--- libecb/ecb.pod	2012/05/29 14:35:43	1.45
+++ libecb/ecb.pod	2015/01/26 12:04:56	1.59
@@ -62,15 +62,17 @@
 
    int8_t   uint8_t   int16_t  uint16_t
    int32_t  uint32_t  int64_t  uint64_t
-   intptr_t uintptr_t ptrdiff_t
+   intptr_t uintptr_t
 
 The macro C<ECB_PTRSIZE> is defined to the size of a pointer on this
 platform (currently C<4> or C<8>) and can be used in preprocessor
 expressions.
 
+For C<ptrdiff_t> and C<size_t> use C<stddef.h>.
+
 =head2 LANGUAGE/COMPILER VERSIONS
 
-All the following symbols expand to an expressionb that cna be tested in
+All the following symbols expand to an expression that can be tested in
 preprocessor instructions as well as treated as a boolean (use C<!!> to
 ensure it's either C<0> or C<1> if you need that).
 
@@ -79,41 +81,88 @@
 =item ECB_C
 
 True if the implementation defines the C<__STDC__> macro to a true value,
-which is typically true for both C and C++ compilers.
+while not claiming to be C++.
 
 =item ECB_C99
 
-True if the implementation claims to be C99 compliant.
+True if the implementation claims to be compliant to C99 (ISO/IEC
+9899:1999) or any later version, while not claiming to be C++.
+
+Note that later versions (ECB_C11) remove core features again (for
+example, variable length arrays).
 
 =item ECB_C11
 
-True if the implementation claims to be C11 compliant.
+True if the implementation claims to be compliant to C11 (ISO/IEC
+9899:2011) or any later version, while not claiming to be C++.
 
 =item ECB_CPP
 
 True if the implementation defines the C<__cplusplus__> macro to a true
 value, which is typically true for C++ compilers.
 
-=item ECB_CPP98
-
-True if the implementation claims to be compliant to ISO/IEC 14882:1998
-(the first C++ ISO standard) or any later vwersion. Typically true for all
-C++ compilers.
-
 =item ECB_CPP11
 
 True if the implementation claims to be compliant to ISO/IEC 14882:2011
-(C++11) or any later vwersion.
+(C++11) or any later version.
 
-=item ECB_GCC_VERSION(major,minor)
+=item ECB_GCC_VERSION (major, minor)
 
 Expands to a true value (suitable for testing in by the preprocessor)
-if the compiler used is GNU C and the version is the givne version, or
+if the compiler used is GNU C and the version is the given version, or
 higher.
 
 This macro tries to return false on compilers that claim to be GCC
 compatible but aren't.
 
+=item ECB_EXTERN_C
+
+Expands to C<extern "C"> in C++, and a simple C<extern> in C.
+
+This can be used to declare a single external C function:
+
+   ECB_EXTERN_C int printf (const char *format, ...);
+
+=item ECB_EXTERN_C_BEG / ECB_EXTERN_C_END
+
+These two macros can be used to wrap multiple C<extern "C"> definitions -
+they expand to nothing in C.
+
+They are most useful in header files:
+
+   ECB_EXTERN_C_BEG
+
+   int mycfun1 (int x);
+   int mycfun2 (int x);
+
+   ECB_EXTERN_C_END
+
+=item ECB_STDFP
+
+If this evaluates to a true value (suitable for testing in by the
+preprocessor), then C<float> and C<double> use IEEE 754 single/binary32
+and double/binary64 representations internally I<and> the endianness of
+both types match the endianness of C<uint32_t> and C<uint64_t>.
+
+This means you can just copy the bits of a C<float> (or C<double>) to an
+C<uint32_t> (or C<uint64_t>) and get the raw IEEE 754 bit representation
+without having to think about format or endianness.
+
+This is true for basically all modern platforms, although F<ecb.h> might
+not be able to deduce this correctly everywhere and might err on the safe
+side.
+
+=item ECB_AMD64, ECB_AMD64_X32
+
+These two macros are defined to C<1> on the x86_64/amd64 ABI and the X32
+ABI, respectively, and undefined elsewhere.
+
+The designers of the new X32 ABI for some inexplicable reason decided to
+make it look exactly like amd64, even though it's completely incompatible
+to that ABI, breaking about every piece of software that assumed that
+C<__x86_64> stands for, well, the x86-64 ABI, making these macros
+necessary.
+
 =back
 
 =head2 GCC ATTRIBUTES
@@ -138,8 +187,9 @@
 
 =item ecb_attribute ((attrs...))
 
-A simple wrapper that expands to C<__attribute__((attrs))> on GCC, and to
-nothing on other compilers, so the effect is that only GCC sees these.
+A simple wrapper that expands to C<__attribute__((attrs))> on GCC 3.1+ and
+Clang 2.8+, and to nothing on other compilers, so the effect is that only
+GCC and Clang see these.
 
 Example: use the C<deprecated> attribute on a function.
 
@@ -163,6 +213,11 @@
     #endif
   }
 
+=item ecb_deprecated
+
+Similar to C<ecb_unused>, but marks a function, variable or type as
+deprecated. This makes some compilers warn when the type is used.
+
 =item ecb_inline
 
 This is not actually an attribute, but you use it like one. It expands
@@ -200,6 +255,27 @@
 In this case, the compiler would probably be smart enough to deduce it on
 its own, so this is mainly useful for declarations.
 
+=item ecb_restrict
+
+Expands to the C<restrict> keyword or equivalent on compilers that support
+them, and to nothing on others. Must be specified on a pointer type or
+an array index to indicate that the memory doesn't alias with any other
+restricted pointer in the same scope.
+
+Example: multiply a vector, and allow the compiler to parallelise the
+loop, because it knows it doesn't overwrite input values.
+
+   void
+   multiply (float *ecb_restrict src,
+             float *ecb_restrict dst,
+             int len, float factor)
+   {
+     int i;
+
+     for (i = 0; i < len; ++i)
+       dst [i] = src [i] * factor;
+   }
+
 =item ecb_const
 
 Declares that the function only depends on the values of its arguments,
@@ -269,7 +345,7 @@
 =item ecb_artificial
 
 Declares the function as "artificial", in this case meaning that this
-function is not really mean to be a function, but more like an accessor
+function is not really meant to be a function, but more like an accessor
 - many methods in C++ classes are mere accessor functions, and having a
 crash reported in such a method, or single-stepping through them, is not
 usually so helpful, especially when it's inlined to just a few instructions.
@@ -299,7 +375,7 @@
 
 =over 4
 
-=item bool ecb_is_constant(expr)
+=item bool ecb_is_constant (expr)
 
 Returns true iff the expression can be deduced to be a compile-time
 constant, and false otherwise.
@@ -575,6 +651,63 @@
 
 =back
 
+=head2 FLOATING POINT FIDDLING
+
+=over 4
+
+=item uint32_t ecb_float_to_binary32  (float  x) [-UECB_NO_LIBM]
+
+=item uint64_t ecb_double_to_binary64 (double x) [-UECB_NO_LIBM]
+
+These functions each take an argument in the native C<float> or C<double>
+type and return the IEEE 754 bit representation of it.
+
+The bit representation is just as IEEE 754 defines it, i.e. the sign bit
+will be the most significant bit, followed by exponent and mantissa.
+
+This function should work even when the native floating point format isn't
+IEEE compliant, of course at a speed and code size penalty, and of course
+also within reasonable limits (it tries to convert NaNs, infinities and
+denormals, but will likely convert negative zero to positive zero).
+
+On all modern platforms (where C<ECB_STDFP> is true), the compiler should
+be able to optimise away this function completely.
+
+These functions can be helpful when serialising floats to the network - you
+can serialise the return value like a normal uint32_t/uint64_t.
+
+Another use for these functions is to manipulate floating point values
+directly.
+
+Silly example: toggle the sign bit of a float.
+
+   /* On gcc-4.7 on amd64, */
+   /* this results in a single add instruction to toggle the bit, and 4 extra */
+   /* instructions to move the float value to an integer register and back. */
+
+   x = ecb_binary32_to_float (ecb_float_to_binary32 (x) ^ 0x80000000U)
+
+=item float  ecb_binary16_to_float  (uint16_t x) [-UECB_NO_LIBM]
+
+=item float  ecb_binary32_to_float  (uint32_t x) [-UECB_NO_LIBM]
+
+=item double ecb_binary32_to_double (uint64_t x) [-UECB_NO_LIBM]
+
+The reverse operation of the previous function - takes the bit
+representation of an IEEE binary16, binary32 or binary64 number and
+converts it to the native C<float> or C<double> format.
+
+This function should work even when the native floating point format isn't
+IEEE compliant, of course at a speed and code size penalty, and of course
+also within reasonable limits (it tries to convert normals and denormals,
+and might be lucky for infinities, and with extraordinary luck, also for
+negative zero).
+
+On all modern platforms (where C<ECB_STDFP> is true), the compiler should
+be able to optimise away this function completely.
+
+=back
+
 =head2 ARITHMETIC
 
 =over 4
@@ -638,7 +771,7 @@
 
 =over 4
 
-=item ECB_NO_THRADS
+=item ECB_NO_THREADS
 
 If F<ecb.h> is never used from multiple threads, then this symbol can
 be defined, in which case memory fences (and similar constructs) are
@@ -654,6 +787,12 @@
 on), then this symbol can be defined, leading to more efficient code and
 fewer dependencies.
 
+=item ECB_NO_LIBM
+
+When defined to C<1>, do not export any functions that might introduce
+dependencies on the math library (usually called F<-lm>) - these are
+marked with [-UECB_NO_LIBM].
+
 =back