acpi_pm_clock() -> Result<(), SystemError> { 199 let fadt = acpi_manager() 200 .tables() 201 .unwrap() 202 .find_table::<Fadt>() 203 .expect("failed to find FADT table"); 204 let pm_timer_block = fadt.pm_timer_block().map_err(|_| SystemError::ENODEV)?; 205 let pm_timer_block = pm_timer_block.ok_or(SystemError::ENODEV)?; 206 let pmtmr_addr = pm_timer_block.address; 207 unsafe { 208 PMTMR_IO_PORT.store(pmtmr_addr as u32, Ordering::SeqCst); 209 } 210 kinfo!("apic_pmtmr I/O port: {}", unsafe { 211 PMTMR_IO_PORT.load(Ordering::SeqCst) 212 }); 213 214 return Ok(()); 215 } 216 217 /// # 初始化ACPI PM Timer作为系统时钟源 218 // #[unified_init(INITCALL_FS)] 219 pub fn init_acpi_pm_clocksource() -> Result<(), SystemError> { 220 let acpi_pm = Acpipm::new(); 221 unsafe { 222 CLOCKSOURCE_ACPI_PM = Some(acpi_pm); 223 } 224 225 // 解析fadt 226 find_acpi_pm_clock()?; 227 228 // 检查pmtmr_io_port是否被设置 229 if unsafe { PMTMR_IO_PORT.load(Ordering::SeqCst) } == 0 { 230 return Err(SystemError::ENODEV); 231 } 232 233 // 验证ACPI PM Timer作为时钟源的稳定性和一致性 234 for j in 0..ACPI_PM_MONOTONIC_CHECKS { 235 let mut cnt = 100 * j; 236 while cnt > 0 { 237 cnt -= 1; 238 } 239 240 let value1 = clocksource_acpi_pm().read().data(); 241 let mut i = 0; 242 for _ in 0..ACPI_PM_READ_CHECKS { 243 let value2 = clocksource_acpi_pm().read().data(); 244 if value2 == value1 { 245 i += 1; 246 continue; 247 } 248 if value2 > value1 { 249 break; 250 } 251 if (value2 < value1) && (value2 < 0xfff) { 252 break; 253 } 254 kinfo!("PM Timer had inconsistens results: {} {}", value1, value2); 255 unsafe { 256 PMTMR_IO_PORT.store(0, Ordering::SeqCst); 257 } 258 return Err(SystemError::EINVAL); 259 } 260 if i == ACPI_PM_READ_CHECKS { 261 kinfo!("PM Timer failed consistency check: {}", value1); 262 unsafe { 263 PMTMR_IO_PORT.store(0, Ordering::SeqCst); 264 } 265 return Err(SystemError::EINVAL); 266 } 267 } 268 269 // 检查ACPI PM Timer的频率是否正确 270 if !verify_pmtmr_rate() { 271 unsafe { 272 PMTMR_IO_PORT.store(0, Ordering::SeqCst); 273 } 274 } 275 276 // 检查TSC时钟源的监视器是否被禁用,如果被禁用则将时钟源的标志设置为CLOCK_SOURCE_MUST_VERIFY 277 // 没有实现clocksource_selecet_watchdog函数,所以这里设置为false 278 let tsc_clocksource_watchdog_disabled = false; 279 if tsc_clocksource_watchdog_disabled { 280 clocksource_acpi_pm().0.lock_irqsave().data.flags |= 281 ClocksourceFlags::CLOCK_SOURCE_MUST_VERIFY; 282 } 283 284 // 注册ACPI PM Timer 285 let acpi_pmtmr = clocksource_acpi_pm() as Arc<dyn Clocksource>; 286 match acpi_pmtmr.register(100, PMTMR_TICKS_PER_SEC as u32) { 287 Ok(_) => { 288 kinfo!("ACPI PM Timer registered as clocksource sccessfully"); 289 return Ok(()); 290 } 291 Err(_) => { 292 kinfo!("ACPI PM Timer init registered failed"); 293 return Err(SystemError::ENOSYS); 294 } 295 }; 296 } 297