libsel4allocman/include/allocman/bootstrap.h - 3p/sel4/sel4_libs - Git at Google

 /*
  * Copyright 2017, Data61
  * Commonwealth Scientific and Industrial Research Organisation (CSIRO)
  * ABN 41 687 119 230.
  *
  * This software may be distributed and modified according to the terms of
  * the BSD 2-Clause license. Note that NO WARRANTY is provided.
  * See "LICENSE_BSD2.txt" for details.
  *
  * @TAG(DATA61_BSD)
  */

 /**
  * @file bootstrap.h
  *
  * @brief Helpers for bootstrapping an allocman on freshly running system
  *
  * Bootstrapping a system is hard. These helpers attempt to make it easy to start
  * a system with a 'common' configuration. Systems that are not common should also
  * be possible, but the code here will be able to help you less.
  *
  * In general to bootstrap a system you need to do the following
  * 1. Describe the current cspace
  * 2. Describe where resources (untypeds, slots etc) can be found
  * 3. (maybe) create and switch to a new cspace
  * These bootstrapping functions attempt to hide the requirements of these steps as
  * much as possible, allowing you to substitute 'bootinfo' if you have it, otherweise
  * requiring some minimal description. However enough internals are provided that
  * each of these steps can be broken into if you need to describe some particularly
  * interesting system.
  *
  * The allocman that gets created as a result of bootstrapping is constructed using
  * some default 'sensible' allocators. Unfortunately if you want different allocators
  * then there is currently no way to control that.
  *
  * Bootstrapping here requires some initial 'pool' of memory. This is memory that
  * must NEVER be freed after you have bootstrapped an allocator. Be very careful
  * you do not put this on a stack (and then free it) or have it as a global and use
  * it multiple times. Unfortunately this pool is the 'magic' that allows the allocators
  * to kick themselves going, and cannot be provided for you. The actual size of the pool
  * is something you will need to work out with trial and error.
  *
  * With all of these methods, once they return failure you are basically 100% fucked
  * since they make no effort to clean up after themselves if they detect failure. The
  * ONLY sane thing you can do is log an error and terminate.
  *
  * See example_bootstrap.c for sample code that shows how to bootstrap in various ways
  *
  */

 #pragma once

 #include <sel4/sel4.h>
 #include <string.h>
 #include <allocman/allocman.h>
 #include <allocman/cspace/simple1level.h>
 #include <allocman/cspace/two_level.h>
 #include <allocman/mspace/fixed_pool.h>
 #include <allocman/mspace/virtual_pool.h>
 #include <allocman/utspace/twinkle.h>
 #include <vspace/vspace.h>
 #include <simple/simple.h>
 #include <sel4platsupport/pmem.h>
 /**
  * Internal data structure for storing bootstrapping information. If you need to break
  * open the boot strapping process, then you will be given a pointer to one of these
  * that you will interract with to finish the boot strapping
  */
 typedef struct bootstrap_info bootstrap_info_t;

 /**
  * Every allocation manager created by these bootstrapping functions has a dual_pool
  * as its memory manager. For the purposes of bootstrapping only the fixed pool (as
  * passed to the boot strapping functions) is used. If you want to use a virtual pool
  * (you almost certainly do so you don't run out of memory or have a stupidly large
  * static pool) then this function will initial the virtual pool after the fact. The
  * reason for this ordering is that it is expected that the creation of a vspace manager
  * might expect an allocator, which you won't have yet if you are boot strapping.
  *
  * Note that there is no protection against calling this function multiple times or
  * from trying to call it on an allocman that does not have a dual_pool as its underlying
  * memory manager. DO NOT FUCK IT UP
  *
  * @param alloc Allocman whose memory manager to configure
  * @param vstart Start of a virtual address range that will be allocated from.
  * @param vsize Size of the virtual address range
  * @param pd Page directory to invoke when mapping frames/page tables
  */
 void bootstrap_configure_virtual_pool(allocman_t *alloc, void *vstart, size_t vsize,
         seL4_CPtr pd);

 /**
  * Simplest bootstrapping method that uses all the information in seL4_BootInfo
  * assumes you are the rootserver. This keeps using whatever cspace you are currently in.
  *
  * @param bi BootInfo as passed to the rootserver
  * @param pool_size Size of the initial pool. See file comments for details
  * @param pool Initial pool. See file comments for details
  *
  * @return returns NULL on error
  */
 allocman_t *bootstrap_use_bootinfo(seL4_BootInfo *bi, size_t pool_size, void *pool);

 /**
  * Bootstraps using all the information in bootinfo, but switches to a new single
  * level cspace. All untypeds specified in bootinfo will be moved to the new cspace,
  * any other capabilities will be left in the old cspace. If you wish to refer to the
  * boot cspace (most likely since it probably has capabilities you still want), then
  * a cspace description of the old cspace can also be returned.
  *
  * @param bi BootInfo as passed to the rootserver
  * @param cnode_size Number of slot bits (cnode_slots = 2^cnode_size) for the new cnode
  * @param pool_size Size of the initial pool. See file comments for details
  * @param pool Initial pool. See file comments for details
  * @param old_cspace Optional location to store a description of the original cspace. You
  * can free this memory back to the allocman when are done with it
  *
  * @return returns NULL on error
  */
 allocman_t *bootstrap_new_1level_bootinfo(seL4_BootInfo *bi, size_t cnode_size, size_t pool_size, void *pool, cspace_simple1level_t **old_cspace);

 /**
  * Bootstraps using all the information in bootinfo, but switches to a new two
  * level cspace. All untypeds specified in bootinfo will be moved to the new cspace,
  * any other capabilities will be left in the old cspace. If you wish to refer to the
  * boot cspace (most likely since it probably has capabilities you still want), then
  * a cspace description of the old cspace can also be returned.
  *
  * @param bi BootInfo as passed to the rootserver
  * @param l1size Number of slot bits (l1_slots = 2^l1size) for the level 1 cnode
  * @param l2size Number of slot bits (l2_slots = 2^l2size) for the level 2 cnode
  * @param pool_size Size of the initial pool. See file comments for details
  * @param pool Initial pool. See file comments for details
  * @param old_cspace Optional location to store a description of the original cspace. You
  * can free this memory back to the allocman when are done with it
  *
  * @return returns NULL on error
  */
 allocman_t *bootstrap_new_2level_bootinfo(seL4_BootInfo *bi, size_t l1size, size_t l2size, size_t pool_size, void *pool, cspace_simple1level_t **old_cspace);

 /**
  * Give an allocator all the untyped memory that simple knows about.
  *
  * This assumes that all the untyped caps are currently as simple thinks they are.
  * If there have been any cspace reshuffles simple will not give allocman useable information
  *
  * Allocman will also try and use sel4platsupport_get_pmem_region_list to find PMEM_TYPE_RAM
  * regions that are device untyped objects.
  */
 int allocman_add_simple_untypeds(allocman_t *alloc, simple_t *simple);

 /**
  * Give an allocator all the untyped memory that simple knows about.
  *
  * This assumes that all the untyped caps are currently as simple thinks they are.
  * If there have been any cspace reshuffles simple will not give allocman useable information
  *
  * If num_regions is set to 0 or region_list is NULL, Allocman will also try and use
  * sel4platsupport_get_pmem_region_list to find PMEM_TYPE_RAM regions that are device untyped objects.
  * Otherwise any device untyped objects that overlap with regions that are type PMEM_TYPE_RAM will be marked as ALLOCMAN_UT_DEV_MEM.
  */
 int allocman_add_simple_untypeds_with_regions(allocman_t *alloc, simple_t *simple, int num_regions, pmem_region_t *region_list);

 /**
  * Bootstraps using all the information provided by simple, but switches to a new two
  * level cspace. All capabilities specified by simple will be moved to the new cspace. All untypeds specified by simple are given to the allocator
  *
  * @param simple simple pointer to the struct
  * @param l1size Number of slot bits (l1_slots = 2^l1size) for the level 1 cnode
  * @param l2size Number of slot bits (l2_slots = 2^l2size) for the level 2 cnode
  * @param pool_size Size of the initial pool. See file comments for details
  * @param pool Initial pool. See file comments for details
  *
  * @return returns NULL on error
  */
 allocman_t *bootstrap_new_2level_simple(simple_t *simple, size_t l1size, size_t l2size, size_t pool_size, void *pool);

 /* As above, but 1 level */
 allocman_t *bootstrap_new_1level_simple(simple_t *simple, size_t l1size, size_t pool_size, void *pool);

 /**
  * Bootstraps into the current environment as defined by simple. This will continue
  * to use the cspace described by simple, as well as all the untypeds it knows about
  *
  * @param simple Pointer to simple interface, will not be retained
  * @param pool_size Size of the initial pool. See file comments for details
  * @param pool Initial pool. See file comments for details
  *
  * @return returns NULL on error
  */
 allocman_t *bootstrap_use_current_simple(simple_t *simple, size_t pool_size, void *pool);

 /**
  * Bootstraps an allocator that will reuse the current single level cspace (which
  * you must describe to it). While bootstrapping should succeed, you will need to
  * add untypeds manually to the returned allocman to make it useful.
  *
  * @param root_cnode Location of the cnode that is the current cspace
  * @param cnode_size Size in slot_bits of the current cnode
  * @param start_slot First free slot in the current cspace
  * @param end_slot Last free slot + 1 in the current cspace
  * @param pool_size Size of the initial pool. See file comments for details
  * @param pool Initial pool. See file comments for details
  *
  * @return returns NULL on error
  */
 allocman_t *bootstrap_use_current_1level(seL4_CPtr root_cnode, size_t cnode_size, seL4_CPtr start_slot, seL4_CPtr end_slot, size_t pool_size, void *pool);

 /**
  * Provides a description of the boot cspace if you are doing a customized
  * bootstrapping. This MUST be set before using boostrap_new_[1|2]level
  *
  * @param bs Internal bootstrapping info as allocated/returned by {@link #bootstrap_create_info}
  * @param cspace CSpace that will be used for bootstrapping purposes. The cspace only needs to exist
  *  for as long as bootstrapping is happening, it will not be used afterwards
  * @param root_cnode Path to the root cnode of cspace. This is needed so that a cap to the old cspace
  *  can be provided in the new cspace
  *
  * @return returns 0 on success
  */
 int bootstrap_set_boot_cspace(bootstrap_info_t *bs, cspace_interface_t cspace, cspacepath_t root_cnode);

 /**
  * Adds knowledge of untypeds to the bootstrapping information. These untypeds will
  * be moved to the new cspace and be given to the untyped manager  once bootstrapping
  * has completed.
  *
  * @param bs Internal bootstrapping info as allocated/returned by {@link #bootstrap_create_info}
  * @param num Number of untypeds to be added
  * @param uts Path to each of the untypeds
  * @param size_bits Size of each of the untypeds
  * @param paddr Optional physical address of each of the untypeds
  * @param isDevice whether this untyped is for a device region or not
  *
  * @return returns 0 on success
  */
 int bootstrap_add_untypeds(bootstrap_info_t *bs, size_t num, const cspacepath_t *uts, size_t *size_bits, uintptr_t *paddr, bool isDevice);

 /**
  * Adds knowledge of all the untypeds of bootinfo to the bootstrapper. These will
  * be moved to the new cspace and given to the untyped manager once bootstrapping has
  * completed
  *
  * @param bs Internal bootstrapping info as allocated/returned by {@link #bootstrap_create_info}
  * @param bi BootInfo as passed to the rootserver
  *
  * @return returns 0 on success
  */
 int bootstrap_add_untypeds_from_bootinfo(bootstrap_info_t *bs, seL4_BootInfo *bi);

 /**
  * Completes bootstrapping into a new single level cspace.
  *
  * @param info Internal bootstrapping info as allocated/returned by {@link #bootstrap_create_info}
  * @param cnode_size Size in slot bits of new cspace
  * @param tcb Path to the TCB of the current thread, need to perform an invocation of seL4_TCB_SetSpace
  * @param pd Path to the PD of the current thread. This is needed to work around seL4 restriction that
  *  requires the address space be set at the same time as the cspace
  * @param oldroot Optional location to store a path to a cnode that is root cnode given in {@link #bootstrap_set_boot_cspace}
  *
  * @return returns NULL on error
  */
 allocman_t *bootstrap_new_1level(bootstrap_info_t *info, size_t cnode_size, cspacepath_t tcb, cspacepath_t pd, cspacepath_t *oldroot);

 /**
  * Completes bootstrapping into a new two level cspace.
  *
  * @param info Internal bootstrapping info as allocated/returned by {@link #bootstrap_create_info}
  * @param l1size Number of slot bits (l1_slots = 2^l1size) for the level 1 cnode
  * @param l2size Number of slot bits (l2_slots = 2^l2size) for the level 2 cnode
  * @param tcb Path to the TCB of the current thread, need to perform an invocation of seL4_TCB_SetSpace
  * @param pd Path to the PD of the current thread. This is needed to work around seL4 restriction that
  *  requires the address space be set at the same time as the cspace
  * @param oldroot Optional location to store a path to a cnode that is root cnode given in {@link #bootstrap_set_boot_cspace}
  *
  * @return returns NULL on error
  */
 allocman_t *bootstrap_new_2level(bootstrap_info_t *info, size_t l1size, size_t l2size, cspacepath_t tcb, cspacepath_t pd, cspacepath_t *oldroot);

 /**
  * This function starts bootstrapping the system, and then 'breaks out' and
  * allows you to give a description of the boot cspace as well as provide any
  * untypeds. A new 1 or 2 level cspace can then be created.
  *
  * @param pool_size Size of the initial pool. See file comments for details
  * @param pool Initial pool. See file comments for details
  *
  * @return returns NULL on error
  */
 bootstrap_info_t *bootstrap_create_info(size_t pool_size, void *pool);

 /**
  * Creates an empty allocman from a starting pool. The returned allocman will not
  * have an attached cspace or utspace. This function provides the ultimate flexibility
  * in how you can boot strap the system (read: this does basically nothing for you).

  * @param pool_size Size of the initial pool. See file comments for details
  * @param pool Initial pool. See file comments for details
  *
  * @return returns NULL on error
  */
 allocman_t *bootstrap_create_allocman(size_t pool_size, void *pool);
	/*
	* Copyright 2017, Data61
	* Commonwealth Scientific and Industrial Research Organisation (CSIRO)
	* ABN 41 687 119 230.
	*
	* This software may be distributed and modified according to the terms of
	* the BSD 2-Clause license. Note that NO WARRANTY is provided.
	* See "LICENSE_BSD2.txt" for details.
	*
	* @TAG(DATA61_BSD)
	*/

	/**
	* @file bootstrap.h
	*
	* @brief Helpers for bootstrapping an allocman on freshly running system
	*
	* Bootstrapping a system is hard. These helpers attempt to make it easy to start
	* a system with a 'common' configuration. Systems that are not common should also
	* be possible, but the code here will be able to help you less.
	*
	* In general to bootstrap a system you need to do the following
	* 1. Describe the current cspace
	* 2. Describe where resources (untypeds, slots etc) can be found
	* 3. (maybe) create and switch to a new cspace
	* These bootstrapping functions attempt to hide the requirements of these steps as
	* much as possible, allowing you to substitute 'bootinfo' if you have it, otherweise
	* requiring some minimal description. However enough internals are provided that
	* each of these steps can be broken into if you need to describe some particularly
	* interesting system.
	*
	* The allocman that gets created as a result of bootstrapping is constructed using
	* some default 'sensible' allocators. Unfortunately if you want different allocators
	* then there is currently no way to control that.
	*
	* Bootstrapping here requires some initial 'pool' of memory. This is memory that
	* must NEVER be freed after you have bootstrapped an allocator. Be very careful
	* you do not put this on a stack (and then free it) or have it as a global and use
	* it multiple times. Unfortunately this pool is the 'magic' that allows the allocators
	* to kick themselves going, and cannot be provided for you. The actual size of the pool
	* is something you will need to work out with trial and error.
	*
	* With all of these methods, once they return failure you are basically 100% fucked
	* since they make no effort to clean up after themselves if they detect failure. The
	* ONLY sane thing you can do is log an error and terminate.
	*
	* See example_bootstrap.c for sample code that shows how to bootstrap in various ways
	*
	*/

	#pragma once

	#include <sel4/sel4.h>
	#include <string.h>
	#include <allocman/allocman.h>
	#include <allocman/cspace/simple1level.h>
	#include <allocman/cspace/two_level.h>
	#include <allocman/mspace/fixed_pool.h>
	#include <allocman/mspace/virtual_pool.h>
	#include <allocman/utspace/twinkle.h>
	#include <vspace/vspace.h>
	#include <simple/simple.h>
	#include <sel4platsupport/pmem.h>
	/**
	* Internal data structure for storing bootstrapping information. If you need to break
	* open the boot strapping process, then you will be given a pointer to one of these
	* that you will interract with to finish the boot strapping
	*/
	typedef struct bootstrap_info bootstrap_info_t;

	/**
	* Every allocation manager created by these bootstrapping functions has a dual_pool
	* as its memory manager. For the purposes of bootstrapping only the fixed pool (as
	* passed to the boot strapping functions) is used. If you want to use a virtual pool
	* (you almost certainly do so you don't run out of memory or have a stupidly large
	* static pool) then this function will initial the virtual pool after the fact. The
	* reason for this ordering is that it is expected that the creation of a vspace manager
	* might expect an allocator, which you won't have yet if you are boot strapping.
	*
	* Note that there is no protection against calling this function multiple times or
	* from trying to call it on an allocman that does not have a dual_pool as its underlying
	* memory manager. DO NOT FUCK IT UP
	*
	* @param alloc Allocman whose memory manager to configure
	* @param vstart Start of a virtual address range that will be allocated from.
	* @param vsize Size of the virtual address range
	* @param pd Page directory to invoke when mapping frames/page tables
	*/
	void bootstrap_configure_virtual_pool(allocman_t alloc, void vstart, size_t vsize,
	seL4_CPtr pd);

	/**
	* Simplest bootstrapping method that uses all the information in seL4_BootInfo
	* assumes you are the rootserver. This keeps using whatever cspace you are currently in.
	*
	* @param bi BootInfo as passed to the rootserver
	* @param pool_size Size of the initial pool. See file comments for details
	* @param pool Initial pool. See file comments for details
	*
	* @return returns NULL on error
	*/
	allocman_t bootstrap_use_bootinfo(seL4_BootInfo bi, size_t pool_size, void *pool);

	/**
	* Bootstraps using all the information in bootinfo, but switches to a new single
	* level cspace. All untypeds specified in bootinfo will be moved to the new cspace,
	* any other capabilities will be left in the old cspace. If you wish to refer to the
	* boot cspace (most likely since it probably has capabilities you still want), then
	* a cspace description of the old cspace can also be returned.
	*
	* @param bi BootInfo as passed to the rootserver
	* @param cnode_size Number of slot bits (cnode_slots = 2^cnode_size) for the new cnode
	* @param pool_size Size of the initial pool. See file comments for details
	* @param pool Initial pool. See file comments for details
	* @param old_cspace Optional location to store a description of the original cspace. You
	* can free this memory back to the allocman when are done with it
	*
	* @return returns NULL on error
	*/
	allocman_t bootstrap_new_1level_bootinfo(seL4_BootInfo bi, size_t cnode_size, size_t pool_size, void pool, cspace_simple1level_t *old_cspace);

	/**
	* Bootstraps using all the information in bootinfo, but switches to a new two
	* level cspace. All untypeds specified in bootinfo will be moved to the new cspace,
	* any other capabilities will be left in the old cspace. If you wish to refer to the
	* boot cspace (most likely since it probably has capabilities you still want), then
	* a cspace description of the old cspace can also be returned.
	*
	* @param bi BootInfo as passed to the rootserver
	* @param l1size Number of slot bits (l1_slots = 2^l1size) for the level 1 cnode
	* @param l2size Number of slot bits (l2_slots = 2^l2size) for the level 2 cnode
	* @param pool_size Size of the initial pool. See file comments for details
	* @param pool Initial pool. See file comments for details
	* @param old_cspace Optional location to store a description of the original cspace. You
	* can free this memory back to the allocman when are done with it
	*
	* @return returns NULL on error
	*/
	allocman_t bootstrap_new_2level_bootinfo(seL4_BootInfo bi, size_t l1size, size_t l2size, size_t pool_size, void pool, cspace_simple1level_t *old_cspace);

	/**
	* Give an allocator all the untyped memory that simple knows about.
	*
	* This assumes that all the untyped caps are currently as simple thinks they are.
	* If there have been any cspace reshuffles simple will not give allocman useable information
	*
	* Allocman will also try and use sel4platsupport_get_pmem_region_list to find PMEM_TYPE_RAM
	* regions that are device untyped objects.
	*/
	int allocman_add_simple_untypeds(allocman_t alloc, simple_t simple);

	/**
	* Give an allocator all the untyped memory that simple knows about.
	*
	* This assumes that all the untyped caps are currently as simple thinks they are.
	* If there have been any cspace reshuffles simple will not give allocman useable information
	*
	* If num_regions is set to 0 or region_list is NULL, Allocman will also try and use
	* sel4platsupport_get_pmem_region_list to find PMEM_TYPE_RAM regions that are device untyped objects.
	* Otherwise any device untyped objects that overlap with regions that are type PMEM_TYPE_RAM will be marked as ALLOCMAN_UT_DEV_MEM.
	*/
	int allocman_add_simple_untypeds_with_regions(allocman_t alloc, simple_t simple, int num_regions, pmem_region_t *region_list);

	/**
	* Bootstraps using all the information provided by simple, but switches to a new two
	* level cspace. All capabilities specified by simple will be moved to the new cspace. All untypeds specified by simple are given to the allocator
	*
	* @param simple simple pointer to the struct
	* @param l1size Number of slot bits (l1_slots = 2^l1size) for the level 1 cnode
	* @param l2size Number of slot bits (l2_slots = 2^l2size) for the level 2 cnode
	* @param pool_size Size of the initial pool. See file comments for details
	* @param pool Initial pool. See file comments for details
	*
	* @return returns NULL on error
	*/
	allocman_t bootstrap_new_2level_simple(simple_t simple, size_t l1size, size_t l2size, size_t pool_size, void *pool);

	/* As above, but 1 level */
	allocman_t bootstrap_new_1level_simple(simple_t simple, size_t l1size, size_t pool_size, void *pool);

	/**
	* Bootstraps into the current environment as defined by simple. This will continue
	* to use the cspace described by simple, as well as all the untypeds it knows about
	*
	* @param simple Pointer to simple interface, will not be retained
	* @param pool_size Size of the initial pool. See file comments for details
	* @param pool Initial pool. See file comments for details
	*
	* @return returns NULL on error
	*/
	allocman_t bootstrap_use_current_simple(simple_t simple, size_t pool_size, void *pool);

	/**
	* Bootstraps an allocator that will reuse the current single level cspace (which
	* you must describe to it). While bootstrapping should succeed, you will need to
	* add untypeds manually to the returned allocman to make it useful.
	*
	* @param root_cnode Location of the cnode that is the current cspace
	* @param cnode_size Size in slot_bits of the current cnode
	* @param start_slot First free slot in the current cspace
	* @param end_slot Last free slot + 1 in the current cspace
	* @param pool_size Size of the initial pool. See file comments for details
	* @param pool Initial pool. See file comments for details
	*
	* @return returns NULL on error
	*/
	allocman_t bootstrap_use_current_1level(seL4_CPtr root_cnode, size_t cnode_size, seL4_CPtr start_slot, seL4_CPtr end_slot, size_t pool_size, void pool);

	/**
	* Provides a description of the boot cspace if you are doing a customized
	* bootstrapping. This MUST be set before using boostrap_new_[1\|2]level
	*
	* @param bs Internal bootstrapping info as allocated/returned by {@link #bootstrap_create_info}
	* @param cspace CSpace that will be used for bootstrapping purposes. The cspace only needs to exist
	* for as long as bootstrapping is happening, it will not be used afterwards
	* @param root_cnode Path to the root cnode of cspace. This is needed so that a cap to the old cspace
	* can be provided in the new cspace
	*
	* @return returns 0 on success
	*/
	int bootstrap_set_boot_cspace(bootstrap_info_t *bs, cspace_interface_t cspace, cspacepath_t root_cnode);

	/**
	* Adds knowledge of untypeds to the bootstrapping information. These untypeds will
	* be moved to the new cspace and be given to the untyped manager once bootstrapping
	* has completed.
	*
	* @param bs Internal bootstrapping info as allocated/returned by {@link #bootstrap_create_info}
	* @param num Number of untypeds to be added
	* @param uts Path to each of the untypeds
	* @param size_bits Size of each of the untypeds
	* @param paddr Optional physical address of each of the untypeds
	* @param isDevice whether this untyped is for a device region or not
	*
	* @return returns 0 on success
	*/
	int bootstrap_add_untypeds(bootstrap_info_t bs, size_t num, const cspacepath_t uts, size_t size_bits, uintptr_t paddr, bool isDevice);

	/**
	* Adds knowledge of all the untypeds of bootinfo to the bootstrapper. These will
	* be moved to the new cspace and given to the untyped manager once bootstrapping has
	* completed
	*
	* @param bs Internal bootstrapping info as allocated/returned by {@link #bootstrap_create_info}
	* @param bi BootInfo as passed to the rootserver
	*
	* @return returns 0 on success
	*/
	int bootstrap_add_untypeds_from_bootinfo(bootstrap_info_t bs, seL4_BootInfo bi);

	/**
	* Completes bootstrapping into a new single level cspace.
	*
	* @param info Internal bootstrapping info as allocated/returned by {@link #bootstrap_create_info}
	* @param cnode_size Size in slot bits of new cspace
	* @param tcb Path to the TCB of the current thread, need to perform an invocation of seL4_TCB_SetSpace
	* @param pd Path to the PD of the current thread. This is needed to work around seL4 restriction that
	* requires the address space be set at the same time as the cspace
	* @param oldroot Optional location to store a path to a cnode that is root cnode given in {@link #bootstrap_set_boot_cspace}
	*
	* @return returns NULL on error
	*/
	allocman_t bootstrap_new_1level(bootstrap_info_t info, size_t cnode_size, cspacepath_t tcb, cspacepath_t pd, cspacepath_t *oldroot);

	/**
	* Completes bootstrapping into a new two level cspace.
	*
	* @param info Internal bootstrapping info as allocated/returned by {@link #bootstrap_create_info}
	* @param l1size Number of slot bits (l1_slots = 2^l1size) for the level 1 cnode
	* @param l2size Number of slot bits (l2_slots = 2^l2size) for the level 2 cnode
	* @param tcb Path to the TCB of the current thread, need to perform an invocation of seL4_TCB_SetSpace
	* @param pd Path to the PD of the current thread. This is needed to work around seL4 restriction that
	* requires the address space be set at the same time as the cspace
	* @param oldroot Optional location to store a path to a cnode that is root cnode given in {@link #bootstrap_set_boot_cspace}
	*
	* @return returns NULL on error
	*/
	allocman_t bootstrap_new_2level(bootstrap_info_t info, size_t l1size, size_t l2size, cspacepath_t tcb, cspacepath_t pd, cspacepath_t *oldroot);

	/**
	* This function starts bootstrapping the system, and then 'breaks out' and
	* allows you to give a description of the boot cspace as well as provide any
	* untypeds. A new 1 or 2 level cspace can then be created.
	*
	* @param pool_size Size of the initial pool. See file comments for details
	* @param pool Initial pool. See file comments for details
	*
	* @return returns NULL on error
	*/
	bootstrap_info_t bootstrap_create_info(size_t pool_size, void pool);

	/**
	* Creates an empty allocman from a starting pool. The returned allocman will not
	* have an attached cspace or utspace. This function provides the ultimate flexibility
	* in how you can boot strap the system (read: this does basically nothing for you).

	* @param pool_size Size of the initial pool. See file comments for details
	* @param pool Initial pool. See file comments for details
	*
	* @return returns NULL on error
	*/
	allocman_t bootstrap_create_allocman(size_t pool_size, void pool);