Greg Clayton 32e0a7509c Many improvements to the Platform base class and subclasses. The base Platform
class now implements the Host functionality for a lot of things that make 
sense by default so that subclasses can check:

int
PlatformSubclass::Foo ()
{
    if (IsHost())
        return Platform::Foo (); // Let the platform base class do the host specific stuff
    
    // Platform subclass specific code...
    int result = ...
    return result;
}

Added new functions to the platform:

    virtual const char *Platform::GetUserName (uint32_t uid);
    virtual const char *Platform::GetGroupName (uint32_t gid);

The user and group names are cached locally so that remote platforms can avoid
sending packets multiple times to resolve this information.

Added the parent process ID to the ProcessInfo class. 

Added a new ProcessInfoMatch class which helps us to match processes up
and changed the Host layer over to using this new class. The new class allows
us to search for processs:
1 - by name (equal to, starts with, ends with, contains, and regex)
2 - by pid
3 - And further check for parent pid == value, uid == value, gid == value, 
    euid == value, egid == value, arch == value, parent == value.
    
This is all hookup up to the "platform process list" command which required
adding dumping routines to dump process information. If the Host class 
implements the process lookup routines, you can now lists processes on 
your local machine:

machine1.foo.com % lldb
(lldb) platform process list 
PID    PARENT USER       GROUP      EFF USER   EFF GROUP  TRIPLE                   NAME
====== ====== ========== ========== ========== ========== ======================== ============================
99538  1      username   usergroup  username   usergroup  x86_64-apple-darwin      FileMerge
94943  1      username   usergroup  username   usergroup  x86_64-apple-darwin      mdworker
94852  244    username   usergroup  username   usergroup  x86_64-apple-darwin      Safari
94727  244    username   usergroup  username   usergroup  x86_64-apple-darwin      Xcode
92742  92710  username   usergroup  username   usergroup  i386-apple-darwin        debugserver


This of course also works remotely with the lldb-platform:

machine1.foo.com % lldb-platform --listen 1234

machine2.foo.com % lldb
(lldb) platform create remote-macosx
  Platform: remote-macosx
 Connected: no
(lldb) platform connect connect://localhost:1444
  Platform: remote-macosx
    Triple: x86_64-apple-darwin
OS Version: 10.6.7 (10J869)
    Kernel: Darwin Kernel Version 10.7.0: Sat Jan 29 15:17:16 PST 2011; root:xnu-1504.9.37~1/RELEASE_I386
  Hostname: machine1.foo.com
 Connected: yes
(lldb) platform process list 
PID    PARENT USER       GROUP      EFF USER   EFF GROUP  TRIPLE                   NAME
====== ====== ========== ========== ========== ========== ======================== ============================
99556  244    username   usergroup  username   usergroup  x86_64-apple-darwin      trustevaluation
99548  65539  username   usergroup  username   usergroup  x86_64-apple-darwin      lldb
99538  1      username   usergroup  username   usergroup  x86_64-apple-darwin      FileMerge
94943  1      username   usergroup  username   usergroup  x86_64-apple-darwin      mdworker
94852  244    username   usergroup  username   usergroup  x86_64-apple-darwin      Safari

The lldb-platform implements everything with the Host:: layer, so this should
"just work" for linux. I will probably be adding more stuff to the Host layer
for launching processes and attaching to processes so that this support should
eventually just work as well.

Modified the target to be able to be created with an architecture that differs
from the main executable. This is needed for iOS debugging since we can have
an "armv6" binary which can run on an "armv7" machine, so we want to be able
to do:

% lldb
(lldb) platform create remote-ios
(lldb) file --arch armv7 a.out

Where "a.out" is an armv6 executable. The platform then can correctly decide
to open all "armv7" images for all dependent shared libraries.

Modified the disassembly to show the current PC value. Example output:

(lldb) disassemble --frame
a.out`main:
   0x1eb7:  pushl  %ebp
   0x1eb8:  movl   %esp, %ebp
   0x1eba:  pushl  %ebx
   0x1ebb:  subl   $20, %esp
   0x1ebe:  calll  0x1ec3                   ; main + 12 at test.c:18
   0x1ec3:  popl   %ebx
-> 0x1ec4:  calll  0x1f12                   ; getpid
   0x1ec9:  movl   %eax, 4(%esp)
   0x1ecd:  leal   199(%ebx), %eax
   0x1ed3:  movl   %eax, (%esp)
   0x1ed6:  calll  0x1f18                   ; printf
   0x1edb:  leal   213(%ebx), %eax
   0x1ee1:  movl   %eax, (%esp)
   0x1ee4:  calll  0x1f1e                   ; puts
   0x1ee9:  calll  0x1f0c                   ; getchar
   0x1eee:  movl   $20, (%esp)
   0x1ef5:  calll  0x1e6a                   ; sleep_loop at test.c:6
   0x1efa:  movl   $12, %eax
   0x1eff:  addl   $20, %esp
   0x1f02:  popl   %ebx
   0x1f03:  leave
   0x1f04:  ret
   
This can be handy when dealing with the new --line options that was recently
added:

(lldb) disassemble --line
a.out`main + 13 at test.c:19
   18  	{
-> 19  		printf("Process: %i\n\n", getpid());
   20  	    puts("Press any key to continue..."); getchar();
-> 0x1ec4:  calll  0x1f12                   ; getpid
   0x1ec9:  movl   %eax, 4(%esp)
   0x1ecd:  leal   199(%ebx), %eax
   0x1ed3:  movl   %eax, (%esp)
   0x1ed6:  calll  0x1f18                   ; printf

Modified the ModuleList to have a lookup based solely on a UUID. Since the
UUID is typically the MD5 checksum of a binary image, there is no need
to give the path and architecture when searching for a pre-existing
image in an image list.

Now that we support remote debugging a bit better, our lldb_private::Module
needs to be able to track what the original path for file was as the platform
knows it, as well as where the file is locally. The module has the two 
following functions to retrieve both paths:

const FileSpec &Module::GetFileSpec () const;
const FileSpec &Module::GetPlatformFileSpec () const;

llvm-svn: 128563
2011-03-30 18:16:51 +00:00

242 lines
8.6 KiB
C++

//===-- DNBArchImpl.h -------------------------------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// Created by Greg Clayton on 6/25/07.
//
//===----------------------------------------------------------------------===//
#ifndef __DebugNubArchMachARM_h__
#define __DebugNubArchMachARM_h__
#if defined (__arm__)
#include "DNBArch.h"
#include <ARMDisassembler/ARMDisassembler.h>
class MachThread;
class DNBArchMachARM : public DNBArchProtocol
{
public:
enum { kMaxNumThumbITBreakpoints = 4 };
DNBArchMachARM(MachThread *thread) :
m_thread(thread),
m_state(),
m_hw_single_chained_step_addr(INVALID_NUB_ADDRESS),
m_sw_single_step_next_pc(INVALID_NUB_ADDRESS),
m_sw_single_step_break_id(INVALID_NUB_BREAK_ID),
m_sw_single_step_itblock_break_count(0),
m_last_decode_pc(INVALID_NUB_ADDRESS)
{
memset(&m_dbg_save, 0, sizeof(m_dbg_save));
ThumbStaticsInit(&m_last_decode_thumb);
for (int i = 0; i < kMaxNumThumbITBreakpoints; i++)
m_sw_single_step_itblock_break_id[i] = INVALID_NUB_BREAK_ID;
}
virtual ~DNBArchMachARM()
{
}
static void Initialize();
static const DNBRegisterSetInfo *
GetRegisterSetInfo(nub_size_t *num_reg_sets);
virtual bool GetRegisterValue(int set, int reg, DNBRegisterValue *value);
virtual bool SetRegisterValue(int set, int reg, const DNBRegisterValue *value);
virtual nub_size_t GetRegisterContext (void *buf, nub_size_t buf_len);
virtual nub_size_t SetRegisterContext (const void *buf, nub_size_t buf_len);
virtual kern_return_t GetRegisterState (int set, bool force);
virtual kern_return_t SetRegisterState (int set);
virtual bool RegisterSetStateIsValid (int set) const;
virtual uint64_t GetPC(uint64_t failValue); // Get program counter
virtual kern_return_t SetPC(uint64_t value);
virtual uint64_t GetSP(uint64_t failValue); // Get stack pointer
virtual void ThreadWillResume();
virtual bool ThreadDidStop();
static DNBArchProtocol *Create (MachThread *thread);
static const uint8_t * const SoftwareBreakpointOpcode (nub_size_t byte_size);
static uint32_t GetCPUType();
virtual uint32_t NumSupportedHardwareBreakpoints();
virtual uint32_t NumSupportedHardwareWatchpoints();
virtual uint32_t EnableHardwareBreakpoint (nub_addr_t addr, nub_size_t size);
virtual uint32_t EnableHardwareWatchpoint (nub_addr_t addr, nub_size_t size, bool read, bool write);
virtual bool DisableHardwareBreakpoint (uint32_t hw_break_index);
virtual bool DisableHardwareWatchpoint (uint32_t hw_break_index);
virtual bool StepNotComplete ();
protected:
kern_return_t EnableHardwareSingleStep (bool enable);
kern_return_t SetSingleStepSoftwareBreakpoints ();
bool ConditionPassed(uint8_t condition, uint32_t cpsr);
bool ComputeNextPC(nub_addr_t currentPC, arm_decoded_instruction_t decodedInstruction, bool currentPCIsThumb, nub_addr_t *targetPC);
void EvaluateNextInstructionForSoftwareBreakpointSetup(nub_addr_t currentPC, uint32_t cpsr, bool currentPCIsThumb, nub_addr_t *nextPC, bool *nextPCIsThumb);
void DecodeITBlockInstructions(nub_addr_t curr_pc);
arm_error_t DecodeInstructionUsingDisassembler(nub_addr_t curr_pc, uint32_t curr_cpsr, arm_decoded_instruction_t *decodedInstruction, thumb_static_data_t *thumbStaticData, nub_addr_t *next_pc);
static nub_bool_t BreakpointHit (nub_process_t pid, nub_thread_t tid, nub_break_t breakID, void *baton);
typedef enum RegisterSetTag
{
e_regSetALL = REGISTER_SET_ALL,
e_regSetGPR = ARM_THREAD_STATE,
e_regSetVFP = ARM_VFP_STATE,
e_regSetEXC = ARM_EXCEPTION_STATE,
e_regSetDBG = ARM_DEBUG_STATE,
kNumRegisterSets
} RegisterSet;
enum
{
Read = 0,
Write = 1,
kNumErrors = 2
};
typedef arm_thread_state_t GPR;
typedef arm_vfp_state_t FPU;
typedef arm_exception_state_t EXC;
static const DNBRegisterInfo g_gpr_registers[];
static const DNBRegisterInfo g_vfp_registers[];
static const DNBRegisterInfo g_exc_registers[];
static const DNBRegisterSetInfo g_reg_sets[];
static const size_t k_num_gpr_registers;
static const size_t k_num_vfp_registers;
static const size_t k_num_exc_registers;
static const size_t k_num_all_registers;
static const size_t k_num_register_sets;
struct Context
{
GPR gpr;
FPU vfp;
EXC exc;
};
struct State
{
Context context;
arm_debug_state_t dbg;
kern_return_t gpr_errs[2]; // Read/Write errors
kern_return_t vfp_errs[2]; // Read/Write errors
kern_return_t exc_errs[2]; // Read/Write errors
kern_return_t dbg_errs[2]; // Read/Write errors
State()
{
uint32_t i;
for (i=0; i<kNumErrors; i++)
{
gpr_errs[i] = -1;
vfp_errs[i] = -1;
exc_errs[i] = -1;
dbg_errs[i] = -1;
}
}
void InvalidateRegisterSetState(int set)
{
SetError (set, Read, -1);
}
kern_return_t GetError (int set, uint32_t err_idx) const
{
if (err_idx < kNumErrors)
{
switch (set)
{
// When getting all errors, just OR all values together to see if
// we got any kind of error.
case e_regSetALL: return gpr_errs[err_idx] |
vfp_errs[err_idx] |
exc_errs[err_idx] |
dbg_errs[err_idx] ;
case e_regSetGPR: return gpr_errs[err_idx];
case e_regSetVFP: return vfp_errs[err_idx];
case e_regSetEXC: return exc_errs[err_idx];
case e_regSetDBG: return dbg_errs[err_idx];
default: break;
}
}
return -1;
}
bool SetError (int set, uint32_t err_idx, kern_return_t err)
{
if (err_idx < kNumErrors)
{
switch (set)
{
case e_regSetALL:
gpr_errs[err_idx] = err;
vfp_errs[err_idx] = err;
dbg_errs[err_idx] = err;
exc_errs[err_idx] = err;
return true;
case e_regSetGPR:
gpr_errs[err_idx] = err;
return true;
case e_regSetVFP:
vfp_errs[err_idx] = err;
return true;
case e_regSetEXC:
exc_errs[err_idx] = err;
return true;
case e_regSetDBG:
dbg_errs[err_idx] = err;
return true;
default: break;
}
}
return false;
}
bool RegsAreValid (int set) const
{
return GetError(set, Read) == KERN_SUCCESS;
}
};
kern_return_t GetGPRState (bool force);
kern_return_t GetVFPState (bool force);
kern_return_t GetEXCState (bool force);
kern_return_t GetDBGState (bool force);
kern_return_t SetGPRState ();
kern_return_t SetVFPState ();
kern_return_t SetEXCState ();
kern_return_t SetDBGState ();
protected:
MachThread * m_thread;
State m_state;
arm_debug_state_t m_dbg_save;
nub_addr_t m_hw_single_chained_step_addr;
// Software single stepping support
nub_addr_t m_sw_single_step_next_pc;
nub_break_t m_sw_single_step_break_id;
nub_break_t m_sw_single_step_itblock_break_id[kMaxNumThumbITBreakpoints];
nub_addr_t m_sw_single_step_itblock_break_count;
// Disassembler state
thumb_static_data_t m_last_decode_thumb;
arm_decoded_instruction_t m_last_decode_arm;
nub_addr_t m_last_decode_pc;
};
#endif // #if defined (__arm__)
#endif // #ifndef __DebugNubArchMachARM_h__