405 lines
15 KiB
Plaintext
405 lines
15 KiB
Plaintext
/* BEGIN_HEADER */
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/* This test module exercises the timing module. One of the expected failure
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modes is for timers to never expire, which could lead to an infinite loop.
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The function timing_timer_simple is protected against this failure mode and
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checks that timers do expire. Other functions will terminate if their
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timers do expire. Therefore it is recommended to run timing_timer_simple
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first and run other test functions only if that timing_timer_simple
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succeeded. */
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#include <limits.h>
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#include "mbedtls/timing.h"
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/* Wait this many milliseconds for a short timing test. This duration
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should be large enough that, in practice, if you read the timer
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value twice in a row, it won't have jumped by that much. */
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#define TIMING_SHORT_TEST_MS 100
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/* A loop that waits TIMING_SHORT_TEST_MS must not take more than this many
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iterations. This value needs to be large enough to accommodate fast
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platforms (e.g. at 4GHz and 10 cycles/iteration a CPU can run through 20
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million iterations in 50ms). The only motivation to keep this value low is
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to avoid having an infinite loop if the timer functions are not implemented
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correctly. Ideally this value should be based on the processor speed but we
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don't have this information! */
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#define TIMING_SHORT_TEST_ITERATIONS_MAX 1e8
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/* alarm(0) must fire in no longer than this amount of time. */
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#define TIMING_ALARM_0_DELAY_MS TIMING_SHORT_TEST_MS
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static int expected_delay_status( uint32_t int_ms, uint32_t fin_ms,
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unsigned long actual_ms )
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{
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return( fin_ms == 0 ? -1 :
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actual_ms >= fin_ms ? 2 :
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actual_ms >= int_ms ? 1 :
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0 );
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}
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/* Some conditions in timing_timer_simple suggest that timers are unreliable.
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Most other test cases rely on timers to terminate, and could loop
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indefinitely if timers are too broken. So if timing_timer_simple detected a
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timer that risks not terminating (going backwards, or not reaching the
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desired count in the alloted clock cycles), set this flag to immediately
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fail those other tests without running any timers. */
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static int timers_are_badly_broken = 0;
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/* END_HEADER */
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/* BEGIN_DEPENDENCIES
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* depends_on:MBEDTLS_TIMING_C
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* END_DEPENDENCIES
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*/
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<<<<<<< HEAD
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/* BEGIN_CASE */
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void timing_timer_simple( )
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{
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struct mbedtls_timing_hr_time timer;
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unsigned long millis = 0;
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unsigned long new_millis = 0;
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unsigned long iterations = 0;
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/* Start the timer. */
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(void) mbedtls_timing_get_timer( &timer, 1 );
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/* Busy-wait loop for a few milliseconds. */
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do
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{
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new_millis = mbedtls_timing_get_timer( &timer, 0 );
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++iterations;
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/* Check that the timer didn't go backwards */
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TEST_ASSERT( new_millis >= millis );
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millis = new_millis;
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}
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while( millis < TIMING_SHORT_TEST_MS &&
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iterations <= TIMING_SHORT_TEST_ITERATIONS_MAX );
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/* The wait duration should have been large enough for at least a
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few runs through the loop, even on the slowest realistic platform. */
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TEST_ASSERT( iterations >= 2 );
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/* The wait duration shouldn't have overflowed the iteration count. */
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TEST_ASSERT( iterations < TIMING_SHORT_TEST_ITERATIONS_MAX );
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return;
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exit:
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if( iterations >= TIMING_SHORT_TEST_ITERATIONS_MAX ||
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new_millis < millis )
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{
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/* The timer was very unreliable: it didn't increment and the loop ran
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out, or it went backwards. Other tests that use timers might go
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into an infinite loop, so we'll skip them. */
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timers_are_badly_broken = 1;
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}
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/* No cleanup needed, but show some diagnostic iterations, because timing
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problems can be hard to reproduce. */
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mbedtls_fprintf( stdout, " Finished with millis=%lu new_millis=%lu get(timer)<=%lu iterations=%lu\n",
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millis, new_millis, mbedtls_timing_get_timer( &timer, 0 ),
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iterations );
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}
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/* END_CASE */
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/* BEGIN_CASE */
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void timing_timer_reset( )
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{
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struct mbedtls_timing_hr_time timer;
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unsigned long millis = 0;
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unsigned long iterations = 0;
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/* Skip this test if it looks like timers don't work at all, to avoid an
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infinite loop below. */
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TEST_ASSERT( !timers_are_badly_broken );
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/* Start the timer. Timers are always reset to 0. */
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TEST_ASSERT( mbedtls_timing_get_timer( &timer, 1 ) == 0 );
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/* Busy-wait loop for a few milliseconds */
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do
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{
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++iterations;
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millis = mbedtls_timing_get_timer( &timer, 0 );
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}
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while( millis < TIMING_SHORT_TEST_MS );
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/* Reset the timer and check that it has restarted. */
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TEST_ASSERT( mbedtls_timing_get_timer( &timer, 1 ) == 0 );
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/* Read the timer immediately after reset. It should be 0 or close
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to it. */
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TEST_ASSERT( mbedtls_timing_get_timer( &timer, 0 ) < TIMING_SHORT_TEST_MS );
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return;
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exit:
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/* No cleanup needed, but show some diagnostic information, because timing
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problems can be hard to reproduce. */
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if( !timers_are_badly_broken )
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mbedtls_fprintf( stdout, " Finished with millis=%lu get(timer)<=%lu iterations=%lu\n",
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millis, mbedtls_timing_get_timer( &timer, 0 ),
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iterations );
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}
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/* END_CASE */
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/* BEGIN_CASE */
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void timing_two_timers( int delta )
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{
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struct mbedtls_timing_hr_time timer1, timer2;
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unsigned long millis1 = 0, millis2 = 0;
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/* Skip this test if it looks like timers don't work at all, to avoid an
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infinite loop below. */
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TEST_ASSERT( !timers_are_badly_broken );
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/* Start the first timer and wait for a short time. */
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(void) mbedtls_timing_get_timer( &timer1, 1 );
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do
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{
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millis1 = mbedtls_timing_get_timer( &timer1, 0 );
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}
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while( millis1 < TIMING_SHORT_TEST_MS );
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/* Do a short busy-wait, so that the difference between timer1 and timer2
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doesn't practically always end up being very close to a whole number of
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milliseconds. */
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while( delta > 0 )
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--delta;
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/* Start the second timer and compare it with the first. */
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mbedtls_timing_get_timer( &timer2, 1 );
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do
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{
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millis1 = mbedtls_timing_get_timer( &timer1, 0 );
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millis2 = mbedtls_timing_get_timer( &timer2, 0 );
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/* The first timer should always be ahead of the first. */
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TEST_ASSERT( millis1 > millis2 );
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/* The timers shouldn't drift apart, i.e. millis2-millis1 should stay
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roughly constant, but this is hard to test reliably, especially in
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a busy environment such as an overloaded continuous integration
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system, so we don't test it it. */
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}
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while( millis2 < TIMING_SHORT_TEST_MS );
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return;
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exit:
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/* No cleanup needed, but show some diagnostic iterations, because timing
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problems can be hard to reproduce. */
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if( !timers_are_badly_broken )
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mbedtls_fprintf( stdout, " Finished with millis1=%lu get(timer1)<=%lu millis2=%lu get(timer2)<=%lu\n",
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millis1, mbedtls_timing_get_timer( &timer1, 0 ),
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millis2, mbedtls_timing_get_timer( &timer2, 0 ) );
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}
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/* END_CASE */
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/* BEGIN_CASE */
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void timing_alarm( int seconds )
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{
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struct mbedtls_timing_hr_time timer;
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unsigned long millis = 0;
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/* We check that about the desired number of seconds has elapsed. Be
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slightly liberal with the lower bound, so as to allow platforms where
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the alarm (with second resolution) and the timer (with millisecond
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resolution) are based on different clocks. Be very liberal with the
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upper bound, because the platform might be busy. */
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unsigned long millis_min = ( seconds > 0 ?
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seconds * 900 :
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0 );
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unsigned long millis_max = ( seconds > 0 ?
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seconds * 1100 + 400 :
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TIMING_ALARM_0_DELAY_MS );
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unsigned long iterations = 0;
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/* Skip this test if it looks like timers don't work at all, to avoid an
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infinite loop below. */
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TEST_ASSERT( !timers_are_badly_broken );
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/* Set an alarm and count how long it takes with a timer. */
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(void) mbedtls_timing_get_timer( &timer, 1 );
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mbedtls_set_alarm( seconds );
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if( seconds > 0 )
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{
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/* We set the alarm for at least 1 second. It should not have fired
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immediately, even on a slow and busy platform. */
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TEST_ASSERT( !mbedtls_timing_alarmed );
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}
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/* A 0-second alarm should fire quickly, but we don't guarantee that it
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fires immediately, so mbedtls_timing_alarmed may or may not be set at
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this point. */
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/* Busy-wait until the alarm rings */
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do
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{
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++iterations;
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millis = mbedtls_timing_get_timer( &timer, 0 );
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}
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while( !mbedtls_timing_alarmed && millis <= millis_max );
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TEST_ASSERT( mbedtls_timing_alarmed );
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TEST_ASSERT( millis >= millis_min );
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TEST_ASSERT( millis <= millis_max );
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mbedtls_timing_alarmed = 0;
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return;
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exit:
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/* Show some diagnostic iterations, because timing
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problems can be hard to reproduce. */
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if( !timers_are_badly_broken )
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mbedtls_fprintf( stdout, " Finished with alarmed=%d millis=%lu get(timer)<=%lu iterations=%lu\n",
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mbedtls_timing_alarmed,
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millis, mbedtls_timing_get_timer( &timer, 0 ),
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iterations );
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/* Cleanup */
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mbedtls_timing_alarmed = 0;
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}
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/* END_CASE */
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/* BEGIN_CASE */
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void timing_delay( int int_ms, int fin_ms )
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{
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/* This function assumes that if int_ms is nonzero then it is large
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enough that we have time to read all timers at least once in an
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interval of time lasting int_ms milliseconds, and likewise for (fin_ms
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- int_ms). So don't call it with arguments that are too small. */
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mbedtls_timing_delay_context delay;
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struct mbedtls_timing_hr_time timer;
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unsigned long delta = 0; /* delay started between timer=0 and timer=delta */
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unsigned long before = 0, after = 0;
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unsigned long iterations = 0;
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int status = -2;
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int saw_status_1 = 0;
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int warn_inconclusive = 0;
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assert( int_ms >= 0 );
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assert( fin_ms >= 0 );
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/* Skip this test if it looks like timers don't work at all, to avoid an
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infinite loop below. */
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TEST_ASSERT( !timers_are_badly_broken );
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/* Start a reference timer. Program a delay, and verify that the status of
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the delay is consistent with the time given by the reference timer. */
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(void) mbedtls_timing_get_timer( &timer, 1 );
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mbedtls_timing_set_delay( &delay, int_ms, fin_ms );
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/* Set delta to an upper bound for the interval between the start of timer
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and the start of delay. Reading timer after starting delay gives us an
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upper bound for the interval, rounded to a 1ms precision. Since this
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might have been rounded down, but we need an upper bound, we add 1. */
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delta = mbedtls_timing_get_timer( &timer, 0 ) + 1;
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status = mbedtls_timing_get_delay( &delay );
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if( fin_ms == 0 )
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{
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/* Cancelled timer. Just check the correct status for this case. */
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TEST_ASSERT( status == -1 );
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return;
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}
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/* Initially, none of the delays must be passed yet if they're nonzero.
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This could fail for very small values of int_ms and fin_ms, where "very
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small" depends how fast and how busy the platform is. */
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if( int_ms > 0 )
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{
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TEST_ASSERT( status == 0 );
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}
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else
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{
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TEST_ASSERT( status == 1 );
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}
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do
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{
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unsigned long delay_min, delay_max;
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int status_min, status_max;
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++iterations;
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before = mbedtls_timing_get_timer( &timer, 0 );
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status = mbedtls_timing_get_delay( &delay );
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after = mbedtls_timing_get_timer( &timer, 0 );
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/* At a time between before and after, the delay's status was status.
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Check that this is consistent given that the delay was started
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between times 0 and delta. */
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delay_min = ( before > delta ? before - delta : 0 );
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status_min = expected_delay_status( int_ms, fin_ms, delay_min );
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delay_max = after;
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status_max = expected_delay_status( int_ms, fin_ms, delay_max );
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TEST_ASSERT( status >= status_min );
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TEST_ASSERT( status <= status_max );
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if( status == 1 )
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saw_status_1 = 1;
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}
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while ( before <= fin_ms + delta && status != 2 );
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/* Since we've waited at least fin_ms, the delay must have fully
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expired. */
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TEST_ASSERT( status == 2 );
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/* If the second delay is more than the first, then there must have been a
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point in time when the first delay was passed but not the second delay.
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This could fail for very small values of (fin_ms - int_ms), where "very
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small" depends how fast and how busy the platform is. In practice, this
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is the test that's most likely to fail on a heavily loaded machine. */
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if( fin_ms > int_ms )
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{
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warn_inconclusive = 1;
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TEST_ASSERT( saw_status_1 );
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}
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return;
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exit:
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/* No cleanup needed, but show some diagnostic iterations, because timing
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problems can be hard to reproduce. */
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if( !timers_are_badly_broken )
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mbedtls_fprintf( stdout, " Finished with delta=%lu before=%lu after=%lu status=%d iterations=%lu\n",
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delta, before, after, status, iterations );
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if( warn_inconclusive )
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mbedtls_fprintf( stdout, " Inconclusive test, try running it on a less heavily loaded machine.\n" );
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}
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/* END_CASE */
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/* BEGIN_CASE */
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void timing_hardclock( )
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{
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/* We make very few guarantees about mbedtls_timing_hardclock: its rate is
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platform-dependent, it can wrap around. So there isn't much we can
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test. But we do at least test that it doesn't crash, stall or return
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completely nonsensical values. */
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struct mbedtls_timing_hr_time timer;
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unsigned long hardclock0 = -1, hardclock1 = -1, delta1 = -1;
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/* Skip this test if it looks like timers don't work at all, to avoid an
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infinite loop below. */
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TEST_ASSERT( !timers_are_badly_broken );
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hardclock0 = mbedtls_timing_hardclock( );
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/* Wait 2ms to ensure a nonzero delay. Since the timer interface has 1ms
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resolution and unspecified precision, waiting 1ms might be a very small
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delay that's rounded up. */
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(void) mbedtls_timing_get_timer( &timer, 1 );
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while( mbedtls_timing_get_timer( &timer, 0 ) < 2 )
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/*busy-wait loop*/;
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hardclock1 = mbedtls_timing_hardclock( );
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/* Although the hardclock counter can wrap around, the difference
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(hardclock1 - hardclock0) is taken modulo the type size, so it is
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correct as long as the counter only wrapped around at most once. We
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further require the difference to be nonzero (after a wait of more than
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1ms, the counter must have changed), and not to be overly large (after
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a wait of less than 3ms, plus time lost because other processes were
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scheduled on the CPU). If the hardclock counter runs at 4GHz, then
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1000000000 (which is 1/4 of the counter wraparound on a 32-bit machine)
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allows 250ms. */
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delta1 = hardclock1 - hardclock0;
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TEST_ASSERT( delta1 > 0 );
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TEST_ASSERT( delta1 < 1000000000 );
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return;
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exit:
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/* No cleanup needed, but show some diagnostic iterations, because timing
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problems can be hard to reproduce. */
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if( !timers_are_badly_broken )
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mbedtls_fprintf( stdout, " Finished with hardclock=%lu,%lu\n",
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hardclock0, hardclock1 );
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}
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/* END_CASE */
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