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|
/*
* Mach Operating System
* Copyright (c) 1991,1990,1989,1988 Carnegie Mellon University.
* Copyright (c) 1993,1994 The University of Utah and
* the Computer Systems Laboratory (CSL).
* All rights reserved.
*
* Permission to use, copy, modify and distribute this software and its
* documentation is hereby granted, provided that both the copyright
* notice and this permission notice appear in all copies of the
* software, derivative works or modified versions, and any portions
* thereof, and that both notices appear in supporting documentation.
*
* CARNEGIE MELLON, THE UNIVERSITY OF UTAH AND CSL ALLOW FREE USE OF
* THIS SOFTWARE IN ITS "AS IS" CONDITION, AND DISCLAIM ANY LIABILITY
* OF ANY KIND FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF
* THIS SOFTWARE.
*
* Carnegie Mellon requests users of this software to return to
*
* Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU
* School of Computer Science
* Carnegie Mellon University
* Pittsburgh PA 15213-3890
*
* any improvements or extensions that they make and grant Carnegie Mellon
* the rights to redistribute these changes.
*/
/*
* Matchmaker definitions file for Mach kernel interface.
*/
#ifdef MACH_KERNEL
simport <kern/compat_xxx_defs.h>; /* for obsolete routines */
#endif /* MACH_KERNEL */
subsystem
#if KERNEL_USER
KernelUser
#endif /* KERNEL_USER */
#if KERNEL_SERVER
KernelServer
#endif /* KERNEL_SERVER */
mach 2000;
#ifdef KERNEL_USER
userprefix r_;
#endif /* KERNEL_USER */
#include <mach/std_types.defs>
#include <mach/mach_types.defs>
skip; /* old port_allocate */
skip; /* old port_deallocate */
skip; /* old port_enable */
skip; /* old port_disable */
skip; /* old port_select */
skip; /* old port_set_backlog */
skip; /* old port_status */
/*
* Create a new task with an empty set of IPC rights,
* and having an address space constructed from the
* target task (or empty, if inherit_memory is FALSE).
*/
routine task_create(
target_task : task_t;
inherit_memory : boolean_t;
out child_task : task_t);
/*
* Destroy the target task, causing all of its threads
* to be destroyed, all of its IPC rights to be deallocated,
* and all of its address space to be deallocated.
*/
routine task_terminate(
target_task : task_t);
/*
* Get user-level handler entry points for all
* emulated system calls.
*/
routine task_get_emulation_vector(
task : task_t;
out vector_start : int;
out emulation_vector: emulation_vector_t);
/*
* Establish user-level handlers for the specified
* system calls. Non-emulated system calls are specified
* with emulation_vector[i] == EML_ROUTINE_NULL.
*/
routine task_set_emulation_vector(
task : task_t;
vector_start : int;
emulation_vector: emulation_vector_t);
/*
* Returns the set of threads belonging to the target task.
*/
routine task_threads(
target_task : task_t;
out thread_list : thread_array_t);
/*
* Returns information about the target task.
*/
routine task_info(
target_task : task_t;
flavor : int;
out task_info_out : task_info_t, CountInOut);
skip; /* old task_status */
skip; /* old task_set_notify */
skip; /* old thread_create */
/*
* Destroy the target thread.
*/
routine thread_terminate(
target_thread : thread_t);
/*
* Return the selected state information for the target
* thread. If the thread is currently executing, the results
* may be stale. [Flavor THREAD_STATE_FLAVOR_LIST provides a
* list of valid flavors for the target thread.]
*/
routine thread_get_state(
target_thread : thread_t;
flavor : int;
out old_state : thread_state_t, CountInOut);
/*
* Set the selected state information for the target thread.
* If the thread is currently executing, the state change
* may be ill-defined.
*/
routine thread_set_state(
target_thread : thread_t;
flavor : int;
new_state : thread_state_t);
/*
* Returns information about the target thread.
*/
routine thread_info(
target_thread : thread_t;
flavor : int;
out thread_info_out : thread_info_t, CountInOut);
skip; /* old thread_mutate */
/*
* Allocate zero-filled memory in the address space
* of the target task, either at the specified address,
* or wherever space can be found (if anywhere is TRUE),
* of the specified size. The address at which the
* allocation actually took place is returned.
*/
#ifdef EMULATOR
skip; /* the emulator redefines vm_allocate using vm_map */
#else /* EMULATOR */
routine vm_allocate(
target_task : vm_task_t;
inout address : vm_address_t;
size : vm_size_t;
anywhere : boolean_t);
#endif /* EMULATOR */
skip; /* old vm_allocate_with_pager */
/*
* Deallocate the specified range from the virtual
* address space of the target task.
*/
routine vm_deallocate(
target_task : vm_task_t;
address : vm_address_t;
size : vm_size_t);
/*
* Set the current or maximum protection attribute
* for the specified range of the virtual address
* space of the target task. The current protection
* limits the memory access rights of threads within
* the task; the maximum protection limits the accesses
* that may be given in the current protection.
* Protections are specified as a set of {read, write, execute}
* *permissions*.
*/
routine vm_protect(
target_task : vm_task_t;
address : vm_address_t;
size : vm_size_t;
set_maximum : boolean_t;
new_protection : vm_prot_t);
/*
* Set the inheritance attribute for the specified range
* of the virtual address space of the target task.
* The inheritance value is one of {none, copy, share}, and
* specifies how the child address space should acquire
* this memory at the time of a task_create call.
*/
routine vm_inherit(
target_task : vm_task_t;
address : vm_address_t;
size : vm_size_t;
new_inheritance : vm_inherit_t);
/*
* Returns the contents of the specified range of the
* virtual address space of the target task. [The
* range must be aligned on a virtual page boundary,
* and must be a multiple of pages in extent. The
* protection on the specified range must permit reading.]
*/
routine vm_read(
target_task : vm_task_t;
address : vm_address_t;
size : vm_size_t;
out data : pointer_t);
/*
* Writes the contents of the specified range of the
* virtual address space of the target task. [The
* range must be aligned on a virtual page boundary,
* and must be a multiple of pages in extent. The
* protection on the specified range must permit writing.]
*/
routine vm_write(
target_task : vm_task_t;
address : vm_address_t;
data : pointer_t);
/*
* Copy the contents of the source range of the virtual
* address space of the target task to the destination
* range in that same address space. [Both of the
* ranges must be aligned on a virtual page boundary,
* and must be multiples of pages in extent. The
* protection on the source range must permit reading,
* and the protection on the destination range must
* permit writing.]
*/
routine vm_copy(
target_task : vm_task_t;
source_address : vm_address_t;
size : vm_size_t;
dest_address : vm_address_t);
/*
* Returns information about the contents of the virtual
* address space of the target task at the specified
* address. The returned protection, inheritance, sharing
* and memory object values apply to the entire range described
* by the address range returned; the memory object offset
* corresponds to the beginning of the address range.
* [If the specified address is not allocated, the next
* highest address range is described. If no addresses beyond
* the one specified are allocated, the call returns KERN_NO_SPACE.]
*/
routine vm_region(
target_task : vm_task_t;
inout address : vm_address_t;
out size : vm_size_t;
out protection : vm_prot_t;
out max_protection : vm_prot_t;
out inheritance : vm_inherit_t;
out is_shared : boolean_t;
/* avoid out-translation of the argument */
out object_name : memory_object_name_t =
MACH_MSG_TYPE_MOVE_SEND
ctype: mach_port_t;
out offset : vm_offset_t);
/*
* Return virtual memory statistics for the host
* on which the target task resides. [Note that the
* statistics are not specific to the target task.]
*/
routine vm_statistics(
target_task : vm_task_t;
out vm_stats : vm_statistics_data_t);
skip; /* old task_by_u*x_pid */
skip; /* old vm_pageable */
/*
* Stash a handful of ports for the target task; child
* tasks inherit this stash at task_create time.
*/
routine mach_ports_register(
target_task : task_t;
init_port_set : mach_port_array_t =
^array[] of mach_port_t);
/*
* Retrieve the stashed ports for the target task.
*/
routine mach_ports_lookup(
target_task : task_t;
out init_port_set : mach_port_array_t =
^array[] of mach_port_t);
skip; /* old u*x_pid */
skip; /* old netipc_listen */
skip; /* old netipc_ignore */
/*
* Provide the data contents of a range of the given memory
* object, with the access restriction specified. [Only
* whole virtual pages of data can be accepted; partial pages
* will be discarded. Data should be provided on request, but
* may be provided in advance as desired. When data already
* held by this kernel is provided again, the new data is ignored.
* The access restriction is the subset of {read, write, execute}
* which are prohibited. The kernel may not provide any data (or
* protection) consistency among pages with different virtual page
* alignments within the same object.]
*/
simpleroutine memory_object_data_provided(
memory_control : memory_object_control_t;
offset : vm_offset_t;
data : pointer_t;
lock_value : vm_prot_t);
/*
* Indicate that a range of the given temporary memory object does
* not exist, and that the backing memory object should be used
* instead (or zero-fill memory be used, if no backing object exists).
* [This call is intended for use only by the default memory manager.
* It should not be used to indicate a real error --
* memory_object_data_error should be used for that purpose.]
*/
simpleroutine memory_object_data_unavailable(
memory_control : memory_object_control_t;
offset : vm_offset_t;
size : vm_size_t);
/*
* Retrieves the attributes currently associated with
* a memory object.
*/
routine memory_object_get_attributes(
memory_control : memory_object_control_t;
out object_ready : boolean_t;
out may_cache : boolean_t;
out copy_strategy : memory_object_copy_strategy_t);
/*
* Sets the default memory manager, the port to which
* newly-created temporary memory objects are delivered.
* [See (memory_object_default)memory_object_create.]
* The old memory manager port is returned.
*/
routine vm_set_default_memory_manager(
host_priv : host_priv_t;
inout default_manager : mach_port_make_send_t);
skip; /* old pager_flush_request */
/*
* Control use of the data associated with the given
* memory object. For each page in the given range,
* perform the following operations, in order:
* 1) restrict access to the page (disallow
* forms specified by "prot");
* 2) write back modifications (if "should_return"
* is RETURN_DIRTY and the page is dirty, or
* "should_return" is RETURN_ALL and the page
* is either dirty or precious); and,
* 3) flush the cached copy (if "should_flush"
* is asserted).
* The set of pages is defined by a starting offset
* ("offset") and size ("size"). Only pages with the
* same page alignment as the starting offset are
* considered.
*
* A single acknowledgement is sent (to the "reply_to"
* port) when these actions are complete.
*
* There are two versions of this routine because IPC distinguishes
* between booleans and integers (a 2-valued integer is NOT a
* boolean). The new routine is backwards compatible at the C
* language interface.
*/
simpleroutine xxx_memory_object_lock_request(
memory_control : memory_object_control_t;
offset : vm_offset_t;
size : vm_size_t;
should_clean : boolean_t;
should_flush : boolean_t;
lock_value : vm_prot_t;
reply_to : mach_port_t =
MACH_MSG_TYPE_MAKE_SEND_ONCE|polymorphic);
simpleroutine memory_object_lock_request(
memory_control : memory_object_control_t;
offset : vm_offset_t;
size : vm_size_t;
should_return : memory_object_return_t;
should_flush : boolean_t;
lock_value : vm_prot_t;
reply_to : mach_port_t =
MACH_MSG_TYPE_MAKE_SEND_ONCE|polymorphic);
/* obsolete */
routine xxx_task_get_emulation_vector(
task : task_t;
out vector_start : int;
out emulation_vector: xxx_emulation_vector_t, IsLong);
/* obsolete */
routine xxx_task_set_emulation_vector(
task : task_t;
vector_start : int;
emulation_vector: xxx_emulation_vector_t, IsLong);
/*
* Returns information about the host on which the
* target object resides. [This object may be
* a task, thread, or memory_object_control port.]
*/
routine xxx_host_info(
target_task : mach_port_t;
out info : machine_info_data_t);
/*
* Returns information about a particular processor on
* the host on which the target task resides.
*/
routine xxx_slot_info(
target_task : task_t;
slot : int;
out info : machine_slot_data_t);
/*
* Performs control operations (currently only
* turning off or on) on a particular processor on
* the host on which the target task resides.
*/
routine xxx_cpu_control(
target_task : task_t;
cpu : int;
running : boolean_t);
skip; /* old thread_statistics */
skip; /* old task_statistics */
skip; /* old netport_init */
skip; /* old netport_enter */
skip; /* old netport_remove */
skip; /* old thread_set_priority */
/*
* Increment the suspend count for the target task.
* No threads within a task may run when the suspend
* count for that task is non-zero.
*/
routine task_suspend(
target_task : task_t);
/*
* Decrement the suspend count for the target task,
* if the count is currently non-zero. If the resulting
* suspend count is zero, then threads within the task
* that also have non-zero suspend counts may execute.
*/
routine task_resume(
target_task : task_t);
/*
* Returns the current value of the selected special port
* associated with the target task.
*/
routine task_get_special_port(
task : task_t;
which_port : int;
out special_port : mach_port_t);
/*
* Set one of the special ports associated with the
* target task.
*/
routine task_set_special_port(
task : task_t;
which_port : int;
special_port : mach_port_t);
/* obsolete */
routine xxx_task_info(
target_task : task_t;
flavor : int;
out task_info_out : task_info_t, IsLong);
/*
* Create a new thread within the target task, returning
* the port representing that new thread. The
* initial execution state of the thread is undefined.
*/
routine thread_create(
parent_task : task_t;
out child_thread : thread_t);
/*
* Increment the suspend count for the target thread.
* Once this call has completed, the thread will not
* execute any further user or meta- instructions.
* Once suspended, a thread may not execute again until
* its suspend count is zero, and the suspend count
* for its task is also zero.
*/
routine thread_suspend(
target_thread : thread_t);
/*
* Decrement the suspend count for the target thread,
* if that count is not already zero.
*/
routine thread_resume(
target_thread : thread_t);
/*
* Cause any user or meta- instructions currently being
* executed by the target thread to be aborted. [Meta-
* instructions consist of the basic traps for IPC
* (e.g., msg_send, msg_receive) and self-identification
* (e.g., task_self, thread_self, thread_reply). Calls
* described by MiG interfaces are not meta-instructions
* themselves.]
*/
routine thread_abort(
target_thread : thread_t);
/* obsolete */
routine xxx_thread_get_state(
target_thread : thread_t;
flavor : int;
out old_state : thread_state_t, IsLong);
/* obsolete */
routine xxx_thread_set_state(
target_thread : thread_t;
flavor : int;
new_state : thread_state_t, IsLong);
/*
* Returns the current value of the selected special port
* associated with the target thread.
*/
routine thread_get_special_port(
thread : thread_t;
which_port : int;
out special_port : mach_port_t);
/*
* Set one of the special ports associated with the
* target thread.
*/
routine thread_set_special_port(
thread : thread_t;
which_port : int;
special_port : mach_port_t);
/* obsolete */
routine xxx_thread_info(
target_thread : thread_t;
flavor : int;
out thread_info_out : thread_info_t, IsLong);
/*
* Establish a user-level handler for the specified
* system call.
*/
routine task_set_emulation(
target_port : task_t;
routine_entry_pt: vm_address_t;
routine_number : int);
/*
* Establish restart pc for interrupted atomic sequences.
* This reuses the message number for the old task_get_io_port.
* See task_info.h for description of flavors.
*
*/
routine task_ras_control(
target_task : task_t;
basepc : vm_address_t;
boundspc : vm_address_t;
flavor : int);
skip; /* old host_ipc_statistics */
skip; /* old port_names */
skip; /* old port_type */
skip; /* old port_rename */
skip; /* old port_allocate */
skip; /* old port_deallocate */
skip; /* old port_set_backlog */
skip; /* old port_status */
skip; /* old port_set_allocate */
skip; /* old port_set_deallocate */
skip; /* old port_set_add */
skip; /* old port_set_remove */
skip; /* old port_set_status */
skip; /* old port_insert_send */
skip; /* old port_extract_send */
skip; /* old port_insert_receive */
skip; /* old port_extract_receive */
/*
* Map a user-defined memory object into the virtual address
* space of the target task. If desired (anywhere is TRUE),
* the kernel will find a suitable address range of the
* specified size; else, the specific address will be allocated.
*
* The beginning address of the range will be aligned on a virtual
* page boundary, be at or beyond the address specified, and
* meet the mask requirements (bits turned on in the mask must not
* be turned on in the result); the size of the range, in bytes,
* will be rounded up to an integral number of virtual pages.
*
* The memory in the resulting range will be associated with the
* specified memory object, with the beginning of the memory range
* referring to the specified offset into the memory object.
*
* The mapping will take the current and maximum protections and
* the inheritance attributes specified; see the vm_protect and
* vm_inherit calls for a description of these attributes.
*
* If desired (copy is TRUE), the memory range will be filled
* with a copy of the data from the memory object; this copy will
* be private to this mapping in this target task. Otherwise,
* the memory in this mapping will be shared with other mappings
* of the same memory object at the same offset (in this task or
* in other tasks). [The Mach kernel only enforces shared memory
* consistency among mappings on one host with similar page alignments.
* The user-defined memory manager for this object is responsible
* for further consistency.]
*/
#ifdef EMULATOR
routine htg_vm_map(
target_task : vm_task_t;
ureplyport reply_port : mach_port_make_send_once_t;
inout address : vm_address_t;
size : vm_size_t;
mask : vm_address_t;
anywhere : boolean_t;
memory_object : memory_object_t;
offset : vm_offset_t;
copy : boolean_t;
cur_protection : vm_prot_t;
max_protection : vm_prot_t;
inheritance : vm_inherit_t);
#else /* EMULATOR */
routine vm_map(
target_task : vm_task_t;
inout address : vm_address_t;
size : vm_size_t;
mask : vm_address_t;
anywhere : boolean_t;
memory_object : memory_object_t;
offset : vm_offset_t;
copy : boolean_t;
cur_protection : vm_prot_t;
max_protection : vm_prot_t;
inheritance : vm_inherit_t);
#endif /* EMULATOR */
/*
* Indicate that a range of the specified memory object cannot
* be provided at this time. [Threads waiting for memory pages
* specified by this call will experience a memory exception.
* Only threads waiting at the time of the call are affected.]
*/
simpleroutine memory_object_data_error(
memory_control : memory_object_control_t;
offset : vm_offset_t;
size : vm_size_t;
error_value : kern_return_t);
/*
* Make decisions regarding the use of the specified
* memory object.
*/
simpleroutine memory_object_set_attributes(
memory_control : memory_object_control_t;
object_ready : boolean_t;
may_cache : boolean_t;
copy_strategy : memory_object_copy_strategy_t);
/*
*/
simpleroutine memory_object_destroy(
memory_control : memory_object_control_t;
reason : kern_return_t);
/*
* Provide the data contents of a range of the given memory
* object, with the access restriction specified, optional
* precious attribute, and reply message. [Only
* whole virtual pages of data can be accepted; partial pages
* will be discarded. Data should be provided on request, but
* may be provided in advance as desired. When data already
* held by this kernel is provided again, the new data is ignored.
* The access restriction is the subset of {read, write, execute}
* which are prohibited. The kernel may not provide any data (or
* protection) consistency among pages with different virtual page
* alignments within the same object. The precious value controls
* how the kernel treats the data. If it is FALSE, the kernel treats
* its copy as a temporary and may throw it away if it hasn't been
* changed. If the precious value is TRUE, the kernel treats its
* copy as a data repository and promises to return it to the manager;
* the manager may tell the kernel to throw it away instead by flushing
* and not cleaning the data -- see memory_object_lock_request. The
* reply_to port is for a compeletion message; it will be
* memory_object_supply_completed.]
*/
simpleroutine memory_object_data_supply(
memory_control : memory_object_control_t;
offset : vm_offset_t;
data : pointer_t, Dealloc[];
lock_value : vm_prot_t;
precious : boolean_t;
reply_to : mach_port_t =
MACH_MSG_TYPE_MAKE_SEND_ONCE|polymorphic);
simpleroutine memory_object_ready(
memory_control : memory_object_control_t;
may_cache : boolean_t;
copy_strategy : memory_object_copy_strategy_t);
simpleroutine memory_object_change_attributes(
memory_control : memory_object_control_t;
may_cache : boolean_t;
copy_strategy : memory_object_copy_strategy_t;
reply_to : mach_port_t =
MACH_MSG_TYPE_MAKE_SEND_ONCE|polymorphic);
skip; /* old host_callout_statistics_reset */
skip; /* old port_set_select */
skip; /* old port_set_backup */
/*
* Set/Get special properties of memory associated
* to some virtual address range, such as cachability,
* migrability, replicability. Machine-dependent.
*/
routine vm_machine_attribute(
target_task : vm_task_t;
address : vm_address_t;
size : vm_size_t;
attribute : vm_machine_attribute_t;
inout value : vm_machine_attribute_val_t);
/*skip;*/ /* old host_fpa_counters_reset */
/*
* This routine is created for allocating DMA buffers.
* We are going to get a contiguous physical memory
* and its physical address in addition to the virtual address.
*/
routine vm_dma_buff_alloc(
host_priv : host_priv_t;
target_task : vm_task_t;
size : vm_size_t;
out vaddr : vm_address_t;
out paddr : vm_address_t);
/*
* There is no more room in this interface for additional calls.
*/
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