/** @file RTC Architectural Protocol GUID as defined in DxeCis 0.96. Copyright (c) 2006 - 2018, Intel Corporation. All rights reserved.
Copyright (c) 2017, AMD Inc. All rights reserved.
Copyright (c) 2018 - 2020, ARM Limited. All rights reserved.
SPDX-License-Identifier: BSD-2-Clause-Patent **/ #include "PcRtc.h" extern UINTN mRtcIndexRegister; extern UINTN mRtcTargetRegister; // // Days of month. // UINTN mDayOfMonth[] = { 31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 }; // // The name of NV variable to store the timezone and daylight saving information. // CHAR16 mTimeZoneVariableName[] = L"RTC"; /** Compare the Hour, Minute and Second of the From time and the To time. Only compare H/M/S in EFI_TIME and ignore other fields here. @param From the first time @param To the second time @return >0 The H/M/S of the From time is later than those of To time @return ==0 The H/M/S of the From time is same as those of To time @return <0 The H/M/S of the From time is earlier than those of To time **/ INTN CompareHMS ( IN EFI_TIME *From, IN EFI_TIME *To ); /** To check if second date is later than first date within 24 hours. @param From the first date @param To the second date @retval TRUE From is previous to To within 24 hours. @retval FALSE From is later, or it is previous to To more than 24 hours. **/ BOOLEAN IsWithinOneDay ( IN EFI_TIME *From, IN EFI_TIME *To ); /** Read RTC content through its registers using IO access. @param Address Address offset of RTC. It is recommended to use macros such as RTC_ADDRESS_SECONDS. @return The data of UINT8 type read from RTC. **/ STATIC UINT8 IoRtcRead ( IN UINTN Address ) { IoWrite8 ( PcdGet8 (PcdRtcIndexRegister), (UINT8)(Address | (UINT8)(IoRead8 (PcdGet8 (PcdRtcIndexRegister)) & 0x80)) ); return IoRead8 (PcdGet8 (PcdRtcTargetRegister)); } /** Write RTC through its registers using IO access. @param Address Address offset of RTC. It is recommended to use macros such as RTC_ADDRESS_SECONDS. @param Data The content you want to write into RTC. **/ STATIC VOID IoRtcWrite ( IN UINTN Address, IN UINT8 Data ) { IoWrite8 ( PcdGet8 (PcdRtcIndexRegister), (UINT8)(Address | (UINT8)(IoRead8 (PcdGet8 (PcdRtcIndexRegister)) & 0x80)) ); IoWrite8 (PcdGet8 (PcdRtcTargetRegister), Data); } /** Read RTC content through its registers using MMIO access. @param Address Address offset of RTC. It is recommended to use macros such as RTC_ADDRESS_SECONDS. @return The data of UINT8 type read from RTC. **/ STATIC UINT8 MmioRtcRead ( IN UINTN Address ) { MmioWrite8 ( mRtcIndexRegister, (UINT8)(Address | (UINT8)(MmioRead8 (mRtcIndexRegister) & 0x80)) ); return MmioRead8 (mRtcTargetRegister); } /** Write RTC through its registers using MMIO access. @param Address Address offset of RTC. It is recommended to use macros such as RTC_ADDRESS_SECONDS. @param Data The content you want to write into RTC. **/ STATIC VOID MmioRtcWrite ( IN UINTN Address, IN UINT8 Data ) { MmioWrite8 ( mRtcIndexRegister, (UINT8)(Address | (UINT8)(MmioRead8 (mRtcIndexRegister) & 0x80)) ); MmioWrite8 (mRtcTargetRegister, Data); } /** Read RTC content through its registers. @param Address Address offset of RTC. It is recommended to use macros such as RTC_ADDRESS_SECONDS. @return The data of UINT8 type read from RTC. **/ STATIC UINT8 RtcRead ( IN UINTN Address ) { if (FeaturePcdGet (PcdRtcUseMmio)) { return MmioRtcRead (Address); } return IoRtcRead (Address); } /** Write RTC through its registers. @param Address Address offset of RTC. It is recommended to use macros such as RTC_ADDRESS_SECONDS. @param Data The content you want to write into RTC. **/ STATIC VOID RtcWrite ( IN UINTN Address, IN UINT8 Data ) { if (FeaturePcdGet (PcdRtcUseMmio)) { MmioRtcWrite (Address, Data); } else { IoRtcWrite (Address, Data); } } /** Initialize RTC. @param Global For global use inside this module. @retval EFI_DEVICE_ERROR Initialization failed due to device error. @retval EFI_SUCCESS Initialization successful. **/ EFI_STATUS PcRtcInit ( IN PC_RTC_MODULE_GLOBALS *Global ) { EFI_STATUS Status; RTC_REGISTER_A RegisterA; RTC_REGISTER_B RegisterB; RTC_REGISTER_D RegisterD; EFI_TIME Time; UINTN DataSize; UINT32 TimerVar; BOOLEAN Enabled; BOOLEAN Pending; // // Acquire RTC Lock to make access to RTC atomic // if (!EfiAtRuntime ()) { EfiAcquireLock (&Global->RtcLock); } // // Initialize RTC Register // // Make sure Division Chain is properly configured, // or RTC clock won't "tick" -- time won't increment // RegisterA.Data = FixedPcdGet8 (PcdInitialValueRtcRegisterA); RtcWrite (RTC_ADDRESS_REGISTER_A, RegisterA.Data); // // Read Register B // RegisterB.Data = RtcRead (RTC_ADDRESS_REGISTER_B); // // Clear RTC flag register // RtcRead (RTC_ADDRESS_REGISTER_C); // // Clear RTC register D // RegisterD.Data = FixedPcdGet8 (PcdInitialValueRtcRegisterD); RtcWrite (RTC_ADDRESS_REGISTER_D, RegisterD.Data); // // Wait for up to 0.1 seconds for the RTC to be updated // Status = RtcWaitToUpdate (PcdGet32 (PcdRealTimeClockUpdateTimeout)); if (EFI_ERROR (Status)) { // // Set the variable with default value if the RTC is functioning incorrectly. // Global->SavedTimeZone = EFI_UNSPECIFIED_TIMEZONE; Global->Daylight = 0; if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } return EFI_DEVICE_ERROR; } // // Get the Time/Date/Daylight Savings values. // Time.Second = RtcRead (RTC_ADDRESS_SECONDS); Time.Minute = RtcRead (RTC_ADDRESS_MINUTES); Time.Hour = RtcRead (RTC_ADDRESS_HOURS); Time.Day = RtcRead (RTC_ADDRESS_DAY_OF_THE_MONTH); Time.Month = RtcRead (RTC_ADDRESS_MONTH); Time.Year = RtcRead (RTC_ADDRESS_YEAR); // // Release RTC Lock. // if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } // // Get the data of Daylight saving and time zone, if they have been // stored in NV variable during previous boot. // DataSize = sizeof (UINT32); Status = EfiGetVariable ( mTimeZoneVariableName, &gEfiCallerIdGuid, NULL, &DataSize, &TimerVar ); if (!EFI_ERROR (Status)) { Time.TimeZone = (INT16)TimerVar; Time.Daylight = (UINT8)(TimerVar >> 16); } else { Time.TimeZone = EFI_UNSPECIFIED_TIMEZONE; Time.Daylight = 0; } // // Validate time fields // Status = ConvertRtcTimeToEfiTime (&Time, RegisterB); if (!EFI_ERROR (Status)) { Status = RtcTimeFieldsValid (&Time); } if (EFI_ERROR (Status)) { // // Report Status Code to indicate that the RTC has bad date and time // REPORT_STATUS_CODE ( EFI_ERROR_CODE | EFI_ERROR_MINOR, (EFI_SOFTWARE_DXE_RT_DRIVER | EFI_SW_EC_BAD_DATE_TIME) ); Time.Second = RTC_INIT_SECOND; Time.Minute = RTC_INIT_MINUTE; Time.Hour = RTC_INIT_HOUR; Time.Day = RTC_INIT_DAY; Time.Month = RTC_INIT_MONTH; Time.Year = MAX (PcdGet16 (PcdRtcDefaultYear), PcdGet16 (PcdMinimalValidYear)); Time.Year = MIN (Time.Year, PcdGet16 (PcdMaximalValidYear)); Time.Nanosecond = 0; Time.TimeZone = EFI_UNSPECIFIED_TIMEZONE; Time.Daylight = 0; } // // Set RTC configuration after get original time // The value of bit AIE should be reserved. // RegisterB.Data = FixedPcdGet8 (PcdInitialValueRtcRegisterB) | (RegisterB.Data & BIT5); RtcWrite (RTC_ADDRESS_REGISTER_B, RegisterB.Data); // // Reset time value according to new RTC configuration // Status = PcRtcSetTime (&Time, Global); if (EFI_ERROR (Status)) { return EFI_DEVICE_ERROR; } // // Reset wakeup time value to valid state when wakeup alarm is disabled and wakeup time is invalid. // Global variable has already had valid SavedTimeZone and Daylight, // so we can use them to get and set wakeup time. // Status = PcRtcGetWakeupTime (&Enabled, &Pending, &Time, Global); if ((!EFI_ERROR (Status)) || (Enabled)) { return EFI_SUCCESS; } // // When wakeup time is disabled and invalid, reset wakeup time register to valid state // but keep wakeup alarm disabled. // Time.Second = RTC_INIT_SECOND; Time.Minute = RTC_INIT_MINUTE; Time.Hour = RTC_INIT_HOUR; Time.Day = RTC_INIT_DAY; Time.Month = RTC_INIT_MONTH; Time.Year = MAX (PcdGet16 (PcdRtcDefaultYear), PcdGet16 (PcdMinimalValidYear)); Time.Year = MIN (Time.Year, PcdGet16 (PcdMaximalValidYear)); Time.Nanosecond = 0; Time.TimeZone = Global->SavedTimeZone; Time.Daylight = Global->Daylight; // // Acquire RTC Lock to make access to RTC atomic // if (!EfiAtRuntime ()) { EfiAcquireLock (&Global->RtcLock); } // // Wait for up to 0.1 seconds for the RTC to be updated // Status = RtcWaitToUpdate (PcdGet32 (PcdRealTimeClockUpdateTimeout)); if (EFI_ERROR (Status)) { if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } return EFI_DEVICE_ERROR; } ConvertEfiTimeToRtcTime (&Time, RegisterB); // // Set the Y/M/D info to variable as it has no corresponding hw registers. // Status = EfiSetVariable ( L"RTCALARM", &gEfiCallerIdGuid, EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS | EFI_VARIABLE_NON_VOLATILE, sizeof (Time), &Time ); if (EFI_ERROR (Status)) { if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } return EFI_DEVICE_ERROR; } // // Inhibit updates of the RTC // RegisterB.Bits.Set = 1; RtcWrite (RTC_ADDRESS_REGISTER_B, RegisterB.Data); // // Set RTC alarm time registers // RtcWrite (RTC_ADDRESS_SECONDS_ALARM, Time.Second); RtcWrite (RTC_ADDRESS_MINUTES_ALARM, Time.Minute); RtcWrite (RTC_ADDRESS_HOURS_ALARM, Time.Hour); // // Allow updates of the RTC registers // RegisterB.Bits.Set = 0; RtcWrite (RTC_ADDRESS_REGISTER_B, RegisterB.Data); // // Release RTC Lock. // if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } return EFI_SUCCESS; } /** Returns the current time and date information, and the time-keeping capabilities of the hardware platform. @param Time A pointer to storage to receive a snapshot of the current time. @param Capabilities An optional pointer to a buffer to receive the real time clock device's capabilities. @param Global For global use inside this module. @retval EFI_SUCCESS The operation completed successfully. @retval EFI_INVALID_PARAMETER Time is NULL. @retval EFI_DEVICE_ERROR The time could not be retrieved due to hardware error. **/ EFI_STATUS PcRtcGetTime ( OUT EFI_TIME *Time, OUT EFI_TIME_CAPABILITIES *Capabilities OPTIONAL, IN PC_RTC_MODULE_GLOBALS *Global ) { EFI_STATUS Status; RTC_REGISTER_B RegisterB; // // Check parameters for null pointer // if (Time == NULL) { return EFI_INVALID_PARAMETER; } // // Acquire RTC Lock to make access to RTC atomic // if (!EfiAtRuntime ()) { EfiAcquireLock (&Global->RtcLock); } // // Wait for up to 0.1 seconds for the RTC to be updated // Status = RtcWaitToUpdate (PcdGet32 (PcdRealTimeClockUpdateTimeout)); if (EFI_ERROR (Status)) { if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } return Status; } // // Read Register B // RegisterB.Data = RtcRead (RTC_ADDRESS_REGISTER_B); // // Get the Time/Date/Daylight Savings values. // Time->Second = RtcRead (RTC_ADDRESS_SECONDS); Time->Minute = RtcRead (RTC_ADDRESS_MINUTES); Time->Hour = RtcRead (RTC_ADDRESS_HOURS); Time->Day = RtcRead (RTC_ADDRESS_DAY_OF_THE_MONTH); Time->Month = RtcRead (RTC_ADDRESS_MONTH); Time->Year = RtcRead (RTC_ADDRESS_YEAR); // // Release RTC Lock. // if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } // // Get the variable that contains the TimeZone and Daylight fields // Time->TimeZone = Global->SavedTimeZone; Time->Daylight = Global->Daylight; // // Make sure all field values are in correct range // Status = ConvertRtcTimeToEfiTime (Time, RegisterB); if (!EFI_ERROR (Status)) { Status = RtcTimeFieldsValid (Time); } if (EFI_ERROR (Status)) { return EFI_DEVICE_ERROR; } // // Fill in Capabilities if it was passed in // if (Capabilities != NULL) { Capabilities->Resolution = 1; // // 1 hertz // Capabilities->Accuracy = 50000000; // // 50 ppm // Capabilities->SetsToZero = FALSE; } return EFI_SUCCESS; } /** Sets the current local time and date information. @param Time A pointer to the current time. @param Global For global use inside this module. @retval EFI_SUCCESS The operation completed successfully. @retval EFI_INVALID_PARAMETER A time field is out of range. @retval EFI_DEVICE_ERROR The time could not be set due due to hardware error. **/ EFI_STATUS PcRtcSetTime ( IN EFI_TIME *Time, IN PC_RTC_MODULE_GLOBALS *Global ) { EFI_STATUS Status; EFI_TIME RtcTime; RTC_REGISTER_B RegisterB; UINT32 TimerVar; if (Time == NULL) { return EFI_INVALID_PARAMETER; } // // Make sure that the time fields are valid // Status = RtcTimeFieldsValid (Time); if (EFI_ERROR (Status)) { return Status; } CopyMem (&RtcTime, Time, sizeof (EFI_TIME)); // // Acquire RTC Lock to make access to RTC atomic // if (!EfiAtRuntime ()) { EfiAcquireLock (&Global->RtcLock); } // // Wait for up to 0.1 seconds for the RTC to be updated // Status = RtcWaitToUpdate (PcdGet32 (PcdRealTimeClockUpdateTimeout)); if (EFI_ERROR (Status)) { if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } return Status; } // // Write timezone and daylight to RTC variable // if ((Time->TimeZone == EFI_UNSPECIFIED_TIMEZONE) && (Time->Daylight == 0)) { Status = EfiSetVariable ( mTimeZoneVariableName, &gEfiCallerIdGuid, 0, 0, NULL ); if (Status == EFI_NOT_FOUND) { Status = EFI_SUCCESS; } } else { TimerVar = Time->Daylight; TimerVar = (UINT32)((TimerVar << 16) | (UINT16)(Time->TimeZone)); Status = EfiSetVariable ( mTimeZoneVariableName, &gEfiCallerIdGuid, EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS | EFI_VARIABLE_NON_VOLATILE, sizeof (TimerVar), &TimerVar ); } if (EFI_ERROR (Status)) { if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } return EFI_DEVICE_ERROR; } // // Read Register B, and inhibit updates of the RTC // RegisterB.Data = RtcRead (RTC_ADDRESS_REGISTER_B); RegisterB.Bits.Set = 1; RtcWrite (RTC_ADDRESS_REGISTER_B, RegisterB.Data); // // Store the century value to RTC before converting to BCD format. // if (Global->CenturyRtcAddress != 0) { RtcWrite (Global->CenturyRtcAddress, DecimalToBcd8 ((UINT8)(RtcTime.Year / 100))); } ConvertEfiTimeToRtcTime (&RtcTime, RegisterB); RtcWrite (RTC_ADDRESS_SECONDS, RtcTime.Second); RtcWrite (RTC_ADDRESS_MINUTES, RtcTime.Minute); RtcWrite (RTC_ADDRESS_HOURS, RtcTime.Hour); RtcWrite (RTC_ADDRESS_DAY_OF_THE_MONTH, RtcTime.Day); RtcWrite (RTC_ADDRESS_MONTH, RtcTime.Month); RtcWrite (RTC_ADDRESS_YEAR, (UINT8)RtcTime.Year); // // Allow updates of the RTC registers // RegisterB.Bits.Set = 0; RtcWrite (RTC_ADDRESS_REGISTER_B, RegisterB.Data); // // Release RTC Lock. // if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } // // Set the variable that contains the TimeZone and Daylight fields // Global->SavedTimeZone = Time->TimeZone; Global->Daylight = Time->Daylight; return EFI_SUCCESS; } /** Returns the current wakeup alarm clock setting. @param Enabled Indicates if the alarm is currently enabled or disabled. @param Pending Indicates if the alarm signal is pending and requires acknowledgment. @param Time The current alarm setting. @param Global For global use inside this module. @retval EFI_SUCCESS The alarm settings were returned. @retval EFI_INVALID_PARAMETER Enabled is NULL. @retval EFI_INVALID_PARAMETER Pending is NULL. @retval EFI_INVALID_PARAMETER Time is NULL. @retval EFI_DEVICE_ERROR The wakeup time could not be retrieved due to a hardware error. @retval EFI_UNSUPPORTED A wakeup timer is not supported on this platform. **/ EFI_STATUS PcRtcGetWakeupTime ( OUT BOOLEAN *Enabled, OUT BOOLEAN *Pending, OUT EFI_TIME *Time, IN PC_RTC_MODULE_GLOBALS *Global ) { EFI_STATUS Status; RTC_REGISTER_B RegisterB; RTC_REGISTER_C RegisterC; EFI_TIME RtcTime; UINTN DataSize; // // Check parameters for null pointers // if ((Enabled == NULL) || (Pending == NULL) || (Time == NULL)) { return EFI_INVALID_PARAMETER; } // // Acquire RTC Lock to make access to RTC atomic // if (!EfiAtRuntime ()) { EfiAcquireLock (&Global->RtcLock); } // // Wait for up to 0.1 seconds for the RTC to be updated // Status = RtcWaitToUpdate (PcdGet32 (PcdRealTimeClockUpdateTimeout)); if (EFI_ERROR (Status)) { if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } return EFI_DEVICE_ERROR; } // // Read Register B and Register C // RegisterB.Data = RtcRead (RTC_ADDRESS_REGISTER_B); RegisterC.Data = RtcRead (RTC_ADDRESS_REGISTER_C); // // Get the Time/Date/Daylight Savings values. // *Enabled = RegisterB.Bits.Aie; *Pending = RegisterC.Bits.Af; Time->Second = RtcRead (RTC_ADDRESS_SECONDS_ALARM); Time->Minute = RtcRead (RTC_ADDRESS_MINUTES_ALARM); Time->Hour = RtcRead (RTC_ADDRESS_HOURS_ALARM); Time->Day = RtcRead (RTC_ADDRESS_DAY_OF_THE_MONTH); Time->Month = RtcRead (RTC_ADDRESS_MONTH); Time->Year = RtcRead (RTC_ADDRESS_YEAR); Time->TimeZone = Global->SavedTimeZone; Time->Daylight = Global->Daylight; // // Get the alarm info from variable // DataSize = sizeof (EFI_TIME); Status = EfiGetVariable ( L"RTCALARM", &gEfiCallerIdGuid, NULL, &DataSize, &RtcTime ); if (!EFI_ERROR (Status)) { // // The alarm variable exists. In this case, we read variable to get info. // Time->Day = RtcTime.Day; Time->Month = RtcTime.Month; Time->Year = RtcTime.Year; } // // Release RTC Lock. // if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } // // Make sure all field values are in correct range // Status = ConvertRtcTimeToEfiTime (Time, RegisterB); if (!EFI_ERROR (Status)) { Status = RtcTimeFieldsValid (Time); } if (EFI_ERROR (Status)) { return EFI_DEVICE_ERROR; } return EFI_SUCCESS; } /** Sets the system wakeup alarm clock time. @param Enabled Enable or disable the wakeup alarm. @param Time If Enable is TRUE, the time to set the wakeup alarm for. If Enable is FALSE, then this parameter is optional, and may be NULL. @param Global For global use inside this module. @retval EFI_SUCCESS If Enable is TRUE, then the wakeup alarm was enabled. If Enable is FALSE, then the wakeup alarm was disabled. @retval EFI_INVALID_PARAMETER A time field is out of range. @retval EFI_DEVICE_ERROR The wakeup time could not be set due to a hardware error. @retval EFI_UNSUPPORTED A wakeup timer is not supported on this platform. **/ EFI_STATUS PcRtcSetWakeupTime ( IN BOOLEAN Enable, IN EFI_TIME *Time OPTIONAL, IN PC_RTC_MODULE_GLOBALS *Global ) { EFI_STATUS Status; EFI_TIME RtcTime; RTC_REGISTER_B RegisterB; EFI_TIME_CAPABILITIES Capabilities; ZeroMem (&RtcTime, sizeof (RtcTime)); if (Enable) { if (Time == NULL) { return EFI_INVALID_PARAMETER; } // // Make sure that the time fields are valid // Status = RtcTimeFieldsValid (Time); if (EFI_ERROR (Status)) { return EFI_INVALID_PARAMETER; } // // Just support set alarm time within 24 hours // Status = PcRtcGetTime (&RtcTime, &Capabilities, Global); if (!EFI_ERROR (Status)) { Status = RtcTimeFieldsValid (&RtcTime); } if (EFI_ERROR (Status)) { return EFI_DEVICE_ERROR; } if (!IsWithinOneDay (&RtcTime, Time)) { return EFI_UNSUPPORTED; } // // Make a local copy of the time and date // CopyMem (&RtcTime, Time, sizeof (EFI_TIME)); } // // Acquire RTC Lock to make access to RTC atomic // if (!EfiAtRuntime ()) { EfiAcquireLock (&Global->RtcLock); } // // Wait for up to 0.1 seconds for the RTC to be updated // Status = RtcWaitToUpdate (PcdGet32 (PcdRealTimeClockUpdateTimeout)); if (EFI_ERROR (Status)) { if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } return EFI_DEVICE_ERROR; } // // Read Register B // RegisterB.Data = RtcRead (RTC_ADDRESS_REGISTER_B); if (Enable) { ConvertEfiTimeToRtcTime (&RtcTime, RegisterB); } else { // // if the alarm is disable, record the current setting. // RtcTime.Second = RtcRead (RTC_ADDRESS_SECONDS_ALARM); RtcTime.Minute = RtcRead (RTC_ADDRESS_MINUTES_ALARM); RtcTime.Hour = RtcRead (RTC_ADDRESS_HOURS_ALARM); RtcTime.Day = RtcRead (RTC_ADDRESS_DAY_OF_THE_MONTH); RtcTime.Month = RtcRead (RTC_ADDRESS_MONTH); RtcTime.Year = RtcRead (RTC_ADDRESS_YEAR); RtcTime.TimeZone = Global->SavedTimeZone; RtcTime.Daylight = Global->Daylight; } // // Set the Y/M/D info to variable as it has no corresponding hw registers. // Status = EfiSetVariable ( L"RTCALARM", &gEfiCallerIdGuid, EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS | EFI_VARIABLE_NON_VOLATILE, sizeof (RtcTime), &RtcTime ); if (EFI_ERROR (Status)) { if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } return EFI_DEVICE_ERROR; } // // Inhibit updates of the RTC // RegisterB.Bits.Set = 1; RtcWrite (RTC_ADDRESS_REGISTER_B, RegisterB.Data); if (Enable) { // // Set RTC alarm time // RtcWrite (RTC_ADDRESS_SECONDS_ALARM, RtcTime.Second); RtcWrite (RTC_ADDRESS_MINUTES_ALARM, RtcTime.Minute); RtcWrite (RTC_ADDRESS_HOURS_ALARM, RtcTime.Hour); RegisterB.Bits.Aie = 1; } else { RegisterB.Bits.Aie = 0; } // // Allow updates of the RTC registers // RegisterB.Bits.Set = 0; RtcWrite (RTC_ADDRESS_REGISTER_B, RegisterB.Data); // // Release RTC Lock. // if (!EfiAtRuntime ()) { EfiReleaseLock (&Global->RtcLock); } return EFI_SUCCESS; } /** Checks an 8-bit BCD value, and converts to an 8-bit value if valid. This function checks the 8-bit BCD value specified by Value. If valid, the function converts it to an 8-bit value and returns it. Otherwise, return 0xff. @param Value The 8-bit BCD value to check and convert @return The 8-bit value converted. Or 0xff if Value is invalid. **/ UINT8 CheckAndConvertBcd8ToDecimal8 ( IN UINT8 Value ) { if ((Value < 0xa0) && ((Value & 0xf) < 0xa)) { return BcdToDecimal8 (Value); } return 0xff; } /** Converts time read from RTC to EFI_TIME format defined by UEFI spec. This function converts raw time data read from RTC to the EFI_TIME format defined by UEFI spec. If data mode of RTC is BCD, then converts it to decimal, If RTC is in 12-hour format, then converts it to 24-hour format. @param Time On input, the time data read from RTC to convert On output, the time converted to UEFI format @param RegisterB Value of Register B of RTC, indicating data mode and hour format. @retval EFI_INVALID_PARAMETER Parameters passed in are invalid. @retval EFI_SUCCESS Convert RTC time to EFI time successfully. **/ EFI_STATUS ConvertRtcTimeToEfiTime ( IN OUT EFI_TIME *Time, IN RTC_REGISTER_B RegisterB ) { BOOLEAN IsPM; UINT8 Century; // IsPM only makes sense for 12-hour format. if (RegisterB.Bits.Mil == 0) { if ((Time->Hour & 0x80) != 0) { IsPM = TRUE; } else { IsPM = FALSE; } Time->Hour = (UINT8)(Time->Hour & 0x7f); } if (RegisterB.Bits.Dm == 0) { Time->Year = CheckAndConvertBcd8ToDecimal8 ((UINT8)Time->Year); Time->Month = CheckAndConvertBcd8ToDecimal8 (Time->Month); Time->Day = CheckAndConvertBcd8ToDecimal8 (Time->Day); Time->Hour = CheckAndConvertBcd8ToDecimal8 (Time->Hour); Time->Minute = CheckAndConvertBcd8ToDecimal8 (Time->Minute); Time->Second = CheckAndConvertBcd8ToDecimal8 (Time->Second); } if ((Time->Year == 0xff) || (Time->Month == 0xff) || (Time->Day == 0xff) || (Time->Hour == 0xff) || (Time->Minute == 0xff) || (Time->Second == 0xff)) { return EFI_INVALID_PARAMETER; } // // For minimal/maximum year range [1970, 2069], // Century is 19 if RTC year >= 70, // Century is 20 otherwise. // Century = (UINT8)(PcdGet16 (PcdMinimalValidYear) / 100); if (Time->Year < PcdGet16 (PcdMinimalValidYear) % 100) { Century++; } Time->Year = (UINT16)(Century * 100 + Time->Year); // // If time is in 12 hour format, convert it to 24 hour format // if (RegisterB.Bits.Mil == 0) { if (IsPM && (Time->Hour < 12)) { Time->Hour = (UINT8)(Time->Hour + 12); } if (!IsPM && (Time->Hour == 12)) { Time->Hour = 0; } } Time->Nanosecond = 0; return EFI_SUCCESS; } /** Wait for a period for the RTC to be ready. @param Timeout Tell how long it should take to wait. @retval EFI_DEVICE_ERROR RTC device error. @retval EFI_SUCCESS RTC is updated and ready. **/ EFI_STATUS RtcWaitToUpdate ( UINTN Timeout ) { RTC_REGISTER_A RegisterA; RTC_REGISTER_D RegisterD; // // See if the RTC is functioning correctly // RegisterD.Data = RtcRead (RTC_ADDRESS_REGISTER_D); if (RegisterD.Bits.Vrt == 0) { return EFI_DEVICE_ERROR; } // // Wait for up to 0.1 seconds for the RTC to be ready. // Timeout = (Timeout / 10) + 1; RegisterA.Data = RtcRead (RTC_ADDRESS_REGISTER_A); while (RegisterA.Bits.Uip == 1 && Timeout > 0) { MicroSecondDelay (10); RegisterA.Data = RtcRead (RTC_ADDRESS_REGISTER_A); Timeout--; } RegisterD.Data = RtcRead (RTC_ADDRESS_REGISTER_D); if ((Timeout == 0) || (RegisterD.Bits.Vrt == 0)) { return EFI_DEVICE_ERROR; } return EFI_SUCCESS; } /** See if all fields of a variable of EFI_TIME type is correct. @param Time The time to be checked. @retval EFI_INVALID_PARAMETER Some fields of Time are not correct. @retval EFI_SUCCESS Time is a valid EFI_TIME variable. **/ EFI_STATUS RtcTimeFieldsValid ( IN EFI_TIME *Time ) { if ((Time->Year < PcdGet16 (PcdMinimalValidYear)) || (Time->Year > PcdGet16 (PcdMaximalValidYear)) || (Time->Month < 1) || (Time->Month > 12) || (!DayValid (Time)) || (Time->Hour > 23) || (Time->Minute > 59) || (Time->Second > 59) || (Time->Nanosecond > 999999999) || (!((Time->TimeZone == EFI_UNSPECIFIED_TIMEZONE) || ((Time->TimeZone >= -1440) && (Time->TimeZone <= 1440)))) || ((Time->Daylight & (~(EFI_TIME_ADJUST_DAYLIGHT | EFI_TIME_IN_DAYLIGHT))) != 0)) { return EFI_INVALID_PARAMETER; } return EFI_SUCCESS; } /** See if field Day of an EFI_TIME is correct. @param Time Its Day field is to be checked. @retval TRUE Day field of Time is correct. @retval FALSE Day field of Time is NOT correct. **/ BOOLEAN DayValid ( IN EFI_TIME *Time ) { // // The validity of Time->Month field should be checked before // ASSERT (Time->Month >= 1); ASSERT (Time->Month <= 12); if ((Time->Day < 1) || (Time->Day > mDayOfMonth[Time->Month - 1]) || ((Time->Month == 2) && (!IsLeapYear (Time) && (Time->Day > 28))) ) { return FALSE; } return TRUE; } /** Check if it is a leap year. @param Time The time to be checked. @retval TRUE It is a leap year. @retval FALSE It is NOT a leap year. **/ BOOLEAN IsLeapYear ( IN EFI_TIME *Time ) { if (Time->Year % 4 == 0) { if (Time->Year % 100 == 0) { if (Time->Year % 400 == 0) { return TRUE; } else { return FALSE; } } else { return TRUE; } } else { return FALSE; } } /** Converts time from EFI_TIME format defined by UEFI spec to RTC format. This function converts time from EFI_TIME format defined by UEFI spec to RTC format. If data mode of RTC is BCD, then converts EFI_TIME to it. If RTC is in 12-hour format, then converts EFI_TIME to it. @param Time On input, the time data read from UEFI to convert On output, the time converted to RTC format @param RegisterB Value of Register B of RTC, indicating data mode **/ VOID ConvertEfiTimeToRtcTime ( IN OUT EFI_TIME *Time, IN RTC_REGISTER_B RegisterB ) { BOOLEAN IsPM; IsPM = TRUE; // // Adjust hour field if RTC is in 12 hour mode // if (RegisterB.Bits.Mil == 0) { if (Time->Hour < 12) { IsPM = FALSE; } if (Time->Hour >= 13) { Time->Hour = (UINT8)(Time->Hour - 12); } else if (Time->Hour == 0) { Time->Hour = 12; } } // // Set the Time/Date values. // Time->Year = (UINT16)(Time->Year % 100); if (RegisterB.Bits.Dm == 0) { Time->Year = DecimalToBcd8 ((UINT8)Time->Year); Time->Month = DecimalToBcd8 (Time->Month); Time->Day = DecimalToBcd8 (Time->Day); Time->Hour = DecimalToBcd8 (Time->Hour); Time->Minute = DecimalToBcd8 (Time->Minute); Time->Second = DecimalToBcd8 (Time->Second); } // // If we are in 12 hour mode and PM is set, then set bit 7 of the Hour field. // if ((RegisterB.Bits.Mil == 0) && IsPM) { Time->Hour = (UINT8)(Time->Hour | 0x80); } } /** Compare the Hour, Minute and Second of the From time and the To time. Only compare H/M/S in EFI_TIME and ignore other fields here. @param From the first time @param To the second time @return >0 The H/M/S of the From time is later than those of To time @return ==0 The H/M/S of the From time is same as those of To time @return <0 The H/M/S of the From time is earlier than those of To time **/ INTN CompareHMS ( IN EFI_TIME *From, IN EFI_TIME *To ) { if ((From->Hour > To->Hour) || ((From->Hour == To->Hour) && (From->Minute > To->Minute)) || ((From->Hour == To->Hour) && (From->Minute == To->Minute) && (From->Second > To->Second))) { return 1; } else if ((From->Hour == To->Hour) && (From->Minute == To->Minute) && (From->Second == To->Second)) { return 0; } else { return -1; } } /** To check if second date is later than first date within 24 hours. @param From the first date @param To the second date @retval TRUE From is previous to To within 24 hours. @retval FALSE From is later, or it is previous to To more than 24 hours. **/ BOOLEAN IsWithinOneDay ( IN EFI_TIME *From, IN EFI_TIME *To ) { BOOLEAN Adjacent; Adjacent = FALSE; // // The validity of From->Month field should be checked before // ASSERT (From->Month >= 1); ASSERT (From->Month <= 12); if (From->Year == To->Year) { if (From->Month == To->Month) { if ((From->Day + 1) == To->Day) { if ((CompareHMS (From, To) >= 0)) { Adjacent = TRUE; } } else if (From->Day == To->Day) { if ((CompareHMS (From, To) <= 0)) { Adjacent = TRUE; } } } else if (((From->Month + 1) == To->Month) && (To->Day == 1)) { if ((From->Month == 2) && !IsLeapYear (From)) { if (From->Day == 28) { if ((CompareHMS (From, To) >= 0)) { Adjacent = TRUE; } } } else if (From->Day == mDayOfMonth[From->Month - 1]) { if ((CompareHMS (From, To) >= 0)) { Adjacent = TRUE; } } } } else if (((From->Year + 1) == To->Year) && (From->Month == 12) && (From->Day == 31) && (To->Month == 1) && (To->Day == 1)) { if ((CompareHMS (From, To) >= 0)) { Adjacent = TRUE; } } return Adjacent; } /** Get the century RTC address from the ACPI FADT table. @return The century RTC address or 0 if not found. **/ UINT8 GetCenturyRtcAddress ( VOID ) { EFI_ACPI_2_0_FIXED_ACPI_DESCRIPTION_TABLE *Fadt; Fadt = (EFI_ACPI_2_0_FIXED_ACPI_DESCRIPTION_TABLE *)EfiLocateFirstAcpiTable ( EFI_ACPI_2_0_FIXED_ACPI_DESCRIPTION_TABLE_SIGNATURE ); if ((Fadt != NULL) && (Fadt->Century > RTC_ADDRESS_REGISTER_D) && (Fadt->Century < 0x80) ) { return Fadt->Century; } else { return 0; } } /** Notification function of ACPI Table change. This is a notification function registered on ACPI Table change event. It saves the Century address stored in ACPI FADT table. @param Event Event whose notification function is being invoked. @param Context Pointer to the notification function's context. **/ VOID EFIAPI PcRtcAcpiTableChangeCallback ( IN EFI_EVENT Event, IN VOID *Context ) { EFI_STATUS Status; EFI_TIME Time; UINT8 CenturyRtcAddress; UINT8 Century; CenturyRtcAddress = GetCenturyRtcAddress (); if ((CenturyRtcAddress != 0) && (mModuleGlobal.CenturyRtcAddress != CenturyRtcAddress)) { mModuleGlobal.CenturyRtcAddress = CenturyRtcAddress; Status = PcRtcGetTime (&Time, NULL, &mModuleGlobal); if (!EFI_ERROR (Status)) { Century = (UINT8)(Time.Year / 100); Century = DecimalToBcd8 (Century); DEBUG ((DEBUG_INFO, "PcRtc: Write 0x%x to CMOS location 0x%x\n", Century, mModuleGlobal.CenturyRtcAddress)); RtcWrite (mModuleGlobal.CenturyRtcAddress, Century); } } }