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[/] [openrisc/] [trunk/] [or1ksim/] [peripheral/] [generic.c] - Rev 164
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/* generic.c -- Generic external peripheral Copyright (C) 2008 Embecosm Limited Contributor Jeremy Bennett <jeremy.bennett@embecosm.com> This file is part of OpenRISC 1000 Architectural Simulator. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program 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 General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see <http://www.gnu.org/licenses/>. */ /* This program is commented throughout in a fashion suitable for processing with Doxygen. */ /* This is functional simulation of any external peripheral. It's job is to * trap accesses in a specific range, so that the simulator can drive an * external device. * * A note on endianess. All external communication is done using HOST * endianess. A set of functions are provided to convert between host and * model endianess (htoml, htoms, mtohl, mtohs). */ /* Autoconf and/or portability configuration */ #include "config.h" /* System includes */ #include <stdlib.h> #include <stdio.h> /* Package includes */ #include "arch.h" #include "sim-config.h" #include "abstract.h" #include "toplevel-support.h" #include "sim-cmd.h" /*! State associated with the generic device. */ struct dev_generic { /* Info about a particular transaction */ enum { /* Direction of the access */ GENERIC_READ, GENERIC_WRITE } trans_direction; enum { /* Size of the access */ GENERIC_BYTE, GENERIC_HW, GENERIC_WORD } trans_size; uint32_t value; /* The value to read/write */ /* Configuration */ int enabled; /* Device enabled */ int byte_enabled; /* Byte R/W allowed */ int hw_enabled; /* Half word R/W allowed */ int word_enabled; /* Full word R/W allowed */ char *name; /* Name of the device */ oraddr_t baseaddr; /* Base address of device */ uint32_t size; /* Address space size (bytes) */ }; /* --------------------------------------------------------------------------*/ /*!Read a byte from an external device To model Wishbone accurately, we always do this as a 4-byte access, with a mask for the bytes we don't want. Since this is only a byte, the endianess of the result is irrelevant. @note We are passed the device address, but we must convert it to a full address for external use, to allow the single upcall handler to decode multiple generic devices. @param[in] addr The device address to read from (host endian). @param[in] dat The device data structure @return The byte read. */ /* --------------------------------------------------------------------------*/ static uint8_t generic_read_byte (oraddr_t addr, void *dat) { struct dev_generic *dev = (struct dev_generic *) dat; if (!config.ext.read_up) { fprintf (stderr, "Byte read from disabled generic device\n"); return 0; } else if (addr >= dev->size) { fprintf (stderr, "Byte read out of range for generic device %s " "(addr %" PRIxADDR ")\n", dev->name, addr); return 0; } else { unsigned long int fulladdr = (unsigned long int) (addr + dev->baseaddr); unsigned long int wordaddr = fulladdr & 0xfffffffc; int bytenum = fulladdr & 0x00000003; unsigned char mask[4]; unsigned char res[4]; /* Set the mask, read and get the result */ memset (mask, 0, sizeof (mask)); mask[bytenum] = 0xff; if (0 != config.ext.read_up (config.ext.class_ptr, wordaddr, mask, res, 4)) { fprintf (stderr, "Warning: external byte read failed.\n"); return 0; } return res[bytenum]; } } /* generic_read_byte() */ /* --------------------------------------------------------------------------*/ /*!Write a byte to an external device To model Wishbone accurately, we always do this as a 4-byte access, with a mask for the bytes we don't want. Since this is only a byte, the endianess of the value is irrelevant. @note We are passed the device address, but we must convert it to a full address for external use, to allow the single upcall handler to decode multiple generic devices. @param[in] addr The device address to write to (host endian) @param[in] value The byte value to write @param[in] dat The device data structure */ /* --------------------------------------------------------------------------*/ static void generic_write_byte (oraddr_t addr, uint8_t value, void *dat) { struct dev_generic *dev = (struct dev_generic *) dat; if (!config.ext.write_up) { fprintf (stderr, "Byte write to disabled generic device\n"); } else if (addr >= dev->size) { fprintf (stderr, "Byte written out of range for generic device %s " "(addr %" PRIxADDR ")\n", dev->name, addr); } else { unsigned long int fulladdr = (unsigned long int) (addr + dev->baseaddr); unsigned long int wordaddr = fulladdr & 0xfffffffc; int bytenum = fulladdr & 0x00000003; unsigned char mask[4]; unsigned char val[4]; /* Set the mask and write data do the write. */ memset (mask, 0, sizeof (mask)); mask[bytenum] = 0xff; val[bytenum] = value; if (0 != config.ext.write_up (config.ext.class_ptr, wordaddr, mask, val, 4)) { fprintf (stderr, "Warning: external byte write failed.\n"); } } } /* generic_write_byte() */ /* --------------------------------------------------------------------------*/ /*!Read a half word from an external device To model Wishbone accurately, we always do this as a 4-byte access, with a mask for the bytes we don't want. Since this is a half word, the result must be converted to host endianess. @note We are passed the device address, but we must convert it to a full address for external use, to allow the single upcall handler to decode multiple generic devices. @param[in] addr The device address to read from (host endian). @param[in] dat The device data structure. @return The half word read (host endian). */ /* --------------------------------------------------------------------------*/ static uint16_t generic_read_hw (oraddr_t addr, void *dat) { struct dev_generic *dev = (struct dev_generic *) dat; if (!config.ext.read_up) { fprintf (stderr, "Half word read from disabled generic device\n"); return 0; } else if (addr >= dev->size) { fprintf (stderr, "Half-word read out of range for generic device %s " "(addr %" PRIxADDR ")\n", dev->name, addr); return 0; } else if (addr & 0x1) { /* This should be trapped elsewhere - here for safety. */ fprintf (stderr, "Unaligned half word read from 0x%" PRIxADDR " ignored\n", addr); return 0; } else { unsigned long int fulladdr = (unsigned long int) (addr + dev->baseaddr); unsigned long int wordaddr = fulladdr & 0xfffffffc; int hwnum = fulladdr & 0x00000002; unsigned char mask[4]; unsigned char res[4]; /* Set the mask, read and get the result */ memset (mask, 0, sizeof (mask)); mask[hwnum ] = 0xff; mask[hwnum + 1] = 0xff; if (0 != config.ext.read_up (config.ext.class_ptr, wordaddr, mask, res, 4)) { fprintf (stderr, "Warning: external half word read failed.\n"); return 0; } /* Result converted according to endianess */ #ifdef OR32_BIG_ENDIAN return (unsigned short int) res[hwnum ] << 8 | (unsigned short int) res[hwnum + 1]; #else return (unsigned short int) res[hwnum + 1] << 8 | (unsigned short int) res[hwnum ]; #endif } } /* generic_read_hw() */ /* --------------------------------------------------------------------------*/ /*!Write a half word to an external device To model Wishbone accurately, we always do this as a 4-byte access, with a mask for the bytes we don't want. Since this is a half word, the value must be converted from host endianess. @note We are passed the device address, but we must convert it to a full address for external use, to allow the single upcall handler to decode multiple generic devices. @param[in] addr The device address to write to (host endian). @param[in] value The half word value to write (model endian). @param[in] dat The device data structure. */ /* --------------------------------------------------------------------------*/ static void generic_write_hw (oraddr_t addr, uint16_t value, void *dat) { struct dev_generic *dev = (struct dev_generic *) dat; if (!config.ext.write_up) { fprintf (stderr, "Half word write to disabled generic device\n"); } else if (addr >= dev->size) { fprintf (stderr, "Half-word written out of range for generic device %s " "(addr %" PRIxADDR ")\n", dev->name, addr); } else if (addr & 0x1) { fprintf (stderr, "Unaligned half word write to 0x%" PRIxADDR " ignored\n", addr); } else { unsigned long int fulladdr = (unsigned long int) (addr + dev->baseaddr); unsigned long int wordaddr = fulladdr & 0xfffffffc; int hwnum = fulladdr & 0x00000002; unsigned char mask[4]; unsigned char val[4]; /* Set the mask and write data do the write. */ memset (mask, 0, sizeof (mask)); mask[hwnum ] = 0xff; mask[hwnum + 1] = 0xff; /* Value converted according to endianess */ #ifdef OR32_BIG_ENDIAN val[hwnum ] = (unsigned char) (value >> 8); val[hwnum + 1] = (unsigned char) (value ); #else val[hwnum + 1] = (unsigned char) (value >> 8); val[hwnum ] = (unsigned char) (value ); #endif if (0 != config.ext.write_up (config.ext.class_ptr, wordaddr, mask, val, 4)) { fprintf (stderr, "Warning: external half word write failed.\n"); } } } /* generic_write_hw() */ /* --------------------------------------------------------------------------*/ /*!Read a full word from an external device Since this is a full word, the result must be converted to host endianess. @note We are passed the device address, but we must convert it to a full address for external use, to allow the single upcall handler to decode multiple generic devices. @param[in] addr The device address to read from (host endian). @param[in] dat The device data structure. @return The full word read (host endian). */ /* --------------------------------------------------------------------------*/ static uint32_t generic_read_word (oraddr_t addr, void *dat) { struct dev_generic *dev = (struct dev_generic *) dat; if (!config.ext.read_up) { fprintf (stderr, "Full word read from disabled generic device\n"); return 0; } else if (addr >= dev->size) { fprintf (stderr, "Full word read out of range for generic device %s " "(addr %" PRIxADDR ")\n", dev->name, addr); return 0; } else if (0 != (addr & 0x3)) { fprintf (stderr, "Unaligned full word read from 0x%" PRIxADDR " ignored\n", addr); return 0; } else { unsigned long int wordaddr = (unsigned long int) (addr + dev->baseaddr); unsigned char mask[4]; unsigned char res[4]; /* Set the mask, read and get the result */ memset (mask, 0xff, sizeof (mask)); if (0 != config.ext.read_up (config.ext.class_ptr, wordaddr, mask, res, 4)) { fprintf (stderr, "Warning: external full word read failed.\n"); return 0; } /* Result converted according to endianess */ #ifdef OR32_BIG_ENDIAN return (unsigned long int) res[0] << 24 | (unsigned long int) res[1] << 16 | (unsigned long int) res[2] << 8 | (unsigned long int) res[3]; #else return (unsigned long int) res[3] << 24 | (unsigned long int) res[2] << 16 | (unsigned long int) res[1] << 8 | (unsigned long int) res[0]; #endif } } /* generic_read_word() */ /* --------------------------------------------------------------------------*/ /*!Write a full word to an external device Since this is a half word, the value must be converted from host endianess. @note We are passed the device address, but we must convert it to a full address for external use, to allow the single upcall handler to decode multiple generic devices. @param[in] addr The device address to write to (host endian). @param[in] value The full word value to write (host endian). @param[in] dat The device data structure. */ /* --------------------------------------------------------------------------*/ static void generic_write_word (oraddr_t addr, uint32_t value, void *dat) { struct dev_generic *dev = (struct dev_generic *) dat; if (!config.ext.write_up) { fprintf (stderr, "Full word write to disabled generic device\n"); } else if (addr >= dev->size) { fprintf (stderr, "Full word written out of range for generic device %s " "(addr %" PRIxADDR ")\n", dev->name, addr); } else if (0 != (addr & 0x3)) { fprintf (stderr, "Unaligned full word write to 0x%" PRIxADDR " ignored\n", addr); } else { unsigned long int wordaddr = (unsigned long int) (addr + dev->baseaddr); unsigned char mask[4]; unsigned char val[4]; /* Set the mask and write data do the write. */ memset (mask, 0xff, sizeof (mask)); /* Value converted according to endianess */ #ifdef OR32_BIG_ENDIAN val[0] = (unsigned char) (value >> 24); val[1] = (unsigned char) (value >> 16); val[2] = (unsigned char) (value >> 8); val[3] = (unsigned char) (value ); #else val[3] = (unsigned char) (value >> 24); val[2] = (unsigned char) (value >> 16); val[1] = (unsigned char) (value >> 8); val[0] = (unsigned char) (value ); #endif if (0 != config.ext.write_up (config.ext.class_ptr, wordaddr, mask, val, 4)) { fprintf (stderr, "Warning: external full word write failed.\n"); } } } /* generic_write_word() */ /* Reset is a null operation */ static void generic_reset (void *dat) { return; } /* generic_reset() */ /* Status report can only advise of configuration. */ static void generic_status (void *dat) { struct dev_generic *dev = (struct dev_generic *) dat; PRINTF ("\nGeneric device \"%s\" at 0x%" PRIxADDR ":\n", dev->name, dev->baseaddr); PRINTF (" Size 0x%" PRIx32 "\n", dev->size); if (dev->byte_enabled) { PRINTF (" Byte R/W enabled\n"); } if (dev->hw_enabled) { PRINTF (" Half word R/W enabled\n"); } if (dev->word_enabled) { PRINTF (" Full word R/W enabled\n"); } PRINTF ("\n"); } /* generic_status() */ /* Functions to set configuration */ static void generic_enabled (union param_val val, void *dat) { ((struct dev_generic *) dat)->enabled = val.int_val; } /* generic_enabled() */ static void generic_byte_enabled (union param_val val, void *dat) { ((struct dev_generic *) dat)->byte_enabled = val.int_val; } /* generic_byte_enabled() */ static void generic_hw_enabled (union param_val val, void *dat) { ((struct dev_generic *) dat)->hw_enabled = val.int_val; } /* generic_hw_enabled() */ static void generic_word_enabled (union param_val val, void *dat) { ((struct dev_generic *) dat)->word_enabled = val.int_val; } /* generic_word_enabled() */ static void generic_name (union param_val val, void *dat) { ((struct dev_generic *) dat)->name = strdup (val.str_val); if (!((struct dev_generic *) dat)->name) { fprintf (stderr, "Peripheral 16450: name \"%s\": Run out of memory\n", val.str_val); exit (-1); } } /* generic_name() */ static void generic_baseaddr (union param_val val, void *dat) { ((struct dev_generic *) dat)->baseaddr = val.addr_val; } /* generic_baseaddr() */ static void generic_size (union param_val val, void *dat) { ((struct dev_generic *) dat)->size = val.int_val; } /* generic_size() */ /* Start of new generic section */ static void * generic_sec_start () { struct dev_generic *new = (struct dev_generic *) malloc (sizeof (struct dev_generic)); if (0 == new) { fprintf (stderr, "Generic peripheral: Run out of memory\n"); exit (-1); } /* Default names */ new->enabled = 1; new->byte_enabled = 1; new->hw_enabled = 1; new->word_enabled = 1; new->name = "anonymous external peripheral"; new->baseaddr = 0; new->size = 0; return new; } /* generic_sec_start() */ /* End of new generic section */ static void generic_sec_end (void *dat) { struct dev_generic *generic = (struct dev_generic *) dat; struct mem_ops ops; /* Give up if not enabled, or if size is zero, or if no access size is enabled. */ if (!generic->enabled) { free (dat); return; } if (0 == generic->size) { fprintf (stderr, "Generic peripheral \"%s\" has size 0: ignoring", generic->name); free (dat); return; } if (!generic->byte_enabled && !generic->hw_enabled && !generic->word_enabled) { fprintf (stderr, "Generic peripheral \"%s\" has no access: ignoring", generic->name); free (dat); return; } /* Zero all the ops, then set the ones we care about. Read/write delays will * come from the peripheral if desired. */ memset (&ops, 0, sizeof (struct mem_ops)); if (generic->byte_enabled) { ops.readfunc8 = generic_read_byte; ops.writefunc8 = generic_write_byte; ops.read_dat8 = dat; ops.write_dat8 = dat; } if (generic->hw_enabled) { ops.readfunc16 = generic_read_hw; ops.writefunc16 = generic_write_hw; ops.read_dat16 = dat; ops.write_dat16 = dat; } if (generic->word_enabled) { ops.readfunc32 = generic_read_word; ops.writefunc32 = generic_write_word; ops.read_dat32 = dat; ops.write_dat32 = dat; } /* Register everything */ reg_mem_area (generic->baseaddr, generic->size, 0, &ops); reg_sim_reset (generic_reset, dat); reg_sim_stat (generic_status, dat); } /* generic_sec_end() */ /* Register a generic section. */ void reg_generic_sec (void) { struct config_section *sec = reg_config_sec ("generic", generic_sec_start, generic_sec_end); reg_config_param (sec, "enabled", paramt_int, generic_enabled); reg_config_param (sec, "byte_enabled", paramt_int, generic_byte_enabled); reg_config_param (sec, "hw_enabled", paramt_int, generic_hw_enabled); reg_config_param (sec, "word_enabled", paramt_int, generic_word_enabled); reg_config_param (sec, "name", paramt_str, generic_name); reg_config_param (sec, "baseaddr", paramt_addr, generic_baseaddr); reg_config_param (sec, "size", paramt_int, generic_size); } /* reg_generic_sec */
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