Provided by: avr-libc_2.0.0+Atmel3.6.0-1_all bug

NAME

       util_delay

SYNOPSIS

   Macros
       #define F_CPU   1000000UL

   Functions
       void _delay_ms (double __ms)
       void _delay_us (double __us)

Detailed Description

       #define F_CPU 1000000UL  // 1 MHz
       //#define F_CPU 14.7456E6
       #include <util/delay.h>

       Note:
           As an alternative method, it is possible to pass the F_CPU macro down to the compiler
           from the Makefile. Obviously, in that case, no #define statement should be used.

       The functions in this header file are wrappers around the basic busy-wait functions from
       <util/delay_basic.h>. They are meant as convenience functions where actual time values can
       be specified rather than a number of cycles to wait for. The idea behind is that compile-
       time constant expressions will be eliminated by compiler optimization so floating-point
       expressions can be used to calculate the number of delay cycles needed based on the CPU
       frequency passed by the macro F_CPU.

       Note:
           In order for these functions to work as intended, compiler optimizations must be
           enabled, and the delay time must be an expression that is a known constant at compile-
           time. If these requirements are not met, the resulting delay will be much longer (and
           basically unpredictable), and applications that otherwise do not use floating-point
           calculations will experience severe code bloat by the floating-point library routines
           linked into the application.

       The functions available allow the specification of microsecond, and millisecond delays
       directly, using the application-supplied macro F_CPU as the CPU clock frequency (in
       Hertz).

Macro Definition Documentation

   #define F_CPU   1000000UL
       CPU frequency in Hz. The macro F_CPU specifies the CPU frequency to be considered by the
       delay macros. This macro is normally supplied by the environment (e.g. from within a
       project header, or the project's Makefile). The value 1 MHz here is only provided as a
       'vanilla' fallback if no such user-provided definition could be found.

       In terms of the delay functions, the CPU frequency can be given as a floating-point
       constant (e.g. 3.6864E6 for 3.6864 MHz). However, the macros in <util/setbaud.h> require
       it to be an integer value.

Function Documentation

   void _delay_ms (double __ms)
       Perform a delay of __ms milliseconds, using _delay_loop_2().

       The macro F_CPU is supposed to be defined to a constant defining the CPU clock frequency
       (in Hertz).

       The maximal possible delay is 262.14 ms / F_CPU in MHz.

       When the user request delay which exceed the maximum possible one, _delay_ms() provides a
       decreased resolution functionality. In this mode _delay_ms() will work with a resolution
       of 1/10 ms, providing delays up to 6.5535 seconds (independent from CPU frequency). The
       user will not be informed about decreased resolution.

       If the avr-gcc toolchain has __builtin_avr_delay_cycles() support, maximal possible delay
       is 4294967.295 ms/ F_CPU in MHz. For values greater than the maximal possible delay,
       overflows results in no delay i.e., 0ms.

       Conversion of __ms into clock cycles may not always result in integer. By default, the
       clock cycles rounded up to next integer. This ensures that the user gets at least __ms
       microseconds of delay.

       Alternatively, by defining the macro __DELAY_ROUND_DOWN__, or __DELAY_ROUND_CLOSEST__,
       before including this header file, the algorithm can be made to round down, or round to
       closest integer, respectively.

       Note:

       The implementation of _delay_ms() based on __builtin_avr_delay_cycles() is not backward
       compatible with older implementations. In order to get functionality backward compatible
       with previous versions, the macro '__DELAY_BACKWARD_COMPATIBLE__' must be defined before
       including this header file. Also, the backward compatible algorithm will be chosen if the
       code is compiled in a freestanding environment (GCC option -ffreestanding), as the math
       functions required for rounding are not available to the compiler then.

   void _delay_us (double __us)
       Perform a delay of __us microseconds, using _delay_loop_1().

       The macro F_CPU is supposed to be defined to a constant defining the CPU clock frequency
       (in Hertz).

       The maximal possible delay is 768 us / F_CPU in MHz.

       If the user requests a delay greater than the maximal possible one, _delay_us() will
       automatically call _delay_ms() instead. The user will not be informed about this case.

       If the avr-gcc toolchain has __builtin_avr_delay_cycles() support, maximal possible delay
       is 4294967.295 us/ F_CPU in MHz. For values greater than the maximal possible delay,
       overflow results in no delay i.e., 0us.

       Conversion of __us into clock cycles may not always result in integer. By default, the
       clock cycles rounded up to next integer. This ensures that the user gets at least __us
       microseconds of delay.

       Alternatively, by defining the macro __DELAY_ROUND_DOWN__, or __DELAY_ROUND_CLOSEST__,
       before including this header file, the algorithm can be made to round down, or round to
       closest integer, respectively.

       Note:

       The implementation of _delay_ms() based on __builtin_avr_delay_cycles() is not backward
       compatible with older implementations. In order to get functionality backward compatible
       with previous versions, the macro __DELAY_BACKWARD_COMPATIBLE__ must be defined before
       including this header file. Also, the backward compatible algorithm will be chosen if the
       code is compiled in a freestanding environment (GCC option -ffreestanding), as the math
       functions required for rounding are not available to the compiler then.

Author

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