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@ -150,8 +150,37 @@ void calibrate_delay_loop(); |
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#endif |
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// Delay in nanoseconds
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#define DELAY_NS(x) DELAY_CYCLES((x) * ((F_CPU) / 1000000UL) / 1000UL) |
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/**************************************************************
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* Delay in nanoseconds. Requires the F_CPU macro. |
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* These macros follow avr-libc delay conventions. |
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* |
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* For AVR there are three possible operation modes, due to its |
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* slower clock speeds and thus coarser delay resolution. For |
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* example, when F_CPU = 16000000 the resolution is 62.5ns. |
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* |
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* Round up (default) |
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* Round up the delay according to the CPU clock resolution. |
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* e.g., 100 will give a delay of 2 cycles (125ns). |
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* |
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* Round down (DELAY_NS_ROUND_DOWN) |
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* Round down the delay according to the CPU clock resolution. |
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* e.g., 100 will be rounded down to 1 cycle (62.5ns). |
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* |
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* Nearest (DELAY_NS_ROUND_CLOSEST) |
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* Round the delay to the nearest number of clock cycles. |
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* e.g., 165 will be rounded up to 3 cycles (187.5ns) because |
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* it's closer to the requested delay than 2 cycle (125ns). |
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*/ |
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#ifndef __AVR__ |
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#undef DELAY_NS_ROUND_DOWN |
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#undef DELAY_NS_ROUND_CLOSEST |
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#endif |
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#if ENABLED(DELAY_NS_ROUND_DOWN) |
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#define DELAY_NS(x) DELAY_CYCLES((x) * ((F_CPU) / 1000000UL) / 1000UL) // floor
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#elif ENABLED(DELAY_NS_ROUND_CLOSEST) |
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#define DELAY_NS(x) DELAY_CYCLES(((x) * ((F_CPU) / 1000000UL) + 500) / 1000UL) // round
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#else |
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#define DELAY_NS(x) DELAY_CYCLES(((x) * ((F_CPU) / 1000000UL) + 999) / 1000UL) // "ceil"
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#endif |
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Mike La Spina
4 years ago
Scott Lahteine