X-Git-Url: https://git.proxmox.com/?p=mirror_edk2.git;a=blobdiff_plain;f=ArmPlatformPkg%2FSec%2FSec.c;h=a40f43683a7d9f22bf83a7097add2cac92c25e6d;hp=64cf0f0d7ebe5aad99a564509dc5e85379aaf0be;hb=8d0fe26cbf66739ba80f7d2fc6acb683cecbf68f;hpb=1ad14bc86b56eb0134b1c9e504a7392e32c44ddb

diff --git a/ArmPlatformPkg/Sec/Sec.c b/ArmPlatformPkg/Sec/Sec.c
index 64cf0f0d7e..a40f43683a 100644
--- a/ArmPlatformPkg/Sec/Sec.c
+++ b/ArmPlatformPkg/Sec/Sec.c
@@ -1,5 +1,5 @@
 /** @file
-*  Main file supporting the SEC Phase for Versatile Express
+*  Main file supporting the SEC Phase on ARM Platforms
 *
 *  Copyright (c) 2011, ARM Limited. All rights reserved.
 *  
@@ -13,68 +13,34 @@
 *
 **/
 
-#include <Library/DebugLib.h>
-#include <Library/PcdLib.h>
+#include <Library/DebugAgentLib.h>
 #include <Library/PrintLib.h>
-#include <Library/BaseLib.h>
 #include <Library/BaseMemoryLib.h>
-#include <Library/ArmLib.h>
 #include <Library/SerialPortLib.h>
-#include <Library/ArmPlatformLib.h>
+#include <Library/ArmGicLib.h>
+#include <Library/ArmCpuLib.h>
 
-#include <Chipset/ArmV7.h>
-#include <Drivers/PL390Gic.h>
+#include "SecInternal.h"
 
-#define ARM_PRIMARY_CORE  0
-
-#define SerialPrint(txt)  SerialPortWrite (txt, AsciiStrLen(txt)+1);
+#define SerialPrint(txt)  SerialPortWrite ((UINT8*)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
+  IN  UINTN                     MpId
   )
 {
   CHAR8           Buffer[100];
   UINTN           CharCount;
+  UINTN           JumpAddress;
 
   // Primary CPU clears out the SCU tag RAMs, secondaries wait
-  if (CoreId == ARM_PRIMARY_CORE) {
-    if (FixedPcdGet32(PcdMPCoreSupport)) {
-      ArmInvalidScu();
+  if (IS_PRIMARY_CORE(MpId)) {
+    ArmCpuSetup (MpId);
+
+    if (ArmIsMpCore()) {
+      ArmCpuSynchronizeSignal (ARM_CPU_EVENT_BOOT_MEM_INIT);
     }
 
     // SEC phase needs to run library constructors by hand. This assumes we are linked against the SerialLib
@@ -85,182 +51,119 @@ CEntryPoint (
     CharCount = AsciiSPrint (Buffer,sizeof (Buffer),"UEFI firmware built at %a on %a\n\r",__TIME__, __DATE__);
     SerialPortWrite ((UINT8 *) Buffer, CharCount);
 
+    // Initialize the Debug Agent for Source Level Debugging
+    InitializeDebugAgent (DEBUG_AGENT_INIT_PREMEM_SEC, NULL, NULL);
+    SaveAndSetDebugTimerInterrupt (TRUE);
+
     // Now we've got UART, make the check:
     // - The Vector table must be 32-byte aligned
     ASSERT(((UINT32)SecVectorTable & ((1 << 5)-1)) == 0);
+
+    // Enable the GIC distributor and CPU Interface
+    // - no other Interrupts are enabled,  doesn't have to worry about the priority.
+    // - all the cores are in secure state, use secure SGI's
+    ArmGicEnableDistributor (PcdGet32(PcdGicDistributorBase));
+    ArmGicEnableInterruptInterface (PcdGet32(PcdGicInterruptInterfaceBase));
+  } else {
+    // Enable the GIC CPU Interface
+    ArmGicEnableInterruptInterface (PcdGet32(PcdGicInterruptInterfaceBase));
   }
 
   // Invalidate the data cache. Doesn't have to do the Data cache clean.
   ArmInvalidateDataCache();
 
-  //Invalidate Instruction Cache
+  // Invalidate Instruction Cache
   ArmInvalidateInstructionCache();
 
-  //Invalidate I & D TLBs
+  // 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)) {
+  if (FixedPcdGet32 (PcdVFPEnabled)) {
     ArmEnableVFP();
   }
 
-  if (CoreId == ARM_PRIMARY_CORE) {
+  if (IS_PRIMARY_CORE(MpId)) {
     // 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)) {
+    if (FeaturePcdGet (PcdSystemMemoryInitializeInSec)) {
       // 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)) {
+  if (FixedPcdGetBool (PcdTrustzoneSupport)) {
+    // Ensure the Monitor Stack Base & Size have been set
+    ASSERT(PcdGet32(PcdCPUCoresSecMonStackBase) != 0);
+    ASSERT(PcdGet32(PcdCPUCoreSecMonStackSize) != 0);
+
+    if (ArmIsMpCore()) {
       // Setup SMP in Non Secure world
-      ArmSetupSmpNonSecure (CoreId);
+      ArmCpuSetupSmpNonSecure (GET_CORE_ID(MpId));
     }
 
     // Enter Monitor Mode
-    enter_monitor_mode((VOID*)(PcdGet32(PcdCPUCoresSecMonStackBase) + (PcdGet32(PcdCPUCoreSecMonStackSize) * CoreId)));
+    enter_monitor_mode ((VOID*)(PcdGet32(PcdCPUCoresSecMonStackBase) + (PcdGet32(PcdCPUCoreSecMonStackSize) * GET_CORE_POS(MpId))));
 
     //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);
+    if (IS_PRIMARY_CORE(MpId)) {
+      ArmPlatformTrustzoneInit ();
+
+      // Waiting for the Primary Core to have finished to initialize the Secure World
+      ArmCpuSynchronizeSignal (ARM_CPU_EVENT_SECURE_INIT);
     } 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);
+      // Waiting for the Primary Core to have finished to initialize the Secure World
+      ArmCpuSynchronizeWait (ARM_CPU_EVENT_SECURE_INIT);
     }
 
     // Transfer the interrupt to Non-secure World
-    PL390GicSetupNonSecure(PcdGet32(PcdGicDistributorBase),PcdGet32(PcdGicInterruptInterfaceBase));
+    ArmGicSetupNonSecure (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));
+    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);
+    ArmWriteScr (SCR_NS | SCR_FW | SCR_AW);
   } else {
-    if (CoreId == ARM_PRIMARY_CORE) {
+    if (IS_PRIMARY_CORE(MpId)) {
       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();
+    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(PcdNormalFvBaseAddress);
-
-      // 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);
+  JumpAddress = PcdGet32 (PcdFvBaseAddress);
+  ArmPlatformSecExtraAction (MpId, &JumpAddress);
 
-      // To enter into Non Secure state, we need to make a return from exception
-      return_from_exception(PcdGet32(PcdNormalFvBaseAddress));
-    } 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(PcdNormalFvBaseAddress));
-  }
+  return_from_exception (JumpAddress);
   //-------------------- 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(PcdNormalFvBaseAddress);
-
-  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,