/* * Copyright (c) 1988 Regents of the University of California. * All rights reserved. * * %sccs.include.redist.c% */ #ifndef lint static char sccsid[] = "@(#)ring.c 5.3 (Berkeley) 12/18/92"; #endif /* not lint */ /* * This defines a structure for a ring buffer. * * The circular buffer has two parts: *((( * full: [consume, supply) * empty: [supply, consume) *]]] * */ #include #include #ifdef size_t #undef size_t #endif #include #ifndef FILIO_H #include #endif #include #include "ring.h" #include "general.h" /* Internal macros */ #if !defined(MIN) #define MIN(a,b) (((a)<(b))? (a):(b)) #endif /* !defined(MIN) */ #define ring_subtract(d,a,b) (((a)-(b) >= 0)? \ (a)-(b): (((a)-(b))+(d)->size)) #define ring_increment(d,a,c) (((a)+(c) < (d)->top)? \ (a)+(c) : (((a)+(c))-(d)->size)) #define ring_decrement(d,a,c) (((a)-(c) >= (d)->bottom)? \ (a)-(c) : (((a)-(c))-(d)->size)) /* * The following is a clock, used to determine full, empty, etc. * * There is some trickiness here. Since the ring buffers are initialized * to ZERO on allocation, we need to make sure, when interpreting the * clock, that when the times are EQUAL, then the buffer is FULL. */ static u_long ring_clock = 0; #define ring_empty(d) (((d)->consume == (d)->supply) && \ ((d)->consumetime >= (d)->supplytime)) #define ring_full(d) (((d)->supply == (d)->consume) && \ ((d)->supplytime > (d)->consumetime)) /* Buffer state transition routines */ ring_init(ring, buffer, count) Ring *ring; unsigned char *buffer; int count; { memset((char *)ring, 0, sizeof *ring); ring->size = count; ring->supply = ring->consume = ring->bottom = buffer; ring->top = ring->bottom+ring->size; #if defined(ENCRYPTION) ring->clearto = 0; #endif return 1; } /* Mark routines */ /* * Mark the most recently supplied byte. */ void ring_mark(ring) Ring *ring; { ring->mark = ring_decrement(ring, ring->supply, 1); } /* * Is the ring pointing to the mark? */ int ring_at_mark(ring) Ring *ring; { if (ring->mark == ring->consume) { return 1; } else { return 0; } } /* * Clear any mark set on the ring. */ void ring_clear_mark(ring) Ring *ring; { ring->mark = 0; } /* * Add characters from current segment to ring buffer. */ void ring_supplied(ring, count) Ring *ring; int count; { ring->supply = ring_increment(ring, ring->supply, count); ring->supplytime = ++ring_clock; } /* * We have just consumed "c" bytes. */ void ring_consumed(ring, count) Ring *ring; int count; { if (count == 0) /* don't update anything */ return; if (ring->mark && (ring_subtract(ring, ring->mark, ring->consume) < count)) { ring->mark = 0; } #if defined(ENCRYPTION) if (ring->consume < ring->clearto && ring->clearto <= ring->consume + count) ring->clearto = 0; else if (ring->consume + count > ring->top && ring->bottom <= ring->clearto && ring->bottom + ((ring->consume + count) - ring->top)) ring->clearto = 0; #endif ring->consume = ring_increment(ring, ring->consume, count); ring->consumetime = ++ring_clock; /* * Try to encourage "ring_empty_consecutive()" to be large. */ if (ring_empty(ring)) { ring->consume = ring->supply = ring->bottom; } } /* Buffer state query routines */ /* Number of bytes that may be supplied */ int ring_empty_count(ring) Ring *ring; { if (ring_empty(ring)) { /* if empty */ return ring->size; } else { return ring_subtract(ring, ring->consume, ring->supply); } } /* number of CONSECUTIVE bytes that may be supplied */ int ring_empty_consecutive(ring) Ring *ring; { if ((ring->consume < ring->supply) || ring_empty(ring)) { /* * if consume is "below" supply, or empty, then * return distance to the top */ return ring_subtract(ring, ring->top, ring->supply); } else { /* * else, return what we may. */ return ring_subtract(ring, ring->consume, ring->supply); } } /* Return the number of bytes that are available for consuming * (but don't give more than enough to get to cross over set mark) */ int ring_full_count(ring) Ring *ring; { if ((ring->mark == 0) || (ring->mark == ring->consume)) { if (ring_full(ring)) { return ring->size; /* nothing consumed, but full */ } else { return ring_subtract(ring, ring->supply, ring->consume); } } else { return ring_subtract(ring, ring->mark, ring->consume); } } /* * Return the number of CONSECUTIVE bytes available for consuming. * However, don't return more than enough to cross over set mark. */ int ring_full_consecutive(ring) Ring *ring; { if ((ring->mark == 0) || (ring->mark == ring->consume)) { if ((ring->supply < ring->consume) || ring_full(ring)) { return ring_subtract(ring, ring->top, ring->consume); } else { return ring_subtract(ring, ring->supply, ring->consume); } } else { if (ring->mark < ring->consume) { return ring_subtract(ring, ring->top, ring->consume); } else { /* Else, distance to mark */ return ring_subtract(ring, ring->mark, ring->consume); } } } /* * Move data into the "supply" portion of of the ring buffer. */ void ring_supply_data(ring, buffer, count) Ring *ring; unsigned char *buffer; int count; { int i; while (count) { i = MIN(count, ring_empty_consecutive(ring)); memcpy(ring->supply, buffer, i); ring_supplied(ring, i); count -= i; buffer += i; } } #ifdef notdef /* * Move data from the "consume" portion of the ring buffer */ void ring_consume_data(ring, buffer, count) Ring *ring; unsigned char *buffer; int count; { int i; while (count) { i = MIN(count, ring_full_consecutive(ring)); memcpy(buffer, ring->consume, i); ring_consumed(ring, i); count -= i; buffer += i; } } #endif #if defined(ENCRYPTION) void ring_encrypt(ring, encryptor) Ring *ring; void (*encryptor)(); { unsigned char *s, *c; if (ring_empty(ring) || ring->clearto == ring->supply) return; if (!(c = ring->clearto)) c = ring->consume; s = ring->supply; if (s <= c) { (*encryptor)(c, ring->top - c); (*encryptor)(ring->bottom, s - ring->bottom); } else (*encryptor)(c, s - c); ring->clearto = ring->supply; } void ring_clearto(ring) Ring *ring; { if (!ring_empty(ring)) ring->clearto = ring->supply; else ring->clearto = 0; } #endif