MdeModulePkg/Universal/EbcDxe/Ipf/EbcLowLevel.s - third_party/edk2 - Git at Google

 ///** @file
 //
 //  Contains low level routines for the Virtual Machine implementation
 //  on an Itanium-based platform.
 //
 //  Copyright (c) 2006 - 2011, Intel Corporation. All rights reserved.<BR>
 //  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.
 //
 //**/

 .file  "EbcLowLevel.s"

 #define PROCEDURE_ENTRY(name)   .##text;            \
                                 .##type name, @function;    \
                                 .##proc name;           \
 name::

 #define PROCEDURE_EXIT(name)    .##endp name

 // Note: use of NESTED_SETUP requires number of locals (l) >= 3

 #define NESTED_SETUP(i,l,o,r) \
          alloc loc1=ar##.##pfs,i,l,o,r ;\
          mov loc0=b0

 #define NESTED_RETURN \
          mov b0=loc0 ;\
          mov ar##.##pfs=loc1 ;;\
          br##.##ret##.##dpnt  b0;;

 .type CopyMem, @function;

 //-----------------------------------------------------------------------------
 //++
 // EbcAsmLLCALLEX
 //
 //  Implements the low level EBC CALLEX instruction. Sets up the
 //  stack pointer, does the spill of function arguments, and
 //  calls the native function. On return it restores the original
 //  stack pointer and returns to the caller.
 //
 // Arguments :
 //
 // On Entry :
 //    in0 = Address of native code to call
 //    in1 = New stack pointer
 //
 // Return Value:
 //
 // As per static calling conventions.
 //
 //--
 //---------------------------------------------------------------------------
 ;// void EbcAsmLLCALLEX (UINTN FunctionAddr, UINTN EbcStackPointer)
 PROCEDURE_ENTRY(EbcAsmLLCALLEX)
   NESTED_SETUP (2,6,8,0)

   // NESTED_SETUP uses loc0 and loc1 for context save

   //
   // Save a copy of the EBC VM stack pointer
   //
   mov r8 = in1;;

   //
   // Copy stack arguments from EBC stack into registers.
   // Assume worst case and copy 8.
   //
   ld8   out0 = [r8], 8;;
   ld8   out1 = [r8], 8;;
   ld8   out2 = [r8], 8;;
   ld8   out3 = [r8], 8;;
   ld8   out4 = [r8], 8;;
   ld8   out5 = [r8], 8;;
   ld8   out6 = [r8], 8;;
   ld8   out7 = [r8], 8;;

   //
   // Save the original stack pointer
   //
   mov   loc2 = r12;

   //
   // Save the gp
   //
   or    loc3 = r1, r0

   //
   // Set the new aligned stack pointer. Reserve space for the required
   // 16-bytes of scratch area as well.
   //
   add  r12 = 48, in1

   //
   // Now call the function. Load up the function address from the descriptor
   // pointed to by in0. Then get the gp from the descriptor at the following
   // address in the descriptor.
   //
   ld8   r31 = [in0], 8;;
   ld8   r30 = [in0];;
   mov   b1 = r31
   mov   r1 = r30
   (p0) br.call.dptk.many b0 = b1;;

   //
   // Restore the original stack pointer and gp
   //
   mov   r12 = loc2
   or    r1 = loc3, r0

   //
   // Now return
   //
   NESTED_RETURN

 PROCEDURE_EXIT(EbcAsmLLCALLEX)

 //-----------------------------------------------------------------------------
 //++
 // EbcLLCALLEXNative
 //
 //  This function is called to execute an EBC CALLEX instruction.
 //  This instruction requires that we thunk out to external native
 //  code. On return, we restore the stack pointer to its original location.
 //  Destroys no working registers.  For IPF, at least 8 register slots
 //  must be allocated on the stack frame to support any number of
 //  arguments beiung passed to the external native function.  The
 //  size of the stack frame is FramePtr - EbcSp.  If this size is less
 //  than 64-bytes, the amount of stack frame allocated is rounded up
 //  to 64-bytes
 //
 // Arguments On Entry :
 //    in0 = CallAddr     The function address.
 //    in1 = EbcSp        The new EBC stack pointer.
 //    in2 = FramePtr     The frame pointer.
 //
 // Return Value:
 //    None
 //
 // C Function Prototype:
 //    VOID
 //    EFIAPI
 //    EbcLLCALLEXNative (
 //      IN UINTN        CallAddr,
 //      IN UINTN        EbcSp,
 //      IN VOID         *FramePtr
 //      );
 //--
 //---------------------------------------------------------------------------

 PROCEDURE_ENTRY(EbcLLCALLEXNative)
   NESTED_SETUP (3,6,3,0)

   mov   loc2 = in2;;              // loc2 = in2 = FramePtr
   mov   loc3 = in1;;              // loc3 = in1 = EbcSp
   sub   loc2 = loc2, loc3;;       // loc2 = loc2 - loc3 = FramePtr - EbcSp
   mov   out2 = loc2;;             // out2 = loc2 = FramePtr - EbcSp
   mov   loc4 = 0x40;;             // loc4 = 0x40
   cmp.leu p6  = out2, loc4;;      // IF out2 < loc4 THEN P6=1 ELSE P6=0; IF (FramePtr - EbcSp) < 0x40 THEN P6 = 1 ELSE P6=0
   (p6) mov   loc2 = loc4;;        // IF P6==1 THEN loc2 = loc4 = 0x40
   mov   loc4 = r12;;              // save sp
   or    loc5 = r1, r0             // save gp

   sub   r12 = r12, loc2;;         // sp = sp - loc2 = sp - MAX (0x40, FramePtr - EbcSp)

   and   r12 = -0x10, r12          // Round sp down to the nearest 16-byte boundary
   mov   out1 = in1;;              // out1 = EbcSp
   mov   out0 = r12;;              // out0 = sp
   adds  r12 = -0x8, r12
   (p0) br.call.dptk.many b0 = CopyMem;;      // CopyMem (sp, EbcSp, (FramePtr - EbcSp))
   adds  r12 = 0x8, r12

   mov   out0 = in0;;              // out0 = CallAddr
   mov   out1 = r12;;              // out1 = sp
   (p0) br.call.dptk.many b0 = EbcAsmLLCALLEX;;    // EbcAsmLLCALLEX (CallAddr, sp)
   mov   r12 = loc4;;              // restore sp
   or    r1 = loc5, r0             // restore gp

   NESTED_RETURN
 PROCEDURE_EXIT(EbcLLCALLEXNative)


 //
 // UINTN EbcLLGetEbcEntryPoint(VOID)
 //
 // Description:
 //    Simply return, so that the caller retrieves the return register
 //    contents (R8). That's where the thunk-to-ebc code stuffed the
 //    EBC entry point.
 //
 PROCEDURE_ENTRY(EbcLLGetEbcEntryPoint)
     br.ret.sptk  b0 ;;
 PROCEDURE_EXIT(EbcLLGetEbcEntryPoint)
	///** @file
	//
	// Contains low level routines for the Virtual Machine implementation
	// on an Itanium-based platform.
	//
	// Copyright (c) 2006 - 2011, Intel Corporation. All rights reserved.<BR>
	// 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.
	//
	//**/

	.file "EbcLowLevel.s"

	#define PROCEDURE_ENTRY(name) .##text; \
	.##type name, @function; \
	.##proc name; \
	name::

	#define PROCEDURE_EXIT(name) .##endp name

	// Note: use of NESTED_SETUP requires number of locals (l) >= 3

	#define NESTED_SETUP(i,l,o,r) \
	alloc loc1=ar##.##pfs,i,l,o,r ;\
	mov loc0=b0

	#define NESTED_RETURN \
	mov b0=loc0 ;\
	mov ar##.##pfs=loc1 ;;\
	br##.##ret##.##dpnt b0;;

	.type CopyMem, @function;

	//-----------------------------------------------------------------------------
	//++
	// EbcAsmLLCALLEX
	//
	// Implements the low level EBC CALLEX instruction. Sets up the
	// stack pointer, does the spill of function arguments, and
	// calls the native function. On return it restores the original
	// stack pointer and returns to the caller.
	//
	// Arguments :
	//
	// On Entry :
	// in0 = Address of native code to call
	// in1 = New stack pointer
	//
	// Return Value:
	//
	// As per static calling conventions.
	//
	//--
	//---------------------------------------------------------------------------
	;// void EbcAsmLLCALLEX (UINTN FunctionAddr, UINTN EbcStackPointer)
	PROCEDURE_ENTRY(EbcAsmLLCALLEX)
	NESTED_SETUP (2,6,8,0)

	// NESTED_SETUP uses loc0 and loc1 for context save

	//
	// Save a copy of the EBC VM stack pointer
	//
	mov r8 = in1;;

	//
	// Copy stack arguments from EBC stack into registers.
	// Assume worst case and copy 8.
	//
	ld8 out0 = [r8], 8;;
	ld8 out1 = [r8], 8;;
	ld8 out2 = [r8], 8;;
	ld8 out3 = [r8], 8;;
	ld8 out4 = [r8], 8;;
	ld8 out5 = [r8], 8;;
	ld8 out6 = [r8], 8;;
	ld8 out7 = [r8], 8;;

	//
	// Save the original stack pointer
	//
	mov loc2 = r12;

	//
	// Save the gp
	//
	or loc3 = r1, r0

	//
	// Set the new aligned stack pointer. Reserve space for the required
	// 16-bytes of scratch area as well.
	//
	add r12 = 48, in1

	//
	// Now call the function. Load up the function address from the descriptor
	// pointed to by in0. Then get the gp from the descriptor at the following
	// address in the descriptor.
	//
	ld8 r31 = [in0], 8;;
	ld8 r30 = [in0];;
	mov b1 = r31
	mov r1 = r30
	(p0) br.call.dptk.many b0 = b1;;

	//
	// Restore the original stack pointer and gp
	//
	mov r12 = loc2
	or r1 = loc3, r0

	//
	// Now return
	//
	NESTED_RETURN

	PROCEDURE_EXIT(EbcAsmLLCALLEX)

	//-----------------------------------------------------------------------------
	//++
	// EbcLLCALLEXNative
	//
	// This function is called to execute an EBC CALLEX instruction.
	// This instruction requires that we thunk out to external native
	// code. On return, we restore the stack pointer to its original location.
	// Destroys no working registers. For IPF, at least 8 register slots
	// must be allocated on the stack frame to support any number of
	// arguments beiung passed to the external native function. The
	// size of the stack frame is FramePtr - EbcSp. If this size is less
	// than 64-bytes, the amount of stack frame allocated is rounded up
	// to 64-bytes
	//
	// Arguments On Entry :
	// in0 = CallAddr The function address.
	// in1 = EbcSp The new EBC stack pointer.
	// in2 = FramePtr The frame pointer.
	//
	// Return Value:
	// None
	//
	// C Function Prototype:
	// VOID
	// EFIAPI
	// EbcLLCALLEXNative (
	// IN UINTN CallAddr,
	// IN UINTN EbcSp,
	// IN VOID *FramePtr
	// );
	//--
	//---------------------------------------------------------------------------

	PROCEDURE_ENTRY(EbcLLCALLEXNative)
	NESTED_SETUP (3,6,3,0)

	mov loc2 = in2;; // loc2 = in2 = FramePtr
	mov loc3 = in1;; // loc3 = in1 = EbcSp
	sub loc2 = loc2, loc3;; // loc2 = loc2 - loc3 = FramePtr - EbcSp
	mov out2 = loc2;; // out2 = loc2 = FramePtr - EbcSp
	mov loc4 = 0x40;; // loc4 = 0x40
	cmp.leu p6 = out2, loc4;; // IF out2 < loc4 THEN P6=1 ELSE P6=0; IF (FramePtr - EbcSp) < 0x40 THEN P6 = 1 ELSE P6=0
	(p6) mov loc2 = loc4;; // IF P6==1 THEN loc2 = loc4 = 0x40
	mov loc4 = r12;; // save sp
	or loc5 = r1, r0 // save gp

	sub r12 = r12, loc2;; // sp = sp - loc2 = sp - MAX (0x40, FramePtr - EbcSp)

	and r12 = -0x10, r12 // Round sp down to the nearest 16-byte boundary
	mov out1 = in1;; // out1 = EbcSp
	mov out0 = r12;; // out0 = sp
	adds r12 = -0x8, r12
	(p0) br.call.dptk.many b0 = CopyMem;; // CopyMem (sp, EbcSp, (FramePtr - EbcSp))
	adds r12 = 0x8, r12

	mov out0 = in0;; // out0 = CallAddr
	mov out1 = r12;; // out1 = sp
	(p0) br.call.dptk.many b0 = EbcAsmLLCALLEX;; // EbcAsmLLCALLEX (CallAddr, sp)
	mov r12 = loc4;; // restore sp
	or r1 = loc5, r0 // restore gp

	NESTED_RETURN
	PROCEDURE_EXIT(EbcLLCALLEXNative)


	//
	// UINTN EbcLLGetEbcEntryPoint(VOID)
	//
	// Description:
	// Simply return, so that the caller retrieves the return register
	// contents (R8). That's where the thunk-to-ebc code stuffed the
	// EBC entry point.
	//
	PROCEDURE_ENTRY(EbcLLGetEbcEntryPoint)
	br.ret.sptk b0 ;;
	PROCEDURE_EXIT(EbcLLGetEbcEntryPoint)