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1 //===-- TimeValue.h - Declare OS TimeValue Concept --------------*- C++ -*-===//
2 //
3 //                     The LLVM Compiler Infrastructure
4 //
5 // This file is distributed under the University of Illinois Open Source
6 // License. See LICENSE.TXT for details.
7 //
8 //===----------------------------------------------------------------------===//
9 //
10 //  This header file declares the operating system TimeValue concept.
11 //
12 //===----------------------------------------------------------------------===//
13 
14 #ifndef LLVM_SUPPORT_TIMEVALUE_H
15 #define LLVM_SUPPORT_TIMEVALUE_H
16 
17 #include "llvm/Support/DataTypes.h"
18 #include <string>
19 
20 namespace llvm {
21 namespace sys {
22   /// This class is used where a precise fixed point in time is required. The
23   /// range of TimeValue spans many hundreds of billions of years both past and
24   /// present.  The precision of TimeValue is to the nanosecond. However, the
25   /// actual precision of its values will be determined by the resolution of
26   /// the system clock. The TimeValue class is used in conjunction with several
27   /// other lib/System interfaces to specify the time at which a call should
28   /// timeout, etc.
29   /// @since 1.4
30   /// @brief Provides an abstraction for a fixed point in time.
31   class TimeValue {
32 
33   /// @name Constants
34   /// @{
35   public:
36 
37     /// A constant TimeValue representing the smallest time
38     /// value permissible by the class. MinTime is some point
39     /// in the distant past, about 300 billion years BCE.
40     /// @brief The smallest possible time value.
MinTime()41     static TimeValue MinTime() {
42       return TimeValue ( INT64_MIN,0 );
43     }
44 
45     /// A constant TimeValue representing the largest time
46     /// value permissible by the class. MaxTime is some point
47     /// in the distant future, about 300 billion years AD.
48     /// @brief The largest possible time value.
MaxTime()49     static TimeValue MaxTime() {
50       return TimeValue ( INT64_MAX,0 );
51     }
52 
53     /// A constant TimeValue representing the base time,
54     /// or zero time of 00:00:00 (midnight) January 1st, 2000.
55     /// @brief 00:00:00 Jan 1, 2000 UTC.
ZeroTime()56     static TimeValue ZeroTime() {
57       return TimeValue ( 0,0 );
58     }
59 
60     /// A constant TimeValue for the Posix base time which is
61     /// 00:00:00 (midnight) January 1st, 1970.
62     /// @brief 00:00:00 Jan 1, 1970 UTC.
PosixZeroTime()63     static TimeValue PosixZeroTime() {
64       return TimeValue ( PosixZeroTimeSeconds,0 );
65     }
66 
67     /// A constant TimeValue for the Win32 base time which is
68     /// 00:00:00 (midnight) January 1st, 1601.
69     /// @brief 00:00:00 Jan 1, 1601 UTC.
Win32ZeroTime()70     static TimeValue Win32ZeroTime() {
71       return TimeValue ( Win32ZeroTimeSeconds,0 );
72     }
73 
74   /// @}
75   /// @name Types
76   /// @{
77   public:
78     typedef int64_t SecondsType;    ///< Type used for representing seconds.
79     typedef int32_t NanoSecondsType;///< Type used for representing nanoseconds.
80 
81     enum TimeConversions {
82       NANOSECONDS_PER_SECOND = 1000000000,  ///< One Billion
83       MICROSECONDS_PER_SECOND = 1000000,    ///< One Million
84       MILLISECONDS_PER_SECOND = 1000,       ///< One Thousand
85       NANOSECONDS_PER_MICROSECOND = 1000,   ///< One Thousand
86       NANOSECONDS_PER_MILLISECOND = 1000000,///< One Million
87       NANOSECONDS_PER_WIN32_TICK = 100      ///< Win32 tick is 10^7 Hz (10ns)
88     };
89 
90   /// @}
91   /// @name Constructors
92   /// @{
93   public:
94     /// \brief Default construct a time value, initializing to ZeroTime.
TimeValue()95     TimeValue() : seconds_(0), nanos_(0) {}
96 
97     /// Caller provides the exact value in seconds and nanoseconds. The
98     /// \p nanos argument defaults to zero for convenience.
99     /// @brief Explicit constructor
100     explicit TimeValue (SecondsType seconds, NanoSecondsType nanos = 0)
seconds_(seconds)101       : seconds_( seconds ), nanos_( nanos ) { this->normalize(); }
102 
103     /// Caller provides the exact value as a double in seconds with the
104     /// fractional part representing nanoseconds.
105     /// @brief Double Constructor.
TimeValue(double new_time)106     explicit TimeValue( double new_time )
107       : seconds_( 0 ) , nanos_ ( 0 ) {
108       SecondsType integer_part = static_cast<SecondsType>( new_time );
109       seconds_ = integer_part;
110       nanos_ = static_cast<NanoSecondsType>( (new_time -
111                static_cast<double>(integer_part)) * NANOSECONDS_PER_SECOND );
112       this->normalize();
113     }
114 
115     /// This is a static constructor that returns a TimeValue that represents
116     /// the current time.
117     /// @brief Creates a TimeValue with the current time (UTC).
118     static TimeValue now();
119 
120   /// @}
121   /// @name Operators
122   /// @{
123   public:
124     /// Add \p that to \p this.
125     /// @returns this
126     /// @brief Incrementing assignment operator.
127     TimeValue& operator += (const TimeValue& that ) {
128       this->seconds_ += that.seconds_  ;
129       this->nanos_ += that.nanos_ ;
130       this->normalize();
131       return *this;
132     }
133 
134     /// Subtract \p that from \p this.
135     /// @returns this
136     /// @brief Decrementing assignment operator.
137     TimeValue& operator -= (const TimeValue &that ) {
138       this->seconds_ -= that.seconds_ ;
139       this->nanos_ -= that.nanos_ ;
140       this->normalize();
141       return *this;
142     }
143 
144     /// Determine if \p this is less than \p that.
145     /// @returns True iff *this < that.
146     /// @brief True if this < that.
147     int operator < (const TimeValue &that) const { return that > *this; }
148 
149     /// Determine if \p this is greather than \p that.
150     /// @returns True iff *this > that.
151     /// @brief True if this > that.
152     int operator > (const TimeValue &that) const {
153       if ( this->seconds_ > that.seconds_ ) {
154           return 1;
155       } else if ( this->seconds_ == that.seconds_ ) {
156           if ( this->nanos_ > that.nanos_ ) return 1;
157       }
158       return 0;
159     }
160 
161     /// Determine if \p this is less than or equal to \p that.
162     /// @returns True iff *this <= that.
163     /// @brief True if this <= that.
164     int operator <= (const TimeValue &that) const { return that >= *this; }
165 
166     /// Determine if \p this is greater than or equal to \p that.
167     /// @returns True iff *this >= that.
168     int operator >= (const TimeValue &that) const {
169       if ( this->seconds_ > that.seconds_ ) {
170           return 1;
171       } else if ( this->seconds_ == that.seconds_ ) {
172           if ( this->nanos_ >= that.nanos_ ) return 1;
173       }
174       return 0;
175     }
176 
177     /// Determines if two TimeValue objects represent the same moment in time.
178     /// @returns True iff *this == that.
179     int operator == (const TimeValue &that) const {
180       return (this->seconds_ == that.seconds_) &&
181              (this->nanos_ == that.nanos_);
182     }
183 
184     /// Determines if two TimeValue objects represent times that are not the
185     /// same.
186     /// @returns True iff *this != that.
187     int operator != (const TimeValue &that) const { return !(*this == that); }
188 
189     /// Adds two TimeValue objects together.
190     /// @returns The sum of the two operands as a new TimeValue
191     /// @brief Addition operator.
192     friend TimeValue operator + (const TimeValue &tv1, const TimeValue &tv2);
193 
194     /// Subtracts two TimeValue objects.
195     /// @returns The difference of the two operands as a new TimeValue
196     /// @brief Subtraction operator.
197     friend TimeValue operator - (const TimeValue &tv1, const TimeValue &tv2);
198 
199   /// @}
200   /// @name Accessors
201   /// @{
202   public:
203 
204     /// Returns only the seconds component of the TimeValue. The nanoseconds
205     /// portion is ignored. No rounding is performed.
206     /// @brief Retrieve the seconds component
seconds()207     SecondsType seconds() const { return seconds_; }
208 
209     /// Returns only the nanoseconds component of the TimeValue. The seconds
210     /// portion is ignored.
211     /// @brief Retrieve the nanoseconds component.
nanoseconds()212     NanoSecondsType nanoseconds() const { return nanos_; }
213 
214     /// Returns only the fractional portion of the TimeValue rounded down to the
215     /// nearest microsecond (divide by one thousand).
216     /// @brief Retrieve the fractional part as microseconds;
microseconds()217     uint32_t microseconds() const {
218       return nanos_ / NANOSECONDS_PER_MICROSECOND;
219     }
220 
221     /// Returns only the fractional portion of the TimeValue rounded down to the
222     /// nearest millisecond (divide by one million).
223     /// @brief Retrieve the fractional part as milliseconds;
milliseconds()224     uint32_t milliseconds() const {
225       return nanos_ / NANOSECONDS_PER_MILLISECOND;
226     }
227 
228     /// Returns the TimeValue as a number of microseconds. Note that the value
229     /// returned can overflow because the range of a uint64_t is smaller than
230     /// the range of a TimeValue. Nevertheless, this is useful on some operating
231     /// systems and is therefore provided.
232     /// @brief Convert to a number of microseconds (can overflow)
usec()233     uint64_t usec() const {
234       return seconds_ * MICROSECONDS_PER_SECOND +
235              ( nanos_ / NANOSECONDS_PER_MICROSECOND );
236     }
237 
238     /// Returns the TimeValue as a number of milliseconds. Note that the value
239     /// returned can overflow because the range of a uint64_t is smaller than
240     /// the range of a TimeValue. Nevertheless, this is useful on some operating
241     /// systems and is therefore provided.
242     /// @brief Convert to a number of milliseconds (can overflow)
msec()243     uint64_t msec() const {
244       return seconds_ * MILLISECONDS_PER_SECOND +
245              ( nanos_ / NANOSECONDS_PER_MILLISECOND );
246     }
247 
248     /// Converts the TimeValue into the corresponding number of seconds
249     /// since the epoch (00:00:00 Jan 1,1970).
toEpochTime()250     uint64_t toEpochTime() const {
251       return seconds_ - PosixZeroTimeSeconds;
252     }
253 
254     /// Converts the TimeValue into the corresponding number of "ticks" for
255     /// Win32 platforms, correcting for the difference in Win32 zero time.
256     /// @brief Convert to Win32's FILETIME
257     /// (100ns intervals since 00:00:00 Jan 1, 1601 UTC)
toWin32Time()258     uint64_t toWin32Time() const {
259       uint64_t result = (uint64_t)10000000 * (seconds_ - Win32ZeroTimeSeconds);
260       result += nanos_ / NANOSECONDS_PER_WIN32_TICK;
261       return result;
262     }
263 
264     /// Provides the seconds and nanoseconds as results in its arguments after
265     /// correction for the Posix zero time.
266     /// @brief Convert to timespec time (ala POSIX.1b)
getTimespecTime(uint64_t & seconds,uint32_t & nanos)267     void getTimespecTime( uint64_t& seconds, uint32_t& nanos ) const {
268       seconds = seconds_ - PosixZeroTimeSeconds;
269       nanos = nanos_;
270     }
271 
272     /// Provides conversion of the TimeValue into a readable time & date.
273     /// @returns std::string containing the readable time value
274     /// @brief Convert time to a string.
275     std::string str() const;
276 
277   /// @}
278   /// @name Mutators
279   /// @{
280   public:
281     /// The seconds component of the TimeValue is set to \p sec without
282     /// modifying the nanoseconds part.  This is useful for whole second
283     /// arithmetic.
284     /// @brief Set the seconds component.
seconds(SecondsType sec)285     void seconds (SecondsType sec ) {
286       this->seconds_ = sec;
287       this->normalize();
288     }
289 
290     /// The nanoseconds component of the TimeValue is set to \p nanos without
291     /// modifying the seconds part. This is useful for basic computations
292     /// involving just the nanoseconds portion. Note that the TimeValue will be
293     /// normalized after this call so that the fractional (nanoseconds) portion
294     /// will have the smallest equivalent value.
295     /// @brief Set the nanoseconds component using a number of nanoseconds.
nanoseconds(NanoSecondsType nanos)296     void nanoseconds ( NanoSecondsType nanos ) {
297       this->nanos_ = nanos;
298       this->normalize();
299     }
300 
301     /// The seconds component remains unchanged.
302     /// @brief Set the nanoseconds component using a number of microseconds.
microseconds(int32_t micros)303     void microseconds ( int32_t micros ) {
304       this->nanos_ = micros * NANOSECONDS_PER_MICROSECOND;
305       this->normalize();
306     }
307 
308     /// The seconds component remains unchanged.
309     /// @brief Set the nanoseconds component using a number of milliseconds.
milliseconds(int32_t millis)310     void milliseconds ( int32_t millis ) {
311       this->nanos_ = millis * NANOSECONDS_PER_MILLISECOND;
312       this->normalize();
313     }
314 
315     /// @brief Converts from microsecond format to TimeValue format
usec(int64_t microseconds)316     void usec( int64_t microseconds ) {
317       this->seconds_ = microseconds / MICROSECONDS_PER_SECOND;
318       this->nanos_ = NanoSecondsType(microseconds % MICROSECONDS_PER_SECOND) *
319         NANOSECONDS_PER_MICROSECOND;
320       this->normalize();
321     }
322 
323     /// @brief Converts from millisecond format to TimeValue format
msec(int64_t milliseconds)324     void msec( int64_t milliseconds ) {
325       this->seconds_ = milliseconds / MILLISECONDS_PER_SECOND;
326       this->nanos_ = NanoSecondsType(milliseconds % MILLISECONDS_PER_SECOND) *
327         NANOSECONDS_PER_MILLISECOND;
328       this->normalize();
329     }
330 
331     /// Converts the \p seconds argument from PosixTime to the corresponding
332     /// TimeValue and assigns that value to \p this.
333     /// @brief Convert seconds form PosixTime to TimeValue
fromEpochTime(SecondsType seconds)334     void fromEpochTime( SecondsType seconds ) {
335       seconds_ = seconds + PosixZeroTimeSeconds;
336       nanos_ = 0;
337       this->normalize();
338     }
339 
340     /// Converts the \p win32Time argument from Windows FILETIME to the
341     /// corresponding TimeValue and assigns that value to \p this.
342     /// @brief Convert seconds form Windows FILETIME to TimeValue
fromWin32Time(uint64_t win32Time)343     void fromWin32Time( uint64_t win32Time ) {
344       this->seconds_ = win32Time / 10000000 + Win32ZeroTimeSeconds;
345       this->nanos_ = NanoSecondsType(win32Time  % 10000000) * 100;
346     }
347 
348   /// @}
349   /// @name Implementation
350   /// @{
351   private:
352     /// This causes the values to be represented so that the fractional
353     /// part is minimized, possibly incrementing the seconds part.
354     /// @brief Normalize to canonical form.
355     void normalize();
356 
357   /// @}
358   /// @name Data
359   /// @{
360   private:
361     /// Store the values as a <timeval>.
362     SecondsType      seconds_;///< Stores the seconds part of the TimeVal
363     NanoSecondsType  nanos_;  ///< Stores the nanoseconds part of the TimeVal
364 
365     static const SecondsType PosixZeroTimeSeconds;
366     static const SecondsType Win32ZeroTimeSeconds;
367   /// @}
368 
369   };
370 
371 inline TimeValue operator + (const TimeValue &tv1, const TimeValue &tv2) {
372   TimeValue sum (tv1.seconds_ + tv2.seconds_, tv1.nanos_ + tv2.nanos_);
373   sum.normalize ();
374   return sum;
375 }
376 
377 inline TimeValue operator - (const TimeValue &tv1, const TimeValue &tv2) {
378   TimeValue difference (tv1.seconds_ - tv2.seconds_, tv1.nanos_ - tv2.nanos_ );
379   difference.normalize ();
380   return difference;
381 }
382 
383 }
384 }
385 
386 #endif
387