diff --git a/contrib/orlp/ipow.h b/contrib/orlp/ipow.h new file mode 100644 index 0000000..699fe02 --- /dev/null +++ b/contrib/orlp/ipow.h @@ -0,0 +1,171 @@ +// Computes an integer power by modular exponentiation. +// +// From https://gist.github.com/orlp/3551590, in turn optimized from +// https://stackoverflow.com/a/101613. +// +// Adapted. +#ifndef ACED_CONTRIB_ORLP_IPOW_H_ +#define ACED_CONTRIB_ORLP_IPOW_H_ + +#include + +int64_t ipow(int64_t base, uint8_t exp) { + static const uint8_t highest_bit_set[] = { + 0, 1, 2, 2, 3, 3, 3, 3, + 4, 4, 4, 4, 4, 4, 4, 4, + 5, 5, 5, 5, 5, 5, 5, 5, + 5, 5, 5, 5, 5, 5, 5, 5, + 6, 6, 6, 6, 6, 6, 6, 6, + 6, 6, 6, 6, 6, 6, 6, 6, + 6, 6, 6, 6, 6, 6, 6, 6, + 6, 6, 6, 6, 6, 6, 6, 255, // anything past 63 is a guaranteed overflow with base > 1 + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + }; + + int64_t result = 1; + + switch (highest_bit_set[exp]) { + case 255: // we use 255 as an overflow marker and return 0 on overflow/underflow + if (base == 1) { + return 1; + } + + if (base == -1) { + return 1 - 2 * (exp & 1); + } + + return 0; + case 6: + if (exp & 1) result *= base; + exp >>= 1; + base *= base; + // fall through + case 5: + if (exp & 1) result *= base; + exp >>= 1; + base *= base; + // fall through + case 4: + if (exp & 1) result *= base; + exp >>= 1; + base *= base; + // fall through + case 3: + if (exp & 1) result *= base; + exp >>= 1; + base *= base; + // fall through + case 2: + if (exp & 1) result *= base; + exp >>= 1; + base *= base; + // fall through + case 1: + if (exp & 1) result *= base; + // fall through + default: + return result; + } +} + +uint64_t upow(uint64_t base, uint8_t exp) { + static const uint8_t highest_bit_set[] = { + 0, 1, 2, 2, 3, 3, 3, 3, + 4, 4, 4, 4, 4, 4, 4, 4, + 5, 5, 5, 5, 5, 5, 5, 5, + 5, 5, 5, 5, 5, 5, 5, 5, + 6, 6, 6, 6, 6, 6, 6, 6, + 6, 6, 6, 6, 6, 6, 6, 6, + 6, 6, 6, 6, 6, 6, 6, 6, + 6, 6, 6, 6, 6, 6, 6, 255, // anything past 63 is a guaranteed overflow with base > 1 + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + 255, 255, 255, 255, 255, 255, 255, 255, + }; + + uint64_t result = 1; + + switch (highest_bit_set[exp]) { + case 255: // we use 255 as an overflow marker and return 0 on overflow/underflow + if (base == 1) { + return 1; + } + return 0; + case 6: + if (exp & 1) result *= base; + exp >>= 1; + base *= base; + // fall through + case 5: + if (exp & 1) result *= base; + exp >>= 1; + base *= base; + // fall through + case 4: + if (exp & 1) result *= base; + exp >>= 1; + base *= base; + // fall through + case 3: + if (exp & 1) result *= base; + exp >>= 1; + base *= base; + // fall through + case 2: + if (exp & 1) result *= base; + exp >>= 1; + base *= base; + // fall through + case 1: + if (exp & 1) result *= base; + // fall through + default: + return result; + } +} + +#endif \ No newline at end of file diff --git a/contrib/stb/stb_ds.h b/contrib/stb/stb_ds.h new file mode 100644 index 0000000..e84c82d --- /dev/null +++ b/contrib/stb/stb_ds.h @@ -0,0 +1,1895 @@ +/* stb_ds.h - v0.67 - public domain data structures - Sean Barrett 2019 + + This is a single-header-file library that provides easy-to-use + dynamic arrays and hash tables for C (also works in C++). + + For a gentle introduction: + http://nothings.org/stb_ds + + To use this library, do this in *one* C or C++ file: + #define STB_DS_IMPLEMENTATION + #include "stb_ds.h" + +TABLE OF CONTENTS + + Table of Contents + Compile-time options + License + Documentation + Notes + Notes - Dynamic arrays + Notes - Hash maps + Credits + +COMPILE-TIME OPTIONS + + #define STBDS_NO_SHORT_NAMES + + This flag needs to be set globally. + + By default stb_ds exposes shorter function names that are not qualified + with the "stbds_" prefix. If these names conflict with the names in your + code, define this flag. + + #define STBDS_SIPHASH_2_4 + + This flag only needs to be set in the file containing #define STB_DS_IMPLEMENTATION. + + By default stb_ds.h hashes using a weaker variant of SipHash and a custom hash for + 4- and 8-byte keys. On 64-bit platforms, you can define the above flag to force + stb_ds.h to use specification-compliant SipHash-2-4 for all keys. Doing so makes + hash table insertion about 20% slower on 4- and 8-byte keys, 5% slower on + 64-byte keys, and 10% slower on 256-byte keys on my test computer. + + #define STBDS_REALLOC(context,ptr,size) better_realloc + #define STBDS_FREE(context,ptr) better_free + + These defines only need to be set in the file containing #define STB_DS_IMPLEMENTATION. + + By default stb_ds uses stdlib realloc() and free() for memory management. You can + substitute your own functions instead by defining these symbols. You must either + define both, or neither. Note that at the moment, 'context' will always be NULL. + @TODO add an array/hash initialization function that takes a memory context pointer. + + #define STBDS_UNIT_TESTS + + Defines a function stbds_unit_tests() that checks the functioning of the data structures. + + Note that on older versions of gcc (e.g. 5.x.x) you may need to build with '-std=c++0x' + (or equivalentally '-std=c++11') when using anonymous structures as seen on the web + page or in STBDS_UNIT_TESTS. + +LICENSE + + Placed in the public domain and also MIT licensed. + See end of file for detailed license information. + +DOCUMENTATION + + Dynamic Arrays + + Non-function interface: + + Declare an empty dynamic array of type T + T* foo = NULL; + + Access the i'th item of a dynamic array 'foo' of type T, T* foo: + foo[i] + + Functions (actually macros) + + arrfree: + void arrfree(T*); + Frees the array. + + arrlen: + ptrdiff_t arrlen(T*); + Returns the number of elements in the array. + + arrlenu: + size_t arrlenu(T*); + Returns the number of elements in the array as an unsigned type. + + arrpop: + T arrpop(T* a) + Removes the final element of the array and returns it. + + arrput: + T arrput(T* a, T b); + Appends the item b to the end of array a. Returns b. + + arrins: + T arrins(T* a, int p, T b); + Inserts the item b into the middle of array a, into a[p], + moving the rest of the array over. Returns b. + + arrinsn: + void arrinsn(T* a, int p, int n); + Inserts n uninitialized items into array a starting at a[p], + moving the rest of the array over. + + arraddnptr: + T* arraddnptr(T* a, int n) + Appends n uninitialized items onto array at the end. + Returns a pointer to the first uninitialized item added. + + arraddnindex: + size_t arraddnindex(T* a, int n) + Appends n uninitialized items onto array at the end. + Returns the index of the first uninitialized item added. + + arrdel: + void arrdel(T* a, int p); + Deletes the element at a[p], moving the rest of the array over. + + arrdeln: + void arrdeln(T* a, int p, int n); + Deletes n elements starting at a[p], moving the rest of the array over. + + arrdelswap: + void arrdelswap(T* a, int p); + Deletes the element at a[p], replacing it with the element from + the end of the array. O(1) performance. + + arrsetlen: + void arrsetlen(T* a, int n); + Changes the length of the array to n. Allocates uninitialized + slots at the end if necessary. + + arrsetcap: + size_t arrsetcap(T* a, int n); + Sets the length of allocated storage to at least n. It will not + change the length of the array. + + arrcap: + size_t arrcap(T* a); + Returns the number of total elements the array can contain without + needing to be reallocated. + + Hash maps & String hash maps + + Given T is a structure type: struct { TK key; TV value; }. Note that some + functions do not require TV value and can have other fields. For string + hash maps, TK must be 'char *'. + + Special interface: + + stbds_rand_seed: + void stbds_rand_seed(size_t seed); + For security against adversarially chosen data, you should seed the + library with a strong random number. Or at least seed it with time(). + + stbds_hash_string: + size_t stbds_hash_string(char *str, size_t seed); + Returns a hash value for a string. + + stbds_hash_bytes: + size_t stbds_hash_bytes(void *p, size_t len, size_t seed); + These functions hash an arbitrary number of bytes. The function + uses a custom hash for 4- and 8-byte data, and a weakened version + of SipHash for everything else. On 64-bit platforms you can get + specification-compliant SipHash-2-4 on all data by defining + STBDS_SIPHASH_2_4, at a significant cost in speed. + + Non-function interface: + + Declare an empty hash map of type T + T* foo = NULL; + + Access the i'th entry in a hash table T* foo: + foo[i] + + Function interface (actually macros): + + hmfree + shfree + void hmfree(T*); + void shfree(T*); + Frees the hashmap and sets the pointer to NULL. + + hmlen + shlen + ptrdiff_t hmlen(T*) + ptrdiff_t shlen(T*) + Returns the number of elements in the hashmap. + + hmlenu + shlenu + size_t hmlenu(T*) + size_t shlenu(T*) + Returns the number of elements in the hashmap. + + hmgeti + shgeti + hmgeti_ts + ptrdiff_t hmgeti(T*, TK key) + ptrdiff_t shgeti(T*, char* key) + ptrdiff_t hmgeti_ts(T*, TK key, ptrdiff_t tempvar) + Returns the index in the hashmap which has the key 'key', or -1 + if the key is not present. + + hmget + hmget_ts + shget + TV hmget(T*, TK key) + TV shget(T*, char* key) + TV hmget_ts(T*, TK key, ptrdiff_t tempvar) + Returns the value corresponding to 'key' in the hashmap. + The structure must have a 'value' field + + hmgets + shgets + T hmgets(T*, TK key) + T shgets(T*, char* key) + Returns the structure corresponding to 'key' in the hashmap. + + hmgetp + shgetp + hmgetp_ts + hmgetp_null + shgetp_null + T* hmgetp(T*, TK key) + T* shgetp(T*, char* key) + T* hmgetp_ts(T*, TK key, ptrdiff_t tempvar) + T* hmgetp_null(T*, TK key) + T* shgetp_null(T*, char *key) + Returns a pointer to the structure corresponding to 'key' in + the hashmap. Functions ending in "_null" return NULL if the key + is not present in the hashmap; the others return a pointer to a + structure holding the default value (but not the searched-for key). + + hmdefault + shdefault + TV hmdefault(T*, TV value) + TV shdefault(T*, TV value) + Sets the default value for the hashmap, the value which will be + returned by hmget/shget if the key is not present. + + hmdefaults + shdefaults + TV hmdefaults(T*, T item) + TV shdefaults(T*, T item) + Sets the default struct for the hashmap, the contents which will be + returned by hmgets/shgets if the key is not present. + + hmput + shput + TV hmput(T*, TK key, TV value) + TV shput(T*, char* key, TV value) + Inserts a pair into the hashmap. If the key is already + present in the hashmap, updates its value. + + hmputs + shputs + T hmputs(T*, T item) + T shputs(T*, T item) + Inserts a struct with T.key into the hashmap. If the struct is already + present in the hashmap, updates it. + + hmdel + shdel + int hmdel(T*, TK key) + int shdel(T*, char* key) + If 'key' is in the hashmap, deletes its entry and returns 1. + Otherwise returns 0. + + Function interface (actually macros) for strings only: + + sh_new_strdup + void sh_new_strdup(T*); + Overwrites the existing pointer with a newly allocated + string hashmap which will automatically allocate and free + each string key using realloc/free + + sh_new_arena + void sh_new_arena(T*); + Overwrites the existing pointer with a newly allocated + string hashmap which will automatically allocate each string + key to a string arena. Every string key ever used by this + hash table remains in the arena until the arena is freed. + Additionally, any key which is deleted and reinserted will + be allocated multiple times in the string arena. + +NOTES + + * These data structures are realloc'd when they grow, and the macro + "functions" write to the provided pointer. This means: (a) the pointer + must be an lvalue, and (b) the pointer to the data structure is not + stable, and you must maintain it the same as you would a realloc'd + pointer. For example, if you pass a pointer to a dynamic array to a + function which updates it, the function must return back the new + pointer to the caller. This is the price of trying to do this in C. + + * The following are the only functions that are thread-safe on a single data + structure, i.e. can be run in multiple threads simultaneously on the same + data structure + hmlen shlen + hmlenu shlenu + hmget_ts shget_ts + hmgeti_ts shgeti_ts + hmgets_ts shgets_ts + + * You iterate over the contents of a dynamic array and a hashmap in exactly + the same way, using arrlen/hmlen/shlen: + + for (i=0; i < arrlen(foo); ++i) + ... foo[i] ... + + * All operations except arrins/arrdel are O(1) amortized, but individual + operations can be slow, so these data structures may not be suitable + for real time use. Dynamic arrays double in capacity as needed, so + elements are copied an average of once. Hash tables double/halve + their size as needed, with appropriate hysteresis to maintain O(1) + performance. + +NOTES - DYNAMIC ARRAY + + * If you know how long a dynamic array is going to be in advance, you can avoid + extra memory allocations by using arrsetlen to allocate it to that length in + advance and use foo[n] while filling it out, or arrsetcap to allocate the memory + for that length and use arrput/arrpush as normal. + + * Unlike some other versions of the dynamic array, this version should + be safe to use with strict-aliasing optimizations. + +NOTES - HASH MAP + + * For compilers other than GCC and clang (e.g. Visual Studio), for hmput/hmget/hmdel + and variants, the key must be an lvalue (so the macro can take the address of it). + Extensions are used that eliminate this requirement if you're using C99 and later + in GCC or clang, or if you're using C++ in GCC. But note that this can make your + code less portable. + + * To test for presence of a key in a hashmap, just do 'hmgeti(foo,key) >= 0'. + + * The iteration order of your data in the hashmap is determined solely by the + order of insertions and deletions. In particular, if you never delete, new + keys are always added at the end of the array. This will be consistent + across all platforms and versions of the library. However, you should not + attempt to serialize the internal hash table, as the hash is not consistent + between different platforms, and may change with future versions of the library. + + * Use sh_new_arena() for string hashmaps that you never delete from. Initialize + with NULL if you're managing the memory for your strings, or your strings are + never freed (at least until the hashmap is freed). Otherwise, use sh_new_strdup(). + @TODO: make an arena variant that garbage collects the strings with a trivial + copy collector into a new arena whenever the table shrinks / rebuilds. Since + current arena recommendation is to only use arena if it never deletes, then + this can just replace current arena implementation. + + * If adversarial input is a serious concern and you're on a 64-bit platform, + enable STBDS_SIPHASH_2_4 (see the 'Compile-time options' section), and pass + a strong random number to stbds_rand_seed. + + * The default value for the hash table is stored in foo[-1], so if you + use code like 'hmget(T,k)->value = 5' you can accidentally overwrite + the value stored by hmdefault if 'k' is not present. + +CREDITS + + Sean Barrett -- library, idea for dynamic array API/implementation + Per Vognsen -- idea for hash table API/implementation + Rafael Sachetto -- arrpop() + github:HeroicKatora -- arraddn() reworking + + Bugfixes: + Andy Durdin + Shane Liesegang + Vinh Truong + Andreas Molzer + github:hashitaku + github:srdjanstipic + Macoy Madson + Andreas Vennstrom + Tobias Mansfield-Williams +*/ + +#ifdef STBDS_UNIT_TESTS +#define _CRT_SECURE_NO_WARNINGS +#endif + +#ifndef INCLUDE_STB_DS_H +#define INCLUDE_STB_DS_H + +#include +#include + +#ifndef STBDS_NO_SHORT_NAMES +#define arrlen stbds_arrlen +#define arrlenu stbds_arrlenu +#define arrput stbds_arrput +#define arrpush stbds_arrput +#define arrpop stbds_arrpop +#define arrfree stbds_arrfree +#define arraddn stbds_arraddn // deprecated, use one of the following instead: +#define arraddnptr stbds_arraddnptr +#define arraddnindex stbds_arraddnindex +#define arrsetlen stbds_arrsetlen +#define arrlast stbds_arrlast +#define arrins stbds_arrins +#define arrinsn stbds_arrinsn +#define arrdel stbds_arrdel +#define arrdeln stbds_arrdeln +#define arrdelswap stbds_arrdelswap +#define arrcap stbds_arrcap +#define arrsetcap stbds_arrsetcap + +#define hmput stbds_hmput +#define hmputs stbds_hmputs +#define hmget stbds_hmget +#define hmget_ts stbds_hmget_ts +#define hmgets stbds_hmgets +#define hmgetp stbds_hmgetp +#define hmgetp_ts stbds_hmgetp_ts +#define hmgetp_null stbds_hmgetp_null +#define hmgeti stbds_hmgeti +#define hmgeti_ts stbds_hmgeti_ts +#define hmdel stbds_hmdel +#define hmlen stbds_hmlen +#define hmlenu stbds_hmlenu +#define hmfree stbds_hmfree +#define hmdefault stbds_hmdefault +#define hmdefaults stbds_hmdefaults + +#define shput stbds_shput +#define shputi stbds_shputi +#define shputs stbds_shputs +#define shget stbds_shget +#define shgeti stbds_shgeti +#define shgets stbds_shgets +#define shgetp stbds_shgetp +#define shgetp_null stbds_shgetp_null +#define shdel stbds_shdel +#define shlen stbds_shlen +#define shlenu stbds_shlenu +#define shfree stbds_shfree +#define shdefault stbds_shdefault +#define shdefaults stbds_shdefaults +#define sh_new_arena stbds_sh_new_arena +#define sh_new_strdup stbds_sh_new_strdup + +#define stralloc stbds_stralloc +#define strreset stbds_strreset +#endif + +#if defined(STBDS_REALLOC) && !defined(STBDS_FREE) || !defined(STBDS_REALLOC) && defined(STBDS_FREE) +#error "You must define both STBDS_REALLOC and STBDS_FREE, or neither." +#endif +#if !defined(STBDS_REALLOC) && !defined(STBDS_FREE) +#include +#define STBDS_REALLOC(c,p,s) realloc(p,s) +#define STBDS_FREE(c,p) free(p) +#endif + +#ifdef _MSC_VER +#define STBDS_NOTUSED(v) (void)(v) +#else +#define STBDS_NOTUSED(v) (void)sizeof(v) +#endif + +#ifdef __cplusplus +extern "C" { +#endif + +// for security against attackers, seed the library with a random number, at least time() but stronger is better +extern void stbds_rand_seed(size_t seed); + +// these are the hash functions used internally if you want to test them or use them for other purposes +extern size_t stbds_hash_bytes(void *p, size_t len, size_t seed); +extern size_t stbds_hash_string(char *str, size_t seed); + +// this is a simple string arena allocator, initialize with e.g. 'stbds_string_arena my_arena={0}'. +typedef struct stbds_string_arena stbds_string_arena; +extern char * stbds_stralloc(stbds_string_arena *a, char *str); +extern void stbds_strreset(stbds_string_arena *a); + +// have to #define STBDS_UNIT_TESTS to call this +extern void stbds_unit_tests(void); + +/////////////// +// +// Everything below here is implementation details +// + +extern void * stbds_arrgrowf(void *a, size_t elemsize, size_t addlen, size_t min_cap); +extern void stbds_arrfreef(void *a); +extern void stbds_hmfree_func(void *p, size_t elemsize); +extern void * stbds_hmget_key(void *a, size_t elemsize, void *key, size_t keysize, int mode); +extern void * stbds_hmget_key_ts(void *a, size_t elemsize, void *key, size_t keysize, ptrdiff_t *temp, int mode); +extern void * stbds_hmput_default(void *a, size_t elemsize); +extern void * stbds_hmput_key(void *a, size_t elemsize, void *key, size_t keysize, int mode); +extern void * stbds_hmdel_key(void *a, size_t elemsize, void *key, size_t keysize, size_t keyoffset, int mode); +extern void * stbds_shmode_func(size_t elemsize, int mode); + +#ifdef __cplusplus +} +#endif + +#if defined(__GNUC__) || defined(__clang__) +#define STBDS_HAS_TYPEOF +#ifdef __cplusplus +//#define STBDS_HAS_LITERAL_ARRAY // this is currently broken for clang +#endif +#endif + +#if !defined(__cplusplus) +#if defined(__STDC_VERSION__) && __STDC_VERSION__ >= 199901L +#define STBDS_HAS_LITERAL_ARRAY +#endif +#endif + +// this macro takes the address of the argument, but on gcc/clang can accept rvalues +#if defined(STBDS_HAS_LITERAL_ARRAY) && defined(STBDS_HAS_TYPEOF) + #if __clang__ + #define STBDS_ADDRESSOF(typevar, value) ((__typeof__(typevar)[1]){value}) // literal array decays to pointer to value + #else + #define STBDS_ADDRESSOF(typevar, value) ((typeof(typevar)[1]){value}) // literal array decays to pointer to value + #endif +#else +#define STBDS_ADDRESSOF(typevar, value) &(value) +#endif + +#define STBDS_OFFSETOF(var,field) ((char *) &(var)->field - (char *) (var)) + +#define stbds_header(t) ((stbds_array_header *) (t) - 1) +#define stbds_temp(t) stbds_header(t)->temp +#define stbds_temp_key(t) (*(char **) stbds_header(t)->hash_table) + +#define stbds_arrsetcap(a,n) (stbds_arrgrow(a,0,n)) +#define stbds_arrsetlen(a,n) ((stbds_arrcap(a) < (size_t) (n) ? stbds_arrsetcap((a),(size_t)(n)),0 : 0), (a) ? stbds_header(a)->length = (size_t) (n) : 0) +#define stbds_arrcap(a) ((a) ? stbds_header(a)->capacity : 0) +#define stbds_arrlen(a) ((a) ? (ptrdiff_t) stbds_header(a)->length : 0) +#define stbds_arrlenu(a) ((a) ? stbds_header(a)->length : 0) +#define stbds_arrput(a,v) (stbds_arrmaybegrow(a,1), (a)[stbds_header(a)->length++] = (v)) +#define stbds_arrpush stbds_arrput // synonym +#define stbds_arrpop(a) (stbds_header(a)->length--, (a)[stbds_header(a)->length]) +#define stbds_arraddn(a,n) ((void)(stbds_arraddnindex(a, n))) // deprecated, use one of the following instead: +#define stbds_arraddnptr(a,n) (stbds_arrmaybegrow(a,n), (n) ? (stbds_header(a)->length += (n), &(a)[stbds_header(a)->length-(n)]) : (a)) +#define stbds_arraddnindex(a,n)(stbds_arrmaybegrow(a,n), (n) ? (stbds_header(a)->length += (n), stbds_header(a)->length-(n)) : stbds_arrlen(a)) +#define stbds_arraddnoff stbds_arraddnindex +#define stbds_arrlast(a) ((a)[stbds_header(a)->length-1]) +#define stbds_arrfree(a) ((void) ((a) ? STBDS_FREE(NULL,stbds_header(a)) : (void)0), (a)=NULL) +#define stbds_arrdel(a,i) stbds_arrdeln(a,i,1) +#define stbds_arrdeln(a,i,n) (memmove(&(a)[i], &(a)[(i)+(n)], sizeof *(a) * (stbds_header(a)->length-(n)-(i))), stbds_header(a)->length -= (n)) +#define stbds_arrdelswap(a,i) ((a)[i] = stbds_arrlast(a), stbds_header(a)->length -= 1) +#define stbds_arrinsn(a,i,n) (stbds_arraddn((a),(n)), memmove(&(a)[(i)+(n)], &(a)[i], sizeof *(a) * (stbds_header(a)->length-(n)-(i)))) +#define stbds_arrins(a,i,v) (stbds_arrinsn((a),(i),1), (a)[i]=(v)) + +#define stbds_arrmaybegrow(a,n) ((!(a) || stbds_header(a)->length + (n) > stbds_header(a)->capacity) \ + ? (stbds_arrgrow(a,n,0),0) : 0) + +#define stbds_arrgrow(a,b,c) ((a) = stbds_arrgrowf_wrapper((a), sizeof *(a), (b), (c))) + +#define stbds_hmput(t, k, v) \ + ((t) = stbds_hmput_key_wrapper((t), sizeof *(t), (void*) STBDS_ADDRESSOF((t)->key, (k)), sizeof (t)->key, 0), \ + (t)[stbds_temp((t)-1)].key = (k), \ + (t)[stbds_temp((t)-1)].value = (v)) + +#define stbds_hmputs(t, s) \ + ((t) = stbds_hmput_key_wrapper((t), sizeof *(t), &(s).key, sizeof (s).key, STBDS_HM_BINARY), \ + (t)[stbds_temp((t)-1)] = (s)) + +#define stbds_hmgeti(t,k) \ + ((t) = stbds_hmget_key_wrapper((t), sizeof *(t), (void*) STBDS_ADDRESSOF((t)->key, (k)), sizeof (t)->key, STBDS_HM_BINARY), \ + stbds_temp((t)-1)) + +#define stbds_hmgeti_ts(t,k,temp) \ + ((t) = stbds_hmget_key_ts_wrapper((t), sizeof *(t), (void*) STBDS_ADDRESSOF((t)->key, (k)), sizeof (t)->key, &(temp), STBDS_HM_BINARY), \ + (temp)) + +#define stbds_hmgetp(t, k) \ + ((void) stbds_hmgeti(t,k), &(t)[stbds_temp((t)-1)]) + +#define stbds_hmgetp_ts(t, k, temp) \ + ((void) stbds_hmgeti_ts(t,k,temp), &(t)[temp]) + +#define stbds_hmdel(t,k) \ + (((t) = stbds_hmdel_key_wrapper((t),sizeof *(t), (void*) STBDS_ADDRESSOF((t)->key, (k)), sizeof (t)->key, STBDS_OFFSETOF((t),key), STBDS_HM_BINARY)),(t)?stbds_temp((t)-1):0) + +#define stbds_hmdefault(t, v) \ + ((t) = stbds_hmput_default_wrapper((t), sizeof *(t)), (t)[-1].value = (v)) + +#define stbds_hmdefaults(t, s) \ + ((t) = stbds_hmput_default_wrapper((t), sizeof *(t)), (t)[-1] = (s)) + +#define stbds_hmfree(p) \ + ((void) ((p) != NULL ? stbds_hmfree_func((p)-1,sizeof*(p)),0 : 0),(p)=NULL) + +#define stbds_hmgets(t, k) (*stbds_hmgetp(t,k)) +#define stbds_hmget(t, k) (stbds_hmgetp(t,k)->value) +#define stbds_hmget_ts(t, k, temp) (stbds_hmgetp_ts(t,k,temp)->value) +#define stbds_hmlen(t) ((t) ? (ptrdiff_t) stbds_header((t)-1)->length-1 : 0) +#define stbds_hmlenu(t) ((t) ? stbds_header((t)-1)->length-1 : 0) +#define stbds_hmgetp_null(t,k) (stbds_hmgeti(t,k) == -1 ? NULL : &(t)[stbds_temp((t)-1)]) + +#define stbds_shput(t, k, v) \ + ((t) = stbds_hmput_key_wrapper((t), sizeof *(t), (void*) (k), sizeof (t)->key, STBDS_HM_STRING), \ + (t)[stbds_temp((t)-1)].value = (v)) + +#define stbds_shputi(t, k, v) \ + ((t) = stbds_hmput_key_wrapper((t), sizeof *(t), (void*) (k), sizeof (t)->key, STBDS_HM_STRING), \ + (t)[stbds_temp((t)-1)].value = (v), stbds_temp((t)-1)) + +#define stbds_shputs(t, s) \ + ((t) = stbds_hmput_key_wrapper((t), sizeof *(t), (void*) (s).key, sizeof (s).key, STBDS_HM_STRING), \ + (t)[stbds_temp((t)-1)] = (s), \ + (t)[stbds_temp((t)-1)].key = stbds_temp_key((t)-1)) // above line overwrites whole structure, so must rewrite key here if it was allocated internally + +#define stbds_pshput(t, p) \ + ((t) = stbds_hmput_key_wrapper((t), sizeof *(t), (void*) (p)->key, sizeof (p)->key, STBDS_HM_PTR_TO_STRING), \ + (t)[stbds_temp((t)-1)] = (p)) + +#define stbds_shgeti(t,k) \ + ((t) = stbds_hmget_key_wrapper((t), sizeof *(t), (void*) (k), sizeof (t)->key, STBDS_HM_STRING), \ + stbds_temp((t)-1)) + +#define stbds_pshgeti(t,k) \ + ((t) = stbds_hmget_key_wrapper((t), sizeof *(t), (void*) (k), sizeof (*(t))->key, STBDS_HM_PTR_TO_STRING), \ + stbds_temp((t)-1)) + +#define stbds_shgetp(t, k) \ + ((void) stbds_shgeti(t,k), &(t)[stbds_temp((t)-1)]) + +#define stbds_pshget(t, k) \ + ((void) stbds_pshgeti(t,k), (t)[stbds_temp((t)-1)]) + +#define stbds_shdel(t,k) \ + (((t) = stbds_hmdel_key_wrapper((t),sizeof *(t), (void*) (k), sizeof (t)->key, STBDS_OFFSETOF((t),key), STBDS_HM_STRING)),(t)?stbds_temp((t)-1):0) +#define stbds_pshdel(t,k) \ + (((t) = stbds_hmdel_key_wrapper((t),sizeof *(t), (void*) (k), sizeof (*(t))->key, STBDS_OFFSETOF(*(t),key), STBDS_HM_PTR_TO_STRING)),(t)?stbds_temp((t)-1):0) + +#define stbds_sh_new_arena(t) \ + ((t) = stbds_shmode_func_wrapper(t, sizeof *(t), STBDS_SH_ARENA)) +#define stbds_sh_new_strdup(t) \ + ((t) = stbds_shmode_func_wrapper(t, sizeof *(t), STBDS_SH_STRDUP)) + +#define stbds_shdefault(t, v) stbds_hmdefault(t,v) +#define stbds_shdefaults(t, s) stbds_hmdefaults(t,s) + +#define stbds_shfree stbds_hmfree +#define stbds_shlenu stbds_hmlenu + +#define stbds_shgets(t, k) (*stbds_shgetp(t,k)) +#define stbds_shget(t, k) (stbds_shgetp(t,k)->value) +#define stbds_shgetp_null(t,k) (stbds_shgeti(t,k) == -1 ? NULL : &(t)[stbds_temp((t)-1)]) +#define stbds_shlen stbds_hmlen + +typedef struct +{ + size_t length; + size_t capacity; + void * hash_table; + ptrdiff_t temp; +} stbds_array_header; + +typedef struct stbds_string_block +{ + struct stbds_string_block *next; + char storage[8]; +} stbds_string_block; + +struct stbds_string_arena +{ + stbds_string_block *storage; + size_t remaining; + unsigned char block; + unsigned char mode; // this isn't used by the string arena itself +}; + +#define STBDS_HM_BINARY 0 +#define STBDS_HM_STRING 1 + +enum +{ + STBDS_SH_NONE, + STBDS_SH_DEFAULT, + STBDS_SH_STRDUP, + STBDS_SH_ARENA +}; + +#ifdef __cplusplus +// in C we use implicit assignment from these void*-returning functions to T*. +// in C++ these templates make the same code work +template static T * stbds_arrgrowf_wrapper(T *a, size_t elemsize, size_t addlen, size_t min_cap) { + return (T*)stbds_arrgrowf((void *)a, elemsize, addlen, min_cap); +} +template static T * stbds_hmget_key_wrapper(T *a, size_t elemsize, void *key, size_t keysize, int mode) { + return (T*)stbds_hmget_key((void*)a, elemsize, key, keysize, mode); +} +template static T * stbds_hmget_key_ts_wrapper(T *a, size_t elemsize, void *key, size_t keysize, ptrdiff_t *temp, int mode) { + return (T*)stbds_hmget_key_ts((void*)a, elemsize, key, keysize, temp, mode); +} +template static T * stbds_hmput_default_wrapper(T *a, size_t elemsize) { + return (T*)stbds_hmput_default((void *)a, elemsize); +} +template static T * stbds_hmput_key_wrapper(T *a, size_t elemsize, void *key, size_t keysize, int mode) { + return (T*)stbds_hmput_key((void*)a, elemsize, key, keysize, mode); +} +template static T * stbds_hmdel_key_wrapper(T *a, size_t elemsize, void *key, size_t keysize, size_t keyoffset, int mode){ + return (T*)stbds_hmdel_key((void*)a, elemsize, key, keysize, keyoffset, mode); +} +template static T * stbds_shmode_func_wrapper(T *, size_t elemsize, int mode) { + return (T*)stbds_shmode_func(elemsize, mode); +} +#else +#define stbds_arrgrowf_wrapper stbds_arrgrowf +#define stbds_hmget_key_wrapper stbds_hmget_key +#define stbds_hmget_key_ts_wrapper stbds_hmget_key_ts +#define stbds_hmput_default_wrapper stbds_hmput_default +#define stbds_hmput_key_wrapper stbds_hmput_key +#define stbds_hmdel_key_wrapper stbds_hmdel_key +#define stbds_shmode_func_wrapper(t,e,m) stbds_shmode_func(e,m) +#endif + +#endif // INCLUDE_STB_DS_H + + +////////////////////////////////////////////////////////////////////////////// +// +// IMPLEMENTATION +// + +#ifdef STB_DS_IMPLEMENTATION +#include +#include + +#ifndef STBDS_ASSERT +#define STBDS_ASSERT_WAS_UNDEFINED +#define STBDS_ASSERT(x) ((void) 0) +#endif + +#ifdef STBDS_STATISTICS +#define STBDS_STATS(x) x +size_t stbds_array_grow; +size_t stbds_hash_grow; +size_t stbds_hash_shrink; +size_t stbds_hash_rebuild; +size_t stbds_hash_probes; +size_t stbds_hash_alloc; +size_t stbds_rehash_probes; +size_t stbds_rehash_items; +#else +#define STBDS_STATS(x) +#endif + +// +// stbds_arr implementation +// + +//int *prev_allocs[65536]; +//int num_prev; + +void *stbds_arrgrowf(void *a, size_t elemsize, size_t addlen, size_t min_cap) +{ + stbds_array_header temp={0}; // force debugging + void *b; + size_t min_len = stbds_arrlen(a) + addlen; + (void) sizeof(temp); + + // compute the minimum capacity needed + if (min_len > min_cap) + min_cap = min_len; + + if (min_cap <= stbds_arrcap(a)) + return a; + + // increase needed capacity to guarantee O(1) amortized + if (min_cap < 2 * stbds_arrcap(a)) + min_cap = 2 * stbds_arrcap(a); + else if (min_cap < 4) + min_cap = 4; + + //if (num_prev < 65536) if (a) prev_allocs[num_prev++] = (int *) ((char *) a+1); + //if (num_prev == 2201) + // num_prev = num_prev; + b = STBDS_REALLOC(NULL, (a) ? stbds_header(a) : 0, elemsize * min_cap + sizeof(stbds_array_header)); + //if (num_prev < 65536) prev_allocs[num_prev++] = (int *) (char *) b; + b = (char *) b + sizeof(stbds_array_header); + if (a == NULL) { + stbds_header(b)->length = 0; + stbds_header(b)->hash_table = 0; + stbds_header(b)->temp = 0; + } else { + STBDS_STATS(++stbds_array_grow); + } + stbds_header(b)->capacity = min_cap; + + return b; +} + +void stbds_arrfreef(void *a) +{ + STBDS_FREE(NULL, stbds_header(a)); +} + +// +// stbds_hm hash table implementation +// + +#ifdef STBDS_INTERNAL_SMALL_BUCKET +#define STBDS_BUCKET_LENGTH 4 +#else +#define STBDS_BUCKET_LENGTH 8 +#endif + +#define STBDS_BUCKET_SHIFT (STBDS_BUCKET_LENGTH == 8 ? 3 : 2) +#define STBDS_BUCKET_MASK (STBDS_BUCKET_LENGTH-1) +#define STBDS_CACHE_LINE_SIZE 64 + +#define STBDS_ALIGN_FWD(n,a) (((n) + (a) - 1) & ~((a)-1)) + +typedef struct +{ + size_t hash [STBDS_BUCKET_LENGTH]; + ptrdiff_t index[STBDS_BUCKET_LENGTH]; +} stbds_hash_bucket; // in 32-bit, this is one 64-byte cache line; in 64-bit, each array is one 64-byte cache line + +typedef struct +{ + char * temp_key; // this MUST be the first field of the hash table + size_t slot_count; + size_t used_count; + size_t used_count_threshold; + size_t used_count_shrink_threshold; + size_t tombstone_count; + size_t tombstone_count_threshold; + size_t seed; + size_t slot_count_log2; + stbds_string_arena string; + stbds_hash_bucket *storage; // not a separate allocation, just 64-byte aligned storage after this struct +} stbds_hash_index; + +#define STBDS_INDEX_EMPTY -1 +#define STBDS_INDEX_DELETED -2 +#define STBDS_INDEX_IN_USE(x) ((x) >= 0) + +#define STBDS_HASH_EMPTY 0 +#define STBDS_HASH_DELETED 1 + +static size_t stbds_hash_seed=0x31415926; + +void stbds_rand_seed(size_t seed) +{ + stbds_hash_seed = seed; +} + +#define stbds_load_32_or_64(var, temp, v32, v64_hi, v64_lo) \ + temp = v64_lo ^ v32, temp <<= 16, temp <<= 16, temp >>= 16, temp >>= 16, /* discard if 32-bit */ \ + var = v64_hi, var <<= 16, var <<= 16, /* discard if 32-bit */ \ + var ^= temp ^ v32 + +#define STBDS_SIZE_T_BITS ((sizeof (size_t)) * 8) + +static size_t stbds_probe_position(size_t hash, size_t slot_count, size_t slot_log2) +{ + size_t pos; + STBDS_NOTUSED(slot_log2); + pos = hash & (slot_count-1); + #ifdef STBDS_INTERNAL_BUCKET_START + pos &= ~STBDS_BUCKET_MASK; + #endif + return pos; +} + +static size_t stbds_log2(size_t slot_count) +{ + size_t n=0; + while (slot_count > 1) { + slot_count >>= 1; + ++n; + } + return n; +} + +static stbds_hash_index *stbds_make_hash_index(size_t slot_count, stbds_hash_index *ot) +{ + stbds_hash_index *t; + t = (stbds_hash_index *) STBDS_REALLOC(NULL,0,(slot_count >> STBDS_BUCKET_SHIFT) * sizeof(stbds_hash_bucket) + sizeof(stbds_hash_index) + STBDS_CACHE_LINE_SIZE-1); + t->storage = (stbds_hash_bucket *) STBDS_ALIGN_FWD((size_t) (t+1), STBDS_CACHE_LINE_SIZE); + t->slot_count = slot_count; + t->slot_count_log2 = stbds_log2(slot_count); + t->tombstone_count = 0; + t->used_count = 0; + + #if 0 // A1 + t->used_count_threshold = slot_count*12/16; // if 12/16th of table is occupied, grow + t->tombstone_count_threshold = slot_count* 2/16; // if tombstones are 2/16th of table, rebuild + t->used_count_shrink_threshold = slot_count* 4/16; // if table is only 4/16th full, shrink + #elif 1 // A2 + //t->used_count_threshold = slot_count*12/16; // if 12/16th of table is occupied, grow + //t->tombstone_count_threshold = slot_count* 3/16; // if tombstones are 3/16th of table, rebuild + //t->used_count_shrink_threshold = slot_count* 4/16; // if table is only 4/16th full, shrink + + // compute without overflowing + t->used_count_threshold = slot_count - (slot_count>>2); + t->tombstone_count_threshold = (slot_count>>3) + (slot_count>>4); + t->used_count_shrink_threshold = slot_count >> 2; + + #elif 0 // B1 + t->used_count_threshold = slot_count*13/16; // if 13/16th of table is occupied, grow + t->tombstone_count_threshold = slot_count* 2/16; // if tombstones are 2/16th of table, rebuild + t->used_count_shrink_threshold = slot_count* 5/16; // if table is only 5/16th full, shrink + #else // C1 + t->used_count_threshold = slot_count*14/16; // if 14/16th of table is occupied, grow + t->tombstone_count_threshold = slot_count* 2/16; // if tombstones are 2/16th of table, rebuild + t->used_count_shrink_threshold = slot_count* 6/16; // if table is only 6/16th full, shrink + #endif + // Following statistics were measured on a Core i7-6700 @ 4.00Ghz, compiled with clang 7.0.1 -O2 + // Note that the larger tables have high variance as they were run fewer times + // A1 A2 B1 C1 + // 0.10ms : 0.10ms : 0.10ms : 0.11ms : 2,000 inserts creating 2K table + // 0.96ms : 0.95ms : 0.97ms : 1.04ms : 20,000 inserts creating 20K table + // 14.48ms : 14.46ms : 10.63ms : 11.00ms : 200,000 inserts creating 200K table + // 195.74ms : 196.35ms : 203.69ms : 214.92ms : 2,000,000 inserts creating 2M table + // 2193.88ms : 2209.22ms : 2285.54ms : 2437.17ms : 20,000,000 inserts creating 20M table + // 65.27ms : 53.77ms : 65.33ms : 65.47ms : 500,000 inserts & deletes in 2K table + // 72.78ms : 62.45ms : 71.95ms : 72.85ms : 500,000 inserts & deletes in 20K table + // 89.47ms : 77.72ms : 96.49ms : 96.75ms : 500,000 inserts & deletes in 200K table + // 97.58ms : 98.14ms : 97.18ms : 97.53ms : 500,000 inserts & deletes in 2M table + // 118.61ms : 119.62ms : 120.16ms : 118.86ms : 500,000 inserts & deletes in 20M table + // 192.11ms : 194.39ms : 196.38ms : 195.73ms : 500,000 inserts & deletes in 200M table + + if (slot_count <= STBDS_BUCKET_LENGTH) + t->used_count_shrink_threshold = 0; + // to avoid infinite loop, we need to guarantee that at least one slot is empty and will terminate probes + STBDS_ASSERT(t->used_count_threshold + t->tombstone_count_threshold < t->slot_count); + STBDS_STATS(++stbds_hash_alloc); + if (ot) { + t->string = ot->string; + // reuse old seed so we can reuse old hashes so below "copy out old data" doesn't do any hashing + t->seed = ot->seed; + } else { + size_t a,b,temp; + memset(&t->string, 0, sizeof(t->string)); + t->seed = stbds_hash_seed; + // LCG + // in 32-bit, a = 2147001325 b = 715136305 + // in 64-bit, a = 2862933555777941757 b = 3037000493 + stbds_load_32_or_64(a,temp, 2147001325, 0x27bb2ee6, 0x87b0b0fd); + stbds_load_32_or_64(b,temp, 715136305, 0, 0xb504f32d); + stbds_hash_seed = stbds_hash_seed * a + b; + } + + { + size_t i,j; + for (i=0; i < slot_count >> STBDS_BUCKET_SHIFT; ++i) { + stbds_hash_bucket *b = &t->storage[i]; + for (j=0; j < STBDS_BUCKET_LENGTH; ++j) + b->hash[j] = STBDS_HASH_EMPTY; + for (j=0; j < STBDS_BUCKET_LENGTH; ++j) + b->index[j] = STBDS_INDEX_EMPTY; + } + } + + // copy out the old data, if any + if (ot) { + size_t i,j; + t->used_count = ot->used_count; + for (i=0; i < ot->slot_count >> STBDS_BUCKET_SHIFT; ++i) { + stbds_hash_bucket *ob = &ot->storage[i]; + for (j=0; j < STBDS_BUCKET_LENGTH; ++j) { + if (STBDS_INDEX_IN_USE(ob->index[j])) { + size_t hash = ob->hash[j]; + size_t pos = stbds_probe_position(hash, t->slot_count, t->slot_count_log2); + size_t step = STBDS_BUCKET_LENGTH; + STBDS_STATS(++stbds_rehash_items); + for (;;) { + size_t limit,z; + stbds_hash_bucket *bucket; + bucket = &t->storage[pos >> STBDS_BUCKET_SHIFT]; + STBDS_STATS(++stbds_rehash_probes); + + for (z=pos & STBDS_BUCKET_MASK; z < STBDS_BUCKET_LENGTH; ++z) { + if (bucket->hash[z] == 0) { + bucket->hash[z] = hash; + bucket->index[z] = ob->index[j]; + goto done; + } + } + + limit = pos & STBDS_BUCKET_MASK; + for (z = 0; z < limit; ++z) { + if (bucket->hash[z] == 0) { + bucket->hash[z] = hash; + bucket->index[z] = ob->index[j]; + goto done; + } + } + + pos += step; // quadratic probing + step += STBDS_BUCKET_LENGTH; + pos &= (t->slot_count-1); + } + } + done: + ; + } + } + } + + return t; +} + +#define STBDS_ROTATE_LEFT(val, n) (((val) << (n)) | ((val) >> (STBDS_SIZE_T_BITS - (n)))) +#define STBDS_ROTATE_RIGHT(val, n) (((val) >> (n)) | ((val) << (STBDS_SIZE_T_BITS - (n)))) + +size_t stbds_hash_string(char *str, size_t seed) +{ + size_t hash = seed; + while (*str) + hash = STBDS_ROTATE_LEFT(hash, 9) + (unsigned char) *str++; + + // Thomas Wang 64-to-32 bit mix function, hopefully also works in 32 bits + hash ^= seed; + hash = (~hash) + (hash << 18); + hash ^= hash ^ STBDS_ROTATE_RIGHT(hash,31); + hash = hash * 21; + hash ^= hash ^ STBDS_ROTATE_RIGHT(hash,11); + hash += (hash << 6); + hash ^= STBDS_ROTATE_RIGHT(hash,22); + return hash+seed; +} + +#ifdef STBDS_SIPHASH_2_4 +#define STBDS_SIPHASH_C_ROUNDS 2 +#define STBDS_SIPHASH_D_ROUNDS 4 +typedef int STBDS_SIPHASH_2_4_can_only_be_used_in_64_bit_builds[sizeof(size_t) == 8 ? 1 : -1]; +#endif + +#ifndef STBDS_SIPHASH_C_ROUNDS +#define STBDS_SIPHASH_C_ROUNDS 1 +#endif +#ifndef STBDS_SIPHASH_D_ROUNDS +#define STBDS_SIPHASH_D_ROUNDS 1 +#endif + +#ifdef _MSC_VER +#pragma warning(push) +#pragma warning(disable:4127) // conditional expression is constant, for do..while(0) and sizeof()== +#endif + +static size_t stbds_siphash_bytes(void *p, size_t len, size_t seed) +{ + unsigned char *d = (unsigned char *) p; + size_t i,j; + size_t v0,v1,v2,v3, data; + + // hash that works on 32- or 64-bit registers without knowing which we have + // (computes different results on 32-bit and 64-bit platform) + // derived from siphash, but on 32-bit platforms very different as it uses 4 32-bit state not 4 64-bit + v0 = ((((size_t) 0x736f6d65 << 16) << 16) + 0x70736575) ^ seed; + v1 = ((((size_t) 0x646f7261 << 16) << 16) + 0x6e646f6d) ^ ~seed; + v2 = ((((size_t) 0x6c796765 << 16) << 16) + 0x6e657261) ^ seed; + v3 = ((((size_t) 0x74656462 << 16) << 16) + 0x79746573) ^ ~seed; + + #ifdef STBDS_TEST_SIPHASH_2_4 + // hardcoded with key material in the siphash test vectors + v0 ^= 0x0706050403020100ull ^ seed; + v1 ^= 0x0f0e0d0c0b0a0908ull ^ ~seed; + v2 ^= 0x0706050403020100ull ^ seed; + v3 ^= 0x0f0e0d0c0b0a0908ull ^ ~seed; + #endif + + #define STBDS_SIPROUND() \ + do { \ + v0 += v1; v1 = STBDS_ROTATE_LEFT(v1, 13); v1 ^= v0; v0 = STBDS_ROTATE_LEFT(v0,STBDS_SIZE_T_BITS/2); \ + v2 += v3; v3 = STBDS_ROTATE_LEFT(v3, 16); v3 ^= v2; \ + v2 += v1; v1 = STBDS_ROTATE_LEFT(v1, 17); v1 ^= v2; v2 = STBDS_ROTATE_LEFT(v2,STBDS_SIZE_T_BITS/2); \ + v0 += v3; v3 = STBDS_ROTATE_LEFT(v3, 21); v3 ^= v0; \ + } while (0) + + for (i=0; i+sizeof(size_t) <= len; i += sizeof(size_t), d += sizeof(size_t)) { + data = d[0] | (d[1] << 8) | (d[2] << 16) | (d[3] << 24); + data |= (size_t) (d[4] | (d[5] << 8) | (d[6] << 16) | (d[7] << 24)) << 16 << 16; // discarded if size_t == 4 + + v3 ^= data; + for (j=0; j < STBDS_SIPHASH_C_ROUNDS; ++j) + STBDS_SIPROUND(); + v0 ^= data; + } + data = len << (STBDS_SIZE_T_BITS-8); + switch (len - i) { + case 7: data |= ((size_t) d[6] << 24) << 24; // fall through + case 6: data |= ((size_t) d[5] << 20) << 20; // fall through + case 5: data |= ((size_t) d[4] << 16) << 16; // fall through + case 4: data |= (d[3] << 24); // fall through + case 3: data |= (d[2] << 16); // fall through + case 2: data |= (d[1] << 8); // fall through + case 1: data |= d[0]; // fall through + case 0: break; + } + v3 ^= data; + for (j=0; j < STBDS_SIPHASH_C_ROUNDS; ++j) + STBDS_SIPROUND(); + v0 ^= data; + v2 ^= 0xff; + for (j=0; j < STBDS_SIPHASH_D_ROUNDS; ++j) + STBDS_SIPROUND(); + +#ifdef STBDS_SIPHASH_2_4 + return v0^v1^v2^v3; +#else + return v1^v2^v3; // slightly stronger since v0^v3 in above cancels out final round operation? I tweeted at the authors of SipHash about this but they didn't reply +#endif +} + +size_t stbds_hash_bytes(void *p, size_t len, size_t seed) +{ +#ifdef STBDS_SIPHASH_2_4 + return stbds_siphash_bytes(p,len,seed); +#else + unsigned char *d = (unsigned char *) p; + + if (len == 4) { + unsigned int hash = d[0] | (d[1] << 8) | (d[2] << 16) | (d[3] << 24); + #if 0 + // HASH32-A Bob Jenkin's hash function w/o large constants + hash ^= seed; + hash -= (hash<<6); + hash ^= (hash>>17); + hash -= (hash<<9); + hash ^= seed; + hash ^= (hash<<4); + hash -= (hash<<3); + hash ^= (hash<<10); + hash ^= (hash>>15); + #elif 1 + // HASH32-BB Bob Jenkin's presumably-accidental version of Thomas Wang hash with rotates turned into shifts. + // Note that converting these back to rotates makes it run a lot slower, presumably due to collisions, so I'm + // not really sure what's going on. + hash ^= seed; + hash = (hash ^ 61) ^ (hash >> 16); + hash = hash + (hash << 3); + hash = hash ^ (hash >> 4); + hash = hash * 0x27d4eb2d; + hash ^= seed; + hash = hash ^ (hash >> 15); + #else // HASH32-C - Murmur3 + hash ^= seed; + hash *= 0xcc9e2d51; + hash = (hash << 17) | (hash >> 15); + hash *= 0x1b873593; + hash ^= seed; + hash = (hash << 19) | (hash >> 13); + hash = hash*5 + 0xe6546b64; + hash ^= hash >> 16; + hash *= 0x85ebca6b; + hash ^= seed; + hash ^= hash >> 13; + hash *= 0xc2b2ae35; + hash ^= hash >> 16; + #endif + // Following statistics were measured on a Core i7-6700 @ 4.00Ghz, compiled with clang 7.0.1 -O2 + // Note that the larger tables have high variance as they were run fewer times + // HASH32-A // HASH32-BB // HASH32-C + // 0.10ms // 0.10ms // 0.10ms : 2,000 inserts creating 2K table + // 0.96ms // 0.95ms // 0.99ms : 20,000 inserts creating 20K table + // 14.69ms // 14.43ms // 14.97ms : 200,000 inserts creating 200K table + // 199.99ms // 195.36ms // 202.05ms : 2,000,000 inserts creating 2M table + // 2234.84ms // 2187.74ms // 2240.38ms : 20,000,000 inserts creating 20M table + // 55.68ms // 53.72ms // 57.31ms : 500,000 inserts & deletes in 2K table + // 63.43ms // 61.99ms // 65.73ms : 500,000 inserts & deletes in 20K table + // 80.04ms // 77.96ms // 81.83ms : 500,000 inserts & deletes in 200K table + // 100.42ms // 97.40ms // 102.39ms : 500,000 inserts & deletes in 2M table + // 119.71ms // 120.59ms // 121.63ms : 500,000 inserts & deletes in 20M table + // 185.28ms // 195.15ms // 187.74ms : 500,000 inserts & deletes in 200M table + // 15.58ms // 14.79ms // 15.52ms : 200,000 inserts creating 200K table with varying key spacing + + return (((size_t) hash << 16 << 16) | hash) ^ seed; + } else if (len == 8 && sizeof(size_t) == 8) { + size_t hash = d[0] | (d[1] << 8) | (d[2] << 16) | (d[3] << 24); + hash |= (size_t) (d[4] | (d[5] << 8) | (d[6] << 16) | (d[7] << 24)) << 16 << 16; // avoid warning if size_t == 4 + hash ^= seed; + hash = (~hash) + (hash << 21); + hash ^= STBDS_ROTATE_RIGHT(hash,24); + hash *= 265; + hash ^= STBDS_ROTATE_RIGHT(hash,14); + hash ^= seed; + hash *= 21; + hash ^= STBDS_ROTATE_RIGHT(hash,28); + hash += (hash << 31); + hash = (~hash) + (hash << 18); + return hash; + } else { + return stbds_siphash_bytes(p,len,seed); + } +#endif +} +#ifdef _MSC_VER +#pragma warning(pop) +#endif + + +static int stbds_is_key_equal(void *a, size_t elemsize, void *key, size_t keysize, size_t keyoffset, int mode, size_t i) +{ + if (mode >= STBDS_HM_STRING) + return 0==strcmp((char *) key, * (char **) ((char *) a + elemsize*i + keyoffset)); + else + return 0==memcmp(key, (char *) a + elemsize*i + keyoffset, keysize); +} + +#define STBDS_HASH_TO_ARR(x,elemsize) ((char*) (x) - (elemsize)) +#define STBDS_ARR_TO_HASH(x,elemsize) ((char*) (x) + (elemsize)) + +#define stbds_hash_table(a) ((stbds_hash_index *) stbds_header(a)->hash_table) + +void stbds_hmfree_func(void *a, size_t elemsize) +{ + if (a == NULL) return; + if (stbds_hash_table(a) != NULL) { + if (stbds_hash_table(a)->string.mode == STBDS_SH_STRDUP) { + size_t i; + // skip 0th element, which is default + for (i=1; i < stbds_header(a)->length; ++i) + STBDS_FREE(NULL, *(char**) ((char *) a + elemsize*i)); + } + stbds_strreset(&stbds_hash_table(a)->string); + } + STBDS_FREE(NULL, stbds_header(a)->hash_table); + STBDS_FREE(NULL, stbds_header(a)); +} + +static ptrdiff_t stbds_hm_find_slot(void *a, size_t elemsize, void *key, size_t keysize, size_t keyoffset, int mode) +{ + void *raw_a = STBDS_HASH_TO_ARR(a,elemsize); + stbds_hash_index *table = stbds_hash_table(raw_a); + size_t hash = mode >= STBDS_HM_STRING ? stbds_hash_string((char*)key,table->seed) : stbds_hash_bytes(key, keysize,table->seed); + size_t step = STBDS_BUCKET_LENGTH; + size_t limit,i; + size_t pos; + stbds_hash_bucket *bucket; + + if (hash < 2) hash += 2; // stored hash values are forbidden from being 0, so we can detect empty slots + + pos = stbds_probe_position(hash, table->slot_count, table->slot_count_log2); + + for (;;) { + STBDS_STATS(++stbds_hash_probes); + bucket = &table->storage[pos >> STBDS_BUCKET_SHIFT]; + + // start searching from pos to end of bucket, this should help performance on small hash tables that fit in cache + for (i=pos & STBDS_BUCKET_MASK; i < STBDS_BUCKET_LENGTH; ++i) { + if (bucket->hash[i] == hash) { + if (stbds_is_key_equal(a, elemsize, key, keysize, keyoffset, mode, bucket->index[i])) { + return (pos & ~STBDS_BUCKET_MASK)+i; + } + } else if (bucket->hash[i] == STBDS_HASH_EMPTY) { + return -1; + } + } + + // search from beginning of bucket to pos + limit = pos & STBDS_BUCKET_MASK; + for (i = 0; i < limit; ++i) { + if (bucket->hash[i] == hash) { + if (stbds_is_key_equal(a, elemsize, key, keysize, keyoffset, mode, bucket->index[i])) { + return (pos & ~STBDS_BUCKET_MASK)+i; + } + } else if (bucket->hash[i] == STBDS_HASH_EMPTY) { + return -1; + } + } + + // quadratic probing + pos += step; + step += STBDS_BUCKET_LENGTH; + pos &= (table->slot_count-1); + } + /* NOTREACHED */ +} + +void * stbds_hmget_key_ts(void *a, size_t elemsize, void *key, size_t keysize, ptrdiff_t *temp, int mode) +{ + size_t keyoffset = 0; + if (a == NULL) { + // make it non-empty so we can return a temp + a = stbds_arrgrowf(0, elemsize, 0, 1); + stbds_header(a)->length += 1; + memset(a, 0, elemsize); + *temp = STBDS_INDEX_EMPTY; + // adjust a to point after the default element + return STBDS_ARR_TO_HASH(a,elemsize); + } else { + stbds_hash_index *table; + void *raw_a = STBDS_HASH_TO_ARR(a,elemsize); + // adjust a to point to the default element + table = (stbds_hash_index *) stbds_header(raw_a)->hash_table; + if (table == 0) { + *temp = -1; + } else { + ptrdiff_t slot = stbds_hm_find_slot(a, elemsize, key, keysize, keyoffset, mode); + if (slot < 0) { + *temp = STBDS_INDEX_EMPTY; + } else { + stbds_hash_bucket *b = &table->storage[slot >> STBDS_BUCKET_SHIFT]; + *temp = b->index[slot & STBDS_BUCKET_MASK]; + } + } + return a; + } +} + +void * stbds_hmget_key(void *a, size_t elemsize, void *key, size_t keysize, int mode) +{ + ptrdiff_t temp; + void *p = stbds_hmget_key_ts(a, elemsize, key, keysize, &temp, mode); + stbds_temp(STBDS_HASH_TO_ARR(p,elemsize)) = temp; + return p; +} + +void * stbds_hmput_default(void *a, size_t elemsize) +{ + // three cases: + // a is NULL <- allocate + // a has a hash table but no entries, because of shmode <- grow + // a has entries <- do nothing + if (a == NULL || stbds_header(STBDS_HASH_TO_ARR(a,elemsize))->length == 0) { + a = stbds_arrgrowf(a ? STBDS_HASH_TO_ARR(a,elemsize) : NULL, elemsize, 0, 1); + stbds_header(a)->length += 1; + memset(a, 0, elemsize); + a=STBDS_ARR_TO_HASH(a,elemsize); + } + return a; +} + +static char *stbds_strdup(char *str); + +void *stbds_hmput_key(void *a, size_t elemsize, void *key, size_t keysize, int mode) +{ + size_t keyoffset=0; + void *raw_a; + stbds_hash_index *table; + + if (a == NULL) { + a = stbds_arrgrowf(0, elemsize, 0, 1); + memset(a, 0, elemsize); + stbds_header(a)->length += 1; + // adjust a to point AFTER the default element + a = STBDS_ARR_TO_HASH(a,elemsize); + } + + // adjust a to point to the default element + raw_a = a; + a = STBDS_HASH_TO_ARR(a,elemsize); + + table = (stbds_hash_index *) stbds_header(a)->hash_table; + + if (table == NULL || table->used_count >= table->used_count_threshold) { + stbds_hash_index *nt; + size_t slot_count; + + slot_count = (table == NULL) ? STBDS_BUCKET_LENGTH : table->slot_count*2; + nt = stbds_make_hash_index(slot_count, table); + if (table) + STBDS_FREE(NULL, table); + else + nt->string.mode = mode >= STBDS_HM_STRING ? STBDS_SH_DEFAULT : 0; + stbds_header(a)->hash_table = table = nt; + STBDS_STATS(++stbds_hash_grow); + } + + // we iterate hash table explicitly because we want to track if we saw a tombstone + { + size_t hash = mode >= STBDS_HM_STRING ? stbds_hash_string((char*)key,table->seed) : stbds_hash_bytes(key, keysize,table->seed); + size_t step = STBDS_BUCKET_LENGTH; + size_t pos; + ptrdiff_t tombstone = -1; + stbds_hash_bucket *bucket; + + // stored hash values are forbidden from being 0, so we can detect empty slots to early out quickly + if (hash < 2) hash += 2; + + pos = stbds_probe_position(hash, table->slot_count, table->slot_count_log2); + + for (;;) { + size_t limit, i; + STBDS_STATS(++stbds_hash_probes); + bucket = &table->storage[pos >> STBDS_BUCKET_SHIFT]; + + // start searching from pos to end of bucket + for (i=pos & STBDS_BUCKET_MASK; i < STBDS_BUCKET_LENGTH; ++i) { + if (bucket->hash[i] == hash) { + if (stbds_is_key_equal(raw_a, elemsize, key, keysize, keyoffset, mode, bucket->index[i])) { + stbds_temp(a) = bucket->index[i]; + if (mode >= STBDS_HM_STRING) + stbds_temp_key(a) = * (char **) ((char *) raw_a + elemsize*bucket->index[i] + keyoffset); + return STBDS_ARR_TO_HASH(a,elemsize); + } + } else if (bucket->hash[i] == 0) { + pos = (pos & ~STBDS_BUCKET_MASK) + i; + goto found_empty_slot; + } else if (tombstone < 0) { + if (bucket->index[i] == STBDS_INDEX_DELETED) + tombstone = (ptrdiff_t) ((pos & ~STBDS_BUCKET_MASK) + i); + } + } + + // search from beginning of bucket to pos + limit = pos & STBDS_BUCKET_MASK; + for (i = 0; i < limit; ++i) { + if (bucket->hash[i] == hash) { + if (stbds_is_key_equal(raw_a, elemsize, key, keysize, keyoffset, mode, bucket->index[i])) { + stbds_temp(a) = bucket->index[i]; + return STBDS_ARR_TO_HASH(a,elemsize); + } + } else if (bucket->hash[i] == 0) { + pos = (pos & ~STBDS_BUCKET_MASK) + i; + goto found_empty_slot; + } else if (tombstone < 0) { + if (bucket->index[i] == STBDS_INDEX_DELETED) + tombstone = (ptrdiff_t) ((pos & ~STBDS_BUCKET_MASK) + i); + } + } + + // quadratic probing + pos += step; + step += STBDS_BUCKET_LENGTH; + pos &= (table->slot_count-1); + } + found_empty_slot: + if (tombstone >= 0) { + pos = tombstone; + --table->tombstone_count; + } + ++table->used_count; + + { + ptrdiff_t i = (ptrdiff_t) stbds_arrlen(a); + // we want to do stbds_arraddn(1), but we can't use the macros since we don't have something of the right type + if ((size_t) i+1 > stbds_arrcap(a)) + *(void **) &a = stbds_arrgrowf(a, elemsize, 1, 0); + raw_a = STBDS_ARR_TO_HASH(a,elemsize); + + STBDS_ASSERT((size_t) i+1 <= stbds_arrcap(a)); + stbds_header(a)->length = i+1; + bucket = &table->storage[pos >> STBDS_BUCKET_SHIFT]; + bucket->hash[pos & STBDS_BUCKET_MASK] = hash; + bucket->index[pos & STBDS_BUCKET_MASK] = i-1; + stbds_temp(a) = i-1; + + switch (table->string.mode) { + case STBDS_SH_STRDUP: stbds_temp_key(a) = *(char **) ((char *) a + elemsize*i) = stbds_strdup((char*) key); break; + case STBDS_SH_ARENA: stbds_temp_key(a) = *(char **) ((char *) a + elemsize*i) = stbds_stralloc(&table->string, (char*)key); break; + case STBDS_SH_DEFAULT: stbds_temp_key(a) = *(char **) ((char *) a + elemsize*i) = (char *) key; break; + default: memcpy((char *) a + elemsize*i, key, keysize); break; + } + } + return STBDS_ARR_TO_HASH(a,elemsize); + } +} + +void * stbds_shmode_func(size_t elemsize, int mode) +{ + void *a = stbds_arrgrowf(0, elemsize, 0, 1); + stbds_hash_index *h; + memset(a, 0, elemsize); + stbds_header(a)->length = 1; + stbds_header(a)->hash_table = h = (stbds_hash_index *) stbds_make_hash_index(STBDS_BUCKET_LENGTH, NULL); + h->string.mode = (unsigned char) mode; + return STBDS_ARR_TO_HASH(a,elemsize); +} + +void * stbds_hmdel_key(void *a, size_t elemsize, void *key, size_t keysize, size_t keyoffset, int mode) +{ + if (a == NULL) { + return 0; + } else { + stbds_hash_index *table; + void *raw_a = STBDS_HASH_TO_ARR(a,elemsize); + table = (stbds_hash_index *) stbds_header(raw_a)->hash_table; + stbds_temp(raw_a) = 0; + if (table == 0) { + return a; + } else { + ptrdiff_t slot; + slot = stbds_hm_find_slot(a, elemsize, key, keysize, keyoffset, mode); + if (slot < 0) + return a; + else { + stbds_hash_bucket *b = &table->storage[slot >> STBDS_BUCKET_SHIFT]; + int i = slot & STBDS_BUCKET_MASK; + ptrdiff_t old_index = b->index[i]; + ptrdiff_t final_index = (ptrdiff_t) stbds_arrlen(raw_a)-1-1; // minus one for the raw_a vs a, and minus one for 'last' + STBDS_ASSERT(slot < (ptrdiff_t) table->slot_count); + --table->used_count; + ++table->tombstone_count; + stbds_temp(raw_a) = 1; + STBDS_ASSERT(table->used_count >= 0); + //STBDS_ASSERT(table->tombstone_count < table->slot_count/4); + b->hash[i] = STBDS_HASH_DELETED; + b->index[i] = STBDS_INDEX_DELETED; + + if (mode == STBDS_HM_STRING && table->string.mode == STBDS_SH_STRDUP) + STBDS_FREE(NULL, *(char**) ((char *) a+elemsize*old_index)); + + // if indices are the same, memcpy is a no-op, but back-pointer-fixup will fail, so skip + if (old_index != final_index) { + // swap delete + memmove((char*) a + elemsize*old_index, (char*) a + elemsize*final_index, elemsize); + + // now find the slot for the last element + if (mode == STBDS_HM_STRING) + slot = stbds_hm_find_slot(a, elemsize, *(char**) ((char *) a+elemsize*old_index + keyoffset), keysize, keyoffset, mode); + else + slot = stbds_hm_find_slot(a, elemsize, (char* ) a+elemsize*old_index + keyoffset, keysize, keyoffset, mode); + STBDS_ASSERT(slot >= 0); + b = &table->storage[slot >> STBDS_BUCKET_SHIFT]; + i = slot & STBDS_BUCKET_MASK; + STBDS_ASSERT(b->index[i] == final_index); + b->index[i] = old_index; + } + stbds_header(raw_a)->length -= 1; + + if (table->used_count < table->used_count_shrink_threshold && table->slot_count > STBDS_BUCKET_LENGTH) { + stbds_header(raw_a)->hash_table = stbds_make_hash_index(table->slot_count>>1, table); + STBDS_FREE(NULL, table); + STBDS_STATS(++stbds_hash_shrink); + } else if (table->tombstone_count > table->tombstone_count_threshold) { + stbds_header(raw_a)->hash_table = stbds_make_hash_index(table->slot_count , table); + STBDS_FREE(NULL, table); + STBDS_STATS(++stbds_hash_rebuild); + } + + return a; + } + } + } + /* NOTREACHED */ +} + +static char *stbds_strdup(char *str) +{ + // to keep replaceable allocator simple, we don't want to use strdup. + // rolling our own also avoids problem of strdup vs _strdup + size_t len = strlen(str)+1; + char *p = (char*) STBDS_REALLOC(NULL, 0, len); + memmove(p, str, len); + return p; +} + +#ifndef STBDS_STRING_ARENA_BLOCKSIZE_MIN +#define STBDS_STRING_ARENA_BLOCKSIZE_MIN 512u +#endif +#ifndef STBDS_STRING_ARENA_BLOCKSIZE_MAX +#define STBDS_STRING_ARENA_BLOCKSIZE_MAX (1u<<20) +#endif + +char *stbds_stralloc(stbds_string_arena *a, char *str) +{ + char *p; + size_t len = strlen(str)+1; + if (len > a->remaining) { + // compute the next blocksize + size_t blocksize = a->block; + + // size is 512, 512, 1024, 1024, 2048, 2048, 4096, 4096, etc., so that + // there are log(SIZE) allocations to free when we destroy the table + blocksize = (size_t) (STBDS_STRING_ARENA_BLOCKSIZE_MIN) << (blocksize>>1); + + // if size is under 1M, advance to next blocktype + if (blocksize < (size_t)(STBDS_STRING_ARENA_BLOCKSIZE_MAX)) + ++a->block; + + if (len > blocksize) { + // if string is larger than blocksize, then just allocate the full size. + // note that we still advance string_block so block size will continue + // increasing, so e.g. if somebody only calls this with 1000-long strings, + // eventually the arena will start doubling and handling those as well + stbds_string_block *sb = (stbds_string_block *) STBDS_REALLOC(NULL, 0, sizeof(*sb)-8 + len); + memmove(sb->storage, str, len); + if (a->storage) { + // insert it after the first element, so that we don't waste the space there + sb->next = a->storage->next; + a->storage->next = sb; + } else { + sb->next = 0; + a->storage = sb; + a->remaining = 0; // this is redundant, but good for clarity + } + return sb->storage; + } else { + stbds_string_block *sb = (stbds_string_block *) STBDS_REALLOC(NULL, 0, sizeof(*sb)-8 + blocksize); + sb->next = a->storage; + a->storage = sb; + a->remaining = blocksize; + } + } + + STBDS_ASSERT(len <= a->remaining); + p = a->storage->storage + a->remaining - len; + a->remaining -= len; + memmove(p, str, len); + return p; +} + +void stbds_strreset(stbds_string_arena *a) +{ + stbds_string_block *x,*y; + x = a->storage; + while (x) { + y = x->next; + STBDS_FREE(NULL, x); + x = y; + } + memset(a, 0, sizeof(*a)); +} + +#endif + +////////////////////////////////////////////////////////////////////////////// +// +// UNIT TESTS +// + +#ifdef STBDS_UNIT_TESTS +#include +#ifdef STBDS_ASSERT_WAS_UNDEFINED +#undef STBDS_ASSERT +#endif +#ifndef STBDS_ASSERT +#define STBDS_ASSERT assert +#include +#endif + +typedef struct { int key,b,c,d; } stbds_struct; +typedef struct { int key[2],b,c,d; } stbds_struct2; + +static char buffer[256]; +char *strkey(int n) +{ +#if defined(_WIN32) && defined(__STDC_WANT_SECURE_LIB__) + sprintf_s(buffer, sizeof(buffer), "test_%d", n); +#else + sprintf(buffer, "test_%d", n); +#endif + return buffer; +} + +void stbds_unit_tests(void) +{ +#if defined(_MSC_VER) && _MSC_VER <= 1200 && defined(__cplusplus) + // VC6 C++ doesn't like the template<> trick on unnamed structures, so do nothing! + STBDS_ASSERT(0); +#else + const int testsize = 100000; + const int testsize2 = testsize/20; + int *arr=NULL; + struct { int key; int value; } *intmap = NULL; + struct { char *key; int value; } *strmap = NULL, s; + struct { stbds_struct key; int value; } *map = NULL; + stbds_struct *map2 = NULL; + stbds_struct2 *map3 = NULL; + stbds_string_arena sa = { 0 }; + int key3[2] = { 1,2 }; + ptrdiff_t temp; + + int i,j; + + STBDS_ASSERT(arrlen(arr)==0); + for (i=0; i < 20000; i += 50) { + for (j=0; j < i; ++j) + arrpush(arr,j); + arrfree(arr); + } + + for (i=0; i < 4; ++i) { + arrpush(arr,1); arrpush(arr,2); arrpush(arr,3); arrpush(arr,4); + arrdel(arr,i); + arrfree(arr); + arrpush(arr,1); arrpush(arr,2); arrpush(arr,3); arrpush(arr,4); + arrdelswap(arr,i); + arrfree(arr); + } + + for (i=0; i < 5; ++i) { + arrpush(arr,1); arrpush(arr,2); arrpush(arr,3); arrpush(arr,4); + stbds_arrins(arr,i,5); + STBDS_ASSERT(arr[i] == 5); + if (i < 4) + STBDS_ASSERT(arr[4] == 4); + arrfree(arr); + } + + i = 1; + STBDS_ASSERT(hmgeti(intmap,i) == -1); + hmdefault(intmap, -2); + STBDS_ASSERT(hmgeti(intmap, i) == -1); + STBDS_ASSERT(hmget (intmap, i) == -2); + for (i=0; i < testsize; i+=2) + hmput(intmap, i, i*5); + for (i=0; i < testsize; i+=1) { + if (i & 1) STBDS_ASSERT(hmget(intmap, i) == -2 ); + else STBDS_ASSERT(hmget(intmap, i) == i*5); + if (i & 1) STBDS_ASSERT(hmget_ts(intmap, i, temp) == -2 ); + else STBDS_ASSERT(hmget_ts(intmap, i, temp) == i*5); + } + for (i=0; i < testsize; i+=2) + hmput(intmap, i, i*3); + for (i=0; i < testsize; i+=1) + if (i & 1) STBDS_ASSERT(hmget(intmap, i) == -2 ); + else STBDS_ASSERT(hmget(intmap, i) == i*3); + for (i=2; i < testsize; i+=4) + hmdel(intmap, i); // delete half the entries + for (i=0; i < testsize; i+=1) + if (i & 3) STBDS_ASSERT(hmget(intmap, i) == -2 ); + else STBDS_ASSERT(hmget(intmap, i) == i*3); + for (i=0; i < testsize; i+=1) + hmdel(intmap, i); // delete the rest of the entries + for (i=0; i < testsize; i+=1) + STBDS_ASSERT(hmget(intmap, i) == -2 ); + hmfree(intmap); + for (i=0; i < testsize; i+=2) + hmput(intmap, i, i*3); + hmfree(intmap); + + #if defined(__clang__) || defined(__GNUC__) + #ifndef __cplusplus + intmap = NULL; + hmput(intmap, 15, 7); + hmput(intmap, 11, 3); + hmput(intmap, 9, 5); + STBDS_ASSERT(hmget(intmap, 9) == 5); + STBDS_ASSERT(hmget(intmap, 11) == 3); + STBDS_ASSERT(hmget(intmap, 15) == 7); + #endif + #endif + + for (i=0; i < testsize; ++i) + stralloc(&sa, strkey(i)); + strreset(&sa); + + { + s.key = "a", s.value = 1; + shputs(strmap, s); + STBDS_ASSERT(*strmap[0].key == 'a'); + STBDS_ASSERT(strmap[0].key == s.key); + STBDS_ASSERT(strmap[0].value == s.value); + shfree(strmap); + } + + { + s.key = "a", s.value = 1; + sh_new_strdup(strmap); + shputs(strmap, s); + STBDS_ASSERT(*strmap[0].key == 'a'); + STBDS_ASSERT(strmap[0].key != s.key); + STBDS_ASSERT(strmap[0].value == s.value); + shfree(strmap); + } + + { + s.key = "a", s.value = 1; + sh_new_arena(strmap); + shputs(strmap, s); + STBDS_ASSERT(*strmap[0].key == 'a'); + STBDS_ASSERT(strmap[0].key != s.key); + STBDS_ASSERT(strmap[0].value == s.value); + shfree(strmap); + } + + for (j=0; j < 2; ++j) { + STBDS_ASSERT(shgeti(strmap,"foo") == -1); + if (j == 0) + sh_new_strdup(strmap); + else + sh_new_arena(strmap); + STBDS_ASSERT(shgeti(strmap,"foo") == -1); + shdefault(strmap, -2); + STBDS_ASSERT(shgeti(strmap,"foo") == -1); + for (i=0; i < testsize; i+=2) + shput(strmap, strkey(i), i*3); + for (i=0; i < testsize; i+=1) + if (i & 1) STBDS_ASSERT(shget(strmap, strkey(i)) == -2 ); + else STBDS_ASSERT(shget(strmap, strkey(i)) == i*3); + for (i=2; i < testsize; i+=4) + shdel(strmap, strkey(i)); // delete half the entries + for (i=0; i < testsize; i+=1) + if (i & 3) STBDS_ASSERT(shget(strmap, strkey(i)) == -2 ); + else STBDS_ASSERT(shget(strmap, strkey(i)) == i*3); + for (i=0; i < testsize; i+=1) + shdel(strmap, strkey(i)); // delete the rest of the entries + for (i=0; i < testsize; i+=1) + STBDS_ASSERT(shget(strmap, strkey(i)) == -2 ); + shfree(strmap); + } + + { + struct { char *key; char value; } *hash = NULL; + char name[4] = "jen"; + shput(hash, "bob" , 'h'); + shput(hash, "sally" , 'e'); + shput(hash, "fred" , 'l'); + shput(hash, "jen" , 'x'); + shput(hash, "doug" , 'o'); + + shput(hash, name , 'l'); + shfree(hash); + } + + for (i=0; i < testsize; i += 2) { + stbds_struct s = { i,i*2,i*3,i*4 }; + hmput(map, s, i*5); + } + + for (i=0; i < testsize; i += 1) { + stbds_struct s = { i,i*2,i*3 ,i*4 }; + stbds_struct t = { i,i*2,i*3+1,i*4 }; + if (i & 1) STBDS_ASSERT(hmget(map, s) == 0); + else STBDS_ASSERT(hmget(map, s) == i*5); + if (i & 1) STBDS_ASSERT(hmget_ts(map, s, temp) == 0); + else STBDS_ASSERT(hmget_ts(map, s, temp) == i*5); + //STBDS_ASSERT(hmget(map, t.key) == 0); + } + + for (i=0; i < testsize; i += 2) { + stbds_struct s = { i,i*2,i*3,i*4 }; + hmputs(map2, s); + } + hmfree(map); + + for (i=0; i < testsize; i += 1) { + stbds_struct s = { i,i*2,i*3,i*4 }; + stbds_struct t = { i,i*2,i*3+1,i*4 }; + if (i & 1) STBDS_ASSERT(hmgets(map2, s.key).d == 0); + else STBDS_ASSERT(hmgets(map2, s.key).d == i*4); + //STBDS_ASSERT(hmgetp(map2, t.key) == 0); + } + hmfree(map2); + + for (i=0; i < testsize; i += 2) { + stbds_struct2 s = { { i,i*2 }, i*3,i*4, i*5 }; + hmputs(map3, s); + } + for (i=0; i < testsize; i += 1) { + stbds_struct2 s = { { i,i*2}, i*3, i*4, i*5 }; + stbds_struct2 t = { { i,i*2}, i*3+1, i*4, i*5 }; + if (i & 1) STBDS_ASSERT(hmgets(map3, s.key).d == 0); + else STBDS_ASSERT(hmgets(map3, s.key).d == i*5); + //STBDS_ASSERT(hmgetp(map3, t.key) == 0); + } +#endif +} +#endif + + +/* +------------------------------------------------------------------------------ +This software is available under 2 licenses -- choose whichever you prefer. +------------------------------------------------------------------------------ +ALTERNATIVE A - MIT License +Copyright (c) 2019 Sean Barrett +Permission is hereby granted, free of charge, to any person obtaining a copy of +this software and associated documentation files (the "Software"), to deal in +the Software without restriction, including without limitation the rights to +use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies +of the Software, and to permit persons to whom the Software is furnished to do +so, subject to the following conditions: +The above copyright notice and this permission notice shall be included in all +copies or substantial portions of the Software. +THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER +LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, +OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE +SOFTWARE. +------------------------------------------------------------------------------ +ALTERNATIVE B - Public Domain (www.unlicense.org) +This is free and unencumbered software released into the public domain. +Anyone is free to copy, modify, publish, use, compile, sell, or distribute this +software, either in source code form or as a compiled binary, for any purpose, +commercial or non-commercial, and by any means. +In jurisdictions that recognize copyright laws, the author or authors of this +software dedicate any and all copyright interest in the software to the public +domain. We make this dedication for the benefit of the public at large and to +the detriment of our heirs and successors. We intend this dedication to be an +overt act of relinquishment in perpetuity of all present and future rights to +this software under copyright law. +THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR +IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, +FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE +AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN +ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION +WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. +------------------------------------------------------------------------------ +*/ diff --git a/src/main.c b/src/main.c index eb33868..d36e09c 100644 --- a/src/main.c +++ b/src/main.c @@ -1,17 +1,80 @@ +#include #include #include #include #include +#include +#include +#define STB_DS_IMPLEMENTATION +#define STBDS_NO_SHORT_NAMES +#include "../contrib/orlp/ipow.h" +#include "../contrib/stb/stb_ds.h" #include "../includes/cg.h" #include "../includes/matrix.h" #include "../includes/permutation.h" -static void ReadArguments(char *from, size_t *into, const char *varname) { - if (!sscanf(from, "%zu", into)) { - fprintf(stderr, "Failed to read %s.", varname); - exit(EXIT_FAILURE); +static uintmax_t _timing_last_count = 0; +static clock_t _timing_last_time = 0.; +static float _timing_rate = 0.; +static float _timing_exp_backoff = 1.; + +static void ReportProgress(uintmax_t current, uintmax_t total, clock_t now) { + _Bool updated = 0; +#pragma omp critical + { + if (current >= _timing_last_count) { + float inferred_rate = (float)(current - _timing_last_count) / + ((float)(now - _timing_last_time) / CLOCKS_PER_SEC); + _timing_rate = _timing_rate * (1. - _timing_exp_backoff) + + inferred_rate * _timing_exp_backoff; + if (_timing_exp_backoff > 0.0001) { + _timing_exp_backoff *= 0.99; + } + _timing_last_count = current; + _timing_last_time = now; + updated = 1; + } } + + if (updated) { + uintmax_t time_left = (total - current) / _timing_rate; + + uintmax_t days = time_left / 60 / 60 / 24; + if (days > 0) { + fprintf(stderr, + "\33[2K\r%zu/%zu (%" PRIuMAX " iter/sec | About %" PRIuMAX + " days left.)", + current, total, (uintmax_t)_timing_rate, days); + } else { + uint8_t hours = (time_left % (60 * 60 * 24)) / 60; + uint8_t minutes = (time_left % (60 * 60)) / 60; + uint8_t seconds = time_left % 60; + + fprintf(stderr, + "\33[2K\r%zu/%zu (%" PRIuMAX " iter/sec | About %" PRIu8 + "h%" PRIu8 "m%" PRIu8 "s left.)", + current, total, (uintmax_t)_timing_rate, hours, minutes, seconds); + } + + fflush(stderr); + } +} + +static uintmax_t Factorial(uint8_t value) { + uintmax_t acc = 1; + for (uint8_t i = 2; i <= value; i++) { + acc *= (uintmax_t)value; + } + return acc; +} + +static _Bool ReadArguments(char *from, size_t *into, const char *varname) { + if (!sscanf(from, "%zu", into)) { + fprintf(stderr, "Failed to parse %s as a positive integer.\n", varname); + return 0; + } + return 1; } static inline void AdvanceConditionalPermutations( @@ -40,220 +103,325 @@ typedef enum { kPRawFmt, } arg_format_t; -int main(int argc, char *argv[]) { - if (argc < 5) { - fprintf(stderr, - "Usage:\n ./main.exe [--cg|--p|--p-raw]"); - exit(EXIT_FAILURE); +typedef struct { + size_t a_out; + size_t b_out; + size_t a_in; + size_t b_in; + arg_format_t formatting; +} args_t; + +static args_t ParseArgs(size_t argc, char *argv[]) { + char **positionals = NULL; + char **flags = NULL; + + for (size_t i = 1; i < argc; i++) { + char *arg = argv[i]; + + if (*arg == '-' && *(arg + 1) == '-') { + stbds_arrput(flags, arg + 2); + } else { + stbds_arrput(positionals, arg); + } } size_t a_out, b_out, a_in, b_in; - ReadArguments(argv[1], &a_out, "A outputs"); - ReadArguments(argv[2], &b_out, "B outputs"); - ReadArguments(argv[3], &a_in, "A inputs"); - ReadArguments(argv[4], &b_in, "B inputs"); + arg_format_t formatting; - int cg_format = kRowFmt; - if (argc > 5) { - if (strcmp(argv[5], "--cg") == 0) { - cg_format = kCgFmt; - } else if (strcmp(argv[5], "--p") == 0) { - cg_format = kPFmt; - } else if (strcmp(argv[5], "--p-raw") == 0) { - cg_format = kPRawFmt; + if (stbds_arrlen(positionals) != 4) { + goto arg_error; + } + + if (!ReadArguments(positionals[0], &a_out, "A outputs") || + !ReadArguments(positionals[1], &b_out, "B outputs") || + !ReadArguments(positionals[2], &a_in, "A inputs") || + !ReadArguments(positionals[3], &b_in, "B inputs")) { + goto arg_error; + } + + formatting = kRowFmt; + for (size_t i = 0; i < stbds_arrlenu(flags); i++) { + char *flag = flags[i]; + if (strcmp(flag, "cg") == 0) { + formatting = kCgFmt; + } else if (strcmp(flag, "p") == 0) { + formatting = kPFmt; + } else if (strcmp(flag, "p-raw") == 0) { + formatting = kPRawFmt; } } + args_t result = { + .a_in = a_in, + .a_out = a_out, + .b_in = b_in, + .b_out = b_out, + .formatting = formatting, + }; + + stbds_arrfree(positionals); + stbds_arrfree(flags); + + return result; + +arg_error: + stbds_arrfree(positionals); + stbds_arrfree(flags); + + fprintf(stderr, "Usage:\n "); + if (argc > 0) { + fprintf(stderr, "%s", argv[0]); + } else { + fprintf(stderr, "./exe"); + } + fprintf(stderr, + " [--cg|--p|--p-raw] "); + exit(EXIT_FAILURE); +} + +int main(int argc, char *argv[]) { + args_t args = ParseArgs(argc, argv); + size_t a_out, a_in, b_out, b_in; + a_out = args.a_out; + b_out = args.b_out; + a_in = args.a_in; + b_in = args.b_in; + + if (a_out < 2 || b_out < 2 || a_in < 2 || b_in < 2) { + fprintf(stderr, + "This program is not prepared to deal with input or output label " + "counts smaller than 2."); + exit(EXIT_FAILURE); + } + size_t row_len = (a_out - 1) * (b_out - 1) * a_in * b_in + (a_out - 1) * a_in + (b_out - 1) * b_in + 1; matrix_t matrix = ParseMatrix(row_len); size_t row_count = matrix.len / matrix.row_len; - data_t *p_buf = malloc(a_out * b_out * a_in * b_in * sizeof(data_t)); - data_t *cg_buf = malloc((((a_out - 1) * (b_out - 1) * a_in * b_in + - (a_out - 1) * a_in + (b_out - 1) * b_in) + - 1) * - sizeof(data_t)); _Bool *seen = calloc(row_count, sizeof(_Bool)); - - if (p_buf == NULL) { - fprintf(stderr, "Failed to allocate P notation buffer. Aborting."); - exit(EXIT_FAILURE); - } - if (cg_buf == NULL) { - fprintf(stderr, "Failed to allocate CG notation buffer. Aborting."); - exit(EXIT_FAILURE); - } if (seen == NULL) { fprintf(stderr, "Failed to allocate equivalence flag string. Aborting."); exit(EXIT_FAILURE); } - permutation_generator_t a_in_perm = PermutationNewGenerator(a_in); - permutation_generator_t b_in_perm = PermutationNewGenerator(b_in); - permutation_generator_t *a_out_perms = - malloc(a_in * sizeof(permutation_generator_t)); - permutation_generator_t *b_out_perms = - malloc(b_in * sizeof(permutation_generator_t)); - - if (a_out_perms == NULL || b_out_perms == NULL) { - fprintf(stderr, - "Failed to allocate space for conditioned permutation generators. " - "Aborting."); - exit(EXIT_FAILURE); - } - - for (size_t i = 0; i < a_in; i++) { - a_out_perms[i] = PermutationNewGenerator(a_out); - PermutationReset(a_out_perms + i); - } - for (size_t i = 0; i < b_in; i++) { - b_out_perms[i] = PermutationNewGenerator(b_out); - PermutationReset(b_out_perms + i); - } - // Start testing for equivalences. + const uintmax_t perm_iterations = + Factorial(a_in) * Factorial(b_in) * + (uintmax_t)upow((uint64_t)(Factorial(a_in)), (uint8_t)a_out) * + (uintmax_t)upow((uint64_t)(Factorial(b_in)), (uint8_t)b_out); + const uintmax_t total = + (uintmax_t)row_count * (uintmax_t)row_count * perm_iterations; + uintmax_t tested = 0; +#pragma omp parallel default(none) \ + shared(stderr, args, a_out, b_out, a_in, b_in, row_len, matrix, row_count, \ + seen, perm_iterations, total, tested) + { + data_t *p_buf = malloc(a_out * b_out * a_in * b_in * sizeof(data_t)); + data_t *cg_buf = malloc((((a_out - 1) * (b_out - 1) * a_in * b_in + + (a_out - 1) * a_in + (b_out - 1) * b_in) + + 1) * + sizeof(data_t)); - for (size_t lhs_i = 0; lhs_i < row_count - 1; lhs_i++) { - if (seen[lhs_i]) { - continue; + if (p_buf == NULL) { + fprintf(stderr, "Failed to allocate P notation buffer. Aborting."); + exit(EXIT_FAILURE); + } + if (cg_buf == NULL) { + fprintf(stderr, "Failed to allocate CG notation buffer. Aborting."); + exit(EXIT_FAILURE); } - fprintf(stderr, "%zu/%zu \033[G", lhs_i, row_count - 1); - fflush(stderr); + permutation_generator_t a_in_perm = PermutationNewGenerator(a_in); + permutation_generator_t b_in_perm = PermutationNewGenerator(b_in); + permutation_generator_t *a_out_perms = + malloc(a_in * sizeof(permutation_generator_t)); + permutation_generator_t *b_out_perms = + malloc(b_in * sizeof(permutation_generator_t)); - data_t *lhs = matrix.head + lhs_i * matrix.row_len; + if (a_out_perms == NULL || b_out_perms == NULL) { + fprintf( + stderr, + "Failed to allocate space for conditioned permutation generators. " + "Aborting."); + exit(EXIT_FAILURE); + } - for (size_t rhs_i = lhs_i + 1; rhs_i < row_count; rhs_i++) { - if (seen[rhs_i]) { - continue; - } - - data_t *rhs = matrix.head + rhs_i * matrix.row_len; - - PermutationReset(&a_in_perm); - while (!a_in_perm.exhausted) { - PermutationReset(&b_in_perm); - while (!b_in_perm.exhausted) { - ResetConditionalPermutations(a_out_perms, a_out); - while (!a_out_perms[a_out - 1].exhausted) { - ResetConditionalPermutations(b_out_perms, b_out); - while (!b_out_perms[b_out - 1].exhausted) { - // Compare the two rows - FromCgToP(a_out, b_out, a_in, b_in, rhs, p_buf, - a_in_perm.permutation, b_in_perm.permutation, - a_out_perms, b_out_perms); - - { - FromPToCg(a_out, b_out, a_in, b_in, cg_buf, p_buf); - _Bool equivalent = 1; - for (size_t i = row_len; i > 0; i--) { - if (lhs[i - 1] != cg_buf[i - 1]) { - equivalent = 0; - break; - } - } - - if (equivalent) { - seen[rhs_i] = 1; - goto skip_permutations; - } - } - - // If the number of output labels are the same, and the number of - // input labels is also the same, we can also check for equality - // under party swapping. - // I don't expect this conditional to be very penalizing because - // it's very predictable. - if (a_in == b_in && a_out == b_out) { - // Use the results in p_buf - PSwapParties(a_out, a_in, p_buf); - FromPToCg(a_out, b_out, a_in, b_in, cg_buf, p_buf); - _Bool equivalent = 1; - for (size_t i = row_len; i > 0; i--) { - if (lhs[i - 1] != cg_buf[i - 1]) { - equivalent = 0; - break; - } - } - - if (equivalent) { - seen[rhs_i] = 1; - goto skip_permutations; - } - } - - AdvanceConditionalPermutations(b_out_perms, b_out); - } - - AdvanceConditionalPermutations(a_out_perms, a_out); - } - - PermutationNext(&b_in_perm); - } - - PermutationNext(&a_in_perm); - } - - skip_permutations:; - } // For loop over rhs_i - } // For loop over lhs_i - - if (cg_format == kPFmt) { - PermutationReset(&a_in_perm); - PermutationReset(&b_in_perm); for (size_t i = 0; i < a_in; i++) { + a_out_perms[i] = PermutationNewGenerator(a_out); PermutationReset(a_out_perms + i); } for (size_t i = 0; i < b_in; i++) { + b_out_perms[i] = PermutationNewGenerator(b_out); PermutationReset(b_out_perms + i); } - } - // Print every unique row - for (size_t i = 0; i < row_count; i++) { - if (!seen[i]) { - switch (cg_format) { - default: - case kRowFmt: { - PrintMatrixRow(&matrix, i); - } break; - case kCgFmt: { - printf("%zu: ", i); - PrintCg(a_out, b_out, a_in, b_in, matrix.head + i * matrix.row_len); - } break; - case kPFmt: { - printf("%zu: ", i); - FromCgToP(a_out, b_out, a_in, b_in, matrix.head + i * matrix.row_len, - p_buf, a_in_perm.permutation, b_in_perm.permutation, - a_out_perms, b_out_perms); - PrintP(a_out, b_out, a_in, b_in, p_buf); - } break; - case kPRawFmt: { - FromCgToP(a_out, b_out, a_in, b_in, matrix.head + i * matrix.row_len, - p_buf, a_in_perm.permutation, b_in_perm.permutation, - a_out_perms, b_out_perms); - PrintPRaw(a_out, b_out, a_in, b_in, p_buf); - } break; +#pragma omp for schedule(guided) + for (size_t lhs_i = 0; lhs_i < row_count - 1; lhs_i++) { + if (seen[lhs_i]) { + const uintmax_t remaining = (uintmax_t)row_count * perm_iterations; +#pragma omp atomic update + tested += remaining; + continue; } + + data_t *lhs = matrix.head + lhs_i * matrix.row_len; + + for (size_t rhs_i = lhs_i + 1; rhs_i < row_count; rhs_i++) { + if (seen[lhs_i]) { + const uintmax_t remaining = + (uintmax_t)(row_count - lhs_i) * perm_iterations; +#pragma omp atomic update + tested += remaining; + break; + } + + if (seen[rhs_i]) { +#pragma omp atomic update + tested += perm_iterations; + continue; + } + + data_t *rhs = matrix.head + rhs_i * matrix.row_len; + + PermutationReset(&a_in_perm); + while (!a_in_perm.exhausted) { + PermutationReset(&b_in_perm); + while (!b_in_perm.exhausted) { + ResetConditionalPermutations(a_out_perms, a_out); + while (!a_out_perms[a_out - 1].exhausted) { + ResetConditionalPermutations(b_out_perms, b_out); + while (!b_out_perms[b_out - 1].exhausted) { + // Compare the two rows + FromCgToP(a_out, b_out, a_in, b_in, rhs, p_buf, + a_in_perm.permutation, b_in_perm.permutation, + a_out_perms, b_out_perms); + + { + FromPToCg(a_out, b_out, a_in, b_in, cg_buf, p_buf); + _Bool equivalent = 1; + for (size_t i = row_len; i > 0; i--) { + if (lhs[i - 1] != cg_buf[i - 1]) { + equivalent = 0; + break; + } + } + + if (equivalent) { + seen[rhs_i] = 1; + goto skip_permutations; + } + } + + // If the number of output labels are the same, and the number + // of input labels is also the same, we can also check for + // equality under party swapping. I don't expect this + // conditional to be very penalizing because it's very + // predictable. + if (a_in == b_in && a_out == b_out) { + // Use the results in p_buf + PSwapParties(a_out, a_in, p_buf); + FromPToCg(a_out, b_out, a_in, b_in, cg_buf, p_buf); + _Bool equivalent = 1; + for (size_t i = row_len; i > 0; i--) { + if (lhs[i - 1] != cg_buf[i - 1]) { + equivalent = 0; + break; + } + } + + if (equivalent) { + seen[rhs_i] = 1; + goto skip_permutations; + } + } + + AdvanceConditionalPermutations(b_out_perms, b_out); + } + + AdvanceConditionalPermutations(a_out_perms, a_out); + } + + PermutationNext(&b_in_perm); + } + + PermutationNext(&a_in_perm); + } + + skip_permutations:; +#pragma omp atomic update + tested += perm_iterations; + { + clock_t now = clock(); +#pragma omp task default(none) shared(tested, total) firstprivate(now) + ReportProgress(tested, total, now); + } + + } // For loop over rhs_i + } // For loop over lhs_i + +#pragma omp single + { + if (args.formatting == kPFmt) { + PermutationReset(&a_in_perm); + PermutationReset(&b_in_perm); + for (size_t i = 0; i < a_in; i++) { + PermutationReset(a_out_perms + i); + } + for (size_t i = 0; i < b_in; i++) { + PermutationReset(b_out_perms + i); + } + } + + // Print every unique row + for (size_t i = 0; i < row_count; i++) { + if (!seen[i]) { + switch (args.formatting) { + default: + case kRowFmt: { + PrintMatrixRow(&matrix, i); + } break; + case kCgFmt: { + printf("%zu: ", i); + PrintCg(a_out, b_out, a_in, b_in, + matrix.head + i * matrix.row_len); + } break; + case kPFmt: { + printf("%zu: ", i); + FromCgToP(a_out, b_out, a_in, b_in, + matrix.head + i * matrix.row_len, p_buf, + a_in_perm.permutation, b_in_perm.permutation, + a_out_perms, b_out_perms); + PrintP(a_out, b_out, a_in, b_in, p_buf); + } break; + case kPRawFmt: { + FromCgToP(a_out, b_out, a_in, b_in, + matrix.head + i * matrix.row_len, p_buf, + a_in_perm.permutation, b_in_perm.permutation, + a_out_perms, b_out_perms); + PrintPRaw(a_out, b_out, a_in, b_in, p_buf); + } break; + } + } + } + } // End of omp single region + + PermutationFree(&a_in_perm); + PermutationFree(&b_in_perm); + for (size_t i = 0; i < a_in; i++) { + PermutationFree(a_out_perms + i); } - } + free(a_out_perms); + for (size_t i = 0; i < b_in; i++) { + PermutationFree(b_out_perms + i); + } + free(b_out_perms); + free(cg_buf); + free(p_buf); + } // End of omp parallel region // Free all the memory so the sanitizer is happy. free(seen); - free(cg_buf); - free(p_buf); - PermutationFree(&a_in_perm); - PermutationFree(&b_in_perm); - for (size_t i = 0; i < a_in; i++) { - PermutationFree(a_out_perms + i); - } - free(a_out_perms); - for (size_t i = 0; i < b_in; i++) { - PermutationFree(b_out_perms + i); - } - free(b_out_perms); MatrixFree(&matrix); return EXIT_SUCCESS; } diff --git a/src/permutation.c b/src/permutation.c index ca16473..5ae713e 100644 --- a/src/permutation.c +++ b/src/permutation.c @@ -84,14 +84,14 @@ void PermutationFree(permutation_generator_t *permutation_generator) { } void PrintPermutation(permutation_generator_t *permutation_generator) { - printf("Permutation{"); + printf("("); for (size_t i = 0; i < permutation_generator->len - 1; i++) { printf("%zu, ", permutation_generator->permutation[i]); } if (permutation_generator->len > 0) { - printf("%zu}\n", + printf("%zu)", permutation_generator->permutation[permutation_generator->len - 1]); } else { - printf("}\n"); + printf(")"); } } \ No newline at end of file