/* This file is part of the program psim. Copyright (C) 1994-1996, Andrew Cagney 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 . */ #ifndef _CORE_H_ #define _CORE_H_ /* Introduction: The core device, positioned at the top of the device tree that models the architecure being simulated, acts as an interface between the processor engines and the modeled devices. On the one side the processor engines issue read and write requests to the core (each request further catagorised as being for an instruction or data subunit) while on the other side, the core is receiving address configuration and DMA requests from child devices. In the below a synopsis of the core object and device in PSIM is given, details of the object can be found in the files <> and <>. */ /* Core:: At the heart of the interface between devices and processor engines is a single core object. This object, in turn, has two children: o a core device which exists in the device tree and provides an interface to the core object to child devices. o a set of access maps which provide an efficient interface to the core object for the processor engines. */ /* basic types */ typedef struct _core core; typedef struct _core_map core_map; /* constructor */ INLINE_CORE\ (core *) core_create (void); INLINE_CORE\ (core *) core_from_device (device *root); INLINE_CORE\ (void) core_init (core *memory); /* Core map management::: The core ojbect manages two different types of address maps: o raw-memory - the address range can be implemented using a simple byte array. No device needs to be notifed of any accesses to the specified memory range. o callback - Any access to the specified address range should be passed on to the associated device. That device can in turn resolve the access - handling or aborting or restarting it. For callback maps it is possible to further order them by specifiying specifying a callback level (eg callback + 1). When the core is resolving an access it searches each of the maps in order. First raw-memory and then callback maps (in assending order of level). This search order makes it possible for latter maps to overlap earlier ones. For instance, a device that wants to be notified of all accesses that are not covered by raw-memory maps could attach its self with an address range of the entire address space. In addition, each attached address map as an associated set of access attributes (readable, writeable, executable) which are verified as part of resolving each access. */ INLINE_CORE\ (void) core_attach (core *map, attach_type attach, int address_space, access_type access, unsigned_word addr, unsigned nr_bytes, /* host limited */ device *device); /*callback/default*/ /* Bugs::: At present there is no method for removing address maps. That will be implemented in a future release. The operation of mapping between an address and its destination device or memory array is currently implemented using a simple linked list. The posibility of replacing this list with a more powerfull data structure exists. */ /* Device:: The device that corresponds to the core object is described separatly in the devices section. */ /* Access maps:: Providing an interface between the processor engines and the core object are the access maps (core_map). Three access maps are provided, one for each of the possible access requests that can be generated by a processor. o read o write o execute A processor being able to request a read (or write) or write operation to any of the maps. Those operations can either be highly efficient (by specifying a specific transfer size) or generic (specifying a parameterized number of bytes). Internally the core object takes the request, determines the approperiate attached address space that it should handle it passes it on. */ INLINE_CORE\ (core_map *) core_readable (core *memory); INLINE_CORE\ (core_map *) core_writeable (core *memory); INLINE_CORE\ (core_map *) core_executable (core *memory); /* Variable sized read/write Transfer (zero) a variable size block of data between the host and target (possibly byte swapping it). Should any problems occure, the number of bytes actually transfered is returned. */ INLINE_CORE\ (unsigned) core_map_read_buffer (core_map *map, void *buffer, unsigned_word addr, unsigned nr_bytes); INLINE_CORE\ (unsigned) core_map_write_buffer (core_map *map, const void *buffer, unsigned_word addr, unsigned nr_bytes); /* Fixed sized read/write Transfer a fixed amout of memory between the host and target. The memory always being translated and the operation always aborting should a problem occure */ #define DECLARE_CORE_WRITE_N(N) \ INLINE_CORE\ (void) core_map_write_##N \ (core_map *map, \ unsigned_word addr, \ unsigned_##N val, \ cpu *processor, \ unsigned_word cia); DECLARE_CORE_WRITE_N(1) DECLARE_CORE_WRITE_N(2) DECLARE_CORE_WRITE_N(4) DECLARE_CORE_WRITE_N(8) DECLARE_CORE_WRITE_N(word) #define DECLARE_CORE_READ_N(N) \ INLINE_CORE\ (unsigned_##N) core_map_read_##N \ (core_map *map, \ unsigned_word addr, \ cpu *processor, \ unsigned_word cia); DECLARE_CORE_READ_N(1) DECLARE_CORE_READ_N(2) DECLARE_CORE_READ_N(4) DECLARE_CORE_READ_N(8) DECLARE_CORE_READ_N(word) #endif