mirror of https://github.com/acidanthera/audk.git
907 lines
25 KiB
C
907 lines
25 KiB
C
/*++
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Copyright (c) 2006, Intel Corporation
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All rights reserved. This program and the accompanying materials
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are licensed and made available under the terms and conditions of the BSD License
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which accompanies this distribution. The full text of the license may be found at
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http://opensource.org/licenses/bsd-license.php
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THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
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WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.
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Module Name:
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EbcSupport.c
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Abstract:
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This module contains EBC support routines that are customized based on
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the target processor.
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--*/
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#include "EbcInt.h"
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#include "EbcExecute.h"
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#define VM_STACK_SIZE (1024 * 32)
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#define EBC_THUNK_SIZE 128
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//
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// For code execution, thunks must be aligned on 16-byte boundary
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//
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#define EBC_THUNK_ALIGNMENT 16
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//
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// Per the IA-64 Software Conventions and Runtime Architecture Guide,
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// section 3.3.4, IPF stack must always be 16-byte aligned.
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//
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#define IPF_STACK_ALIGNMENT 16
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//
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// Opcodes for IPF instructions. We'll need to hand-create thunk code (stuffing
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// bits) to insert a jump to the interpreter.
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//
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#define OPCODE_NOP (UINT64) 0x00008000000
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#define OPCODE_BR_COND_SPTK_FEW (UINT64) 0x00100000000
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#define OPCODE_MOV_BX_RX (UINT64) 0x00E00100000
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//
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// Opcode for MOVL instruction
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//
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#define MOVL_OPCODE 0x06
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VOID
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EbcAsmLLCALLEX (
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IN UINTN CallAddr,
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IN UINTN EbcSp
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);
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STATIC
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EFI_STATUS
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WriteBundle (
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IN VOID *MemPtr,
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IN UINT8 Template,
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IN UINT64 Slot0,
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IN UINT64 Slot1,
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IN UINT64 Slot2
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);
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STATIC
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VOID
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PushU64 (
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VM_CONTEXT *VmPtr,
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UINT64 Arg
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)
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{
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//
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// Advance the VM stack down, and then copy the argument to the stack.
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// Hope it's aligned.
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//
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VmPtr->R[0] -= sizeof (UINT64);
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*(UINT64 *) VmPtr->R[0] = Arg;
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}
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UINT64
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EbcInterpret (
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UINT64 Arg1,
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...
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)
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{
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//
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// Create a new VM context on the stack
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//
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VM_CONTEXT VmContext;
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UINTN Addr;
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VA_LIST List;
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UINT64 Arg2;
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UINT64 Arg3;
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UINT64 Arg4;
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UINT64 Arg5;
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UINT64 Arg6;
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UINT64 Arg7;
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UINT64 Arg8;
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UINTN Arg9Addr;
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//
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// Get the EBC entry point from the processor register. Make sure you don't
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// call any functions before this or you could mess up the register the
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// entry point is passed in.
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//
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Addr = EbcLLGetEbcEntryPoint ();
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//
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// Need the args off the stack.
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//
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VA_START (List, Arg1);
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Arg2 = VA_ARG (List, UINT64);
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Arg3 = VA_ARG (List, UINT64);
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Arg4 = VA_ARG (List, UINT64);
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Arg5 = VA_ARG (List, UINT64);
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Arg6 = VA_ARG (List, UINT64);
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Arg7 = VA_ARG (List, UINT64);
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Arg8 = VA_ARG (List, UINT64);
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Arg9Addr = (UINTN) List;
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//
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// Now clear out our context
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//
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ZeroMem ((VOID *) &VmContext, sizeof (VM_CONTEXT));
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//
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// Set the VM instruction pointer to the correct location in memory.
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//
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VmContext.Ip = (VMIP) Addr;
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//
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// Initialize the stack pointer for the EBC. Get the current system stack
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// pointer and adjust it down by the max needed for the interpreter.
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//
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Addr = (UINTN) Arg9Addr;
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//
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// NOTE: Eventually we should have the interpreter allocate memory
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// for stack space which it will use during its execution. This
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// would likely improve performance because the interpreter would
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// no longer be required to test each memory access and adjust
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// those reading from the stack gap.
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//
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// For IPF, the stack looks like (assuming 10 args passed)
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// arg10
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// arg9 (Bottom of high stack)
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// [ stack gap for interpreter execution ]
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// [ magic value for detection of stack corruption ]
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// arg8 (Top of low stack)
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// arg7....
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// arg1
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// [ 64-bit return address ]
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// [ ebc stack ]
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// If the EBC accesses memory in the stack gap, then we assume that it's
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// actually trying to access args9 and greater. Therefore we need to
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// adjust memory accesses in this region to point above the stack gap.
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//
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VmContext.HighStackBottom = (UINTN) Addr;
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//
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// Now adjust the EBC stack pointer down to leave a gap for interpreter
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// execution. Then stuff a magic value there.
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//
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VmContext.R[0] = (UINT64) Addr;
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VmContext.R[0] -= VM_STACK_SIZE;
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PushU64 (&VmContext, (UINT64) VM_STACK_KEY_VALUE);
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VmContext.StackMagicPtr = (UINTN *) VmContext.R[0];
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VmContext.LowStackTop = (UINTN) VmContext.R[0];
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//
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// Push the EBC arguments on the stack. Does not matter that they may not
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// all be valid.
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//
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PushU64 (&VmContext, Arg8);
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PushU64 (&VmContext, Arg7);
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PushU64 (&VmContext, Arg6);
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PushU64 (&VmContext, Arg5);
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PushU64 (&VmContext, Arg4);
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PushU64 (&VmContext, Arg3);
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PushU64 (&VmContext, Arg2);
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PushU64 (&VmContext, Arg1);
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//
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// Push a bogus return address on the EBC stack because the
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// interpreter expects one there. For stack alignment purposes on IPF,
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// EBC return addresses are always 16 bytes. Push a bogus value as well.
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//
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PushU64 (&VmContext, 0);
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PushU64 (&VmContext, 0xDEADBEEFDEADBEEF);
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VmContext.StackRetAddr = (UINT64) VmContext.R[0];
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//
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// Begin executing the EBC code
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//
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EbcExecute (&VmContext);
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//
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// Return the value in R[7] unless there was an error
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//
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return (UINT64) VmContext.R[7];
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}
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UINT64
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ExecuteEbcImageEntryPoint (
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IN EFI_HANDLE ImageHandle,
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IN EFI_SYSTEM_TABLE *SystemTable
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)
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/*++
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Routine Description:
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IPF implementation.
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Begin executing an EBC image. The address of the entry point is passed
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in via a processor register, so we'll need to make a call to get the
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value.
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Arguments:
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ImageHandle - image handle for the EBC application we're executing
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SystemTable - standard system table passed into an driver's entry point
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Returns:
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The value returned by the EBC application we're going to run.
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--*/
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{
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//
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// Create a new VM context on the stack
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//
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VM_CONTEXT VmContext;
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UINTN Addr;
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//
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// Get the EBC entry point from the processor register. Make sure you don't
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// call any functions before this or you could mess up the register the
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// entry point is passed in.
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//
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Addr = EbcLLGetEbcEntryPoint ();
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//
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// Now clear out our context
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//
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ZeroMem ((VOID *) &VmContext, sizeof (VM_CONTEXT));
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//
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// Save the image handle so we can track the thunks created for this image
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//
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VmContext.ImageHandle = ImageHandle;
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VmContext.SystemTable = SystemTable;
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//
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// Set the VM instruction pointer to the correct location in memory.
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//
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VmContext.Ip = (VMIP) Addr;
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//
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// Get the stack pointer. This is the bottom of the upper stack.
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//
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Addr = EbcLLGetStackPointer ();
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VmContext.HighStackBottom = (UINTN) Addr;
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VmContext.R[0] = (INT64) Addr;
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//
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// Allocate stack space for the interpreter. Then put a magic value
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// at the bottom so we can detect stack corruption.
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//
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VmContext.R[0] -= VM_STACK_SIZE;
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PushU64 (&VmContext, (UINT64) VM_STACK_KEY_VALUE);
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VmContext.StackMagicPtr = (UINTN *) (UINTN) VmContext.R[0];
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//
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// When we thunk to external native code, we copy the last 8 qwords from
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// the EBC stack into the processor registers, and adjust the stack pointer
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// up. If the caller is not passing 8 parameters, then we've moved the
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// stack pointer up into the stack gap. If this happens, then the caller
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// can mess up the stack gap contents (in particular our magic value).
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// Therefore, leave another gap below the magic value. Pick 10 qwords down,
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// just as a starting point.
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//
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VmContext.R[0] -= 10 * sizeof (UINT64);
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//
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// Align the stack pointer such that after pushing the system table,
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// image handle, and return address on the stack, it's aligned on a 16-byte
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// boundary as required for IPF.
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//
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VmContext.R[0] &= (INT64)~0x0f;
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VmContext.LowStackTop = (UINTN) VmContext.R[0];
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//
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// Simply copy the image handle and system table onto the EBC stack.
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// Greatly simplifies things by not having to spill the args
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//
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PushU64 (&VmContext, (UINT64) SystemTable);
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PushU64 (&VmContext, (UINT64) ImageHandle);
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//
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// Interpreter assumes 64-bit return address is pushed on the stack.
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// IPF does not do this so pad the stack accordingly. Also, a
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// "return address" is 16 bytes as required for IPF stack alignments.
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//
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PushU64 (&VmContext, (UINT64) 0);
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PushU64 (&VmContext, (UINT64) 0x1234567887654321);
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VmContext.StackRetAddr = (UINT64) VmContext.R[0];
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//
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// Begin executing the EBC code
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//
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EbcExecute (&VmContext);
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//
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// Return the value in R[7] unless there was an error
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//
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return (UINT64) VmContext.R[7];
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}
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EFI_STATUS
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EbcCreateThunks (
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IN EFI_HANDLE ImageHandle,
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IN VOID *EbcEntryPoint,
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OUT VOID **Thunk,
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IN UINT32 Flags
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)
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/*++
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Routine Description:
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Create thunks for an EBC image entry point, or an EBC protocol service.
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Arguments:
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ImageHandle - Image handle for the EBC image. If not null, then we're
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creating a thunk for an image entry point.
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EbcEntryPoint - Address of the EBC code that the thunk is to call
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Thunk - Returned thunk we create here
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Flags - Flags indicating options for creating the thunk
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Returns:
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Standard EFI status.
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--*/
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{
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UINT8 *Ptr;
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UINT8 *ThunkBase;
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UINT64 Addr;
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UINT64 Code[3]; // Code in a bundle
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UINT64 RegNum; // register number for MOVL
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UINT64 I; // bits of MOVL immediate data
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UINT64 Ic; // bits of MOVL immediate data
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UINT64 Imm5c; // bits of MOVL immediate data
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UINT64 Imm9d; // bits of MOVL immediate data
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UINT64 Imm7b; // bits of MOVL immediate data
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UINT64 Br; // branch register for loading and jumping
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UINT64 *Data64Ptr;
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UINT32 ThunkSize;
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UINT32 Size;
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EFI_STATUS Status;
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//
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// Check alignment of pointer to EBC code, which must always be aligned
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// on a 2-byte boundary.
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//
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if ((UINT32) (UINTN) EbcEntryPoint & 0x01) {
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return EFI_INVALID_PARAMETER;
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}
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//
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// Allocate memory for the thunk. Make the (most likely incorrect) assumption
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// that the returned buffer is not aligned, so round up to the next
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// alignment size.
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//
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Size = EBC_THUNK_SIZE + EBC_THUNK_ALIGNMENT - 1;
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ThunkSize = Size;
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Status = gBS->AllocatePool (
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EfiBootServicesData,
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Size,
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(VOID *) &Ptr
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);
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if (Status != EFI_SUCCESS) {
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return EFI_OUT_OF_RESOURCES;
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}
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//
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// Save the start address of the buffer.
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//
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ThunkBase = Ptr;
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//
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// Make sure it's aligned for code execution. If not, then
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// round up.
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//
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if ((UINT32) (UINTN) Ptr & (EBC_THUNK_ALIGNMENT - 1)) {
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Ptr = (UINT8 *) (((UINTN) Ptr + (EBC_THUNK_ALIGNMENT - 1)) &~ (UINT64) (EBC_THUNK_ALIGNMENT - 1));
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}
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//
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// Return the pointer to the thunk to the caller to user as the
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// image entry point.
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//
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*Thunk = (VOID *) Ptr;
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//
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// Clear out the thunk entry
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// ZeroMem(Ptr, Size);
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//
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// For IPF, when you do a call via a function pointer, the function pointer
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// actually points to a function descriptor which consists of a 64-bit
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// address of the function, followed by a 64-bit gp for the function being
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// called. See the the Software Conventions and Runtime Architecture Guide
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// for details.
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// So first off in our thunk, create a descriptor for our actual thunk code.
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// This means we need to create a pointer to the thunk code (which follows
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// the descriptor we're going to create), followed by the gp of the Vm
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// interpret function we're going to eventually execute.
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//
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Data64Ptr = (UINT64 *) Ptr;
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//
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// Write the function's entry point (which is our thunk code that follows
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// this descriptor we're creating).
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//
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*Data64Ptr = (UINT64) (Data64Ptr + 2);
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//
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// Get the gp from the descriptor for EbcInterpret and stuff it in our thunk
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// descriptor.
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//
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*(Data64Ptr + 1) = *(UINT64 *) ((UINT64 *) (UINTN) EbcInterpret + 1);
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//
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// Advance our thunk data pointer past the descriptor. Since the
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// descriptor consists of 16 bytes, the pointer is still aligned for
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// IPF code execution (on 16-byte boundary).
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//
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Ptr += sizeof (UINT64) * 2;
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//
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// *************************** MAGIC BUNDLE ********************************
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//
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// Write magic code bundle for: movl r8 = 0xca112ebcca112ebc to help the VM
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// to recognize it is a thunk.
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//
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Addr = (UINT64) 0xCA112EBCCA112EBC;
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//
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// Now generate the code bytes. First is nop.m 0x0
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//
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Code[0] = OPCODE_NOP;
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//
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// Next is simply Addr[62:22] (41 bits) of the address
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//
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Code[1] = RightShiftU64 (Addr, 22) & 0x1ffffffffff;
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//
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// Extract bits from the address for insertion into the instruction
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// i = Addr[63:63]
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//
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I = RightShiftU64 (Addr, 63) & 0x01;
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//
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// ic = Addr[21:21]
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//
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Ic = RightShiftU64 (Addr, 21) & 0x01;
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//
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// imm5c = Addr[20:16] for 5 bits
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//
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Imm5c = RightShiftU64 (Addr, 16) & 0x1F;
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//
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// imm9d = Addr[15:7] for 9 bits
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//
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Imm9d = RightShiftU64 (Addr, 7) & 0x1FF;
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//
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// imm7b = Addr[6:0] for 7 bits
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//
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Imm7b = Addr & 0x7F;
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//
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// The EBC entry point will be put into r8, so r8 can be used here
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// temporary. R8 is general register and is auto-serialized.
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//
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RegNum = 8;
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//
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// Next is jumbled data, including opcode and rest of address
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//
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Code[2] = LeftShiftU64 (Imm7b, 13)
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| LeftShiftU64 (0x00, 20) // vc
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| LeftShiftU64 (Ic, 21)
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| LeftShiftU64 (Imm5c, 22)
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| LeftShiftU64 (Imm9d, 27)
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| LeftShiftU64 (I, 36)
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| LeftShiftU64 ((UINT64)MOVL_OPCODE, 37)
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| LeftShiftU64 ((RegNum & 0x7F), 6);
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WriteBundle ((VOID *) Ptr, 0x05, Code[0], Code[1], Code[2]);
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//
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// *************************** FIRST BUNDLE ********************************
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//
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// Write code bundle for: movl r8 = EBC_ENTRY_POINT so we pass
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// the ebc entry point in to the interpreter function via a processor
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// register.
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// Note -- we could easily change this to pass in a pointer to a structure
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// that contained, among other things, the EBC image's entry point. But
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// for now pass it directly.
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//
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Ptr += 16;
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Addr = (UINT64) EbcEntryPoint;
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//
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// Now generate the code bytes. First is nop.m 0x0
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//
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Code[0] = OPCODE_NOP;
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//
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// Next is simply Addr[62:22] (41 bits) of the address
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//
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Code[1] = RightShiftU64 (Addr, 22) & 0x1ffffffffff;
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//
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// Extract bits from the address for insertion into the instruction
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// i = Addr[63:63]
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//
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I = RightShiftU64 (Addr, 63) & 0x01;
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//
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// ic = Addr[21:21]
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//
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Ic = RightShiftU64 (Addr, 21) & 0x01;
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//
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// imm5c = Addr[20:16] for 5 bits
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//
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Imm5c = RightShiftU64 (Addr, 16) & 0x1F;
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//
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// imm9d = Addr[15:7] for 9 bits
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//
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Imm9d = RightShiftU64 (Addr, 7) & 0x1FF;
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//
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// imm7b = Addr[6:0] for 7 bits
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//
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Imm7b = Addr & 0x7F;
|
|
|
|
//
|
|
// Put the EBC entry point in r8, which is the location of the return value
|
|
// for functions.
|
|
//
|
|
RegNum = 8;
|
|
|
|
//
|
|
// Next is jumbled data, including opcode and rest of address
|
|
//
|
|
Code[2] = LeftShiftU64 (Imm7b, 13)
|
|
| LeftShiftU64 (0x00, 20) // vc
|
|
| LeftShiftU64 (Ic, 21)
|
|
| LeftShiftU64 (Imm5c, 22)
|
|
| LeftShiftU64 (Imm9d, 27)
|
|
| LeftShiftU64 (I, 36)
|
|
| LeftShiftU64 ((UINT64)MOVL_OPCODE, 37)
|
|
| LeftShiftU64 ((RegNum & 0x7F), 6);
|
|
|
|
WriteBundle ((VOID *) Ptr, 0x05, Code[0], Code[1], Code[2]);
|
|
|
|
//
|
|
// *************************** NEXT BUNDLE *********************************
|
|
//
|
|
// Write code bundle for:
|
|
// movl rx = offset_of(EbcInterpret|ExecuteEbcImageEntryPoint)
|
|
//
|
|
// Advance pointer to next bundle, then compute the offset from this bundle
|
|
// to the address of the entry point of the interpreter.
|
|
//
|
|
Ptr += 16;
|
|
if (Flags & FLAG_THUNK_ENTRY_POINT) {
|
|
Addr = (UINT64) ExecuteEbcImageEntryPoint;
|
|
} else {
|
|
Addr = (UINT64) EbcInterpret;
|
|
}
|
|
//
|
|
// Indirection on Itanium-based systems
|
|
//
|
|
Addr = *(UINT64 *) Addr;
|
|
|
|
//
|
|
// Now write the code to load the offset into a register
|
|
//
|
|
Code[0] = OPCODE_NOP;
|
|
|
|
//
|
|
// Next is simply Addr[62:22] (41 bits) of the address
|
|
//
|
|
Code[1] = RightShiftU64 (Addr, 22) & 0x1ffffffffff;
|
|
|
|
//
|
|
// Extract bits from the address for insertion into the instruction
|
|
// i = Addr[63:63]
|
|
//
|
|
I = RightShiftU64 (Addr, 63) & 0x01;
|
|
//
|
|
// ic = Addr[21:21]
|
|
//
|
|
Ic = RightShiftU64 (Addr, 21) & 0x01;
|
|
//
|
|
// imm5c = Addr[20:16] for 5 bits
|
|
//
|
|
Imm5c = RightShiftU64 (Addr, 16) & 0x1F;
|
|
//
|
|
// imm9d = Addr[15:7] for 9 bits
|
|
//
|
|
Imm9d = RightShiftU64 (Addr, 7) & 0x1FF;
|
|
//
|
|
// imm7b = Addr[6:0] for 7 bits
|
|
//
|
|
Imm7b = Addr & 0x7F;
|
|
|
|
//
|
|
// Put it in r31, a scratch register
|
|
//
|
|
RegNum = 31;
|
|
|
|
//
|
|
// Next is jumbled data, including opcode and rest of address
|
|
//
|
|
Code[2] = LeftShiftU64(Imm7b, 13)
|
|
| LeftShiftU64 (0x00, 20) // vc
|
|
| LeftShiftU64 (Ic, 21)
|
|
| LeftShiftU64 (Imm5c, 22)
|
|
| LeftShiftU64 (Imm9d, 27)
|
|
| LeftShiftU64 (I, 36)
|
|
| LeftShiftU64 ((UINT64)MOVL_OPCODE, 37)
|
|
| LeftShiftU64 ((RegNum & 0x7F), 6);
|
|
|
|
WriteBundle ((VOID *) Ptr, 0x05, Code[0], Code[1], Code[2]);
|
|
|
|
//
|
|
// *************************** NEXT BUNDLE *********************************
|
|
//
|
|
// Load branch register with EbcInterpret() function offset from the bundle
|
|
// address: mov b6 = RegNum
|
|
//
|
|
// See volume 3 page 4-29 of the Arch. Software Developer's Manual.
|
|
//
|
|
// Advance pointer to next bundle
|
|
//
|
|
Ptr += 16;
|
|
Code[0] = OPCODE_NOP;
|
|
Code[1] = OPCODE_NOP;
|
|
Code[2] = OPCODE_MOV_BX_RX;
|
|
|
|
//
|
|
// Pick a branch register to use. Then fill in the bits for the branch
|
|
// register and user register (same user register as previous bundle).
|
|
//
|
|
Br = 6;
|
|
Code[2] |= LeftShiftU64 (Br, 6);
|
|
Code[2] |= LeftShiftU64 (RegNum, 13);
|
|
WriteBundle ((VOID *) Ptr, 0x0d, Code[0], Code[1], Code[2]);
|
|
|
|
//
|
|
// *************************** NEXT BUNDLE *********************************
|
|
//
|
|
// Now do the branch: (p0) br.cond.sptk.few b6
|
|
//
|
|
// Advance pointer to next bundle.
|
|
// Fill in the bits for the branch register (same reg as previous bundle)
|
|
//
|
|
Ptr += 16;
|
|
Code[0] = OPCODE_NOP;
|
|
Code[1] = OPCODE_NOP;
|
|
Code[2] = OPCODE_BR_COND_SPTK_FEW;
|
|
Code[2] |= LeftShiftU64 (Br, 13);
|
|
WriteBundle ((VOID *) Ptr, 0x1d, Code[0], Code[1], Code[2]);
|
|
|
|
//
|
|
// Add the thunk to our list of allocated thunks so we can do some cleanup
|
|
// when the image is unloaded. Do this last since the Add function flushes
|
|
// the instruction cache for us.
|
|
//
|
|
EbcAddImageThunk (ImageHandle, (VOID *) ThunkBase, ThunkSize);
|
|
|
|
//
|
|
// Done
|
|
//
|
|
return EFI_SUCCESS;
|
|
}
|
|
|
|
STATIC
|
|
EFI_STATUS
|
|
WriteBundle (
|
|
IN VOID *MemPtr,
|
|
IN UINT8 Template,
|
|
IN UINT64 Slot0,
|
|
IN UINT64 Slot1,
|
|
IN UINT64 Slot2
|
|
)
|
|
/*++
|
|
|
|
Routine Description:
|
|
|
|
Given raw bytes of Itanium based code, format them into a bundle and
|
|
write them out.
|
|
|
|
Arguments:
|
|
|
|
MemPtr - pointer to memory location to write the bundles to
|
|
Template - 5-bit template
|
|
Slot0-2 - instruction slot data for the bundle
|
|
|
|
Returns:
|
|
|
|
EFI_INVALID_PARAMETER - Pointer is not aligned
|
|
- No more than 5 bits in template
|
|
- More than 41 bits used in code
|
|
EFI_SUCCESS - All data is written.
|
|
|
|
--*/
|
|
{
|
|
UINT8 *BPtr;
|
|
UINT32 Index;
|
|
UINT64 Low64;
|
|
UINT64 High64;
|
|
|
|
//
|
|
// Verify pointer is aligned
|
|
//
|
|
if ((UINT64) MemPtr & 0xF) {
|
|
return EFI_INVALID_PARAMETER;
|
|
}
|
|
//
|
|
// Verify no more than 5 bits in template
|
|
//
|
|
if (Template &~0x1F) {
|
|
return EFI_INVALID_PARAMETER;
|
|
}
|
|
//
|
|
// Verify max of 41 bits used in code
|
|
//
|
|
if ((Slot0 | Slot1 | Slot2) &~0x1ffffffffff) {
|
|
return EFI_INVALID_PARAMETER;
|
|
}
|
|
|
|
Low64 = LeftShiftU64 (Slot1, 46) | LeftShiftU64 (Slot0, 5) | Template;
|
|
High64 = RightShiftU64 (Slot1, 18) | LeftShiftU64 (Slot2, 23);
|
|
|
|
//
|
|
// Now write it all out
|
|
//
|
|
BPtr = (UINT8 *) MemPtr;
|
|
for (Index = 0; Index < 8; Index++) {
|
|
*BPtr = (UINT8) Low64;
|
|
Low64 = RightShiftU64 (Low64, 8);
|
|
BPtr++;
|
|
}
|
|
|
|
for (Index = 0; Index < 8; Index++) {
|
|
*BPtr = (UINT8) High64;
|
|
High64 = RightShiftU64 (High64, 8);
|
|
BPtr++;
|
|
}
|
|
|
|
return EFI_SUCCESS;
|
|
}
|
|
|
|
VOID
|
|
EbcLLCALLEX (
|
|
IN VM_CONTEXT *VmPtr,
|
|
IN UINTN FuncAddr,
|
|
IN UINTN NewStackPointer,
|
|
IN VOID *FramePtr,
|
|
IN UINT8 Size
|
|
)
|
|
/*++
|
|
|
|
Routine Description:
|
|
|
|
This function is called to execute an EBC CALLEX instruction.
|
|
The function check the callee's content to see whether it is common native
|
|
code or a thunk to another piece of EBC code.
|
|
If the callee is common native code, use EbcLLCAllEXASM to manipulate,
|
|
otherwise, set the VM->IP to target EBC code directly to avoid another VM
|
|
be startup which cost time and stack space.
|
|
|
|
Arguments:
|
|
|
|
VmPtr - Pointer to a VM context.
|
|
FuncAddr - Callee's address
|
|
NewStackPointer - New stack pointer after the call
|
|
FramePtr - New frame pointer after the call
|
|
Size - The size of call instruction
|
|
|
|
Returns:
|
|
|
|
None.
|
|
|
|
--*/
|
|
{
|
|
UINTN IsThunk;
|
|
UINTN TargetEbcAddr;
|
|
UINTN CodeOne18;
|
|
UINTN CodeOne23;
|
|
UINTN CodeTwoI;
|
|
UINTN CodeTwoIc;
|
|
UINTN CodeTwo7b;
|
|
UINTN CodeTwo5c;
|
|
UINTN CodeTwo9d;
|
|
UINTN CalleeAddr;
|
|
|
|
IsThunk = 1;
|
|
TargetEbcAddr = 0;
|
|
|
|
//
|
|
// FuncAddr points to the descriptor of the target instructions.
|
|
//
|
|
CalleeAddr = *((UINT64 *)FuncAddr);
|
|
|
|
//
|
|
// Processor specific code to check whether the callee is a thunk to EBC.
|
|
//
|
|
if (*((UINT64 *)CalleeAddr) != 0xBCCA000100000005) {
|
|
IsThunk = 0;
|
|
goto Action;
|
|
}
|
|
if (*((UINT64 *)CalleeAddr + 1) != 0x697623C1004A112E) {
|
|
IsThunk = 0;
|
|
goto Action;
|
|
}
|
|
|
|
CodeOne18 = RightShiftU64 (*((UINT64 *)CalleeAddr + 2), 46) & 0x3FFFF;
|
|
CodeOne23 = (*((UINT64 *)CalleeAddr + 3)) & 0x7FFFFF;
|
|
CodeTwoI = RightShiftU64 (*((UINT64 *)CalleeAddr + 3), 59) & 0x1;
|
|
CodeTwoIc = RightShiftU64 (*((UINT64 *)CalleeAddr + 3), 44) & 0x1;
|
|
CodeTwo7b = RightShiftU64 (*((UINT64 *)CalleeAddr + 3), 36) & 0x7F;
|
|
CodeTwo5c = RightShiftU64 (*((UINT64 *)CalleeAddr + 3), 45) & 0x1F;
|
|
CodeTwo9d = RightShiftU64 (*((UINT64 *)CalleeAddr + 3), 50) & 0x1FF;
|
|
|
|
TargetEbcAddr = CodeTwo7b
|
|
| LeftShiftU64 (CodeTwo9d, 7)
|
|
| LeftShiftU64 (CodeTwo5c, 16)
|
|
| LeftShiftU64 (CodeTwoIc, 21)
|
|
| LeftShiftU64 (CodeOne18, 22)
|
|
| LeftShiftU64 (CodeOne23, 40)
|
|
| LeftShiftU64 (CodeTwoI, 63)
|
|
;
|
|
|
|
Action:
|
|
if (IsThunk == 1){
|
|
//
|
|
// The callee is a thunk to EBC, adjust the stack pointer down 16 bytes and
|
|
// put our return address and frame pointer on the VM stack.
|
|
// Then set the VM's IP to new EBC code.
|
|
//
|
|
VmPtr->R[0] -= 8;
|
|
VmWriteMemN (VmPtr, (UINTN) VmPtr->R[0], (UINTN) FramePtr);
|
|
VmPtr->FramePtr = (VOID *) (UINTN) VmPtr->R[0];
|
|
VmPtr->R[0] -= 8;
|
|
VmWriteMem64 (VmPtr, (UINTN) VmPtr->R[0], (UINT64) (VmPtr->Ip + Size));
|
|
|
|
VmPtr->Ip = (VMIP) (UINTN) TargetEbcAddr;
|
|
} else {
|
|
//
|
|
// The callee is not a thunk to EBC, call native code.
|
|
//
|
|
EbcLLCALLEXNative (FuncAddr, NewStackPointer, FramePtr);
|
|
|
|
//
|
|
// Get return value and advance the IP.
|
|
//
|
|
VmPtr->R[7] = EbcLLGetReturnValue ();
|
|
VmPtr->Ip += Size;
|
|
}
|
|
}
|
|
|
|
VOID
|
|
EbcLLCALLEXNative (
|
|
IN UINTN CallAddr,
|
|
IN UINTN EbcSp,
|
|
IN VOID *FramePtr
|
|
)
|
|
/*++
|
|
|
|
Routine Description:
|
|
Implements the EBC CALLEX instruction to call an external function, which
|
|
seems to be native code.
|
|
|
|
We'll copy the entire EBC stack frame down below itself in memory and use
|
|
that copy for passing parameters.
|
|
|
|
Arguments:
|
|
CallAddr - address (function pointer) of function to call
|
|
EbcSp - current EBC stack pointer
|
|
FramePtr - current EBC frame pointer.
|
|
|
|
Returns:
|
|
NA
|
|
|
|
--*/
|
|
{
|
|
UINTN FrameSize;
|
|
VOID *Destination;
|
|
VOID *Source;
|
|
//
|
|
// The stack for an EBC function looks like this:
|
|
// FramePtr (8)
|
|
// RetAddr (8)
|
|
// Locals (n)
|
|
// Stack for passing args (m)
|
|
//
|
|
// Pad the frame size with 64 bytes because the low-level code we call
|
|
// will move the stack pointer up assuming worst-case 8 args in registers.
|
|
//
|
|
FrameSize = (UINTN) FramePtr - (UINTN) EbcSp + 64;
|
|
Source = (VOID *) EbcSp;
|
|
Destination = (VOID *) ((UINT8 *) EbcSp - FrameSize - IPF_STACK_ALIGNMENT);
|
|
Destination = (VOID *) ((UINTN) ((UINTN) Destination + IPF_STACK_ALIGNMENT - 1) &~((UINTN) IPF_STACK_ALIGNMENT - 1));
|
|
gBS->CopyMem (Destination, Source, FrameSize);
|
|
EbcAsmLLCALLEX ((UINTN) CallAddr, (UINTN) Destination);
|
|
}
|