/* $NetBSD: iomod.h,v 1.1 2014/02/24 07:23:43 skrll Exp $ */ /* $OpenBSD: iomod.h,v 1.18 2007/10/20 16:41:45 miod Exp $ */ /* * Copyright (c) 2000-2004 Michael Shalayeff * All rights reserved. * * 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. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR OR HIS RELATIVES 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 MIND, 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. */ /* * Copyright (c) 1990 mt Xinu, Inc. All rights reserved. * Copyright (c) 1990,1991,1992,1994 University of Utah. All rights reserved. * * Permission to use, copy, modify and distribute this software is hereby * granted provided that (1) source code retains these copyright, permission, * and disclaimer notices, and (2) redistributions including binaries * reproduce the notices in supporting documentation, and (3) all advertising * materials mentioning features or use of this software display the following * acknowledgement: ``This product includes software developed by the * Computer Systems Laboratory at the University of Utah.'' * * Copyright (c) 1990 mt Xinu, Inc. * This file may be freely distributed in any form as long as * this copyright notice is included. * MTXINU, THE UNIVERSITY OF UTAH, AND CSL PROVIDE THIS SOFTWARE ``AS * IS'' AND WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, * WITHOUT LIMITATION, THE IMPLIED WARRANTIES OF MERCHANTIBILITY AND * FITNESS FOR A PARTICULAR PURPOSE. * * CSL requests users of this software to return to csl-dist@cs.utah.edu any * improvements that they make and grant CSL redistribution rights. * * Utah $Hdr: iomod.h 1.6 94/12/14$ */ #ifndef _MACHINE_IOMOD_H_ #define _MACHINE_IOMOD_H_ #include /* * Structures and definitions for I/O Modules on HP-PA (9000/800). * * Memory layout: * * 0x00000000 +---------------------------------+ * | Page Zero | * 0x00000800 + - - - - - - - - - - - - - - - - + * | | * | | * | Memory Address Space | * | | * | | * 0xEF000000 +---------------------------------+ * | | * | PDC Address Space | * | | * 0xF1000000 +---------------------------------+ * | | * | | * | I/O Address Space | * | | * | | * 0xFFF80000 + - - - - - - - - - - - - - - - - + * | Fixed Physical Address Space | * 0xFFFC0000 + - - - - - - - - - - - - - - - - + * | Local Broadcast Address Space | * 0xFFFE0000 + - - - - - - - - - - - - - - - - + * | Global Broadcast Address Space | * 0xFFFFFFFF +---------------------------------+ * * "Memory Address Space" is used by memory modules, * "Page Zero" is described below. * "PDC Address Space" is used by Processor-Dependent Code. * "I/O Address Space" is used by I/O modules (and is not cached), * "Fixed Physical" is used by modules on the central bus, * "Local Broadcast" is used to reach all modules on the same bus, and * "Global Broadcast" is used to reach all modules (thru bus converters). * * SPA space (see below) ranges from 0xF1000000 thru 0xFFFC0000. */ #define HPPA_IOBEGIN 0xF0000000 #define HPPA_IOLEN 0x10000000 #define PDC_ADDR 0xEF000000 /* explained above */ #define IO_ADDR 0xF1000000 #define SGC_SLOT1 0xF4000000 /* (hppa) */ #define SGC_SLOT2 0xF8000000 /* (hppa) */ #define SGC_SIZE 0x02000000 /* (hppa) */ #define FP_ADDR 0xFFF80000 #define LBCAST_ADDR 0xFFFC0000 #define GBCAST_ADDR 0xFFFE0000 #define PDC_LOW PDC_ADDR /* define some ranges */ #define PDC_HIGH IO_ADDR #define FPA_LOW FP_ADDR #define FPA_HIGH LBCAST_ADDR #define SPA_LOW IO_ADDR #define SPA_HIGH LBCAST_ADDR #define SGC_LOW SGC_SLOT1 #define SGC_HIGH (SGC_SLOT2+SGC_SIZE) #define FPA_IOMOD ((FPA_HIGH-FPA_LOW)/sizeof(struct iomod)) #define MAXMODBUS ((int)(FPA_IOMOD)) /* maximum modules/bus */ #define HPPA_FLEX_COUNT 0x4000 /* number of "flex" blocks */ #define HPPA_FLEX_MASK 0xFFFC0000 /* (see below) */ #define HPPA_FLEX_SIZE (~HPPA_FLEX_MASK + 1) #define HPPA_FLEX(a) (((a) & HPPA_FLEX_MASK) >> 18) /* size of HPA space for any device */ #define IOMOD_HPASIZE 0x1000 /* offset to the device-specific registers, * basically sizeof(struct iomod) (see later) */ #define IOMOD_DEVOFFSET 0x800 #if !defined(_LOCORE) /* * The first 2K of Soft Physical Address space on the Initial Memory Module * is aptly called "page zero". The following structure defines the format * of page zero. Individual members of this structure should be accessed * as "PAGE0->member". */ #define PAGE0 ((struct pagezero *)0) /* can't get any lower than this! */ struct pagezero { /* [0x000] Initialize Vectors */ int ivec_special; /* must be zero */ int (*ivec_mempf)(void); /* powerfail recovery software */ int (*ivec_toc)(void); /* exec'd after Transfer Of Control */ u_int ivec_toclen; /* bytes of ivec_toc code */ int (*ivec_rendz)(void); /* exec'd after Rendezvous Signal */ u_int ivec_mempflen; /* bytes of ivec_mempf code */ u_int ivec_resv[2]; /* (reserved) */ u_int ivec_mbz; /* must be zero */ u_int ivec_resv2[7]; /* (reserved) */ /* [0x040] Processor Dependent */ union { u_int pd_Resv1[112]; /* (reserved) processor dependent */ struct { /* Viper-specific data */ u_int v_Resv1[39]; u_int v_Ctrlcpy; /* copy of Viper `vi_control' */ u_int v_Resv2[72]; } pd_Viper; } pz_Pdep; /* [0x200] IODC Data Area Descriptors use PDC_ALLOC to allocate these memory regions */ u_int iodc_cons_base; /* */ u_int iodc_cons_size; /* */ u_int iodc_kbrd_base; /* */ u_int iodc_kbrd_size; /* */ u_int iodc_boot_base; /* */ u_int iodc_boot_size; /* */ /* [0x218] */ u_int resv1[0x41]; /* [0x31C] Capability Flags */ u_int cap_flags; /* system capabitlities */ #define HPPA_CAP_WIDESCSI 0x00000001 /* [0x320] Keyboard Extensions */ u_int kbrd_ext[2]; /* [0x328] Boot Device Extensions */ u_int boot_ext[2]; /* [0x330] Console/Display Extensions */ u_int cons_ext[2]; /* [0x338] Initial Memory Module Extensions */ u_int imm_ext[2]; /* [0x340] Memory Configuration */ u_int memc_cont_l; /* memc_cont low part */ u_int memc_phsize_l; /* memc_phsize low part */ u_int memc_adsize_l; /* memc_adsize low part */ u_int memc_resv; /* (reserved) */ u_int memc_cont; /* bytes of contiguous valid memory */ u_int memc_phsize; /* bytes of valid physical memory */ u_int memc_adsize; /* bytes of SPA space used by PDC */ u_int memc_hpa_h; /* HPA of CPU (high) */ /* [0x360] Miscellaneous */ struct boot_err mem_be[8]; /* boot errors (see above) */ u_int mem_free; /* first free phys. memory location */ u_int mem_hpa; /* HPA of CPU */ int (*mem_pdc)(void); /* PDC entry point */ u_int mem_10msec; /* # of Interval Timer ticks in 10msec*/ /* [0x390] Initial Memory Module */ struct iomod *imm_hpa; /* HPA of Initial Memory module */ u_int imm_soft_boot; /* 0 == hard boot, 1 == soft boot */ u_int imm_spa_size; /* bytes of SPA in IMM */ u_int imm_max_mem; /* bytes of mem in IMM (<= spa_size) */ /* [0x3A0] Boot Console/Display, Device, and Keyboard */ struct pz_device mem_cons; /* description of console device */ struct pz_device mem_boot; /* description of boot device */ struct pz_device mem_kbd; /* description of keyboard device */ /* [0x430] Reserved */ u_int resv2[116]; /* (reserved) */ /* [0x600] Processor Dependent */ u_int pd_resv2[128]; /* (reserved) processor dependent */ }; #define v_ctrlcpy pz_Pdep.pd_Viper.v_Ctrlcpy /* * Every module has 4K-bytes of address space associated with it. * A Hard Physical Address (HPA) can be broken down as follows. * * Since this is an I/O space, the high 4 bits are always 1's. * * The "flex" address specifies which bus a module is on; there are * 256K-bytes of HPA space for each bus, however only values from * 64 - 1022 are valid for the "flex" field (1022 designates the * central bus). The "flex" addr is set at bus configuration time. * * The "fixed" address specifies a particular module on the same * bus (i.e. among modules with the same "flex" address). This * value can also be found in "device_path.dp_mod" in "pdc.h". * * A modules HPA space consists of 2 pages; the "up" bit specifies * which of these pages is being addressed. In general, the lower * page is privileged and the upper page it module-type dependent. * */ struct hpa { u_int hpa_ones: 4, /* must be 1's; this is an I/O space addr */ hpa_flex:10, /* bus address for this module */ hpa_fixed:6, /* location of module on bus */ hpa_up : 1, /* 1 == upper page, 0 == lower page */ hpa_set : 5, /* register set */ hpa_reg : 4, /* register number within a register set */ hpa_zeros:2; /* must be 0's; addrs are word aligned */ }; /* * Certain modules require additional memory (i.e. more than that * provided by the HPA space). A Soft Physical Address (SPA) can be * broken down as follows, on a module-type specific basis (either * Memory SPA or I/O SPA). * * SPA space must be a power of 2, and aligned accordingly. The IODC * provides all information needed by software to configure SPA space * for a particular module. */ struct memspa { u_int spa_page:21, /* page of memory */ spa_off :11; /* offset into memory page */ }; struct iospa { u_int spa_ones: 4, /* must be 1's; this is an I/O space addr */ spa_iopg:17, /* page in I/O address space */ spa_set : 5, /* register set */ spa_reg : 4, /* register number within a register set */ spa_mode: 2; /* aligned according to bus transaction mode */ }; /* * It is possible to send a command to all modules on a particular bus * (local broadcast), or all modules (global broadcast). A Broadcast * Physical Address (BPA) can be broken down as follows. * * Read and Clear transactions are not allowed in BPA space. All pages * in BPA space are privileged. */ struct bpa { u_int bpa_ones:14, /* must be 1's; this is in BPA space */ bpa_gbl : 1, /* 0 == local, 1 == global broadcast */ bpa_page: 6, /* page in local/global BPA space */ bpa_set : 5, /* register set */ bpa_reg : 4, /* register number within a register set */ bpa_zeros:2; /* must be 0's; addrs are word aligned */ }; /* * All I/O and Memory modules have 4K-bytes of HPA space associated with * it (described above), however not all modules implement every register. * The first 2K-bytes of registers are "privileged". * * (WO) == Write Only, (RO) == Read Only */ struct iomod { /* SRS (Supervisor Register Set) */ u_int io_eir; /* (WO) interrupt CPU; set bits in EIR CR */ u_int io_eim; /* (WO) External Interrupt Message address */ u_int io_dc_rw; /* write address of IODC to read IODC data */ u_int io_ii_rw; /* read/clear external intrpt msg (bit-26) */ void * io_dma_link; /* pointer to "next quad" in DMA chain */ u_int io_dma_command; /* (RO) chain command to exec on "next quad" */ void * io_dma_address; /* (RO) start of DMA */ u_int io_dma_count; /* (RO) number of bytes remaining to xfer */ void * io_flex; /* (WO) HPA flex addr, LSB: bus master flag */ void * io_spa; /* (WO) SPA space; 0-20:addr, 24-31:iodc_spa */ u_int resv1[2]; /* (reserved) */ u_int io_command; /* (WO) module commands (see below) */ u_int io_status; /* (RO) error returns (see below) */ u_int io_control; /* memory err logging (bit-9), bc forwarding */ u_int io_test; /* (RO) self-test information */ /* ARS (Auxiliary Register Set) */ u_int io_err_sadd; /* (RO) slave bus error or memory error addr */ void * chain_addr; /* start address of chain RAM */ u_int sub_mask_clr; /* ignore intrpts on sub-channel (bitmask) */ u_int sub_mask_set; /* service intrpts on sub-channel (bitmask) */ u_int diagnostic; /* diagnostic use (reserved) */ u_int resv2[2]; /* (reserved) */ void * nmi_address; /* address to send data to when NMI detected */ void * nmi_data; /* NMI data to be sent */ u_int resv3[3]; /* (reserved) */ u_int io_mem_low; /* bottom of memory address range */ u_int io_mem_high; /* top of memory address range */ u_int io_io_low; /* bottom of I/O HPA address Range */ u_int io_io_high; /* top of I/O HPA address Range */ u_int priv_trs[160]; /* TRSes (Type-dependent Reg Sets) */ u_int priv_hvrs[320]; /* HVRSes (HVERSION-dependent Register Sets) */ u_int hvrs[512]; /* HVRSes (HVERSION-dependent Register Sets) */ }; #define IOMOD_IO_IO_LOW(mod) (((struct iomod *)(mod))->io_io_low) #define IOMOD_IO_IO_HIGH(mod) (((struct iomod *)(mod))->io_io_high) #endif /* !_LOCORE */ /* primarily for a "reboot" and "_rtt" routines */ #define iomod_command (4*12) /* io_flex */ #define DMA_ENABLE 0x1 /* flex register enable DMA bit */ /* io_spa */ #define IOSPA(spa,iodc_data) \ ((volatile void *) \ (spa | iodc_data.iodc_spa_shift | iodc_data.iodc_spa_enb << 5 | \ iodc_data.iodc_spa_pack << 6 | iodc_data.iodc_spa_io << 7)) /* io_command */ #define CMD_STOP 0 /* halt any I/O, enable diagnostic access */ #define CMD_FLUSH 1 /* abort DMA */ #define CMD_CHAIN 2 /* initiate DMA */ #define CMD_CLEAR 3 /* clear errors */ #define CMD_RESET 5 /* reset any module */ /* io_status */ #define IO_ERR_MEM_SL 0x10000 /* SPA space lost or corrupted */ #define IO_ERR_MEM_SE 0x00200 /* severity: minor */ #define IO_ERR_MEM_HE 0x00100 /* severity: affects invalid parts */ #define IO_ERR_MEM_FE 0x00080 /* severity: bad */ #define IO_ERR_MEM_RY 0x00040 /* IO_COMMAND register ready for command */ #define IO_ERR_DMA_DG 0x00010 /* module in diagnostic mode */ #define IO_ERR_DMA_PW 0x00004 /* Power Failing */ #define IO_ERR_DMA_PL 0x00002 /* Power Lost */ #define IO_ERR_VAL(x) (((x) >> 10) & 0x3f) #define IO_ERR_DEPEND 0 /* unspecified error */ #define IO_ERR_SPA 1 /* (module-type specific) */ #define IO_ERR_INTERNAL 2 /* (module-type specific) */ #define IO_ERR_MODE 3 /* invalid mode or address space mapping */ #define IO_ERR_ERROR_M 4 /* bus error (master detect) */ #define IO_ERR_DPARITY_S 5 /* data parity (slave detect) */ #define IO_ERR_PROTO_M 6 /* protocol error (master detect) */ #define IO_ERR_ADDRESS 7 /* no slave acknowledgement in transaction */ #define IO_ERR_MORE 8 /* device transferred more data than expected */ #define IO_ERR_LESS 9 /* device transferred less data than expected */ #define IO_ERR_SAPARITY 10 /* slave address phase parity */ #define IO_ERR_MAPARITY 11 /* master address phase parity */ #define IO_ERR_MDPARITY 12 /* mode phase parity */ #define IO_ERR_STPARITY 13 /* status phase parity */ #define IO_ERR_CMD 14 /* unimplemented I/O Command */ #define IO_ERR_BUS 15 /* generic bus error */ #define IO_ERR_CORR 24 /* correctable memory error */ #define IO_ERR_UNCORR 25 /* uncorrectable memory error */ #define IO_ERR_MAP 26 /* equivalent to IO_ERR_CORR */ #define IO_ERR_LINK 28 /* Bus Converter "link" (connection) error */ #define IO_ERR_CCMD 32 /* Illegal DMA command */ #define IO_ERR_ERROR_S 52 /* bus error (slave detect) */ #define IO_ERR_DPARITY_M 53 /* data parity (master detect) */ #define IO_ERR_PROTOCOL 54 /* protocol error (slave detect) */ #define IO_ERR_SELFTEST 58 /* (module-type specific) */ #define IO_ERR_BUSY 59 /* slave was busy too often or too long */ #define IO_ERR_RETRY 60 /* "busied" transaction not retried soon enough */ #define IO_ERR_ACCESS 61 /* illegal register access */ #define IO_ERR_IMPROP 62 /* "improper" data written */ #define IO_ERR_UNKNOWN 63 /* io_control (memory) */ #define IO_CTL_MEMINIT 0x0 /* prevent some bus errors during memory init */ #define IO_CTL_MEMOKAY 0x100 /* enable all bus error logging */ /* io_spa */ #define SPA_ENABLE 0x20 /* io_spa register enable spa bit */ #define EIM_GRPMASK 0x1F /* EIM register group mask */ #define EIEM_MASK(eim) (0x80000000 >> (eim & EIM_GRPMASK)) #define EIEM_BITCNT 32 /* number of bits in EIEM register */ #endif /* _MACHINE_IOMOD_H_ */