path: root/lib/Support/Windows/Process.inc

//===- Win32/Process.cpp - Win32 Process Implementation ------- -*- C++ -*-===//
//
//                     The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file provides the Win32 specific implementation of the Process class.
//
//===----------------------------------------------------------------------===//

#include "llvm/Support/Allocator.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/WindowsError.h"
#include <malloc.h>

// The Windows.h header must be after LLVM and standard headers.
#include "WindowsSupport.h"

#include <direct.h>
#include <io.h>
#include <psapi.h>
#include <shellapi.h>

#ifdef __MINGW32__
 #if (HAVE_LIBPSAPI != 1)
  #error "libpsapi.a should be present"
 #endif
 #if (HAVE_LIBSHELL32 != 1)
  #error "libshell32.a should be present"
 #endif
#else
 #pragma comment(lib, "psapi.lib")
 #pragma comment(lib, "shell32.lib")
#endif

//===----------------------------------------------------------------------===//
//=== WARNING: Implementation here must contain only Win32 specific code
//===          and must not be UNIX code
//===----------------------------------------------------------------------===//

#ifdef __MINGW32__
// This ban should be lifted when MinGW 1.0+ has defined this value.
#  define _HEAPOK (-2)
#endif

using namespace llvm;
using namespace sys;


process::id_type self_process::get_id() {
  return GetCurrentProcessId();
}

static TimeValue getTimeValueFromFILETIME(FILETIME Time) {
  ULARGE_INTEGER TimeInteger;
  TimeInteger.LowPart = Time.dwLowDateTime;
  TimeInteger.HighPart = Time.dwHighDateTime;

  // FILETIME's are # of 100 nanosecond ticks (1/10th of a microsecond)
  return TimeValue(
      static_cast<TimeValue::SecondsType>(TimeInteger.QuadPart / 10000000),
      static_cast<TimeValue::NanoSecondsType>(
          (TimeInteger.QuadPart % 10000000) * 100));
}

TimeValue self_process::get_user_time() const {
  FILETIME ProcCreate, ProcExit, KernelTime, UserTime;
  if (GetProcessTimes(GetCurrentProcess(), &ProcCreate, &ProcExit, &KernelTime,
                      &UserTime) == 0)
    return TimeValue();

  return getTimeValueFromFILETIME(UserTime);
}

TimeValue self_process::get_system_time() const {
  FILETIME ProcCreate, ProcExit, KernelTime, UserTime;
  if (GetProcessTimes(GetCurrentProcess(), &ProcCreate, &ProcExit, &KernelTime,
                      &UserTime) == 0)
    return TimeValue();

  return getTimeValueFromFILETIME(KernelTime);
}

// This function retrieves the page size using GetNativeSystemInfo() and is
// present solely so it can be called once to initialize the self_process member
// below.
static unsigned getPageSize() {
  // GetNativeSystemInfo() provides the physical page size which may differ
  // from GetSystemInfo() in 32-bit applications running under WOW64.
  SYSTEM_INFO info;
  GetNativeSystemInfo(&info);
  // FIXME: FileOffset in MapViewOfFile() should be aligned to not dwPageSize,
  // but dwAllocationGranularity.
  return static_cast<unsigned>(info.dwPageSize);
}

// This constructor guaranteed to be run exactly once on a single thread, and
// sets up various process invariants that can be queried cheaply from then on.
self_process::self_process() : PageSize(getPageSize()) {
}


size_t
Process::GetMallocUsage()
{
  _HEAPINFO hinfo;
  hinfo._pentry = NULL;

  size_t size = 0;

  while (_heapwalk(&hinfo) == _HEAPOK)
    size += hinfo._size;

  return size;
}

void Process::GetTimeUsage(TimeValue &elapsed, TimeValue &user_time,
                           TimeValue &sys_time) {
  elapsed = TimeValue::now();

  FILETIME ProcCreate, ProcExit, KernelTime, UserTime;
  if (GetProcessTimes(GetCurrentProcess(), &ProcCreate, &ProcExit, &KernelTime,
                      &UserTime) == 0)
    return;

  user_time = getTimeValueFromFILETIME(UserTime);
  sys_time = getTimeValueFromFILETIME(KernelTime);
}

// Some LLVM programs such as bugpoint produce core files as a normal part of
// their operation. To prevent the disk from filling up, this configuration
// item does what's necessary to prevent their generation.
void Process::PreventCoreFiles() {
  // Windows does have the concept of core files, called minidumps.  However,
  // disabling minidumps for a particular application extends past the lifetime
  // of that application, which is the incorrect behavior for this API.
  // Additionally, the APIs require elevated privileges to disable and re-
  // enable minidumps, which makes this untenable. For more information, see
  // WerAddExcludedApplication and WerRemoveExcludedApplication (Vista and
  // later).
  //
  // Windows also has modal pop-up message boxes.  As this method is used by
  // bugpoint, preventing these pop-ups is additionally important.
  SetErrorMode(SEM_FAILCRITICALERRORS |
               SEM_NOGPFAULTERRORBOX |
               SEM_NOOPENFILEERRORBOX);
}

/// Returns the environment variable \arg Name's value as a string encoded in
/// UTF-8. \arg Name is assumed to be in UTF-8 encoding.
Optional<std::string> Process::GetEnv(StringRef Name) {
  // Convert the argument to UTF-16 to pass it to _wgetenv().
  SmallVector<wchar_t, 128> NameUTF16;
  if (windows::UTF8ToUTF16(Name, NameUTF16))
    return None;

  // Environment variable can be encoded in non-UTF8 encoding, and there's no
  // way to know what the encoding is. The only reliable way to look up
  // multibyte environment variable is to use GetEnvironmentVariableW().
  SmallVector<wchar_t, MAX_PATH> Buf;
  size_t Size = MAX_PATH;
  do {
    Buf.reserve(Size);
    Size =
        GetEnvironmentVariableW(NameUTF16.data(), Buf.data(), Buf.capacity());
    if (Size == 0)
      return None;

    // Try again with larger buffer.
  } while (Size > Buf.capacity());
  Buf.set_size(Size);

  // Convert the result from UTF-16 to UTF-8.
  SmallVector<char, MAX_PATH> Res;
  if (windows::UTF16ToUTF8(Buf.data(), Size, Res))
    return None;
  return std::string(Res.data());
}

static error_code windows_error(DWORD E) {
  return mapWindowsError(E);
}

error_code
Process::GetArgumentVector(SmallVectorImpl<const char *> &Args,
                           ArrayRef<const char *>,
                           SpecificBumpPtrAllocator<char> &ArgAllocator) {
  int NewArgCount;
  error_code ec;

  wchar_t **UnicodeCommandLine = CommandLineToArgvW(GetCommandLineW(),
                                                    &NewArgCount);
  if (!UnicodeCommandLine)
    return windows_error(::GetLastError());

  Args.reserve(NewArgCount);

  for (int i = 0; i < NewArgCount; ++i) {
    SmallVector<char, MAX_PATH> NewArgString;
    ec = windows::UTF16ToUTF8(UnicodeCommandLine[i],
                              wcslen(UnicodeCommandLine[i]),
                              NewArgString);
    if (ec)
      break;

    char *Buffer = ArgAllocator.Allocate(NewArgString.size() + 1);
    ::memcpy(Buffer, NewArgString.data(), NewArgString.size() + 1);
    Args.push_back(Buffer);
  }
  LocalFree(UnicodeCommandLine);
  if (ec)
    return ec;

  return error_code();
}

bool Process::StandardInIsUserInput() {
  return FileDescriptorIsDisplayed(0);
}

bool Process::StandardOutIsDisplayed() {
  return FileDescriptorIsDisplayed(1);
}

bool Process::StandardErrIsDisplayed() {
  return FileDescriptorIsDisplayed(2);
}

bool Process::FileDescriptorIsDisplayed(int fd) {
  DWORD Mode;  // Unused
  return (GetConsoleMode((HANDLE)_get_osfhandle(fd), &Mode) != 0);
}

unsigned Process::StandardOutColumns() {
  unsigned Columns = 0;
  CONSOLE_SCREEN_BUFFER_INFO csbi;
  if (GetConsoleScreenBufferInfo(GetStdHandle(STD_OUTPUT_HANDLE), &csbi))
    Columns = csbi.dwSize.X;
  return Columns;
}

unsigned Process::StandardErrColumns() {
  unsigned Columns = 0;
  CONSOLE_SCREEN_BUFFER_INFO csbi;
  if (GetConsoleScreenBufferInfo(GetStdHandle(STD_ERROR_HANDLE), &csbi))
    Columns = csbi.dwSize.X;
  return Columns;
}

// The terminal always has colors.
bool Process::FileDescriptorHasColors(int fd) {
  return FileDescriptorIsDisplayed(fd);
}

bool Process::StandardOutHasColors() {
  return FileDescriptorHasColors(1);
}

bool Process::StandardErrHasColors() {
  return FileDescriptorHasColors(2);
}

static bool UseANSI = false;
void Process::UseANSIEscapeCodes(bool enable) {
  UseANSI = enable;
}

namespace {
class DefaultColors
{
  private:
    WORD defaultColor;
  public:
    DefaultColors()
     :defaultColor(GetCurrentColor()) {}
    static unsigned GetCurrentColor() {
      CONSOLE_SCREEN_BUFFER_INFO csbi;
      if (GetConsoleScreenBufferInfo(GetStdHandle(STD_OUTPUT_HANDLE), &csbi))
        return csbi.wAttributes;
      return 0;
    }
    WORD operator()() const { return defaultColor; }
};

DefaultColors defaultColors;
}

bool Process::ColorNeedsFlush() {
  return !UseANSI;
}

const char *Process::OutputBold(bool bg) {
  if (UseANSI) return "\033[1m";

  WORD colors = DefaultColors::GetCurrentColor();
  if (bg)
    colors |= BACKGROUND_INTENSITY;
  else
    colors |= FOREGROUND_INTENSITY;
  SetConsoleTextAttribute(GetStdHandle(STD_OUTPUT_HANDLE), colors);
  return 0;
}

const char *Process::OutputColor(char code, bool bold, bool bg) {
  if (UseANSI) return colorcodes[bg?1:0][bold?1:0][code&7];

  WORD colors;
  if (bg) {
    colors = ((code&1) ? BACKGROUND_RED : 0) |
      ((code&2) ? BACKGROUND_GREEN : 0 ) |
      ((code&4) ? BACKGROUND_BLUE : 0);
    if (bold)
      colors |= BACKGROUND_INTENSITY;
  } else {
    colors = ((code&1) ? FOREGROUND_RED : 0) |
      ((code&2) ? FOREGROUND_GREEN : 0 ) |
      ((code&4) ? FOREGROUND_BLUE : 0);
    if (bold)
      colors |= FOREGROUND_INTENSITY;
  }
  SetConsoleTextAttribute(GetStdHandle(STD_OUTPUT_HANDLE), colors);
  return 0;
}

static WORD GetConsoleTextAttribute(HANDLE hConsoleOutput) {
  CONSOLE_SCREEN_BUFFER_INFO info;
  GetConsoleScreenBufferInfo(GetStdHandle(STD_OUTPUT_HANDLE), &info);
  return info.wAttributes;
}

const char *Process::OutputReverse() {
  if (UseANSI) return "\033[7m";

  const WORD attributes
   = GetConsoleTextAttribute(GetStdHandle(STD_OUTPUT_HANDLE));

  const WORD foreground_mask = FOREGROUND_BLUE | FOREGROUND_GREEN |
    FOREGROUND_RED | FOREGROUND_INTENSITY;
  const WORD background_mask = BACKGROUND_BLUE | BACKGROUND_GREEN |
    BACKGROUND_RED | BACKGROUND_INTENSITY;
  const WORD color_mask = foreground_mask | background_mask;

  WORD new_attributes =
    ((attributes & FOREGROUND_BLUE     )?BACKGROUND_BLUE     :0) |
    ((attributes & FOREGROUND_GREEN    )?BACKGROUND_GREEN    :0) |
    ((attributes & FOREGROUND_RED      )?BACKGROUND_RED      :0) |
    ((attributes & FOREGROUND_INTENSITY)?BACKGROUND_INTENSITY:0) |
    ((attributes & BACKGROUND_BLUE     )?FOREGROUND_BLUE     :0) |
    ((attributes & BACKGROUND_GREEN    )?FOREGROUND_GREEN    :0) |
    ((attributes & BACKGROUND_RED      )?FOREGROUND_RED      :0) |
    ((attributes & BACKGROUND_INTENSITY)?FOREGROUND_INTENSITY:0) |
    0;
  new_attributes = (attributes & ~color_mask) | (new_attributes & color_mask);

  SetConsoleTextAttribute(GetStdHandle(STD_OUTPUT_HANDLE), new_attributes);
  return 0;
}

const char *Process::ResetColor() {
  if (UseANSI) return "\033[0m";
  SetConsoleTextAttribute(GetStdHandle(STD_OUTPUT_HANDLE), defaultColors());
  return 0;
}

unsigned Process::GetRandomNumber() {
  HCRYPTPROV HCPC;
  if (!::CryptAcquireContextW(&HCPC, NULL, NULL, PROV_RSA_FULL,
                              CRYPT_VERIFYCONTEXT))
    report_fatal_error("Could not acquire a cryptographic context");

  ScopedCryptContext CryptoProvider(HCPC);
  unsigned Ret;
  if (!::CryptGenRandom(CryptoProvider, sizeof(Ret),
                        reinterpret_cast<BYTE *>(&Ret)))
    report_fatal_error("Could not generate a random number");
  return Ret;
}