/** @file * Main file supporting the SEC Phase for Versatile Express * * Copyright (c) 2011, ARM Limited. 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 #include #include #include #include #include #include #include #include #include #define ARM_PRIMARY_CORE 0 #define SerialPrint(txt) SerialPortWrite (txt, AsciiStrLen(txt)+1); extern VOID *monitor_vector_table; VOID ArmSetupGicNonSecure ( IN INTN GicDistributorBase, IN INTN GicInterruptInterfaceBase ); // Vector Table for Sec Phase VOID SecVectorTable ( VOID ); VOID NonSecureWaitForFirmware ( VOID ); VOID enter_monitor_mode( IN VOID* Stack ); VOID return_from_exception ( IN UINTN NonSecureBase ); VOID copy_cpsr_into_spsr ( VOID ); VOID CEntryPoint ( IN UINTN CoreId ) { CHAR8 Buffer[100]; UINTN CharCount; // Primary CPU clears out the SCU tag RAMs, secondaries wait if (CoreId == ARM_PRIMARY_CORE) { if (FixedPcdGet32(PcdMPCoreSupport)) { ArmInvalidScu(); } // SEC phase needs to run library constructors by hand. This assumes we are linked against the SerialLib // In non SEC modules the init call is in autogenerated code. SerialPortInitialize (); // Start talking CharCount = AsciiSPrint (Buffer,sizeof (Buffer),"UEFI firmware built at %a on %a\n\r",__TIME__, __DATE__); SerialPortWrite ((UINT8 *) Buffer, CharCount); // Now we've got UART, make the check: // - The Vector table must be 32-byte aligned ASSERT(((UINT32)SecVectorTable & ((1 << 5)-1)) == 0); } // Invalidate the data cache. Doesn't have to do the Data cache clean. ArmInvalidateDataCache(); //Invalidate Instruction Cache ArmInvalidateInstructionCache(); //Invalidate I & D TLBs ArmInvalidateInstructionAndDataTlb(); // Enable Full Access to CoProcessors ArmWriteCPACR (CPACR_CP_FULL_ACCESS); // Enable SWP instructions ArmEnableSWPInstruction(); // Enable program flow prediction, if supported. ArmEnableBranchPrediction(); if (FixedPcdGet32(PcdVFPEnabled)) { ArmEnableVFP(); } if (CoreId == ARM_PRIMARY_CORE) { // Initialize peripherals that must be done at the early stage // Example: Some L2x0 controllers must be initialized in Secure World ArmPlatformSecInitialize (); // If we skip the PEI Core we could want to initialize the DRAM in the SEC phase. // If we are in standalone, we need the initialization to copy the UEFI firmware into DRAM if (FeaturePcdGet(PcdSkipPeiCore) || !FeaturePcdGet(PcdStandalone)) { // Initialize system memory (DRAM) ArmPlatformInitializeSystemMemory(); } // Some platform can change their physical memory mapping ArmPlatformBootRemapping(); } // Test if Trustzone is supported on this platform if (ArmPlatformTrustzoneSupported()) { if (FixedPcdGet32(PcdMPCoreSupport)) { // Setup SMP in Non Secure world ArmSetupSmpNonSecure(CoreId); } // Enter Monitor Mode enter_monitor_mode((VOID*)(PcdGet32(PcdCPUCoresSecMonStackBase) + (PcdGet32(PcdCPUCoreSecMonStackSize) * CoreId))); //Write the monitor mode vector table address ArmWriteVMBar((UINT32) &monitor_vector_table); //-------------------- Monitor Mode --------------------- // Setup the Trustzone Chipsets if (CoreId == ARM_PRIMARY_CORE) { ArmPlatformTrustzoneInit(); // Wake up the secondary cores by sending a interrupt to everyone else // NOTE 1: The Software Generated Interrupts are always enabled on Cortex-A9 // MPcore test chip on Versatile Express board, So the Software doesn't have to // enable SGI's explicitly. // 2: As no other Interrupts are enabled, doesn't have to worry about the priority. // 3: As all the cores are in secure state, use secure SGI's // PL390GicEnableDistributor (PcdGet32(PcdGicDistributorBase)); PL390GicEnableInterruptInterface(PcdGet32(PcdGicInterruptInterfaceBase)); // Send SGI to all Secondary core to wake them up from WFI state. PL390GicSendSgiTo (PcdGet32(PcdGicDistributorBase), GIC_ICDSGIR_FILTER_EVERYONEELSE, 0x0E); } else { // The secondary cores need to wait until the Trustzone chipsets configuration is done // before switching to Non Secure World // Enabled GIC CPU Interface PL390GicEnableInterruptInterface (PcdGet32(PcdGicInterruptInterfaceBase)); // Waiting for the SGI from the primary core ArmCallWFI(); // Acknowledge the interrupt and send End of Interrupt signal. PL390GicAcknowledgeSgiFrom(PcdGet32(PcdGicInterruptInterfaceBase), ARM_PRIMARY_CORE); } // Transfer the interrupt to Non-secure World PL390GicSetupNonSecure(PcdGet32(PcdGicDistributorBase),PcdGet32(PcdGicInterruptInterfaceBase)); // Write to CP15 Non-secure Access Control Register : // - Enable CP10 and CP11 accesses in NS World // - Enable Access to Preload Engine in NS World // - Enable lockable TLB entries allocation in NS world // - Enable R/W access to SMP bit of Auxiliary Control Register in NS world ArmWriteNsacr(NSACR_NS_SMP | NSACR_TL | NSACR_PLE | NSACR_CP(10) | NSACR_CP(11)); // CP15 Secure Configuration Register with Non Secure bit (SCR_NS), CPSR.A modified in any // security state (SCR_AW), CPSR.F modified in any security state (SCR_FW) ArmWriteScr(SCR_NS | SCR_FW | SCR_AW); } else { if (CoreId == ARM_PRIMARY_CORE) { SerialPrint ("Trust Zone Configuration is disabled\n\r"); } // Trustzone is not enabled, just enable the Distributor and CPU interface if (CoreId == ARM_PRIMARY_CORE) { PL390GicEnableDistributor (PcdGet32(PcdGicDistributorBase)); } PL390GicEnableInterruptInterface(PcdGet32(PcdGicInterruptInterfaceBase)); // With Trustzone support the transition from Sec to Normal world is done by return_from_exception(). // If we want to keep this function call we need to ensure the SVC's SPSR point to the same Program // Status Register as the the current one (CPSR). copy_cpsr_into_spsr(); } // If ArmVe has not been built as Standalone then we need to patch the DRAM to add an infinite loop at the start address if (FeaturePcdGet(PcdStandalone) == FALSE) { if (CoreId == ARM_PRIMARY_CORE) { UINTN* StartAddress = (UINTN*)PcdGet32(PcdNormalFdBaseAddress); // Patch the DRAM to make an infinite loop at the start address *StartAddress = 0xEAFFFFFE; // opcode for while(1) CharCount = AsciiSPrint (Buffer,sizeof (Buffer),"Waiting for firmware at 0x%08X ...\n\r",StartAddress); SerialPortWrite ((UINT8 *) Buffer, CharCount); // To enter into Non Secure state, we need to make a return from exception return_from_exception(PcdGet32(PcdNormalFdBaseAddress)); } else { // When the primary core is stopped by the hardware debugger to copy the firmware // into DRAM. The secondary cores are still running. As soon as the first bytes of // the firmware are written into DRAM, the secondary cores will start to execute the // code even if the firmware is not entirely written into the memory. // That's why the secondary cores need to be parked in WFI and wake up once the // firmware is ready. // Enter Secondary Cores into non Secure State. To enter into Non Secure state, we need to make a return from exception return_from_exception((UINTN)NonSecureWaitForFirmware); } } else { // To enter into Non Secure state, we need to make a return from exception return_from_exception(PcdGet32(PcdNormalFdBaseAddress)); } //-------------------- Non Secure Mode --------------------- // PEI Core should always load and never return ASSERT (FALSE); } // When the firmware is built as not Standalone, the secondary cores need to wait the firmware // entirely written into DRAM. It is the firmware from DRAM which will wake up the secondary cores. VOID NonSecureWaitForFirmware ( VOID ) { VOID (*secondary_start)(VOID); // The secondary cores will execute the firmware once wake from WFI. secondary_start = (VOID (*)())PcdGet32(PcdNormalFdBaseAddress); ArmCallWFI(); // Acknowledge the interrupt and send End of Interrupt signal. PL390GicAcknowledgeSgiFrom(PcdGet32(PcdGicInterruptInterfaceBase),ARM_PRIMARY_CORE); // Jump to secondary core entry point. secondary_start(); // PEI Core should always load and never return ASSERT (FALSE); } VOID SecCommonExceptionEntry ( IN UINT32 Entry, IN UINT32 LR ) { CHAR8 Buffer[100]; UINTN CharCount; switch (Entry) { case 0: CharCount = AsciiSPrint (Buffer,sizeof (Buffer),"Reset Exception at 0x%X\n\r",LR); break; case 1: CharCount = AsciiSPrint (Buffer,sizeof (Buffer),"Undefined Exception at 0x%X\n\r",LR); break; case 2: CharCount = AsciiSPrint (Buffer,sizeof (Buffer),"SWI Exception at 0x%X\n\r",LR); break; case 3: CharCount = AsciiSPrint (Buffer,sizeof (Buffer),"PrefetchAbort Exception at 0x%X\n\r",LR); break; case 4: CharCount = AsciiSPrint (Buffer,sizeof (Buffer),"DataAbort Exception at 0x%X\n\r",LR); break; case 5: CharCount = AsciiSPrint (Buffer,sizeof (Buffer),"Reserved Exception at 0x%X\n\r",LR); break; case 6: CharCount = AsciiSPrint (Buffer,sizeof (Buffer),"IRQ Exception at 0x%X\n\r",LR); break; case 7: CharCount = AsciiSPrint (Buffer,sizeof (Buffer),"FIQ Exception at 0x%X\n\r",LR); break; default: CharCount = AsciiSPrint (Buffer,sizeof (Buffer),"Unknown Exception at 0x%X\n\r",LR); break; } SerialPortWrite ((UINT8 *) Buffer, CharCount); while(1); }