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b75a7d8f A |
1 | /* |
2 | ************************************************************************ | |
73c04bcf | 3 | * Copyright (c) 1997-2006, International Business Machines |
b75a7d8f A |
4 | * Corporation and others. All Rights Reserved. |
5 | ************************************************************************ | |
6 | */ | |
7 | ||
8 | #ifndef _UTIMER_H | |
9 | #define _UTIMER_H | |
10 | ||
73c04bcf A |
11 | #include "unicode/utypes.h" |
12 | ||
13 | #if defined(U_WINDOWS) | |
374ca955 A |
14 | # define VC_EXTRALEAN |
15 | # define WIN32_LEAN_AND_MEAN | |
b75a7d8f A |
16 | # include <windows.h> |
17 | #else | |
374ca955 | 18 | # include <time.h> |
b75a7d8f A |
19 | # include <sys/time.h> |
20 | # include <unistd.h> | |
21 | #endif | |
22 | ||
23 | /** | |
24 | * This API provides functions for performing performance measurement | |
25 | * There are 3 main usage scenarios. | |
26 | * i) Loop until a threshold time is reached: | |
27 | * Example: | |
28 | * <code> | |
29 | * typedef Params Params; | |
30 | * struct Params{ | |
31 | * UChar* target; | |
32 | * int32_t targetLen; | |
33 | * const UChar* source; | |
34 | * int32_t sourceLen; | |
35 | * UNormalizationMode mode; | |
36 | * } | |
37 | * void NormFn( void* param){ | |
38 | * Params* parameters = ( Params*) param; | |
39 | * UErrorCode error = U_ZERO_ERROR; | |
40 | * unorm_normalize(parameters->source, parameters->sourceLen, parameters->mode, 0, parameters->target, parameters->targetLen, &error); | |
41 | * if(U_FAILURE(error)){ | |
42 | * printf("Normalization failed\n"); | |
43 | * } | |
44 | * } | |
45 | * | |
46 | * int main(){ | |
47 | * // time the normalization function | |
48 | * double timeTaken = 0; | |
49 | * Params param; | |
50 | * param.source // set up the source buffer | |
51 | * param.target // set up the target buffer | |
52 | * .... so on ... | |
53 | * UTimer timer; | |
54 | * // time the loop for 10 seconds at least and find out the loop count and time taken | |
55 | * timeTaken = utimer_loopUntilDone((double)10,(void*) param, NormFn, &loopCount); | |
56 | * } | |
57 | * </code> | |
58 | * | |
59 | * ii) Measure the time taken | |
60 | * Example: | |
61 | * <code> | |
73c04bcf A |
62 | * double perfNormalization(NormFn fn,const char* mode,Line* fileLines,int32_t loopCount){ |
63 | * int line; | |
64 | * int loops; | |
65 | * UErrorCode error = U_ZERO_ERROR; | |
66 | * UChar* dest=NULL; | |
67 | * int32_t destCapacity=0; | |
68 | * int len =-1; | |
69 | * double elapsedTime = 0; | |
70 | * int retVal=0; | |
b75a7d8f | 71 | * |
73c04bcf A |
72 | * UChar arr[5000]; |
73 | * dest=arr; | |
74 | * destCapacity = 5000; | |
75 | * UTimer start; | |
b75a7d8f | 76 | * |
73c04bcf A |
77 | * // Initialize cache and ensure the data is loaded. |
78 | * // This loop checks for errors in Normalization. Once we pass the initialization | |
79 | * // without errors we can safelly assume that there are no errors while timing the | |
80 | * // funtion | |
81 | * for (loops=0; loops<10; loops++) { | |
82 | * for (line=0; line < gNumFileLines; line++) { | |
83 | * if (opt_uselen) { | |
84 | * len = fileLines[line].len; | |
85 | * } | |
b75a7d8f | 86 | * |
73c04bcf A |
87 | * retVal= fn(fileLines[line].name,len,dest,destCapacity,&error); |
88 | * #if defined(U_WINDOWS) | |
89 | * if(retVal==0 ){ | |
90 | * fprintf(stderr,"Normalization of string in Windows API failed for mode %s. ErrorNo: %i at line number %i\n",mode,GetLastError(),line); | |
91 | * return 0; | |
b75a7d8f | 92 | * } |
73c04bcf A |
93 | * #endif |
94 | * if(U_FAILURE(error)){ | |
95 | * fprintf(stderr,"Normalization of string in ICU API failed for mode %s. Error: %s at line number %i\n",mode,u_errorName(error),line); | |
96 | * return 0; | |
97 | * } | |
98 | * | |
b75a7d8f | 99 | * } |
73c04bcf | 100 | * } |
b75a7d8f | 101 | * |
73c04bcf | 102 | * //compute the time |
b75a7d8f | 103 | * |
73c04bcf A |
104 | * utimer_getTime(&start); |
105 | * for (loops=0; loops<loopCount; loops++) { | |
106 | * for (line=0; line < gNumFileLines; line++) { | |
107 | * if (opt_uselen) { | |
108 | * len = fileLines[line].len; | |
b75a7d8f | 109 | * } |
b75a7d8f | 110 | * |
73c04bcf A |
111 | * retVal= fn(fileLines[line].name,len,dest,destCapacity,&error); |
112 | * | |
113 | * } | |
b75a7d8f | 114 | * } |
73c04bcf A |
115 | * |
116 | * return utimer_getElapsedSeconds(&start); | |
117 | * } | |
b75a7d8f A |
118 | * </code> |
119 | * | |
120 | * iii) Let a higher level function do the calculation of confidence levels etc. | |
121 | * Example: | |
122 | * <code> | |
123 | * void perf(UTimer* timer, UChar* source, int32_t sourceLen, UChar* target, int32_t targetLen, int32_t loopCount,UNormalizationMode mode, UErrorCode* error){ | |
124 | * int32_t loops; | |
125 | * for (loops=0; loops<loopCount; loops++) { | |
126 | * unorm_normalize(source,sourceLen,target, targetLen,mode,error); | |
127 | * } | |
128 | * utimer_getTime(timer); | |
129 | * } | |
130 | * void main(const char* argsc, int argv){ | |
131 | * // read the file and setup the data | |
132 | * // set up options | |
133 | * UTimer start,timer1, timer2, timer3, timer4; | |
134 | * double NFDTimeTaken, NFCTimeTaken, FCDTimeTaken; | |
135 | * switch(opt){ | |
136 | * case 0: | |
137 | * utimer_getTime(start); | |
138 | * perf(timer1, source,sourceLen, target, targetLen,loopCount,UNORM_NFD,&error); | |
139 | * NFDTimeTaken = utimer_getDeltaSeconds(start,timer1); | |
140 | * case 1: | |
141 | * timer_getTime(start); | |
142 | * perf(timer2,source,sourceLen,target,targetLen,loopCount,UNORM_NFC,&error); | |
143 | * NFCTimeTaken = utimer_getDeltaSeconds(start,timer2); | |
144 | * perf(timer3, source, sourceLen, target,targetLen, loopCount, UNORM_FCD,&error); | |
145 | * // ........so on ............. | |
146 | * } | |
147 | * // calculate confidence levels etc and print | |
148 | * | |
149 | * } | |
150 | * | |
151 | * </code> | |
152 | * | |
153 | */ | |
154 | ||
155 | typedef struct UTimer UTimer; | |
156 | ||
157 | typedef void FuntionToBeTimed(void* param); | |
158 | ||
159 | ||
73c04bcf | 160 | #if defined(U_WINDOWS) |
b75a7d8f A |
161 | |
162 | struct UTimer{ | |
163 | LARGE_INTEGER start; | |
164 | LARGE_INTEGER placeHolder; | |
165 | }; | |
166 | ||
167 | int uprv_initFrequency(UTimer* timer) | |
168 | { | |
169 | return QueryPerformanceFrequency(&timer->placeHolder); | |
170 | } | |
171 | void uprv_start(UTimer* timer) | |
172 | { | |
173 | QueryPerformanceCounter(&timer->start); | |
174 | } | |
175 | double uprv_delta(UTimer* timer1, UTimer* timer2){ | |
176 | return ((double)(timer2->start.QuadPart - timer1->start.QuadPart))/((double)timer1->placeHolder.QuadPart); | |
177 | } | |
178 | UBool uprv_compareFrequency(UTimer* timer1, UTimer* timer2){ | |
179 | return (timer1->placeHolder.QuadPart == timer2->placeHolder.QuadPart); | |
180 | } | |
181 | ||
182 | #else | |
183 | ||
184 | struct UTimer{ | |
185 | struct timeval start; | |
186 | struct timeval placeHolder; | |
187 | }; | |
188 | ||
189 | int32_t uprv_initFrequency(UTimer* /*timer*/) | |
190 | { | |
191 | return 0; | |
192 | } | |
193 | void uprv_start(UTimer* timer) | |
194 | { | |
195 | gettimeofday(&timer->start, 0); | |
196 | } | |
197 | double uprv_delta(UTimer* timer1, UTimer* timer2){ | |
198 | double t1, t2; | |
199 | ||
200 | t1 = (double)timer1->start.tv_sec + (double)timer1->start.tv_usec/(1000*1000); | |
201 | t2 = (double)timer2->start.tv_sec + (double)timer2->start.tv_usec/(1000*1000); | |
202 | return (t2-t1); | |
203 | } | |
204 | UBool uprv_compareFrequency(UTimer* /*timer1*/, UTimer* /*timer2*/){ | |
205 | return TRUE; | |
206 | } | |
207 | ||
208 | #endif | |
209 | /** | |
210 | * Intializes the timer with the current time | |
211 | * | |
212 | * @param timer A pointer to UTimer struct to recieve the current time | |
213 | */ | |
73c04bcf | 214 | static U_INLINE void U_EXPORT2 |
b75a7d8f A |
215 | utimer_getTime(UTimer* timer){ |
216 | uprv_initFrequency(timer); | |
217 | uprv_start(timer); | |
218 | } | |
219 | ||
220 | /** | |
221 | * Returns the difference in times between timer1 and timer2 by subtracting | |
222 | * timer1's time from timer2's time | |
223 | * | |
224 | * @param timer1 A pointer to UTimer struct to be used as starting time | |
225 | * @param timer2 A pointer to UTimer struct to be used as end time | |
226 | * @return Time in seconds | |
227 | */ | |
73c04bcf | 228 | static U_INLINE double U_EXPORT2 |
b75a7d8f A |
229 | utimer_getDeltaSeconds(UTimer* timer1, UTimer* timer2){ |
230 | if(uprv_compareFrequency(timer1,timer2)){ | |
231 | return uprv_delta(timer1,timer2); | |
232 | } | |
233 | /* got error return -1 */ | |
234 | return -1; | |
235 | } | |
236 | ||
237 | /** | |
238 | * Returns the time elapsed from the starting time represented by the | |
239 | * UTimer struct pointer passed | |
240 | * @param timer A pointer to UTimer struct to be used as starting time | |
241 | * @return Time elapsed in seconds | |
242 | */ | |
73c04bcf | 243 | static U_INLINE double U_EXPORT2 |
b75a7d8f A |
244 | utimer_getElapsedSeconds(UTimer* timer){ |
245 | UTimer temp; | |
246 | utimer_getTime(&temp); | |
247 | return uprv_delta(timer,&temp); | |
248 | } | |
249 | ||
250 | /** | |
251 | * Executes the function pointed to for a given time and returns exact time | |
252 | * taken and number of iterations of the loop | |
253 | * @param thresholTimeVal | |
254 | * @param loopCount output param to recieve the number of iterations | |
255 | * @param fn The funtion to be executed | |
256 | * @param param Parameters to be passed to the fn | |
257 | * @return the time elapsed in seconds | |
258 | */ | |
73c04bcf | 259 | static U_INLINE double U_EXPORT2 |
b75a7d8f A |
260 | utimer_loopUntilDone(double thresholdTimeVal, |
261 | int32_t* loopCount, | |
262 | FuntionToBeTimed fn, | |
263 | void* param){ | |
264 | UTimer timer; | |
265 | double currentVal=0; | |
266 | *loopCount = 0; | |
267 | utimer_getTime(&timer); | |
268 | for(;currentVal<thresholdTimeVal;){ | |
269 | fn(param); | |
270 | currentVal = utimer_getElapsedSeconds(&timer); | |
271 | *loopCount++; | |
272 | } | |
273 | return currentVal; | |
274 | } | |
275 | ||
276 | #endif | |
277 |