/* Copyright (C) 1992, 1996, 1997, 1998, 1999 Free Software Foundation, Inc. This file is part of the GNU C Library. Contributed by David Mosberger. The GNU C Library is free software; you can redistribute it and/or modify it under the terms of the GNU Library General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. The GNU C Library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Library General Public License for more details. You should have received a copy of the GNU Library General Public License along with the GNU C Library; see the file COPYING.LIB. If not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /* I/O access is restricted to ISA port space (ports 0..65535). Modern devices hopefully are sane enough not to put any performance critical registers in i/o space. On the first call to ioperm() or _sethae(), the entire (E)ISA port space is mapped into the virtual address space at address io.base. mprotect() calls are then used to enable/disable access to ports. Per page, there are PAGE_SIZE>>IO_SHIFT I/O ports (e.g., 256 ports on a Low Cost Alpha based system using 8KB pages). Keep in mind that this code should be able to run in a 32bit address space. It is therefore unreasonable to expect mmap'ing the entire sparse address space would work (e.g., the Low Cost Alpha chip has an I/O address space that's 512MB large!). */ #include #include #include #include #include #include #include #include #include #include #include #define PATH_ALPHA_SYSTYPE "/etc/alpha_systype" #define PATH_CPUINFO "/proc/cpuinfo" #define MAX_PORT 0x10000 #define vuip volatile unsigned int * #define JENSEN_IO_BASE (0xfffffc0300000000UL) #define JENSEN_SPARSE_MEM (0xfffffc0200000000UL) /* With respect to the I/O architecture, APECS and LCA are identical, so the following defines apply to LCA as well. */ #define APECS_IO_BASE (0xfffffc01c0000000UL) #define APECS_SPARSE_MEM (0xfffffc0200000000UL) #define APECS_DENSE_MEM (0xfffffc0300000000UL) /* The same holds for CIA and PYXIS. */ #define CIA_IO_BASE (0xfffffc8580000000UL) #define CIA_SPARSE_MEM (0xfffffc8000000000UL) #define CIA_DENSE_MEM (0xfffffc8600000000UL) /* SABLE is EV4, GAMMA is EV5 */ #define T2_IO_BASE (0xfffffc03a0000000UL) #define T2_SPARSE_MEM (0xfffffc0200000000UL) #define T2_DENSE_MEM (0xfffffc03c0000000UL) #define GAMMA_IO_BASE (0xfffffc83a0000000UL) #define GAMMA_SPARSE_MEM (0xfffffc8200000000UL) #define GAMMA_DENSE_MEM (0xfffffc83c0000000UL) /* these are for the RAWHIDE family */ #define MCPCIA_IO_BASE (0xfffffcf980000000UL) #define MCPCIA_SPARSE_MEM (0xfffffcf800000000UL) #define MCPCIA_DENSE_MEM (0xfffffcf900000000UL) /* Tsunami has no SPARSE space */ /* NOTE: these are hardwired to PCI bus 0 addresses!!! */ /* Also, these are PHYSICAL, as/so there's no KSEG translation */ #define TSUNAMI_IO_BASE (0x00000801fc000000UL + 0xfffffc0000000000UL) #define TSUNAMI_DENSE_MEM (0x0000080000000000UL + 0xfffffc0000000000UL) /* Polaris has SPARSE space, but we prefer to use only DENSE */ /* because of some idiosyncracies in actually using SPARSE */ #define POLARIS_IO_BASE (0xfffffcf9fc000000UL) #define POLARIS_DENSE_MEM (0xfffffcf900000000UL) typedef enum { IOSYS_UNKNOWN, IOSYS_JENSEN, IOSYS_APECS, IOSYS_CIA, IOSYS_T2, IOSYS_TSUNAMI, IOSYS_MCPCIA, IOSYS_GAMMA, IOSYS_POLARIS, IOSYS_CPUDEP, IOSYS_PCIDEP } iosys_t; typedef enum { IOSWIZZLE_JENSEN, IOSWIZZLE_SPARSE, IOSWIZZLE_DENSE } ioswizzle_t; static struct io_system { int hae_shift; unsigned long int bus_memory_base; unsigned long int sparse_bus_mem_base; unsigned long int bus_io_base; } io_system[] = { /* NOTE! must match iosys_t enumeration */ /* UNKNOWN */ {0, 0, 0, 0}, /* JENSEN */ {7, 0, JENSEN_SPARSE_MEM, JENSEN_IO_BASE}, /* APECS */ {5, APECS_DENSE_MEM, APECS_SPARSE_MEM, APECS_IO_BASE}, /* CIA */ {5, CIA_DENSE_MEM, CIA_SPARSE_MEM, CIA_IO_BASE}, /* T2 */ {5, T2_DENSE_MEM, T2_SPARSE_MEM, T2_IO_BASE}, /* TSUNAMI */ {0, TSUNAMI_DENSE_MEM, 0, TSUNAMI_IO_BASE}, /* MCPCIA */ {5, MCPCIA_DENSE_MEM, MCPCIA_SPARSE_MEM, MCPCIA_IO_BASE}, /* GAMMA */ {5, GAMMA_DENSE_MEM, GAMMA_SPARSE_MEM, GAMMA_IO_BASE}, /* POLARIS */ {0, POLARIS_DENSE_MEM, 0, POLARIS_IO_BASE}, /* CPUDEP */ {0, 0, 0, 0}, /* for platforms dependent on CPU type */ /* PCIDEP */ {0, 0, 0, 0}, /* for platforms dependent on core logic */ }; static struct platform { const char *name; iosys_t io_sys; } platform[] = { {"Alcor", IOSYS_CIA}, {"Avanti", IOSYS_APECS}, {"XL", IOSYS_APECS}, {"Cabriolet", IOSYS_APECS}, {"EB164", IOSYS_PCIDEP}, {"EB64+", IOSYS_APECS}, {"EB66", IOSYS_APECS}, {"EB66P", IOSYS_APECS}, {"Jensen", IOSYS_JENSEN}, {"Mikasa", IOSYS_CPUDEP}, {"Noritake", IOSYS_CPUDEP}, {"Noname", IOSYS_APECS}, {"Sable", IOSYS_CPUDEP}, {"Miata", IOSYS_CIA}, {"Tsunami", IOSYS_TSUNAMI}, {"Rawhide", IOSYS_MCPCIA}, {"Ruffian", IOSYS_CIA}, {"Takara", IOSYS_CIA}, }; struct ioswtch { void (*sethae)(unsigned long int addr); void (*outb)(unsigned char b, unsigned long int port); void (*outw)(unsigned short b, unsigned long int port); void (*outl)(unsigned int b, unsigned long int port); unsigned int (*inb)(unsigned long int port); unsigned int (*inw)(unsigned long int port); unsigned int (*inl)(unsigned long int port); }; static struct { struct hae { unsigned long int cache; unsigned long int * reg; } hae; unsigned long int base; struct ioswtch * swp; unsigned long int bus_memory_base; unsigned long int sparse_bus_memory_base; unsigned long int io_base; iosys_t sys; ioswizzle_t swiz; int hae_shift; } io; extern void __sethae (unsigned long int); /* we can't use asm/io.h */ static inline unsigned long int port_to_cpu_addr (unsigned long int port, ioswizzle_t ioswiz, int size) { if (ioswiz == IOSWIZZLE_SPARSE) return (port << 5) + ((size - 1) << 3) + io.base; else if (ioswiz == IOSWIZZLE_DENSE) return port + io.base; else return (port << 7) + ((size - 1) << 5) + io.base; } static inline void inline_sethae (unsigned long int addr, ioswizzle_t ioswiz) { if (ioswiz == IOSWIZZLE_SPARSE) { unsigned long int msb; /* no need to set hae if msb is 0: */ msb = addr & 0xf8000000; if (msb && msb != io.hae.cache) { __sethae (msb); io.hae.cache = msb; } } else { /* hae on the Jensen is bits 31:25 shifted right */ addr >>= 25; if (addr != io.hae.cache) { __sethae (addr); io.hae.cache = addr; } } } static inline void inline_outb (unsigned char b, unsigned long int port, ioswizzle_t ioswiz) { unsigned int w; unsigned long int addr = port_to_cpu_addr (port, ioswiz, 1); inline_sethae (0, ioswiz); asm ("insbl %2,%1,%0" : "=r" (w) : "ri" (port & 0x3), "r" (b)); *(vuip)addr = w; mb (); } static inline void inline_outw (unsigned short int b, unsigned long int port, ioswizzle_t ioswiz) { unsigned int w; unsigned long int addr = port_to_cpu_addr (port, ioswiz, 2); inline_sethae (0, ioswiz); asm ("inswl %2,%1,%0" : "=r" (w) : "ri" (port & 0x3), "r" (b)); *(vuip)addr = w; mb (); } static inline void inline_outl (unsigned int b, unsigned long int port, ioswizzle_t ioswiz) { unsigned long int addr = port_to_cpu_addr (port, ioswiz, 4); inline_sethae (0, ioswiz); *(vuip)addr = b; mb (); } static inline unsigned int inline_inb (unsigned long int port, ioswizzle_t ioswiz) { unsigned long int result, addr = port_to_cpu_addr (port, ioswiz, 1); inline_sethae (0, ioswiz); result = *(vuip) addr; result >>= (port & 3) * 8; return 0xffUL & result; } static inline unsigned int inline_inw (unsigned long int port, ioswizzle_t ioswiz) { unsigned long int result, addr = port_to_cpu_addr (port, ioswiz, 2); inline_sethae (0, ioswiz); result = *(vuip) addr; result >>= (port & 3) * 8; return 0xffffUL & result; } static inline unsigned int inline_inl (unsigned long int port, ioswizzle_t ioswiz) { unsigned long int addr = port_to_cpu_addr (port, ioswiz, 4); inline_sethae (0, ioswiz); return *(vuip) addr; } /* * Now define the inline functions for CPUs supporting byte/word insns, * and whose core logic supports I/O space accesses utilizing them. * * These routines could be used by MIATA, for example, because it has * and EV56 plus PYXIS, but it currently uses SPARSE anyway. This is * also true of RX164 which used POLARIS, but we will choose to use * these routines in that case instead of SPARSE. * * These routines are necessary for TSUNAMI/TYPHOON based platforms, * which will have (at least) EV6. */ static inline unsigned long int dense_port_to_cpu_addr (unsigned long int port) { return port + io.base; } static inline void inline_bwx_outb (unsigned char b, unsigned long int port) { unsigned long int addr = dense_port_to_cpu_addr (port); __asm__ __volatile__ ("stb %1,%0" : : "m"(*(unsigned char *)addr), "r"(b)); mb (); } static inline void inline_bwx_outw (unsigned short int b, unsigned long int port) { unsigned long int addr = dense_port_to_cpu_addr (port); __asm__ __volatile__ ("stw %1,%0" : : "m"(*(unsigned short *)addr), "r"(b)); mb (); } static inline void inline_bwx_outl (unsigned int b, unsigned long int port) { unsigned long int addr = dense_port_to_cpu_addr (port); *(vuip)addr = b; mb (); } static inline unsigned int inline_bwx_inb (unsigned long int port) { unsigned long int r, addr = dense_port_to_cpu_addr (port); __asm__ __volatile__ ("ldbu %0,%1" : "=r"(r) : "m"(*(unsigned char *)addr)); return 0xffUL & r; } static inline unsigned int inline_bwx_inw (unsigned long int port) { unsigned long int r, addr = dense_port_to_cpu_addr (port); __asm__ __volatile__ ("ldwu %0,%1" : "=r"(r) : "m"(*(unsigned short *)addr)); return 0xffffUL & r; } static inline unsigned int inline_bwx_inl (unsigned long int port) { unsigned long int addr = dense_port_to_cpu_addr (port); return *(vuip) addr; } /* macros to define routines with appropriate names and functions */ /* these do either SPARSE or JENSEN swizzle */ #define DCL_SETHAE(name, ioswiz) \ static void \ name##_sethae (unsigned long int addr) \ { \ inline_sethae (addr, IOSWIZZLE_##ioswiz); \ } #define DCL_OUT(name, func, type, ioswiz) \ static void \ name##_##func (unsigned type b, unsigned long int addr) \ { \ inline_##func (b, addr, IOSWIZZLE_##ioswiz); \ } #define DCL_IN(name, func, ioswiz) \ static unsigned int \ name##_##func (unsigned long int addr) \ { \ return inline_##func (addr, IOSWIZZLE_##ioswiz); \ } /* these do DENSE, so no swizzle is needed */ #define DCL_OUT_BWX(name, func, type) \ static void \ name##_##func (unsigned type b, unsigned long int addr) \ { \ inline_bwx_##func (b, addr); \ } #define DCL_IN_BWX(name, func) \ static unsigned int \ name##_##func (unsigned long int addr) \ { \ return inline_bwx_##func (addr); \ } /* now declare/define the necessary routines */ DCL_SETHAE(jensen, JENSEN) DCL_OUT(jensen, outb, char, JENSEN) DCL_OUT(jensen, outw, short int, JENSEN) DCL_OUT(jensen, outl, int, JENSEN) DCL_IN(jensen, inb, JENSEN) DCL_IN(jensen, inw, JENSEN) DCL_IN(jensen, inl, JENSEN) DCL_SETHAE(sparse, SPARSE) DCL_OUT(sparse, outb, char, SPARSE) DCL_OUT(sparse, outw, short int, SPARSE) DCL_OUT(sparse, outl, int, SPARSE) DCL_IN(sparse, inb, SPARSE) DCL_IN(sparse, inw, SPARSE) DCL_IN(sparse, inl, SPARSE) DCL_OUT_BWX(dense, outb, char) DCL_OUT_BWX(dense, outw, short int) DCL_OUT_BWX(dense, outl, int) DCL_IN_BWX(dense, inb) DCL_IN_BWX(dense, inw) DCL_IN_BWX(dense, inl) /* define the "swizzle" switch */ static struct ioswtch ioswtch[] = { { jensen_sethae, jensen_outb, jensen_outw, jensen_outl, jensen_inb, jensen_inw, jensen_inl }, { sparse_sethae, sparse_outb, sparse_outw, sparse_outl, sparse_inb, sparse_inw, sparse_inl }, { NULL, dense_outb, dense_outw, dense_outl, dense_inb, dense_inw, dense_inl } }; /* routine to process the /proc/cpuinfo information into the fields */ /* that are required for correctly determining the platform parameters */ char systype[256]; /* system type field */ char sysvari[256]; /* system variation field */ char cpumodel[256]; /* cpu model field */ int got_type, got_vari, got_model; static int process_cpuinfo(void) { char dummy[256]; FILE * fp; fp = fopen (PATH_CPUINFO, "r"); if (!fp) return 0; got_type = got_vari = got_model = 0; systype[0] = sysvari[0] = cpumodel[0] = 0; while (1) { if (fgets (dummy, 256, fp) == NULL) break; /* fprintf(stderr, "read: %s", dummy); */ if (!got_type && sscanf (dummy, "system type : %256[^\n]\n", systype) == 1) got_type = 1; if (!got_vari && sscanf (dummy, "system variation : %256[^\n]\n", sysvari) == 1) got_vari = 1; if (!got_model && sscanf (dummy, "cpu model : %256[^\n]\n", cpumodel) == 1) got_model = 1; } fclose (fp); #if 1 fprintf(stderr, "system type: %s\n", systype); fprintf(stderr, "system vari: %s\n", sysvari); fprintf(stderr, "cpu model: %s\n", cpumodel); #endif return got_type+got_vari+got_model; } /* * Initialize I/O system. To determine what I/O system we're dealing * with, we first try to read the value of symlink PATH_ALPHA_SYSTYPE, * if that fails, we lookup the "system type" field in /proc/cpuinfo. * If that fails as well, we give up. * * If the value received from PATH_ALPHA_SYSTYPE begins with a number, * assume this is a previously unsupported system and the values encode, * in order, ",,,". */ static int init_iosys (void) { int i, n; n = readlink (PATH_ALPHA_SYSTYPE, systype, sizeof (systype) - 1); if (n > 0) { systype[n] = '\0'; if (isdigit (systype[0])) { if (sscanf (systype, "%li,%i,%li,%li", &io.io_base, &io.hae_shift, &io.bus_memory_base, &io.sparse_bus_memory_base) == 4) { io.sys = IOSYS_UNKNOWN; io.swiz = IOSWIZZLE_SPARSE; io.swp = &ioswtch[IOSWIZZLE_SPARSE]; return 0; } /* else we're likely going to fail with the system match below */ } } else { n = process_cpuinfo(); if (!n) { /* this can happen if the format of /proc/cpuinfo changes... */ fprintf (stderr, "ioperm.init_iosys(): Unable to determine system type.\n" "\t(May need " PATH_ALPHA_SYSTYPE " symlink?)\n"); __set_errno (ENODEV); return -1; } } /* translate systype name into i/o system: */ for (i = 0; i < sizeof (platform) / sizeof (platform[0]); ++i) { if (strcmp (platform[i].name, systype) == 0) { io.sys = platform[i].io_sys; /* some platforms can have either EV4 or EV5 CPUs */ if (io.sys == IOSYS_CPUDEP) /* SABLE or MIKASA or NORITAKE so far */ { if (strcmp (platform[i].name, "Sable") == 0) { if (strncmp (cpumodel, "EV4", 3) == 0) io.sys = IOSYS_T2; else if (strncmp (cpumodel, "EV5", 3) == 0) io.sys = IOSYS_GAMMA; } else { /* this covers MIKASA/NORITAKE */ if (strncmp (cpumodel, "EV4", 3) == 0) io.sys = IOSYS_APECS; else if (strncmp (cpumodel, "EV5", 3) == 0) io.sys = IOSYS_CIA; } if (io.sys == IOSYS_CPUDEP) { /* This can happen if the format of /proc/cpuinfo changes.*/ fprintf (stderr, "ioperm.init_iosys(): Unable to determine" " CPU model.\n"); __set_errno (ENODEV); return -1; } } /* some platforms can have different core logic chipsets */ if (io.sys == IOSYS_PCIDEP) /* EB164 so far */ { if (strcmp (systype, "EB164") == 0) { if (strncmp (sysvari, "RX164", 5) == 0) io.sys = IOSYS_POLARIS; else io.sys = IOSYS_CIA; } if (io.sys == IOSYS_PCIDEP) { /* This can happen if the format of /proc/cpuinfo changes.*/ fprintf (stderr, "ioperm.init_iosys(): Unable to determine" " core logic chipset.\n"); __set_errno (ENODEV); return -1; } } io.hae_shift = io_system[io.sys].hae_shift; io.bus_memory_base = io_system[io.sys].bus_memory_base; io.sparse_bus_memory_base = io_system[io.sys].sparse_bus_mem_base; io.io_base = io_system[io.sys].bus_io_base; if (io.sys == IOSYS_JENSEN) io.swiz = IOSWIZZLE_JENSEN; else if (io.sys == IOSYS_TSUNAMI || io.sys == IOSYS_POLARIS) io.swiz = IOSWIZZLE_DENSE; else io.swiz = IOSWIZZLE_SPARSE; io.swp = &ioswtch[io.swiz]; return 0; } } /* systype is not a know platform name... */ __set_errno (EINVAL); #if 1 fprintf(stderr, "init_iosys: platform not recognized\n"); #endif return -1; } int _ioperm (unsigned long int from, unsigned long int num, int turn_on) { unsigned long int addr, len; int prot, err; if (!io.swp && init_iosys() < 0) { #if 1 fprintf(stderr, "ioperm: init_iosys() failed\n"); #endif return -1; } /* this test isn't as silly as it may look like; consider overflows! */ if (from >= MAX_PORT || from + num > MAX_PORT) { __set_errno (EINVAL); #if 1 fprintf(stderr, "ioperm: from/num out of range\n"); #endif return -1; } #if 1 fprintf(stderr, "ioperm: turn_on %d io.base %ld\n", turn_on, io.base); #endif if (turn_on) { if (!io.base) { int fd; io.hae.reg = 0; /* not used in user-level */ io.hae.cache = 0; if (io.swiz != IOSWIZZLE_DENSE) __sethae (io.hae.cache); /* synchronize with hw */ fd = open ("/dev/mem", O_RDWR); if (fd < 0) { #if 1 fprintf(stderr, "ioperm: /dev/mem open failed\n"); #endif return -1; } addr = port_to_cpu_addr (0, io.swiz, 1); len = port_to_cpu_addr (MAX_PORT, io.swiz, 1) - addr; io.base = (unsigned long int) __mmap (0, len, PROT_NONE, MAP_SHARED, fd, io.io_base); close (fd); #if 1 fprintf(stderr, "ioperm: mmap of len 0x%lx returned 0x%lx\n", len, io.base); #endif if ((long) io.base == -1) return -1; } prot = PROT_READ | PROT_WRITE; } else { if (!io.base) return 0; /* never was turned on... */ /* turnoff access to relevant pages: */ prot = PROT_NONE; } addr = port_to_cpu_addr (from, io.swiz, 1); addr &= PAGE_MASK; len = port_to_cpu_addr (from + num, io.swiz, 1) - addr; err = mprotect ((void *) addr, len, prot); #if 1 fprintf(stderr, "ioperm: mprotect returned %d\n", err); #endif return err; } int _iopl (unsigned int level) { if (level > 3) { __set_errno (EINVAL); return -1; } if (level) { return _ioperm (0, MAX_PORT, 1); } return 0; } void _sethae (unsigned long int addr) { if (!io.swp && init_iosys () < 0) return; io.swp->sethae (addr); } void _outb (unsigned char b, unsigned long int port) { if (port >= MAX_PORT) return; io.swp->outb (b, port); } void _outw (unsigned short b, unsigned long int port) { if (port >= MAX_PORT) return; io.swp->outw (b, port); } void _outl (unsigned int b, unsigned long int port) { if (port >= MAX_PORT) return; io.swp->outl (b, port); } unsigned int _inb (unsigned long int port) { return io.swp->inb (port); } unsigned int _inw (unsigned long int port) { return io.swp->inw (port); } unsigned int _inl (unsigned long int port) { return io.swp->inl (port); } unsigned long int _bus_base(void) { if (!io.swp && init_iosys () < 0) return -1; return io.bus_memory_base; } unsigned long int _bus_base_sparse(void) { if (!io.swp && init_iosys () < 0) return -1; return io.sparse_bus_memory_base; } int _hae_shift(void) { if (!io.swp && init_iosys () < 0) return -1; return io.hae_shift; } weak_alias (_sethae, sethae); weak_alias (_ioperm, ioperm); weak_alias (_iopl, iopl); weak_alias (_inb, inb); weak_alias (_inw, inw); weak_alias (_inl, inl); weak_alias (_outb, outb); weak_alias (_outw, outw); weak_alias (_outl, outl); weak_alias (_bus_base, bus_base); weak_alias (_bus_base_sparse, bus_base_sparse); weak_alias (_hae_shift, hae_shift);