/* $NetBSD: param.h,v 1.599.2.14 2024/04/20 13:32:21 martin Exp $ */ /*- * Copyright (c) 1982, 1986, 1989, 1993 * The Regents of the University of California. All rights reserved. * (c) UNIX System Laboratories, Inc. * All or some portions of this file are derived from material licensed * to the University of California by American Telephone and Telegraph * Co. or Unix System Laboratories, Inc. and are reproduced herein with * the permission of UNIX System Laboratories, Inc. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * @(#)param.h 8.3 (Berkeley) 4/4/95 */ #ifndef _SYS_PARAM_H_ #define _SYS_PARAM_H_ #ifdef _KERNEL_OPT #include "opt_param.h" #endif /* * Historic BSD #defines -- probably will remain untouched for all time. */ #define BSD 199506 /* System version (year & month). */ #define BSD4_3 1 #define BSD4_4 1 /* * #define __NetBSD_Version__ MMmmrrpp00 * * M = major version * m = minor version; a minor number of 99 indicates current. * r = 0 (*) * p = patchlevel * * When new releases are made, src/gnu/usr.bin/groff/tmac/mdoc.local * needs to be updated and the changes sent back to the groff maintainers. * * (*) Up to 2.0I "release" used to be "",A-Z,Z[A-Z] but numeric * e.g. NetBSD-1.2D = 102040000 ('D' == 4) * NetBSD-2.0H (200080000) was changed on 20041001 to: * 2.99.9 (299000900) */ #define __NetBSD_Version__ 904000000 /* NetBSD 9.4 */ #define __NetBSD_Prereq__(M,m,p) (((((M) * 100000000) + \ (m) * 1000000) + (p) * 100) <= __NetBSD_Version__) /* * Historical NetBSD #define * * NetBSD 1.4 was the last release for which this value was incremented. * The value is now permanently fixed at 199905. It will never be * changed again. * * New code must use __NetBSD_Version__ instead, and should not even * count on NetBSD being defined. * */ #define NetBSD 199905 /* NetBSD version (year & month). */ /* * These macros determine if we are running in protected mode or not. * _HARDKERNEL: code uses kernel namespace and runs in hw priviledged mode * _SOFTKERNEL: code uses kernel namespace but runs without hw priviledges */ #if defined(_KERNEL) && !defined(_RUMPKERNEL) #define _HARDKERNEL #endif #if defined(_KERNEL) && defined(_RUMPKERNEL) #define _SOFTKERNEL #endif #include #ifndef __ASSEMBLER__ #include #include /* * Machine-independent constants (some used in following include files). * Redefined constants are from POSIX 1003.1 limits file. * * MAXCOMLEN should be >= sizeof(ac_comm) (see ) * MAXHOSTNAMELEN should be >= (_POSIX_HOST_NAME_MAX + 1) (see ) * MAXLOGNAME should be >= UT_NAMESIZE (see ) */ #include #define MAXCOMLEN 16 /* max command name remembered */ #define MAXINTERP PATH_MAX /* max interpreter file name length */ /* DEPRECATED: use LOGIN_NAME_MAX instead. */ #define MAXLOGNAME (LOGIN_NAME_MAX - 1) /* max login name length */ #define NCARGS ARG_MAX /* max bytes for an exec function */ #define NGROUPS NGROUPS_MAX /* max number groups */ #define NOGROUP 65535 /* marker for empty group set member */ #define MAXHOSTNAMELEN 256 /* max hostname size */ #ifndef NOFILE #define NOFILE OPEN_MAX /* max open files per process */ #endif #ifndef MAXUPRC /* max simultaneous processes */ #define MAXUPRC CHILD_MAX /* POSIX 1003.1-compliant default */ #else #if (MAXUPRC - 0) < CHILD_MAX #error MAXUPRC less than CHILD_MAX. See options(4) for details. #endif /* (MAXUPRC - 0) < CHILD_MAX */ #endif /* !defined(MAXUPRC) */ /* Macros for min/max. */ #define MIN(a,b) ((/*CONSTCOND*/(a)<(b))?(a):(b)) #define MAX(a,b) ((/*CONSTCOND*/(a)>(b))?(a):(b)) /* More types and definitions used throughout the kernel. */ #ifdef _KERNEL #include #include #include #include #include #include #include #ifndef NPROC #define NPROC (20 + 16 * MAXUSERS) #endif #ifndef MAXFILES #define MAXFILES (3 * (NPROC + MAXUSERS) + 80) #define MAXFILES_IMPLICIT #endif #ifndef NTEXT #define NTEXT (80 + NPROC / 8) /* actually the object cache */ #endif #ifndef NVNODE #define NVNODE (NPROC + NTEXT + 100) #define NVNODE_IMPLICIT #endif #ifndef VNODE_KMEM_MAXPCT #define VNODE_KMEM_MAXPCT 60 #endif #ifndef BUFCACHE_VA_MAXPCT #define BUFCACHE_VA_MAXPCT 20 #endif #define VNODE_COST 2048 /* assumed space in bytes */ #endif /* _KERNEL */ /* Signals. */ #include /* Machine type dependent parameters. */ #include #include #define DEV_BSHIFT 9 /* log2(DEV_BSIZE) */ #define DEV_BSIZE (1 << DEV_BSHIFT) /* 512 */ #ifndef BLKDEV_IOSIZE #define BLKDEV_IOSIZE 2048 #endif #ifndef MAXPHYS #define MAXPHYS (64 * 1024) /* max raw I/O transfer size */ #endif /* pages ("clicks") to disk blocks */ #define ctod(x) ((x) << (PGSHIFT - DEV_BSHIFT)) #define dtoc(x) ((x) >> (PGSHIFT - DEV_BSHIFT)) /* bytes to pages */ #define ctob(x) ((x) << PGSHIFT) #define btoc(x) (((x) + PGOFSET) >> PGSHIFT) /* bytes to disk blocks */ #define dbtob(x) ((x) << DEV_BSHIFT) #define btodb(x) ((x) >> DEV_BSHIFT) #ifndef COHERENCY_UNIT #define COHERENCY_UNIT 64 #endif #ifndef CACHE_LINE_SIZE #define CACHE_LINE_SIZE 64 #endif #ifndef MAXCPUS #define MAXCPUS 32 #endif #ifndef MAX_LWP_PER_PROC #define MAX_LWP_PER_PROC 8000 #endif /* * Stack macros. On most architectures, the stack grows down, * towards lower addresses; it is the rare architecture where * it grows up, towards higher addresses. * * STACK_GROW and STACK_SHRINK adjust a stack pointer by some * size, no questions asked. STACK_ALIGN aligns a stack pointer. * * STACK_ALLOC returns a pointer to allocated stack space of * some size; given such a pointer and a size, STACK_MAX gives * the maximum (in the "maxsaddr" sense) stack address of the * allocated memory. */ #if defined(_KERNEL) || defined(__EXPOSE_STACK) #ifndef STACK_ALIGNBYTES #define STACK_ALIGNBYTES __ALIGNBYTES #endif #ifdef __MACHINE_STACK_GROWS_UP #define STACK_GROW(sp, _size) (((char *)(void *)(sp)) + (_size)) #define STACK_SHRINK(sp, _size) (((char *)(void *)(sp)) - (_size)) #define STACK_ALIGN(sp, bytes) \ ((char *)((((unsigned long)(sp)) + (bytes)) & ~(bytes))) #define STACK_ALLOC(sp, _size) ((char *)(void *)(sp)) #define STACK_MAX(p, _size) (((char *)(void *)(p)) + (_size)) #else #define STACK_GROW(sp, _size) (((char *)(void *)(sp)) - (_size)) #define STACK_SHRINK(sp, _size) (((char *)(void *)(sp)) + (_size)) #define STACK_ALIGN(sp, bytes) \ ((char *)(((unsigned long)(sp)) & ~(bytes))) #define STACK_ALLOC(sp, _size) (((char *)(void *)(sp)) - (_size)) #define STACK_MAX(p, _size) ((char *)(void *)(p)) #endif #define STACK_LEN_ALIGN(len, bytes) (((len) + (bytes)) & ~(bytes)) #endif /* defined(_KERNEL) || defined(__EXPOSE_STACK) */ /* * Round p (pointer or byte index) up to a correctly-aligned value for all * data types (int, long, ...). The result is u_int and must be cast to * any desired pointer type. * * ALIGNED_POINTER is a boolean macro that checks whether an address * is valid to fetch data elements of type t from on this architecture * using ALIGNED_POINTER_LOAD. This does not reflect the optimal * alignment, just the possibility (within reasonable limits). * * uint32_t x; * unsigned char *p = ...; * * if (ALIGNED_POINTER(p, uint32_t)) { * uint32_t t; * ALIGNED_POINTER_LOAD(&t, p, uint32_t); * x = t; * } else { * uint32_t t; * memcpy(&t, p, sizeof(t)); * x = t; * } * */ #define ALIGNBYTES __ALIGNBYTES #ifndef ALIGN #define ALIGN(p) (((uintptr_t)(p) + ALIGNBYTES) & ~ALIGNBYTES) #endif #ifndef ALIGNED_POINTER #define ALIGNED_POINTER(p,t) ((((uintptr_t)(p)) & (sizeof(t) - 1)) == 0) #endif #ifndef ALIGNED_POINTER_LOAD #define ALIGNED_POINTER_LOAD(q,p,t) (*(q) = *((const t *)(p))) #endif /* * Historic priority levels. These are meaningless and remain only * for source compatibility. Do not use in new code. */ #define PSWP 0 #define PVM 4 #define PINOD 8 #define PRIBIO 16 #define PVFS 20 #define PZERO 22 #define PSOCK 24 #define PWAIT 32 #define PLOCK 36 #define PPAUSE 40 #define PUSER 50 #define MAXPRI 127 #define PCATCH 0x100 /* OR'd with pri for tsleep to check signals */ #define PNORELOCK 0x200 /* OR'd with pri for tsleep to not relock */ /* * New priority levels. */ #define PRI_COUNT 224 #define PRI_NONE (-1) #define PRI_KERNEL_RT 192 #define NPRI_KERNEL_RT 32 #define MAXPRI_KERNEL_RT (PRI_KERNEL_RT + NPRI_KERNEL_RT - 1) #define PRI_USER_RT 128 #define NPRI_USER_RT 64 #define MAXPRI_USER_RT (PRI_USER_RT + NPRI_USER_RT - 1) #define PRI_KTHREAD 96 #define NPRI_KTHREAD 32 #define MAXPRI_KTHREAD (PRI_KTHREAD + NPRI_KTHREAD - 1) #define PRI_KERNEL 64 #define NPRI_KERNEL 32 #define MAXPRI_KERNEL (PRI_KERNEL + NPRI_KERNEL - 1) #define PRI_USER 0 #define NPRI_USER 64 #define MAXPRI_USER (PRI_USER + NPRI_USER - 1) /* Priority range used by POSIX real-time features */ #define SCHED_PRI_MIN 0 #define SCHED_PRI_MAX 63 /* * Kernel thread priorities. */ #define PRI_SOFTSERIAL MAXPRI_KERNEL_RT #define PRI_SOFTNET (MAXPRI_KERNEL_RT - schedppq * 1) #define PRI_SOFTBIO (MAXPRI_KERNEL_RT - schedppq * 2) #define PRI_SOFTCLOCK (MAXPRI_KERNEL_RT - schedppq * 3) #define PRI_XCALL MAXPRI_KTHREAD #define PRI_PGDAEMON (MAXPRI_KTHREAD - schedppq * 1) #define PRI_VM (MAXPRI_KTHREAD - schedppq * 2) #define PRI_IOFLUSH (MAXPRI_KTHREAD - schedppq * 3) #define PRI_BIO (MAXPRI_KTHREAD - schedppq * 4) #define PRI_IDLE PRI_USER /* * Miscellaneous. */ #define NBPW sizeof(int) /* number of bytes per word (integer) */ #define CMASK 022 /* default file mask: S_IWGRP|S_IWOTH */ #define NODEV (dev_t)(-1) /* non-existent device */ /* * File system parameters and macros. * * The file system is made out of blocks of at most MAXBSIZE units, with * smaller units (fragments) only in the last direct block. MAXBSIZE * primarily determines the size of buffers in the buffer pool. It may be * made larger without any effect on existing file systems; however making * it smaller may make some file systems unmountable. */ #ifndef MAXBSIZE /* XXX */ #define MAXBSIZE MAXPHYS #endif #define MAXFRAG 8 /* * MAXPATHLEN defines the longest permissible path length after expanding * symbolic links. It is used to allocate a temporary buffer from the buffer * pool in which to do the name expansion, hence should be a power of two, * and must be less than or equal to MAXBSIZE. MAXSYMLINKS defines the * maximum number of symbolic links that may be expanded in a path name. * It should be set high enough to allow all legitimate uses, but halt * infinite loops reasonably quickly. * * MAXSYMLINKS should be >= _POSIX_SYMLOOP_MAX (see ) */ #define MAXPATHLEN PATH_MAX #define MAXSYMLINKS 32 /* * This is the maximum individual filename component length enforced by * namei. Filesystems cannot exceed this limit. The upper bound for that * limit is NAME_MAX. We don't bump it for now, for compatibility with * old binaries during the time where MAXNAMLEN was 511 and NAME_MAX was * 255 */ #define KERNEL_NAME_MAX 255 /* Bit map related macros. */ #define setbit(a,i) ((a)[(i)/NBBY] |= 1<<((i)%NBBY)) #define clrbit(a,i) ((a)[(i)/NBBY] &= ~(1<<((i)%NBBY))) #define isset(a,i) ((a)[(i)/NBBY] & (1<<((i)%NBBY))) #define isclr(a,i) (((a)[(i)/NBBY] & (1<<((i)%NBBY))) == 0) /* Macros for counting and rounding. */ #ifndef howmany #define howmany(x, y) (((x)+((y)-1))/(y)) #endif #define roundup(x, y) ((((x)+((y)-1))/(y))*(y)) #define rounddown(x,y) (((x)/(y))*(y)) /* * Rounding to powers of two. The naive definitions of roundup2 and * rounddown2, * * #define roundup2(x,m) (((x) + ((m) - 1)) & ~((m) - 1)) * #define rounddown2(x,m) ((x) & ~((m) - 1)), * * exhibit a quirk of integer arithmetic in C because the complement * happens in the type of m, not in the type of x. So if unsigned int * is 32-bit, and m is an unsigned int while x is a uint64_t, then * roundup2 and rounddown2 would have the unintended effect of clearing * the upper 32 bits of the result(!). These definitions avoid the * pitfalls of C arithmetic depending on the types of x and m, and * additionally avoid multiply evaluating their arguments. */ #define roundup2(x,m) ((((x) - 1) | ((m) - 1)) + 1) #define rounddown2(x,m) ((x) & ~((__typeof__(x))((m) - 1))) #define powerof2(x) ((((x)-1)&(x))==0) /* * Constants for setting the parameters of the kernel memory allocator. * * 2 ** MINBUCKET is the smallest unit of memory that will be * allocated. It must be at least large enough to hold a pointer. * * Units of memory less or equal to MAXALLOCSAVE will permanently * allocate physical memory; requests for these size pieces of * memory are quite fast. Allocations greater than MAXALLOCSAVE must * always allocate and free physical memory; requests for these * size allocations should be done infrequently as they will be slow. * * Constraints: NBPG <= MAXALLOCSAVE <= 2 ** (MINBUCKET + 14), and * MAXALLOCSAVE must be a power of two. */ #ifdef _LP64 #define MINBUCKET 5 /* 5 => min allocation of 32 bytes */ #else #define MINBUCKET 4 /* 4 => min allocation of 16 bytes */ #endif #define MAXALLOCSAVE (2 * NBPG) /* * Scale factor for scaled integers used to count %cpu time and load avgs. * * The number of CPU `tick's that map to a unique `%age' can be expressed * by the formula (1 / (2 ^ (FSHIFT - 11))). The maximum load average that * can be calculated (assuming 32 bits) can be closely approximated using * the formula (2 ^ (2 * (16 - FSHIFT))) for (FSHIFT < 15). * * For the scheduler to maintain a 1:1 mapping of CPU `tick' to `%age', * FSHIFT must be at least 11; this gives us a maximum load avg of ~1024. */ #define FSHIFT 11 /* bits to right of fixed binary point */ #define FSCALE (1<. */ #ifndef UBC_WINSHIFT #define UBC_WINSHIFT 13 #endif #ifndef UBC_NWINS #define UBC_NWINS 1024 #endif #ifdef _KERNEL /* * macro to convert from milliseconds to hz without integer overflow * Default version using only 32bits arithmetics. * 64bit port can define 64bit version in their * 0x20000 is safe for hz < 20000 */ #ifndef mstohz #define mstohz(ms) \ (__predict_false((ms) >= 0x20000) ? \ ((ms +0u) / 1000u) * hz : \ ((ms +0u) * hz) / 1000u) #endif #ifndef hztoms #define hztoms(t) \ (__predict_false((t) >= 0x20000) ? \ ((t +0u) / hz) * 1000u : \ ((t +0u) * 1000u) / hz) #endif #define hz2bintime(t) (ms2bintime(hztoms(t))) extern const int schedppq; extern size_t coherency_unit; #endif /* _KERNEL */ /* * Minimum alignment of "struct lwp" needed by the architecture. * This counts when packing a lock byte into a word alongside a * pointer to an LWP. */ #ifndef MIN_LWP_ALIGNMENT #define MIN_LWP_ALIGNMENT 32 #endif #endif /* !__ASSEMBLER__ */ #endif /* !_SYS_PARAM_H_ */