| … | |
… | |
| 53 | C<uint32_t>, then the corresponding function works only with that type. If |
53 | C<uint32_t>, then the corresponding function works only with that type. If |
| 54 | only a generic name is used (C<expr>, C<cond>, C<value> and so on), then |
54 | only a generic name is used (C<expr>, C<cond>, C<value> and so on), then |
| 55 | the corresponding function relies on C to implement the correct types, and |
55 | the corresponding function relies on C to implement the correct types, and |
| 56 | is usually implemented as a macro. Specifically, a "bool" in this manual |
56 | is usually implemented as a macro. Specifically, a "bool" in this manual |
| 57 | refers to any kind of boolean value, not a specific type. |
57 | refers to any kind of boolean value, not a specific type. |
|
|
58 | |
|
|
59 | =head2 TYPES / TYPE SUPPORT |
|
|
60 | |
|
|
61 | ecb.h makes sure that the following types are defined (in the expected way): |
|
|
62 | |
|
|
63 | int8_t uint8_t int16_t uint16_t |
|
|
64 | int32_t uint32_t int64_t uint64_t |
|
|
65 | intptr_t uintptr_t |
|
|
66 | |
|
|
67 | The macro C<ECB_PTRSIZE> is defined to the size of a pointer on this |
|
|
68 | platform (currently C<4> or C<8>) and can be used in preprocessor |
|
|
69 | expressions. |
|
|
70 | |
|
|
71 | For C<ptrdiff_t> and C<size_t> use C<stddef.h>. |
|
|
72 | |
|
|
73 | =head2 LANGUAGE/COMPILER VERSIONS |
|
|
74 | |
|
|
75 | All the following symbols expand to an expression that can be tested in |
|
|
76 | preprocessor instructions as well as treated as a boolean (use C<!!> to |
|
|
77 | ensure it's either C<0> or C<1> if you need that). |
|
|
78 | |
|
|
79 | =over 4 |
|
|
80 | |
|
|
81 | =item ECB_C |
|
|
82 | |
|
|
83 | True if the implementation defines the C<__STDC__> macro to a true value, |
|
|
84 | while not claiming to be C++. |
|
|
85 | |
|
|
86 | =item ECB_C99 |
|
|
87 | |
|
|
88 | True if the implementation claims to be compliant to C99 (ISO/IEC |
|
|
89 | 9899:1999) or any later version, while not claiming to be C++. |
|
|
90 | |
|
|
91 | Note that later versions (ECB_C11) remove core features again (for |
|
|
92 | example, variable length arrays). |
|
|
93 | |
|
|
94 | =item ECB_C11 |
|
|
95 | |
|
|
96 | True if the implementation claims to be compliant to C11 (ISO/IEC |
|
|
97 | 9899:2011) or any later version, while not claiming to be C++. |
|
|
98 | |
|
|
99 | =item ECB_CPP |
|
|
100 | |
|
|
101 | True if the implementation defines the C<__cplusplus__> macro to a true |
|
|
102 | value, which is typically true for C++ compilers. |
|
|
103 | |
|
|
104 | =item ECB_CPP11 |
|
|
105 | |
|
|
106 | True if the implementation claims to be compliant to ISO/IEC 14882:2011 |
|
|
107 | (C++11) or any later version. |
|
|
108 | |
|
|
109 | =item ECB_GCC_VERSION(major,minor) |
|
|
110 | |
|
|
111 | Expands to a true value (suitable for testing in by the preprocessor) |
|
|
112 | if the compiler used is GNU C and the version is the given version, or |
|
|
113 | higher. |
|
|
114 | |
|
|
115 | This macro tries to return false on compilers that claim to be GCC |
|
|
116 | compatible but aren't. |
|
|
117 | |
|
|
118 | =item ECB_EXTERN_C |
|
|
119 | |
|
|
120 | Expands to C<extern "C"> in C++, and a simple C<extern> in C. |
|
|
121 | |
|
|
122 | This can be used to declare a single external C function: |
|
|
123 | |
|
|
124 | ECB_EXTERN_C int printf (const char *format, ...); |
|
|
125 | |
|
|
126 | =item ECB_EXTERN_C_BEG / ECB_EXTERN_C_END |
|
|
127 | |
|
|
128 | These two macros can be used to wrap multiple C<extern "C"> definitions - |
|
|
129 | they expand to nothing in C. |
|
|
130 | |
|
|
131 | They are most useful in header files: |
|
|
132 | |
|
|
133 | ECB_EXTERN_C_BEG |
|
|
134 | |
|
|
135 | int mycfun1 (int x); |
|
|
136 | int mycfun2 (int x); |
|
|
137 | |
|
|
138 | ECB_EXTERN_C_END |
|
|
139 | |
|
|
140 | =item ECB_STDFP |
|
|
141 | |
|
|
142 | If this evaluates to a true value (suitable for testing in by the |
|
|
143 | preprocessor), then C<float> and C<double> use IEEE 754 single/binary32 |
|
|
144 | and double/binary64 representations internally I<and> the endianness of |
|
|
145 | both types match the endianness of C<uint32_t> and C<uint64_t>. |
|
|
146 | |
|
|
147 | This means you can just copy the bits of a C<float> (or C<double>) to an |
|
|
148 | C<uint32_t> (or C<uint64_t>) and get the raw IEEE 754 bit representation |
|
|
149 | without having to think about format or endianness. |
|
|
150 | |
|
|
151 | This is true for basically all modern platforms, although F<ecb.h> might |
|
|
152 | not be able to deduce this correctly everywhere and might err on the safe |
|
|
153 | side. |
|
|
154 | |
|
|
155 | =item ECB_AMD64, ECB_AMD64_X32 |
|
|
156 | |
|
|
157 | These two macros are defined to C<1> on the x86_64/amd64 ABI and the X32 |
|
|
158 | ABI, respectively, and undefined elsewhere. |
|
|
159 | |
|
|
160 | The designers of the new X32 ABI for some inexplicable reason decided to |
|
|
161 | make it look exactly like amd64, even though it's completely incompatible |
|
|
162 | to that ABI, breaking about every piece of software that assumed that |
|
|
163 | C<__x86_64> stands for, well, the x86-64 ABI, making these macros |
|
|
164 | necessary. |
|
|
165 | |
|
|
166 | =back |
| 58 | |
167 | |
| 59 | =head2 GCC ATTRIBUTES |
168 | =head2 GCC ATTRIBUTES |
| 60 | |
169 | |
| 61 | A major part of libecb deals with GCC attributes. These are additional |
170 | A major part of libecb deals with GCC attributes. These are additional |
| 62 | attributes that you can assign to functions, variables and sometimes even |
171 | attributes that you can assign to functions, variables and sometimes even |
| … | |
… | |
| 138 | } |
247 | } |
| 139 | |
248 | |
| 140 | In this case, the compiler would probably be smart enough to deduce it on |
249 | In this case, the compiler would probably be smart enough to deduce it on |
| 141 | its own, so this is mainly useful for declarations. |
250 | its own, so this is mainly useful for declarations. |
| 142 | |
251 | |
|
|
252 | =item ecb_restrict |
|
|
253 | |
|
|
254 | Expands to the C<restrict> keyword or equivalent on compilers that support |
|
|
255 | them, and to nothing on others. Must be specified on a pointer type or |
|
|
256 | an array index to indicate that the memory doesn't alias with any other |
|
|
257 | restricted pointer in the same scope. |
|
|
258 | |
|
|
259 | Example: multiply a vector, and allow the compiler to parallelise the |
|
|
260 | loop, because it knows it doesn't overwrite input values. |
|
|
261 | |
|
|
262 | void |
|
|
263 | multiply (float *ecb_restrict src, |
|
|
264 | float *ecb_restrict dst, |
|
|
265 | int len, float factor) |
|
|
266 | { |
|
|
267 | int i; |
|
|
268 | |
|
|
269 | for (i = 0; i < len; ++i) |
|
|
270 | dst [i] = src [i] * factor; |
|
|
271 | } |
|
|
272 | |
| 143 | =item ecb_const |
273 | =item ecb_const |
| 144 | |
274 | |
| 145 | Declares that the function only depends on the values of its arguments, |
275 | Declares that the function only depends on the values of its arguments, |
| 146 | much like a mathematical function. It specifically does not read or write |
276 | much like a mathematical function. It specifically does not read or write |
| 147 | any memory any arguments might point to, global variables, or call any |
277 | any memory any arguments might point to, global variables, or call any |
| … | |
… | |
| 207 | functions only called in exceptional or rare cases. |
337 | functions only called in exceptional or rare cases. |
| 208 | |
338 | |
| 209 | =item ecb_artificial |
339 | =item ecb_artificial |
| 210 | |
340 | |
| 211 | Declares the function as "artificial", in this case meaning that this |
341 | Declares the function as "artificial", in this case meaning that this |
| 212 | function is not really mean to be a function, but more like an accessor |
342 | function is not really meant to be a function, but more like an accessor |
| 213 | - many methods in C++ classes are mere accessor functions, and having a |
343 | - many methods in C++ classes are mere accessor functions, and having a |
| 214 | crash reported in such a method, or single-stepping through them, is not |
344 | crash reported in such a method, or single-stepping through them, is not |
| 215 | usually so helpful, especially when it's inlined to just a few instructions. |
345 | usually so helpful, especially when it's inlined to just a few instructions. |
| 216 | |
346 | |
| 217 | Marking them as artificial will instruct the debugger about just this, |
347 | Marking them as artificial will instruct the debugger about just this, |
| … | |
… | |
| 396 | After processing the node, (part of) the next node might already be in |
526 | After processing the node, (part of) the next node might already be in |
| 397 | cache. |
527 | cache. |
| 398 | |
528 | |
| 399 | =back |
529 | =back |
| 400 | |
530 | |
| 401 | =head2 BIT FIDDLING / BITSTUFFS |
531 | =head2 BIT FIDDLING / BIT WIZARDRY |
| 402 | |
532 | |
| 403 | =over 4 |
533 | =over 4 |
| 404 | |
534 | |
| 405 | =item bool ecb_big_endian () |
535 | =item bool ecb_big_endian () |
| 406 | |
536 | |
| … | |
… | |
| 412 | |
542 | |
| 413 | On systems that are neither, their return values are unspecified. |
543 | On systems that are neither, their return values are unspecified. |
| 414 | |
544 | |
| 415 | =item int ecb_ctz32 (uint32_t x) |
545 | =item int ecb_ctz32 (uint32_t x) |
| 416 | |
546 | |
|
|
547 | =item int ecb_ctz64 (uint64_t x) |
|
|
548 | |
| 417 | Returns the index of the least significant bit set in C<x> (or |
549 | Returns the index of the least significant bit set in C<x> (or |
| 418 | equivalently the number of bits set to 0 before the least significant bit |
550 | equivalently the number of bits set to 0 before the least significant bit |
| 419 | set), starting from 0. If C<x> is 0 the result is undefined. For example: |
551 | set), starting from 0. If C<x> is 0 the result is undefined. |
|
|
552 | |
|
|
553 | For smaller types than C<uint32_t> you can safely use C<ecb_ctz32>. |
|
|
554 | |
|
|
555 | For example: |
| 420 | |
556 | |
| 421 | ecb_ctz32 (3) = 0 |
557 | ecb_ctz32 (3) = 0 |
| 422 | ecb_ctz32 (6) = 1 |
558 | ecb_ctz32 (6) = 1 |
| 423 | |
559 | |
|
|
560 | =item bool ecb_is_pot32 (uint32_t x) |
|
|
561 | |
|
|
562 | =item bool ecb_is_pot64 (uint32_t x) |
|
|
563 | |
|
|
564 | Return true iff C<x> is a power of two or C<x == 0>. |
|
|
565 | |
|
|
566 | For smaller types then C<uint32_t> you can safely use C<ecb_is_pot32>. |
|
|
567 | |
|
|
568 | =item int ecb_ld32 (uint32_t x) |
|
|
569 | |
|
|
570 | =item int ecb_ld64 (uint64_t x) |
|
|
571 | |
|
|
572 | Returns the index of the most significant bit set in C<x>, or the number |
|
|
573 | of digits the number requires in binary (so that C<< 2**ld <= x < |
|
|
574 | 2**(ld+1) >>). If C<x> is 0 the result is undefined. A common use case is |
|
|
575 | to compute the integer binary logarithm, i.e. C<floor (log2 (n))>, for |
|
|
576 | example to see how many bits a certain number requires to be encoded. |
|
|
577 | |
|
|
578 | This function is similar to the "count leading zero bits" function, except |
|
|
579 | that that one returns how many zero bits are "in front" of the number (in |
|
|
580 | the given data type), while C<ecb_ld> returns how many bits the number |
|
|
581 | itself requires. |
|
|
582 | |
|
|
583 | For smaller types than C<uint32_t> you can safely use C<ecb_ld32>. |
|
|
584 | |
| 424 | =item int ecb_popcount32 (uint32_t x) |
585 | =item int ecb_popcount32 (uint32_t x) |
| 425 | |
586 | |
|
|
587 | =item int ecb_popcount64 (uint64_t x) |
|
|
588 | |
| 426 | Returns the number of bits set to 1 in C<x>. For example: |
589 | Returns the number of bits set to 1 in C<x>. |
|
|
590 | |
|
|
591 | For smaller types than C<uint32_t> you can safely use C<ecb_popcount32>. |
|
|
592 | |
|
|
593 | For example: |
| 427 | |
594 | |
| 428 | ecb_popcount32 (7) = 3 |
595 | ecb_popcount32 (7) = 3 |
| 429 | ecb_popcount32 (255) = 8 |
596 | ecb_popcount32 (255) = 8 |
| 430 | |
597 | |
|
|
598 | =item uint8_t ecb_bitrev8 (uint8_t x) |
|
|
599 | |
|
|
600 | =item uint16_t ecb_bitrev16 (uint16_t x) |
|
|
601 | |
|
|
602 | =item uint32_t ecb_bitrev32 (uint32_t x) |
|
|
603 | |
|
|
604 | Reverses the bits in x, i.e. the MSB becomes the LSB, MSB-1 becomes LSB+1 |
|
|
605 | and so on. |
|
|
606 | |
|
|
607 | Example: |
|
|
608 | |
|
|
609 | ecb_bitrev8 (0xa7) = 0xea |
|
|
610 | ecb_bitrev32 (0xffcc4411) = 0x882233ff |
|
|
611 | |
| 431 | =item uint32_t ecb_bswap16 (uint32_t x) |
612 | =item uint32_t ecb_bswap16 (uint32_t x) |
| 432 | |
613 | |
| 433 | =item uint32_t ecb_bswap32 (uint32_t x) |
614 | =item uint32_t ecb_bswap32 (uint32_t x) |
| 434 | |
615 | |
|
|
616 | =item uint64_t ecb_bswap64 (uint64_t x) |
|
|
617 | |
| 435 | These two functions return the value of the 16-bit (32-bit) value C<x> |
618 | These functions return the value of the 16-bit (32-bit, 64-bit) value |
| 436 | after reversing the order of bytes (0x11223344 becomes 0x44332211). |
619 | C<x> after reversing the order of bytes (0x11223344 becomes 0x44332211 in |
|
|
620 | C<ecb_bswap32>). |
|
|
621 | |
|
|
622 | =item uint8_t ecb_rotl8 (uint8_t x, unsigned int count) |
|
|
623 | |
|
|
624 | =item uint16_t ecb_rotl16 (uint16_t x, unsigned int count) |
|
|
625 | |
|
|
626 | =item uint32_t ecb_rotl32 (uint32_t x, unsigned int count) |
|
|
627 | |
|
|
628 | =item uint64_t ecb_rotl64 (uint64_t x, unsigned int count) |
|
|
629 | |
|
|
630 | =item uint8_t ecb_rotr8 (uint8_t x, unsigned int count) |
|
|
631 | |
|
|
632 | =item uint16_t ecb_rotr16 (uint16_t x, unsigned int count) |
| 437 | |
633 | |
| 438 | =item uint32_t ecb_rotr32 (uint32_t x, unsigned int count) |
634 | =item uint32_t ecb_rotr32 (uint32_t x, unsigned int count) |
| 439 | |
635 | |
| 440 | =item uint32_t ecb_rotl32 (uint32_t x, unsigned int count) |
636 | =item uint64_t ecb_rotr64 (uint64_t x, unsigned int count) |
| 441 | |
637 | |
| 442 | These two functions return the value of C<x> after rotating all the bits |
638 | These two families of functions return the value of C<x> after rotating |
| 443 | by C<count> positions to the right or left respectively. |
639 | all the bits by C<count> positions to the right (C<ecb_rotr>) or left |
|
|
640 | (C<ecb_rotl>). |
| 444 | |
641 | |
| 445 | Current GCC versions understand these functions and usually compile them |
642 | Current GCC versions understand these functions and usually compile them |
| 446 | to "optimal" code (e.g. a single C<roll> on x86). |
643 | to "optimal" code (e.g. a single C<rol> or a combination of C<shld> on |
|
|
644 | x86). |
|
|
645 | |
|
|
646 | =back |
|
|
647 | |
|
|
648 | =head2 FLOATING POINT FIDDLING |
|
|
649 | |
|
|
650 | =over 4 |
|
|
651 | |
|
|
652 | =item uint32_t ecb_float_to_binary32 (float x) [-UECB_NO_LIBM] |
|
|
653 | |
|
|
654 | =item uint64_t ecb_double_to_binary64 (double x) [-UECB_NO_LIBM] |
|
|
655 | |
|
|
656 | These functions each take an argument in the native C<float> or C<double> |
|
|
657 | type and return the IEEE 754 bit representation of it. |
|
|
658 | |
|
|
659 | The bit representation is just as IEEE 754 defines it, i.e. the sign bit |
|
|
660 | will be the most significant bit, followed by exponent and mantissa. |
|
|
661 | |
|
|
662 | This function should work even when the native floating point format isn't |
|
|
663 | IEEE compliant, of course at a speed and code size penalty, and of course |
|
|
664 | also within reasonable limits (it tries to convert NaNs, infinities and |
|
|
665 | denormals, but will likely convert negative zero to positive zero). |
|
|
666 | |
|
|
667 | On all modern platforms (where C<ECB_STDFP> is true), the compiler should |
|
|
668 | be able to optimise away this function completely. |
|
|
669 | |
|
|
670 | These functions can be helpful when serialising floats to the network - you |
|
|
671 | can serialise the return value like a normal uint32_t/uint64_t. |
|
|
672 | |
|
|
673 | Another use for these functions is to manipulate floating point values |
|
|
674 | directly. |
|
|
675 | |
|
|
676 | Silly example: toggle the sign bit of a float. |
|
|
677 | |
|
|
678 | /* On gcc-4.7 on amd64, */ |
|
|
679 | /* this results in a single add instruction to toggle the bit, and 4 extra */ |
|
|
680 | /* instructions to move the float value to an integer register and back. */ |
|
|
681 | |
|
|
682 | x = ecb_binary32_to_float (ecb_float_to_binary32 (x) ^ 0x80000000U) |
|
|
683 | |
|
|
684 | =item float ecb_binary32_to_float (uint32_t x) [-UECB_NO_LIBM] |
|
|
685 | |
|
|
686 | =item double ecb_binary32_to_double (uint64_t x) [-UECB_NO_LIBM] |
|
|
687 | |
|
|
688 | The reverse operation of the previos function - takes the bit representation |
|
|
689 | of an IEEE binary32 or binary64 number and converts it to the native C<float> |
|
|
690 | or C<double> format. |
|
|
691 | |
|
|
692 | This function should work even when the native floating point format isn't |
|
|
693 | IEEE compliant, of course at a speed and code size penalty, and of course |
|
|
694 | also within reasonable limits (it tries to convert normals and denormals, |
|
|
695 | and might be lucky for infinities, and with extraordinary luck, also for |
|
|
696 | negative zero). |
|
|
697 | |
|
|
698 | On all modern platforms (where C<ECB_STDFP> is true), the compiler should |
|
|
699 | be able to optimise away this function completely. |
| 447 | |
700 | |
| 448 | =back |
701 | =back |
| 449 | |
702 | |
| 450 | =head2 ARITHMETIC |
703 | =head2 ARITHMETIC |
| 451 | |
704 | |
| … | |
… | |
| 475 | change direction for negative values: |
728 | change direction for negative values: |
| 476 | |
729 | |
| 477 | for (m = -100; m <= 100; ++m) |
730 | for (m = -100; m <= 100; ++m) |
| 478 | int elem = myarray [ecb_mod (m, ecb_array_length (myarray))]; |
731 | int elem = myarray [ecb_mod (m, ecb_array_length (myarray))]; |
| 479 | |
732 | |
|
|
733 | =item x = ecb_div_rd (val, div) |
|
|
734 | |
|
|
735 | =item x = ecb_div_ru (val, div) |
|
|
736 | |
|
|
737 | Returns C<val> divided by C<div> rounded down or up, respectively. |
|
|
738 | C<val> and C<div> must have integer types and C<div> must be strictly |
|
|
739 | positive. Note that these functions are implemented with macros in C |
|
|
740 | and with function templates in C++. |
|
|
741 | |
| 480 | =back |
742 | =back |
| 481 | |
743 | |
| 482 | =head2 UTILITY |
744 | =head2 UTILITY |
| 483 | |
745 | |
| 484 | =over 4 |
746 | =over 4 |
| … | |
… | |
| 493 | for (i = 0; i < ecb_array_length (primes); i++) |
755 | for (i = 0; i < ecb_array_length (primes); i++) |
| 494 | sum += primes [i]; |
756 | sum += primes [i]; |
| 495 | |
757 | |
| 496 | =back |
758 | =back |
| 497 | |
759 | |
|
|
760 | =head2 SYMBOLS GOVERNING COMPILATION OF ECB.H ITSELF |
| 498 | |
761 | |
|
|
762 | These symbols need to be defined before including F<ecb.h> the first time. |
|
|
763 | |
|
|
764 | =over 4 |
|
|
765 | |
|
|
766 | =item ECB_NO_THREADS |
|
|
767 | |
|
|
768 | If F<ecb.h> is never used from multiple threads, then this symbol can |
|
|
769 | be defined, in which case memory fences (and similar constructs) are |
|
|
770 | completely removed, leading to more efficient code and fewer dependencies. |
|
|
771 | |
|
|
772 | Setting this symbol to a true value implies C<ECB_NO_SMP>. |
|
|
773 | |
|
|
774 | =item ECB_NO_SMP |
|
|
775 | |
|
|
776 | The weaker version of C<ECB_NO_THREADS> - if F<ecb.h> is used from |
|
|
777 | multiple threads, but never concurrently (e.g. if the system the program |
|
|
778 | runs on has only a single CPU with a single core, no hyperthreading and so |
|
|
779 | on), then this symbol can be defined, leading to more efficient code and |
|
|
780 | fewer dependencies. |
|
|
781 | |
|
|
782 | =item ECB_NO_LIBM |
|
|
783 | |
|
|
784 | When defined to C<1>, do not export any functions that might introduce |
|
|
785 | dependencies on the math library (usually called F<-lm>) - these are |
|
|
786 | marked with [-UECB_NO_LIBM]. |
|
|
787 | |
|
|
788 | =back |
|
|
789 | |
|
|
790 | |
