/** @file Helper functions for PCH SMM dispatcher. @copyright INTEL CONFIDENTIAL Copyright 1999 - 2018 Intel Corporation. The source code contained or described herein and all documents related to the source code ("Material") are owned by Intel Corporation or its suppliers or licensors. Title to the Material remains with Intel Corporation or its suppliers and licensors. The Material may contain trade secrets and proprietary and confidential information of Intel Corporation and its suppliers and licensors, and is protected by worldwide copyright and trade secret laws and treaty provisions. No part of the Material may be used, copied, reproduced, modified, published, uploaded, posted, transmitted, distributed, or disclosed in any way without Intel's prior express written permission. 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This file may be modified by the user, subject to additional terms of the license agreement. @par Specification Reference: **/ #include "PchSmmHelpers.h" #include /// /// #define BIT_ZERO 0x00000001 /// GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT32 BIT_ZERO = 0x00000001; /// /// SUPPORT / HELPER FUNCTIONS (PCH version-independent) /// /** Compare 2 SMM source descriptors' enable settings. @param[in] Src1 Pointer to the PCH SMI source description table 1 @param[in] Src2 Pointer to the PCH SMI source description table 2 @retval TRUE The enable settings of the 2 SMM source descriptors are identical. @retval FALSE The enable settings of the 2 SMM source descriptors are not identical. **/ BOOLEAN CompareEnables ( CONST IN PCH_SMM_SOURCE_DESC *Src1, CONST IN PCH_SMM_SOURCE_DESC *Src2 ) { BOOLEAN IsEqual; UINTN DescIndex; IsEqual = TRUE; for (DescIndex = 0; DescIndex < NUM_EN_BITS; DescIndex++) { /// /// It's okay to compare a NULL bit description to a non-NULL bit description. /// They are unequal and these tests will generate the correct result. /// if (Src1->En[DescIndex].Bit != Src2->En[DescIndex].Bit || Src1->En[DescIndex].Reg.Type != Src2->En[DescIndex].Reg.Type || Src1->En[DescIndex].Reg.Data.raw != Src2->En[DescIndex].Reg.Data.raw ) { IsEqual = FALSE; break; /// /// out of for loop /// } } return IsEqual; } /** Compare a bit descriptor to the enables of source descriptor. Includes null address type. @param[in] BitDesc Pointer to the PCH SMI bit descriptor @param[in] Src Pointer to the PCH SMI source description table 2 @retval TRUE The bit desc is equal to any of the enables in source descriptor @retval FALSE The bid desc is not equal to all of the enables in source descriptor **/ BOOLEAN IsBitEqualToAnySourceEn ( CONST IN PCH_SMM_BIT_DESC *BitDesc, CONST IN PCH_SMM_SOURCE_DESC *Src ) { BOOLEAN IsEqual; UINTN DescIndex; IsEqual = FALSE; for (DescIndex = 0; DescIndex < NUM_EN_BITS; ++DescIndex) { if ((BitDesc->Reg.Type == Src->En[DescIndex].Reg.Type) && (BitDesc->Reg.Data.raw == Src->En[DescIndex].Reg.Data.raw) && (BitDesc->Bit == Src->En[DescIndex].Bit)) { IsEqual = TRUE; break; } } return IsEqual; } /** Compare 2 SMM source descriptors' statuses. @param[in] Src1 Pointer to the PCH SMI source description table 1 @param[in] Src2 Pointer to the PCH SMI source description table 2 @retval TRUE The statuses of the 2 SMM source descriptors are identical. @retval FALSE The statuses of the 2 SMM source descriptors are not identical. **/ BOOLEAN CompareStatuses ( CONST IN PCH_SMM_SOURCE_DESC *Src1, CONST IN PCH_SMM_SOURCE_DESC *Src2 ) { BOOLEAN IsEqual; UINTN DescIndex; IsEqual = TRUE; for (DescIndex = 0; DescIndex < NUM_STS_BITS; DescIndex++) { /// /// It's okay to compare a NULL bit description to a non-NULL bit description. /// They are unequal and these tests will generate the correct result. /// if (Src1->Sts[DescIndex].Bit != Src2->Sts[DescIndex].Bit || Src1->Sts[DescIndex].Reg.Type != Src2->Sts[DescIndex].Reg.Type || Src1->Sts[DescIndex].Reg.Data.raw != Src2->Sts[DescIndex].Reg.Data.raw ) { IsEqual = FALSE; break; /// /// out of for loop /// } } return IsEqual; } /** Compare 2 SMM source descriptors, based on Enable settings and Status settings of them. @param[in] Src1 Pointer to the PCH SMI source description table 1 @param[in] Src2 Pointer to the PCH SMI source description table 2 @retval TRUE The 2 SMM source descriptors are identical. @retval FALSE The 2 SMM source descriptors are not identical. **/ BOOLEAN CompareSources ( CONST IN PCH_SMM_SOURCE_DESC *Src1, CONST IN PCH_SMM_SOURCE_DESC *Src2 ) { return (BOOLEAN) (CompareEnables (Src1, Src2) && CompareStatuses (Src1, Src2)); } /** Check if an SMM source is active. @param[in] Src Pointer to the PCH SMI source description table @param[in] SciEn Indicate if SCI is enabled or not @param[in] SmiEnValue Value from R_ACPI_IO_SMI_EN @param[in] SmiStsValue Value from R_ACPI_IO_SMI_STS @retval TRUE It is active. @retval FALSE It is inactive. **/ BOOLEAN SourceIsActive ( CONST IN PCH_SMM_SOURCE_DESC *Src, CONST IN BOOLEAN SciEn, CONST IN UINT32 SmiEnValue, CONST IN UINT32 SmiStsValue ) { UINTN DescIndex; /// /// This source is dependent on SciEn, and SciEn == 1. An ACPI OS is present, /// so we shouldn't do anything w/ this source until SciEn == 0. /// if ((Src->Flags == PCH_SMM_SCI_EN_DEPENDENT) && (SciEn)) { return FALSE; } /// /// Checking top level SMI status. If the status is not active, return false immediately /// if (!IS_BIT_DESC_NULL (Src->PmcSmiSts)) { if ((Src->PmcSmiSts.Reg.Type == ACPI_ADDR_TYPE) && (Src->PmcSmiSts.Reg.Data.acpi == R_ACPI_IO_SMI_STS) && ((SmiStsValue & (1u << Src->PmcSmiSts.Bit)) == 0)) { return FALSE; } } /// /// Read each bit desc from hardware and make sure it's a one /// for (DescIndex = 0; DescIndex < NUM_EN_BITS; DescIndex++) { if (!IS_BIT_DESC_NULL (Src->En[DescIndex])) { if ((Src->En[DescIndex].Reg.Type == ACPI_ADDR_TYPE) && (Src->En[DescIndex].Reg.Data.acpi == R_ACPI_IO_SMI_EN) && ((SmiEnValue & (1u << Src->En[DescIndex].Bit)) == 0)) { return FALSE; } else if (ReadBitDesc (&Src->En[DescIndex]) == 0) { return FALSE; } } } /// /// Read each bit desc from hardware and make sure it's a one /// for (DescIndex = 0; DescIndex < NUM_STS_BITS; DescIndex++) { if (!IS_BIT_DESC_NULL (Src->Sts[DescIndex])) { if ((Src->Sts[DescIndex].Reg.Type == ACPI_ADDR_TYPE) && (Src->Sts[DescIndex].Reg.Data.acpi == R_ACPI_IO_SMI_STS) && ((SmiStsValue & (1u << Src->Sts[DescIndex].Bit)) == 0)) { return FALSE; } else if (ReadBitDesc (&Src->Sts[DescIndex]) == 0) { return FALSE; } } } return TRUE; } /** Enable the SMI source event by set the SMI enable bit, this function would also clear SMI status bit to make initial state is correct @param[in] SrcDesc Pointer to the PCH SMI source description table **/ VOID PchSmmEnableSource ( CONST PCH_SMM_SOURCE_DESC *SrcDesc ) { UINTN DescIndex; /// /// Set enables to 1 by writing a 1 /// for (DescIndex = 0; DescIndex < NUM_EN_BITS; DescIndex++) { if (!IS_BIT_DESC_NULL (SrcDesc->En[DescIndex])) { WriteBitDesc (&SrcDesc->En[DescIndex], 1, FALSE); } } /// /// Clear statuses to 0 by writing a 1 /// for (DescIndex = 0; DescIndex < NUM_STS_BITS; DescIndex++) { if (!IS_BIT_DESC_NULL (SrcDesc->Sts[DescIndex])) { WriteBitDesc (&SrcDesc->Sts[DescIndex], 1, TRUE); } } } /** Disable the SMI source event by clear the SMI enable bit @param[in] SrcDesc Pointer to the PCH SMI source description table **/ VOID PchSmmDisableSource ( CONST PCH_SMM_SOURCE_DESC *SrcDesc ) { UINTN DescIndex; for (DescIndex = 0; DescIndex < NUM_EN_BITS; DescIndex++) { if (!IS_BIT_DESC_NULL (SrcDesc->En[DescIndex])) { WriteBitDesc (&SrcDesc->En[DescIndex], 0, FALSE); } } } /** Clear the SMI status bit by set the source bit of SMI status register @param[in] SrcDesc Pointer to the PCH SMI source description table **/ VOID PchSmmClearSource ( CONST PCH_SMM_SOURCE_DESC *SrcDesc ) { UINTN DescIndex; for (DescIndex = 0; DescIndex < NUM_STS_BITS; DescIndex++) { if (!IS_BIT_DESC_NULL (SrcDesc->Sts[DescIndex])) { WriteBitDesc (&SrcDesc->Sts[DescIndex], 1, TRUE); } } } /** Sets the source to a 1 and then waits for it to clear. Be very careful when calling this function -- it will not ASSERT. An acceptable case to call the function is when waiting for the NEWCENTURY_STS bit to clear (which takes 3 RTCCLKs). @param[in] SrcDesc Pointer to the PCH SMI source description table **/ VOID PchSmmClearSourceAndBlock ( CONST PCH_SMM_SOURCE_DESC *SrcDesc ) { UINTN DescIndex; BOOLEAN IsSet; for (DescIndex = 0; DescIndex < NUM_STS_BITS; DescIndex++) { if (!IS_BIT_DESC_NULL (SrcDesc->Sts[DescIndex])) { /// /// Write the bit /// WriteBitDesc (&SrcDesc->Sts[DescIndex], 1, TRUE); /// /// Don't return until the bit actually clears. /// IsSet = TRUE; while (IsSet) { IsSet = ReadBitDesc (&SrcDesc->Sts[DescIndex]); /// /// IsSet will eventually clear -- or else we'll have /// an infinite loop. /// } } } }