static CSSM_RETURN hashDataRateCryptKit(
TestParams *params)
{
ckUpdateFcn updatePtr = NULL;
ckFinalFcn finalPtr = NULL;
ckInitFcn initPtr = NULL;
struct MD5Context md5;
sha1Obj sha;
void *ctx;
unsigned loop;
unsigned iloop;
double startTime, endTime;
double timeSpent, timeSpentMs;
uint8 ptext[PTEXT_SIZE];
uint8 digest[MAX_DIGEST_SIZE];
unsigned digestLen = 16;
/* we reuse this one inside the loop */
switch(params->algId) {
case CSSM_ALGID_SHA1:
sha = sha1Alloc();
ctx = sha;
initPtr = (ckInitFcn)sha1Reinit;
updatePtr = (ckUpdateFcn)sha1AddData;
finalPtr = (ckFinalFcn)ckSha1Final;
digestLen = 20;
break;
case CSSM_ALGID_MD5:
ctx = &md5;
initPtr = (ckInitFcn)MD5Init;
updatePtr = (ckUpdateFcn)MD5Update;
finalPtr = (ckFinalFcn)MD5Final;
break;
default:
printf("***Sorry, CryptKit can only do SHA1 and MD5.\n");
return 1;
}
/* random data, const thru the loops */
initPtext(ptext, PTEXT_SIZE);
/* start critical timing loop */
startTime = CFAbsoluteTimeGetCurrent();
for(loop=0; loop<params->loops; loop++) {
initPtr(ctx);
for(iloop=0; iloop<INNER_LOOPS; iloop++) {
updatePtr(ctx, ptext, PTEXT_SIZE);
}
finalPtr(ctx, digest);
}
endTime = CFAbsoluteTimeGetCurrent();
timeSpent = endTime - startTime;
timeSpentMs = timeSpent * 1000.0;
float bytesPerLoop = INNER_LOOPS * PTEXT_SIZE;
float totalBytes = params->loops * bytesPerLoop;
/* careful, KByte = 1024, ms = 1/1000 */
printf(" Digest %.0f bytes : %u ops in %.2f ms; %f ms/op, %.0f KBytes/s\n",
bytesPerLoop, params->loops,
timeSpentMs, timeSpentMs / (double)params->loops,
((float)totalBytes / 1024.0) / timeSpent);
if(params->dumpDigest) {
dumpDigest(digest, digestLen);
}
return CSSM_OK;
}
int main()
{
DDRB |= 1<<LED_PIN; // led pin as output
PORTB |= 1<<SWITCH_PIN; // pullup for switch
LED_OFF;
_delay_ms(2);
initPtr(); // cherche le point d'écriture dans le tampon
if(ACQ_MODE) {
int cnt = 0;
int seconds = LOG_INTERVAL - 5; // first mesurement: 5 seconds after power on
write_record(0x7F00, 0); // place a power on mark
for(;;) {
if(ACQ_MODE) {
_delay_ms(20); // TODO work with timer interrupt
if(cnt++>50) { // augmente le compteur de secondes
seconds += 1;
cnt = 0;
}
if(seconds>=LOG_INTERVAL) {
if(sensorRead()) {
write_record(sensor_bytes[0]<<8 | sensor_bytes[1], sensor_bytes[2]<<8 | sensor_bytes[3]);
// clear le compteur de seconde uniquement en cas de succès de lecture (ceci permet de tolérer des échec de lecture du capteur)
seconds = 0;
}
}
// Led clignotante pour signaler le mode aquisition
if((cnt%25)>22) LED_ON;
else LED_OFF;
}
else {
LED_OFF;
}
}
}
else {
#if defined(__AVR_ATtiny85__) || defined(__AVR_ATtiny45__) || defined(__AVR_ATtiny25__)
uint8_t calibrationValue = eeprom_read_byte(0); /* calibration value from last time */
if (calibrationValue != 0xFF)
{
OSCCAL = calibrationValue;
}
#endif
stdout = &mystdout; // set default stream
// initialize report (I never assume it's initialized to 0 automatically)
keyboard_report_reset();
wdt_disable(); // disable watchdog, good habit if you don't use it
// enforce USB re-enumeration by pretending to disconnect and reconnect
usbDeviceDisconnect();
_delay_ms(250);
usbDeviceConnect();
// initialize various modules
usbInit();
sei(); // enable interrupts
while (1) // main loop, do forever
{
if (blink_count > 2) // activated by blinking lights
{
#if !defined(__AVR_ATtiny85__) && !defined(__AVR_ATtiny45__) && !defined(__AVR_ATtiny25__)
DDRD |= _BV(1); // LED lights for debug
PORTD |= _BV(1);
#endif
puts_P(PSTR("----------------------------------"));
printf("LogStick 1.0 interval %d seconds\n", LOG_INTERVAL);
if(ACQ_MODE) printf("Ptr %x\n", ptr);
puts_P(PSTR("----------------------------------"));
// PLACE TEXT HERE
//puts_P(PSTR(" ")); // test size
int humidity;
int temperature;
int p = ptr; // pointeur de la prochaine écriture en mode ACQ
for(;;) {
p -= 4;
if(p<START_PTR) p = MAX_PTR-4;
if(p==ptr) break;
humidity = eeprom_read_word(p);
temperature = eeprom_read_word(p+2);
if(humidity==0x7F00) {
if(ACQ_MODE) printf("%x:", p);
puts_P(PSTR("---POWER ON---"));
}
else if(humidity==0x7FFF) {
puts_P(PSTR("---PTR MARK---")); // ne devrait pas se produire
}
else {
if(ACQ_MODE) printf("%x:%d.%d,%d.%d\n", p, humidity/10, humidity%10, temperature/10, temperature%10);
else printf("%d.%d,%d.%d\n", humidity/10, humidity%10, temperature/10, temperature%10);
}
}
puts_P(PSTR("------------------------------END-"));
blink_count = 0; // reset
}
// perform usb related background tasks
usbPoll(); // this needs to be called at least once every 10 ms
// this is also called in send_report_once
}
}
return 0;
}
static CSSM_RETURN hashDataRateCommonCrypto(
TestParams *params)
{
CC_CTX ctx;
ccUpdateFcn updatePtr = NULL;
ccFinalFcn finalPtr = NULL;
ccInitFcn initPtr = NULL;
unsigned loop;
unsigned iloop;
double startTime, endTime;
double timeSpent, timeSpentMs;
uint8 ptext[PTEXT_SIZE];
uint8 digest[MAX_DIGEST_SIZE];
unsigned digestLen = 16;
/* we reuse this one inside the loop */
switch(params->algId) {
case CSSM_ALGID_SHA1:
initPtr = (ccInitFcn)CC_SHA1_Init;
updatePtr = (ccUpdateFcn)CC_SHA1_Update;
finalPtr = (ccFinalFcn)CC_SHA1_Final;
digestLen = 20;
break;
case CSSM_ALGID_SHA224:
initPtr = (ccInitFcn)CC_SHA224_Init;
updatePtr = (ccUpdateFcn)CC_SHA224_Update;
finalPtr = (ccFinalFcn)CC_SHA224_Final;
digestLen = 28;
break;
case CSSM_ALGID_SHA256:
initPtr = (ccInitFcn)CC_SHA256_Init;
updatePtr = (ccUpdateFcn)CC_SHA256_Update;
finalPtr = (ccFinalFcn)CC_SHA256_Final;
digestLen = 32;
break;
case CSSM_ALGID_SHA384:
initPtr = (ccInitFcn)CC_SHA384_Init;
updatePtr = (ccUpdateFcn)CC_SHA384_Update;
finalPtr = (ccFinalFcn)CC_SHA384_Final;
digestLen = 48;
break;
case CSSM_ALGID_SHA512:
initPtr = (ccInitFcn)CC_SHA512_Init;
updatePtr = (ccUpdateFcn)CC_SHA512_Update;
finalPtr = (ccFinalFcn)CC_SHA512_Final;
digestLen = 64;
break;
case CSSM_ALGID_MD5:
initPtr = (ccInitFcn)CC_MD5_Init;
updatePtr = (ccUpdateFcn)CC_MD5_Update;
finalPtr = (ccFinalFcn)CC_MD5_Final;
digestLen = 16;
break;
default:
printf("***BRRRZAP!\n");
return 1;
}
/* random data, const thru the loops */
initPtext(ptext, PTEXT_SIZE);
/* start critical timing loop */
startTime = CFAbsoluteTimeGetCurrent();
for(loop=0; loop<params->loops; loop++) {
initPtr(&ctx);
for(iloop=0; iloop<INNER_LOOPS; iloop++) {
updatePtr(&ctx, ptext, PTEXT_SIZE);
}
finalPtr(digest, &ctx);
}
endTime = CFAbsoluteTimeGetCurrent();
timeSpent = endTime - startTime;
timeSpentMs = timeSpent * 1000.0;
float bytesPerLoop = INNER_LOOPS * PTEXT_SIZE;
float totalBytes = params->loops * bytesPerLoop;
/* careful, KByte = 1024, ms = 1/1000 */
printf(" Digest %.0f bytes : %u ops in %.2f ms; %f ms/op, %.0f KBytes/s\n",
bytesPerLoop, params->loops,
timeSpentMs, timeSpentMs / (double)params->loops,
((float)totalBytes / 1024.0) / timeSpent);
if(params->dumpDigest) {
dumpDigest(digest, digestLen);
}
return CSSM_OK;
}
