/** @file RTC Architectural Protocol GUID as defined in DxeCis 0.96. Copyright (c) 2006 - 2015, Intel Corporation. All rights reserved.
This program and the accompanying materials are licensed and made available under the terms and conditions of the BSD License which accompanies this distribution. The full text of the license may be found at http://opensource.org/licenses/bsd-license.php THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. **/ #include "PcRtc.h" /** 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. @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. **/ UINT8 RtcRead ( IN UINT8 Address ) { IoWrite8 (PCAT_RTC_ADDRESS_REGISTER, (UINT8) (Address | (UINT8) (IoRead8 (PCAT_RTC_ADDRESS_REGISTER) & 0x80))); return IoRead8 (PCAT_RTC_DATA_REGISTER); } /** 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. **/ VOID RtcWrite ( IN UINT8 Address, IN UINT8 Data ) { IoWrite8 (PCAT_RTC_ADDRESS_REGISTER, (UINT8) (Address | (UINT8) (IoRead8 (PCAT_RTC_ADDRESS_REGISTER) & 0x80))); IoWrite8 (PCAT_RTC_DATA_REGISTER, 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 = RTC_INIT_REGISTER_A; 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 = RTC_INIT_REGISTER_D; 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); // // Set RTC configuration after get original time // The value of bit AIE should be reserved. // RegisterB.Data = RTC_INIT_REGISTER_B | (RegisterB.Data & BIT5); RtcWrite (RTC_ADDRESS_REGISTER_B, RegisterB.Data); // // 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 ( L"RTC", &gEfiCallerIdGuid, NULL, &DataSize, (VOID *) &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 = PcdGet16 (PcdMinimalValidYear); Time.Nanosecond = 0; Time.TimeZone = EFI_UNSPECIFIED_TIMEZONE; Time.Daylight = 0; } // // 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 ((Enabled) || (!EFI_ERROR (Status))) { 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 = PcdGet16 (PcdMinimalValidYear); 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 // TimerVar = Time->Daylight; TimerVar = (UINT32) ((TimerVar << 16) | (UINT16)(Time->TimeZone)); Status = EfiSetVariable ( L"RTC", &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 // PcRtcGetTime (&RtcTime, &Capabilities, Global); 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; 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 ) { INTN DayOfMonth[12]; DayOfMonth[0] = 31; DayOfMonth[1] = 29; DayOfMonth[2] = 31; DayOfMonth[3] = 30; DayOfMonth[4] = 31; DayOfMonth[5] = 30; DayOfMonth[6] = 31; DayOfMonth[7] = 31; DayOfMonth[8] = 30; DayOfMonth[9] = 31; DayOfMonth[10] = 30; DayOfMonth[11] = 31; // // The validity of Time->Month field should be checked before // ASSERT (Time->Month >=1); ASSERT (Time->Month <=12); if (Time->Day < 1 || Time->Day > DayOfMonth[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's. This function converts time from EFI_TIME format defined by UEFI spec to RTC's. 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 ) { UINT8 DayOfMonth[12]; BOOLEAN Adjacent; DayOfMonth[0] = 31; DayOfMonth[1] = 29; DayOfMonth[2] = 31; DayOfMonth[3] = 30; DayOfMonth[4] = 31; DayOfMonth[5] = 30; DayOfMonth[6] = 31; DayOfMonth[7] = 31; DayOfMonth[8] = 30; DayOfMonth[9] = 31; DayOfMonth[10] = 30; DayOfMonth[11] = 31; 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 == DayOfMonth[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; } /** This function find ACPI table with the specified signature in RSDT or XSDT. @param Sdt ACPI RSDT or XSDT. @param Signature ACPI table signature. @param TablePointerSize Size of table pointer: 4 or 8. @return ACPI table or NULL if not found. **/ VOID * ScanTableInSDT ( IN EFI_ACPI_DESCRIPTION_HEADER *Sdt, IN UINT32 Signature, IN UINTN TablePointerSize ) { UINTN Index; UINTN EntryCount; UINTN EntryBase; EFI_ACPI_DESCRIPTION_HEADER *Table; EntryCount = (Sdt->Length - sizeof (EFI_ACPI_DESCRIPTION_HEADER)) / TablePointerSize; EntryBase = (UINTN) (Sdt + 1); for (Index = 0; Index < EntryCount; Index++) { // // When TablePointerSize is 4 while sizeof (VOID *) is 8, make sure the upper 4 bytes are zero. // Table = 0; CopyMem (&Table, (VOID *) (EntryBase + Index * TablePointerSize), TablePointerSize); if (Table->Signature == Signature) { return Table; } } return NULL; } /** 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_ACPI_2_0_ROOT_SYSTEM_DESCRIPTION_POINTER *Rsdp; EFI_ACPI_DESCRIPTION_HEADER *Rsdt; EFI_ACPI_DESCRIPTION_HEADER *Xsdt; EFI_ACPI_2_0_FIXED_ACPI_DESCRIPTION_TABLE *Fadt; EFI_TIME Time; UINT8 Century; Status = EfiGetSystemConfigurationTable (&gEfiAcpiTableGuid, (VOID **) &Rsdp); if (EFI_ERROR (Status)) { Status = EfiGetSystemConfigurationTable (&gEfiAcpi10TableGuid, (VOID **) &Rsdp); } if (EFI_ERROR (Status)) { return; } // // Find FADT in XSDT // Fadt = NULL; if (Rsdp->Revision >= EFI_ACPI_2_0_ROOT_SYSTEM_DESCRIPTION_POINTER_REVISION) { Xsdt = (EFI_ACPI_DESCRIPTION_HEADER *) (UINTN) Rsdp->XsdtAddress; Fadt = ScanTableInSDT (Xsdt, EFI_ACPI_2_0_FIXED_ACPI_DESCRIPTION_TABLE_SIGNATURE, sizeof (UINT64)); } if (Fadt == NULL) { // // Find FADT in RSDT // Rsdt = (EFI_ACPI_DESCRIPTION_HEADER *) (UINTN) Rsdp->RsdtAddress; Fadt = ScanTableInSDT (Rsdt, EFI_ACPI_2_0_FIXED_ACPI_DESCRIPTION_TABLE_SIGNATURE, sizeof (UINT32)); } if ((Fadt != NULL) && (Fadt->Century > RTC_ADDRESS_REGISTER_D) && (Fadt->Century < 0x80) && (mModuleGlobal.CenturyRtcAddress != Fadt->Century) ) { mModuleGlobal.CenturyRtcAddress = Fadt->Century; Status = PcRtcGetTime (&Time, NULL, &mModuleGlobal); if (!EFI_ERROR (Status)) { Century = (UINT8) (Time.Year / 100); Century = DecimalToBcd8 (Century); DEBUG ((EFI_D_INFO, "PcRtc: Write 0x%x to CMOS location 0x%x\n", Century, mModuleGlobal.CenturyRtcAddress)); RtcWrite (mModuleGlobal.CenturyRtcAddress, Century); } } }