/*************************************************************************** * Copyright 1995, Technion, Israel Institute of Technology * Electrical Eng, Software Lab. * Author: Michael Veksler. *************************************************************************** * File: bit_array.c * Purpose : manipulate array of bits * Portability: This is not completely portable, non CISC arcitectures * Might not have atomic Clear/Set/Toggle bit. On those * architectures semaphores should be used. * Big Endian Concerns: This code is big endian compatible, * but the byte order will be different (i.e. bit 0 will be * located in byte 3). *************************************************************************** */ #ifdef CONFIG_IPC /* ** uncoment the following line to disable assertions, ** this may boost performance by up to 50% */ /* #define NDEBUG */ #if defined(linux) && !defined(NO_ASM) #include #if LINUX_VERSION_CODE <= 131328 /* Linux 2.1.x doesn't return values with clear_bit and set_bit */ #define HAS_BITOPS #endif #endif #include #include #include "bit_array.h" #ifdef HAS_BITOPS #define inline __inline__ /* So we can compile with -ansi */ #include #else static __inline__ int clear_bit(int bit, int *mem); static __inline__ int set_bit(int bit, int *mem); #endif /* HAS_BITOPS */ #define INT_NR(bit_nr) ((bit_nr) >> INT_LOG2) #define INT_COUNT(bit_count) INT_NR( bit_count + BITS_PER_INT - 1 ) #define BIT_IN_INT(bit_nr) ((bit_nr) & (BITS_PER_INT - 1)) #if !defined(HAS_BITOPS) /* first_zero maps bytes value to the index of first zero bit */ static char first_zero[256]; static int arrays_initialized=0; /* ** initialize static arrays used for bit operations speedup. ** Currently initialized: first_zero[256] ** set "arrays_initialized" to inidate that arrays where initialized */ static void initialize_arrays() { int i; int bit; for (i=0 ; i<256 ; i++) { /* find the first zero bit in `i' */ for (bit=0 ; bit < BITS_PER_BYTE ; bit++) /* break if the bit is zero */ if ( ( (1 << bit) & i ) == 0) break; first_zero[i]= bit; } arrays_initialized=1; } /* ** Find first zero bit in the integer. ** Assume there is at least one zero. */ static __inline__ int find_zbit_in_integer(unsigned int integer) { int i; /* find the zero bit */ for (i=0 ; i < sizeof(int) ; i++, integer>>=8) { int byte= integer & 0xff; if (byte != 0xff) return ( first_zero[ byte ] + (i << BYTE_LOG2) ); } assert(0); /* never reached */ return 0; } /* return -1 on failure */ static __inline__ int find_first_zero_bit(unsigned *array, int bits) { unsigned int integer; int i; int bytes=INT_COUNT(bits); if (!arrays_initialized) initialize_arrays(); for ( i=bytes ; i ; i--, array++) { integer= *array; /* test if integer contains a zero bit */ if (integer != ~0U) return ( find_zbit_in_integer(integer) + ((bytes-i) << INT_LOG2) ); } /* indicate failure */ return -1; } static __inline__ int test_bit(int pos, unsigned *array) { unsigned int integer; int bit = BIT_IN_INT(pos); integer= array[ pos >> INT_LOG2 ]; return ( (integer & (1 << bit)) != 0 ? 1 : 0 ) ; } /* ** The following two functions are x86 specific , ** other processors will need porting */ /* inputs: bit number and memory address (32 bit) */ /* output: Value of the bit before modification */ static __inline__ int clear_bit(int bit, int *mem) { int ret; __asm__("xor %1,%1 btrl %2,%0 adcl %1,%1" :"=m" (*mem), "=&r" (ret) :"r" (bit)); return (ret); } static __inline__ int set_bit(int bit, int *mem) { int ret; __asm__("xor %1,%1 btsl %2,%0 adcl %1,%1" :"=m" (*mem), "=&r" (ret) :"r" (bit)); return (ret); } #endif /* !deined(HAS_BITOPS) */ /* AssembleArray: assemble an array object using existing data */ bit_array *AssembleArray(bit_array *new_array, unsigned int *buff, int bits) { assert(new_array!=NULL); assert(buff!=NULL); assert(bits>0); assert((1 << INT_LOG2) == BITS_PER_INT); /* if fails, redefine INT_LOG2 */ new_array->bits=bits; new_array->array=buff; return new_array; } /* ResetArray: reset the bit array to zeros */ int ResetArray(bit_array *bits) { int i; int *p; assert(bits!=NULL); assert(bits->array!=NULL); for(i= INT_COUNT(bits->bits), p=bits->array; i ; p++, i--) *p=0; return 1; } /* VacantBit: find a vacant (zero) bit in the array, * Return: Bit index on success, -1 on failure. */ int VacantBit(bit_array *bits) { int bit; assert(bits!=NULL); assert(bits->array!=NULL); bit= find_first_zero_bit(bits->array, bits->bits); if (bit >= bits->bits) /* failed? */ return -1; return bit; } int SampleBit(bit_array *bits, int i) { assert(bits != NULL); assert(bits->array != NULL); assert(i >= 0 && i < bits->bits); return ( test_bit(i,bits->array) != 0 ? 1 : 0 ); } /* ** Use "compare and exchange" mechanism to make sure ** that bits are not modified while "integer" value ** is calculated. ** ** This may be the slowest technique, but it is the most portable ** (Since most architectures have compare and exchange command) */ int AssignBit(bit_array *bits, int bit_nr, int val) { int ret; assert(bits != NULL); assert(bits->array != NULL); assert(val==0 || val==1); assert(bit_nr >= 0 && bit_nr < bits->bits); if (val==0) ret= clear_bit(BIT_IN_INT(bit_nr), &bits->array[ INT_NR(bit_nr) ]); else ret= set_bit(BIT_IN_INT(bit_nr), &bits->array[ INT_NR(bit_nr) ]); return ( (ret!=0) ? 1 : 0); } /* ** Allocate a free bit (==0) and make it used (==1). ** This operation is guaranteed to resemble an atomic instruction. ** ** Return: allocated bit index, or -1 on failure. ** ** There is a crack between locating free bit, and allocating it. ** We assign 1 to the bit, test it was not '1' before the assignment. ** If it was, restart the seek and assign cycle. ** */ int AllocateBit(bit_array *bits) { int bit_nr; int orig_bit; assert(bits != NULL); assert(bits->array != NULL); do { bit_nr= VacantBit(bits); if (bit_nr == -1) /* No vacant bit ? */ return -1; orig_bit = AssignBit(bits, bit_nr, 1); } while (orig_bit != 0); /* it got assigned before we tried */ return bit_nr; } #endif /* CONFIG_IPC */