/** @file C Entry point for the SEC. First C code after the reset vector. Copyright (c) 2008-2009, Apple Inc. All rights reserved. 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 VOID EFIAPI _ModuleEntryPoint( VOID ); CHAR8 * DeCygwinPathIfNeeded ( IN CHAR8 *Name ); VOID PadConfiguration ( VOID ); VOID ClockInit ( VOID ); VOID TimerInit ( VOID ) { UINTN Timer = FixedPcdGet32(PcdBeagleFreeTimer); UINT32 TimerBaseAddress = TimerBase(Timer); // Set source clock for GPT3 & GPT4 to SYS_CLK MmioOr32(CM_CLKSEL_PER, CM_CLKSEL_PER_CLKSEL_GPT3_SYS | CM_CLKSEL_PER_CLKSEL_GPT4_SYS); // Set count & reload registers MmioWrite32(TimerBaseAddress + GPTIMER_TCRR, 0x00000000); MmioWrite32(TimerBaseAddress + GPTIMER_TLDR, 0x00000000); // Disable interrupts MmioWrite32(TimerBaseAddress + GPTIMER_TIER, TIER_TCAR_IT_DISABLE | TIER_OVF_IT_DISABLE | TIER_MAT_IT_DISABLE); // Start Timer MmioWrite32(TimerBaseAddress + GPTIMER_TCLR, TCLR_AR_AUTORELOAD | TCLR_ST_ON); //Disable OMAP Watchdog timer (WDT2) MmioWrite32(WDTIMER2_BASE + WSPR, 0xAAAA); DEBUG ((EFI_D_ERROR, "Magic delay to disable watchdog timers properly.\n")); MmioWrite32(WDTIMER2_BASE + WSPR, 0x5555); } VOID UartInit ( VOID ) { UINTN Uart = FixedPcdGet32(PcdBeagleConsoleUart); UINT32 UartBaseAddress = UartBase(Uart); // Set MODE_SELECT=DISABLE before trying to initialize or modify DLL, DLH registers. MmioWrite32(UartBaseAddress + UART_MDR1_REG, UART_MDR1_MODE_SELECT_DISABLE); // Put device in configuration mode. MmioWrite32(UartBaseAddress + UART_LCR_REG, UART_LCR_DIV_EN_ENABLE); // Programmable divisor N = 48Mhz/16/115200 = 26 MmioWrite32(UartBaseAddress + UART_DLL_REG, 26); // low divisor MmioWrite32(UartBaseAddress + UART_DLH_REG, 0); // high divisor // Enter into UART operational mode. MmioWrite32(UartBaseAddress + UART_LCR_REG, UART_LCR_DIV_EN_DISABLE | UART_LCR_CHAR_LENGTH_8); // Force DTR and RTS output to active MmioWrite32(UartBaseAddress + UART_MCR_REG, UART_MCR_RTS_FORCE_ACTIVE | UART_MCR_DTR_FORCE_ACTIVE); // Clear & enable fifos MmioWrite32(UartBaseAddress + UART_FCR_REG, UART_FCR_TX_FIFO_CLEAR | UART_FCR_RX_FIFO_CLEAR | UART_FCR_FIFO_ENABLE); // Restore MODE_SELECT MmioWrite32(UartBaseAddress + UART_MDR1_REG, UART_MDR1_MODE_SELECT_UART_16X); } VOID InitCache ( IN UINT32 MemoryBase, IN UINT32 MemoryLength ); EFI_STATUS EFIAPI ExtractGuidedSectionLibConstructor ( VOID ); EFI_STATUS EFIAPI LzmaDecompressLibConstructor ( VOID ); /** If the build is done on cygwin the paths are cygpaths. /cygdrive/c/tmp.txt vs c:\tmp.txt so we need to convert them to work with RVD commands This is just code to help print out RVD symbol load command. If you build with cygwin paths aren't compatible with RVD. @param Name Path to convert if needed **/ CHAR8 * SecDeCygwinPathIfNeeded ( IN CHAR8 *Name ) { CHAR8 *Ptr; UINTN Index; UINTN Len; Ptr = AsciiStrStr (Name, "/cygdrive/"); if (Ptr == NULL) { return Name; } Len = AsciiStrLen (Ptr); // convert "/cygdrive" to spaces for (Index = 0; Index < 9; Index++) { Ptr[Index] = ' '; } // convert /c to c: Ptr[9] = Ptr[10]; Ptr[10] = ':'; // switch path seperators for (Index = 11; Index < Len; Index++) { if (Ptr[Index] == '/') { Ptr[Index] = '\\' ; } } return Name; } VOID CEntryPoint ( IN VOID *MemoryBase, IN UINTN MemorySize, IN VOID *StackBase, IN UINTN StackSize ) { VOID *HobBase; //Set up Pin muxing. PadConfiguration(); // Set up system clocking ClockInit(); // Build a basic HOB list HobBase = (VOID *)(UINTN)(FixedPcdGet32(PcdEmbeddedFdBaseAddress) + FixedPcdGet32(PcdEmbeddedFdSize)); CreateHobList(MemoryBase, MemorySize, HobBase, StackBase); // Enable program flow prediction, if supported. ArmEnableBranchPrediction(); // Initialize CPU cache InitCache((UINT32)MemoryBase, (UINT32)MemorySize); // Add memory allocation hob for relocated FD BuildMemoryAllocationHob(FixedPcdGet32(PcdEmbeddedFdBaseAddress), FixedPcdGet32(PcdEmbeddedFdSize), EfiBootServicesData); // Add the FVs to the hob list BuildFvHob(PcdGet32(PcdFlashFvMainBase), PcdGet32(PcdFlashFvMainSize)); // Start talking UartInit(); DEBUG((EFI_D_ERROR, "UART Enabled\n")); DEBUG_CODE_BEGIN (); // // On a debug build print out information about the SEC. This is really info about // the PE/COFF file we are currently running from. Useful for loading symbols in a // debugger. Remember our image is really part of the FV. // RETURN_STATUS Status; EFI_PEI_FV_HANDLE VolumeHandle; EFI_PEI_FILE_HANDLE FileHandle; VOID *PeCoffImage; UINT32 Offset; CHAR8 *FilePath; FfsAnyFvFindFirstFile (EFI_FV_FILETYPE_SECURITY_CORE, &VolumeHandle, &FileHandle); Status = FfsFindSectionData (EFI_SECTION_TE, FileHandle, &PeCoffImage); if (EFI_ERROR (Status)) { // Usually is a TE (PI striped down PE/COFF), but could be a full PE/COFF Status = FfsFindSectionData (EFI_SECTION_PE32, FileHandle, &PeCoffImage); } if (!EFI_ERROR (Status)) { Offset = PeCoffGetSizeOfHeaders (PeCoffImage); FilePath = PeCoffLoaderGetPdbPointer (PeCoffImage); if (FilePath != NULL) { // // In general you should never have to use #ifdef __CC_ARM in the code. It // is hidden in the away in the MdePkg. But here we would like to print differnt things // for different toolchains. // #ifdef __CC_ARM // Print out the command for the RVD debugger to load symbols for this image DEBUG ((EFI_D_ERROR, "load /a /ni /np %a &0x%08x\n", SecDeCygwinPathIfNeeded (FilePath), PeCoffImage + Offset)); #elif __GNUC__ // This may not work correctly if you generate PE/COFF directlyas then the Offset would not be required DEBUG ((EFI_D_ERROR, "add-symbol-file %a 0x%08x\n", FilePath, PeCoffImage + Offset)); #else DEBUG ((EFI_D_ERROR, "SEC starts at 0x%08x with an entry point at 0x%08x %a\n", PeCoffImage, _ModuleEntryPoint, FilePath)); #endif } } DEBUG_CODE_END (); // Start up a free running time so that the timer lib will work TimerInit(); // SEC phase needs to run library constructors by hand. ExtractGuidedSectionLibConstructor(); LzmaDecompressLibConstructor(); // Load the DXE Core and transfer control to it LoadDxeCoreFromFv(NULL, 0); // DXE Core should always load and never return ASSERT(FALSE); }