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382 lines
10 KiB
382 lines
10 KiB
/*++
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Copyright (c) 1996 Microsoft Corporation
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Module Name:
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compile.c
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Abstract:
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This module contains code to put the fragments into the translation
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cache.
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Author:
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Dave Hastings (daveh) creation-date 27-Jun-1995
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Revision History:
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Dave Hastings (daveh) 16-Jan-1996
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Move operand handling into fragment library
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Notes:
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We don't yet have any code to handle processor errata
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--*/
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#include <nt.h>
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#include <ntrtl.h>
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#include <nturtl.h>
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#include <windows.h>
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#define _WX86CPUAPI_
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#include <wx86.h>
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#include <wx86nt.h>
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#include <wx86cpu.h>
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#include <cpuassrt.h>
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#include <config.h>
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#include <instr.h>
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#include <threadst.h>
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#include <frag.h>
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#include <analysis.h>
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#include <entrypt.h>
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#include <compilep.h>
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#include <compiler.h>
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#include <tc.h>
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#include <mrsw.h>
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#include <stdio.h>
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#include <stdlib.h>
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ASSERTNAME;
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#if _ALPHA_
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#define MAX_RISC_COUNT 32768
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#else
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#define MAX_RISC_COUNT 16384
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#endif
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DWORD TranslationCacheFlags; // indicates what kind of code is in the TC
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#ifdef CODEGEN_PROFILE
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DWORD EPSequence;
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#endif
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//
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// This is guaranteed only to be accessed by a single thread at a time.
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//
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INSTRUCTION InstructionStream[MAX_INSTR_COUNT];
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ULONG NumberOfInstructions;
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PENTRYPOINT
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CreateEntryPoints(
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PENTRYPOINT ContainingEntrypoint,
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PBYTE EntryPointMemory
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)
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/*++
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Routine Description:
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This function takes the InstructionStream and creates entrypoints
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from the information computed by LocateEntrypoints().
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Entrypoints are then added into the Red/Black tree.
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Arguments:
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ContainingEntrypoint -- entrypoint which describes this range of intel
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code already
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EntryPointMemory -- pre-allocated Entrypoint memory
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Return Value:
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The Entry Point corresponding to the first instruction
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--*/
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{
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ULONG i, j, intelDest;
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PEPNODE EP;
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PENTRYPOINT EntryPoint;
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PENTRYPOINT PrevEntryPoint;
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#ifdef CODEGEN_PROFILE
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ULONG CreateTime;
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CreateTime = GetCurrentTime();
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EPSequence++;
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#endif
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//
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// Performance is O(n) always.
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//
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i=0;
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PrevEntryPoint = InstructionStream[0].EntryPoint;
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while (i<NumberOfInstructions) {
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//
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// This loop skips from entrypoint to entrypoint.
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//
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CPUASSERT(i == 0 || InstructionStream[i-1].EntryPoint != PrevEntryPoint);
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//
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// Get an entrypoint node from the EntryPointMemory allocated by
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// our caller.
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//
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if (ContainingEntrypoint) {
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EntryPoint = (PENTRYPOINT)EntryPointMemory;
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EntryPointMemory+=sizeof(ENTRYPOINT);
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} else {
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EP = (PEPNODE)EntryPointMemory;
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EntryPoint = &EP->ep;
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EntryPointMemory+=sizeof(EPNODE);
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}
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//
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// Find the next entrypoint and the RISC address of the next
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// instruction which begins an entrypoint. Each instruction
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// in that range contains a pointer to the containing Entrypoint.
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//
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for (j=i+1; j<NumberOfInstructions; ++j) {
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if (InstructionStream[j].EntryPoint != PrevEntryPoint) {
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PrevEntryPoint = InstructionStream[j].EntryPoint;
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break;
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}
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InstructionStream[j].EntryPoint = EntryPoint;
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}
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//
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// Fill in the Entrypoint structure
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//
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#ifdef CODEGEN_PROFILE
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EntryPoint->SequenceNumber = EPSequence;
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EntryPoint->CreationTime = CreateTime;
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#endif
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EntryPoint->intelStart = (PVOID)InstructionStream[i].IntelAddress;
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if (j < NumberOfInstructions) {
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EntryPoint->intelEnd = (PVOID)(InstructionStream[j].IntelAddress-1);
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} else {
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ULONG Prev;
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for (Prev=j-1; InstructionStream[Prev].Size == 0; Prev--)
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;
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EntryPoint->intelEnd = (PVOID)(InstructionStream[Prev].IntelAddress +
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InstructionStream[Prev].Size - 1);
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}
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InstructionStream[i].EntryPoint = EntryPoint;
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if (ContainingEntrypoint) {
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//
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// Link this sub-entrypoint into the containing entrypoint
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//
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EntryPoint->SubEP = ContainingEntrypoint->SubEP;
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ContainingEntrypoint->SubEP = EntryPoint;
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} else {
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INT RetVal;
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//
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// Insert it into the EP tree
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//
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EntryPoint->SubEP = NULL;
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RetVal = insertEntryPoint(EP);
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CPUASSERT(RetVal==1);
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}
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//
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// Advance to the next instruction which contains an
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// Entrypoint.
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//
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i=j;
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}
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if (ContainingEntrypoint) {
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// Indicate that the Entrypoints are present
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EntrypointTimestamp++;
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}
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return InstructionStream[0].EntryPoint;
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}
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PENTRYPOINT
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Compile(
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PENTRYPOINT ContainingEntrypoint,
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PVOID Eip
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)
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/*++
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Routine Description:
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This function puts together code fragments to execute the Intel
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code stream at Eip. It gets a stream of pre-decoded instructions
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from the code analysis module.
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Arguments:
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ContaingingEntrypoint -- If NULL, there is no entrypoint which already
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describes the Intel address to be compiled.
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Otherwise, this entrypoint describes the
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Intel address. The caller ensures that the
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Entrypoint->intelStart != Eip.
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Eip -- Supplies the location to compile from
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Return Value:
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pointer to the entrypoint for the compiled code
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--*/
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{
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ULONG NativeSize, InstructionSize, IntelSize, OperationSize;
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PCHAR CodeLocation, CurrentCodeLocation;
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ULONG i;
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PENTRYPOINT Entrypoint;
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INT RetVal;
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PVOID StopEip;
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DWORD cEntryPoints;
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PBYTE EntryPointMemory;
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DWORD EPSize;
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#if defined(_ALPHA_)
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ULONG ECUSize, ECUOffset;
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#endif
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#if DBG
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DWORD OldEPTimestamp;
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#endif
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DECLARE_CPU;
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if (ContainingEntrypoint) {
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//
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// See if the entrypoint exactly describes the x86 address
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//
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if (ContainingEntrypoint->intelStart == Eip) {
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return ContainingEntrypoint;
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}
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//
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// No need to compile past the end of the current entrypoint
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//
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StopEip = ContainingEntrypoint->intelEnd;
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//
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// Assert that the ContainingEntrypoint is actually an EPNODE.
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//
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CPUASSERTMSG( ((PEPNODE)ContainingEntrypoint)->intelColor == RED ||
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((PEPNODE)ContainingEntrypoint)->intelColor == BLACK,
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"ContainingEntrypoint is not an EPNODE!");
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} else {
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//
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// Find out if there is a compiled block following this one
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//
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Entrypoint = GetNextEPFromIntelAddr(Eip);
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if (Entrypoint == NULL) {
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StopEip = (PVOID)0xffffffff;
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} else {
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StopEip = Entrypoint->intelStart;
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}
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}
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//
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// Get the stream of instructions to compile.
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// If the Trap Flag is set, then compile only one instruction
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//
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if (cpu->flag_tf) {
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NumberOfInstructions = 1;
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} else {
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NumberOfInstructions = CpuInstructionLookahead;
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}
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cEntryPoints = GetInstructionStream(InstructionStream,
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&NumberOfInstructions,
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Eip,
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StopEip
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);
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//
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// Pre-allocate enough space from the Translation Cache to store
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// the compiled code.
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//
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CodeLocation = AllocateTranslationCache(MAX_RISC_COUNT);
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//
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// Allocate memory for all of the Entrypoints. This must be done
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// after the Translation Cache allocation, in case that allocation
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// caused a cache flush.
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//
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if (ContainingEntrypoint) {
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EPSize = cEntryPoints * sizeof(ENTRYPOINT);
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} else {
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EPSize = cEntryPoints * sizeof(EPNODE);
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}
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EntryPointMemory = (PBYTE)EPAlloc(EPSize);
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if (!EntryPointMemory) {
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//
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// Either failed to commit extra pages of memory to grow Entrypoint
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// memory, or there are so many entrypoints that the the reserved
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// size has been exceeded. Flush the Translation Cache, which will
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// free up memory, then try the allocation again.
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//
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FlushTranslationCache(0, 0xffffffff);
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EntryPointMemory = (PBYTE)EPAlloc(EPSize);
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if (!EntryPointMemory) {
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//
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// We've tried our hardest, but there simply isn't any
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// memory available. Time to give up.
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//
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RtlRaiseStatus(STATUS_NO_MEMORY);
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}
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//
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// Now that the cache has been flushed, CodeLocation is invalid.
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// re-allocate from the Translation Cache. We know that
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// the cache was just flushed, so it is impossible for the cache
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// to flush again, which would invalidate EntryPointMemory.
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//
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#if DBG
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OldEPTimestamp = EntrypointTimestamp;
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#endif
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CodeLocation = AllocateTranslationCache(MAX_RISC_COUNT);
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CPUASSERTMSG(EntrypointTimestamp == OldEPTimestamp,
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"Unexpected Translation Cache flush!");
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}
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//
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// Fill in the IntelStart, IntelEnd, and update
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// InstructionStream[]->EntryPoint
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//
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CreateEntryPoints(ContainingEntrypoint, EntryPointMemory);
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//
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// Generate RISC code from the x86 code
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//
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NativeSize = PlaceInstructions(CodeLocation, cEntryPoints);
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//
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// Give back the unused part of the Translation Cache
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//
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FreeUnusedTranslationCache(CodeLocation + NativeSize);
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//
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// Flush the information to the instruction cache
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//
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NtFlushInstructionCache(NtCurrentProcess(), CodeLocation, NativeSize);
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//
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// Update the flags indicating what kind of code is in the TC
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//
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TranslationCacheFlags |= CompilerFlags;
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return (PENTRYPOINT)EntryPointMemory;
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}
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