libsel4vka/include/vka/vka.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)
  */

 #pragma once

 #include <autoconf.h>
 #include <sel4vka/gen_config.h>

 #include <sel4/sel4.h>
 #include <sel4/types.h>
 #include <assert.h>
 #include <stdint.h>
 #include <utils/util.h>
 #include <vka/cspacepath_t.h>

 /**
  * Allocate a slot in a cspace.
  *
  * @param data cookie for the underlying allocator
  * @param res pointer to a cptr to store the allocated slot
  * @return 0 on success
  */
 typedef int (*vka_cspace_alloc_fn)(void *data, seL4_CPtr *res);

 /**
  * Convert an allocated cptr to a cspacepath, for use in
  * operations such as Untyped_Retype
  *
  * @param data cookie for the underlying allocator
  * @param slot a cslot allocated by the cspace alloc function
  * @param res pointer to a cspacepath struct to fill out
  */
 typedef void (*vka_cspace_make_path_fn)(void *data, seL4_CPtr slot, cspacepath_t *res);

 /**
  * Free an allocated cslot
  *
  * @param data cookie for the underlying allocator
  * @param slot a cslot allocated by the cspace alloc function
  */
 typedef void (*vka_cspace_free_fn)(void *data, seL4_CPtr slot);

 /**
  * Allocate a portion of an untyped into an object
  *
  * @param data cookie for the underlying allocator
  * @param dest path to an empty cslot to place the cap to the allocated object
  * @param type the seL4 object type to allocate (as passed to Untyped_Retype)
  * @param size_bits the size of the object to allocate (as passed to Untyped_Retype)
  * @param res pointer to a location to store the cookie representing this allocation
  * @return 0 on success
  */
 typedef int (*vka_utspace_alloc_fn)(void *data, const cspacepath_t *dest, seL4_Word type, seL4_Word size_bits,
                                     seL4_Word *res);

 /**
  * Allocate a portion of an untyped into an object
  *
  * @param data cookie for the underlying allocator
  * @param dest path to an empty cslot to place the cap to the allocated object
  * @param type the seL4 object type to allocate (as passed to Untyped_Retype)
  * @param size_bits the size of the object to allocate (as passed to Untyped_Retype)
  * @param paddr The desired physical address that this object should start at
  * @param cookie pointer to a location to store the cookie representing this allocation
  * @return 0 on success
  */
 typedef int (*vka_utspace_alloc_at_fn)(void *data, const cspacepath_t *dest, seL4_Word type, seL4_Word size_bits,
                                        uintptr_t paddr, seL4_Word *cookie);

 /**
  * Allocate a portion of an untyped into an object
  *
  * @param data cookie for the underlying allocator
  * @param dest path to an empty cslot to place the cap to the allocated object
  * @param type the seL4 object type to allocate (as passed to Untyped_Retype)
  * @param size_bits the size of the object to allocate (as passed to Untyped_Retype)
  * @param can_use_dev whether the allocator can use device untyped instead of regular untyped
  * @param res pointer to a location to store the cookie representing this allocation
  * @return 0 on success
  */
 typedef int (*vka_utspace_alloc_maybe_device_fn)(void *data, const cspacepath_t *dest, seL4_Word type,
                                                  seL4_Word size_bits, bool can_use_dev, seL4_Word *res);

 /**
  * Free a portion of an allocated untyped. Is the responsibility of the caller to
  * have already deleted the object (by deleting all capabilities) first
  *
  * @param data cookie for the underlying allocator
  * @param type the seL4 object type that was allocated (as passed to Untyped_Retype)
  * @param size_bits the size of the object that was allocated (as passed to Untyped_Retype)
  * @param target cookie to the allocation as given by the utspace alloc function
  */
 typedef void (*vka_utspace_free_fn)(void *data, seL4_Word type, seL4_Word size_bits, seL4_Word target);

 /**
  * Request the physical address of an object.
  *
  * @param data cookie for the underlying allocator
  * @param target cookie to the allocation as given by the utspace alloc function
  * @param type the seL4 object type that was allocated (as passed to Untyped_Retype)
  * @param size_bits the size of the object that was allocated (as passed to Untyped_Retype)
  * @return paddr of object, or VKA_NO_PADDR on error
  */
 typedef uintptr_t (*vka_utspace_paddr_fn)(void *data, seL4_Word target, seL4_Word type, seL4_Word size_bits);

 #define VKA_NO_PADDR 1

 /*
  * Generic Virtual Kernel Allocator (VKA) data structure.
  *
  * This is similar in concept to the Linux VFS structures, but for
  * the seL4 kernel object allocator instead of the Linux file system.
  *
  * Alternatively, you can think of this as a abstract class in an
  * OO hierarchy, of which has several implementations.
  */

 typedef struct vka {
     void *data;
     vka_cspace_alloc_fn cspace_alloc;
     vka_cspace_make_path_fn cspace_make_path;
     vka_utspace_alloc_fn utspace_alloc;
     vka_utspace_alloc_maybe_device_fn utspace_alloc_maybe_device;
     vka_utspace_alloc_at_fn utspace_alloc_at;
     vka_cspace_free_fn cspace_free;
     vka_utspace_free_fn utspace_free;
     vka_utspace_paddr_fn utspace_paddr;
 } vka_t;

 static inline int vka_cspace_alloc(vka_t *vka, seL4_CPtr *res)
 {
     if (!vka) {
         ZF_LOGE("vka is NULL");
         return -1;
     }

     if (!res) {
         ZF_LOGE("res is NULL");
         return -1;
     }

     if (!vka->cspace_alloc) {
         ZF_LOGE("Unimplemented");
         return -1;
     }

     return vka->cspace_alloc(vka->data, res);
 }

 static inline void vka_cspace_make_path(vka_t *vka, seL4_CPtr slot, cspacepath_t *res)
 {

     if (!res) {
         ZF_LOGF("res is NULL");
     }

     if (!vka) {
         ZF_LOGF("vka is NULL");
     }

     if (!vka->cspace_make_path) {
         ZF_LOGF("Unimplmented");
     }

     vka->cspace_make_path(vka->data, slot, res);
 }

 /*
  * Wrapper functions to make calls more convenient
  */
 static inline int vka_cspace_alloc_path(vka_t *vka, cspacepath_t *res)
 {
     seL4_CPtr slot;
     int error = vka_cspace_alloc(vka, &slot);

     if (error == seL4_NoError) {
         vka_cspace_make_path(vka, slot, res);
     }

     return error;
 }

 static inline void vka_cspace_free(vka_t *vka, seL4_CPtr slot)
 {
 #ifdef CONFIG_DEBUG_BUILD
     if (seL4_DebugCapIdentify(slot) != 0) {
         ZF_LOGF("slot is not free: call vka_cnode_delete first");
         /* this terminates the system */
     }
 #endif

     if (!vka->cspace_free) {
         ZF_LOGE("Not implemented");
         return;
     }

     vka->cspace_free(vka->data, slot);
 }

 static inline void vka_cspace_free_path(vka_t *vka, cspacepath_t path)
 {
     vka_cspace_free(vka, path.capPtr);
 }

 static inline int vka_utspace_alloc(vka_t *vka, const cspacepath_t *dest, seL4_Word type, seL4_Word size_bits,
                                     seL4_Word *res)
 {
     if (!vka) {
         ZF_LOGE("vka is NULL");
         return -1;
     }

     if (!res) {
         ZF_LOGE("res is NULL");
         return -1;
     }

     if (!vka->utspace_alloc) {
         ZF_LOGE("Not implemented");
         return -1;
     }

     return vka->utspace_alloc(vka->data, dest, type, size_bits, res);
 }

 static inline int vka_utspace_alloc_maybe_device(vka_t *vka, const cspacepath_t *dest, seL4_Word type,
                                                  seL4_Word size_bits, bool can_use_dev, seL4_Word *res)
 {
     if (!vka) {
         ZF_LOGE("vka is NULL");
         return -1;
     }

     if (!res) {
         ZF_LOGE("res is NULL");
         return -1;
     }

     if (!vka->utspace_alloc_maybe_device) {
         ZF_LOGE("Not implemented");
         return -1;
     }

     return vka->utspace_alloc_maybe_device(vka->data, dest, type, size_bits, can_use_dev, res);
 }

 static inline int vka_utspace_alloc_at(vka_t *vka, const cspacepath_t *dest, seL4_Word type, seL4_Word size_bits,
                                        uintptr_t paddr, seL4_Word *cookie)
 {
     if (!vka) {
         ZF_LOGE("vka is NULL");
         return -1;
     }
     if (!cookie) {
         ZF_LOGE("cookie is NULL");
         return -1;
     }
     if (!vka->utspace_alloc_at) {
         ZF_LOGE("Not implemented");
         return -1;
     }

     return vka->utspace_alloc_at(vka->data, dest, type, size_bits, paddr, cookie);
 }

 static inline void vka_utspace_free(vka_t *vka, seL4_Word type, seL4_Word size_bits, seL4_Word target)
 {
     if (!vka) {
         ZF_LOGE("vka is NULL");
         return ;
     }

     if (!vka->utspace_free) {
 #ifndef CONFIG_LIB_VKA_ALLOW_MEMORY_LEAKS
         ZF_LOGF("Not implemented");
         /* This terminates the system */
 #endif
         return;
     }

     vka->utspace_free(vka->data, type, size_bits, target);
 }

 static inline uintptr_t vka_utspace_paddr(vka_t *vka, seL4_Word target, seL4_Word type, seL4_Word size_bits)
 {

     if (!vka) {
         ZF_LOGE("vka is NULL");
         return VKA_NO_PADDR;
     }

     if (!vka->utspace_paddr) {
         ZF_LOGE("Not implemented");
         return VKA_NO_PADDR;
     }

     return vka->utspace_paddr(vka->data, target, type, size_bits);
 }
	/*
	* 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)
	*/

	#pragma once

	#include <autoconf.h>
	#include <sel4vka/gen_config.h>

	#include <sel4/sel4.h>
	#include <sel4/types.h>
	#include <assert.h>
	#include <stdint.h>
	#include <utils/util.h>
	#include <vka/cspacepath_t.h>

	/**
	* Allocate a slot in a cspace.
	*
	* @param data cookie for the underlying allocator
	* @param res pointer to a cptr to store the allocated slot
	* @return 0 on success
	*/
	typedef int (vka_cspace_alloc_fn)(void data, seL4_CPtr *res);

	/**
	* Convert an allocated cptr to a cspacepath, for use in
	* operations such as Untyped_Retype
	*
	* @param data cookie for the underlying allocator
	* @param slot a cslot allocated by the cspace alloc function
	* @param res pointer to a cspacepath struct to fill out
	*/
	typedef void (vka_cspace_make_path_fn)(void data, seL4_CPtr slot, cspacepath_t *res);

	/**
	* Free an allocated cslot
	*
	* @param data cookie for the underlying allocator
	* @param slot a cslot allocated by the cspace alloc function
	*/
	typedef void (vka_cspace_free_fn)(void data, seL4_CPtr slot);

	/**
	* Allocate a portion of an untyped into an object
	*
	* @param data cookie for the underlying allocator
	* @param dest path to an empty cslot to place the cap to the allocated object
	* @param type the seL4 object type to allocate (as passed to Untyped_Retype)
	* @param size_bits the size of the object to allocate (as passed to Untyped_Retype)
	* @param res pointer to a location to store the cookie representing this allocation
	* @return 0 on success
	*/
	typedef int (vka_utspace_alloc_fn)(void data, const cspacepath_t *dest, seL4_Word type, seL4_Word size_bits,
	seL4_Word *res);

	/**
	* Allocate a portion of an untyped into an object
	*
	* @param data cookie for the underlying allocator
	* @param dest path to an empty cslot to place the cap to the allocated object
	* @param type the seL4 object type to allocate (as passed to Untyped_Retype)
	* @param size_bits the size of the object to allocate (as passed to Untyped_Retype)
	* @param paddr The desired physical address that this object should start at
	* @param cookie pointer to a location to store the cookie representing this allocation
	* @return 0 on success
	*/
	typedef int (vka_utspace_alloc_at_fn)(void data, const cspacepath_t *dest, seL4_Word type, seL4_Word size_bits,
	uintptr_t paddr, seL4_Word *cookie);

	/**
	* Allocate a portion of an untyped into an object
	*
	* @param data cookie for the underlying allocator
	* @param dest path to an empty cslot to place the cap to the allocated object
	* @param type the seL4 object type to allocate (as passed to Untyped_Retype)
	* @param size_bits the size of the object to allocate (as passed to Untyped_Retype)
	* @param can_use_dev whether the allocator can use device untyped instead of regular untyped
	* @param res pointer to a location to store the cookie representing this allocation
	* @return 0 on success
	*/
	typedef int (vka_utspace_alloc_maybe_device_fn)(void data, const cspacepath_t *dest, seL4_Word type,
	seL4_Word size_bits, bool can_use_dev, seL4_Word *res);

	/**
	* Free a portion of an allocated untyped. Is the responsibility of the caller to
	* have already deleted the object (by deleting all capabilities) first
	*
	* @param data cookie for the underlying allocator
	* @param type the seL4 object type that was allocated (as passed to Untyped_Retype)
	* @param size_bits the size of the object that was allocated (as passed to Untyped_Retype)
	* @param target cookie to the allocation as given by the utspace alloc function
	*/
	typedef void (vka_utspace_free_fn)(void data, seL4_Word type, seL4_Word size_bits, seL4_Word target);

	/**
	* Request the physical address of an object.
	*
	* @param data cookie for the underlying allocator
	* @param target cookie to the allocation as given by the utspace alloc function
	* @param type the seL4 object type that was allocated (as passed to Untyped_Retype)
	* @param size_bits the size of the object that was allocated (as passed to Untyped_Retype)
	* @return paddr of object, or VKA_NO_PADDR on error
	*/
	typedef uintptr_t (vka_utspace_paddr_fn)(void data, seL4_Word target, seL4_Word type, seL4_Word size_bits);

	#define VKA_NO_PADDR 1

	/*
	* Generic Virtual Kernel Allocator (VKA) data structure.
	*
	* This is similar in concept to the Linux VFS structures, but for
	* the seL4 kernel object allocator instead of the Linux file system.
	*
	* Alternatively, you can think of this as a abstract class in an
	* OO hierarchy, of which has several implementations.
	*/

	typedef struct vka {
	void *data;
	vka_cspace_alloc_fn cspace_alloc;
	vka_cspace_make_path_fn cspace_make_path;
	vka_utspace_alloc_fn utspace_alloc;
	vka_utspace_alloc_maybe_device_fn utspace_alloc_maybe_device;
	vka_utspace_alloc_at_fn utspace_alloc_at;
	vka_cspace_free_fn cspace_free;
	vka_utspace_free_fn utspace_free;
	vka_utspace_paddr_fn utspace_paddr;
	} vka_t;

	static inline int vka_cspace_alloc(vka_t vka, seL4_CPtr res)
	{
	if (!vka) {
	ZF_LOGE("vka is NULL");
	return -1;
	}

	if (!res) {
	ZF_LOGE("res is NULL");
	return -1;
	}

	if (!vka->cspace_alloc) {
	ZF_LOGE("Unimplemented");
	return -1;
	}

	return vka->cspace_alloc(vka->data, res);
	}

	static inline void vka_cspace_make_path(vka_t vka, seL4_CPtr slot, cspacepath_t res)
	{

	if (!res) {
	ZF_LOGF("res is NULL");
	}

	if (!vka) {
	ZF_LOGF("vka is NULL");
	}

	if (!vka->cspace_make_path) {
	ZF_LOGF("Unimplmented");
	}

	vka->cspace_make_path(vka->data, slot, res);
	}

	/*
	* Wrapper functions to make calls more convenient
	*/
	static inline int vka_cspace_alloc_path(vka_t vka, cspacepath_t res)
	{
	seL4_CPtr slot;
	int error = vka_cspace_alloc(vka, &slot);

	if (error == seL4_NoError) {
	vka_cspace_make_path(vka, slot, res);
	}

	return error;
	}

	static inline void vka_cspace_free(vka_t *vka, seL4_CPtr slot)
	{
	#ifdef CONFIG_DEBUG_BUILD
	if (seL4_DebugCapIdentify(slot) != 0) {
	ZF_LOGF("slot is not free: call vka_cnode_delete first");
	/* this terminates the system */
	}
	#endif

	if (!vka->cspace_free) {
	ZF_LOGE("Not implemented");
	return;
	}

	vka->cspace_free(vka->data, slot);
	}

	static inline void vka_cspace_free_path(vka_t *vka, cspacepath_t path)
	{
	vka_cspace_free(vka, path.capPtr);
	}

	static inline int vka_utspace_alloc(vka_t vka, const cspacepath_t dest, seL4_Word type, seL4_Word size_bits,
	seL4_Word *res)
	{
	if (!vka) {
	ZF_LOGE("vka is NULL");
	return -1;
	}

	if (!res) {
	ZF_LOGE("res is NULL");
	return -1;
	}

	if (!vka->utspace_alloc) {
	ZF_LOGE("Not implemented");
	return -1;
	}

	return vka->utspace_alloc(vka->data, dest, type, size_bits, res);
	}

	static inline int vka_utspace_alloc_maybe_device(vka_t vka, const cspacepath_t dest, seL4_Word type,
	seL4_Word size_bits, bool can_use_dev, seL4_Word *res)
	{
	if (!vka) {
	ZF_LOGE("vka is NULL");
	return -1;
	}

	if (!res) {
	ZF_LOGE("res is NULL");
	return -1;
	}

	if (!vka->utspace_alloc_maybe_device) {
	ZF_LOGE("Not implemented");
	return -1;
	}

	return vka->utspace_alloc_maybe_device(vka->data, dest, type, size_bits, can_use_dev, res);
	}

	static inline int vka_utspace_alloc_at(vka_t vka, const cspacepath_t dest, seL4_Word type, seL4_Word size_bits,
	uintptr_t paddr, seL4_Word *cookie)
	{
	if (!vka) {
	ZF_LOGE("vka is NULL");
	return -1;
	}
	if (!cookie) {
	ZF_LOGE("cookie is NULL");
	return -1;
	}
	if (!vka->utspace_alloc_at) {
	ZF_LOGE("Not implemented");
	return -1;
	}

	return vka->utspace_alloc_at(vka->data, dest, type, size_bits, paddr, cookie);
	}

	static inline void vka_utspace_free(vka_t *vka, seL4_Word type, seL4_Word size_bits, seL4_Word target)
	{
	if (!vka) {
	ZF_LOGE("vka is NULL");
	return ;
	}

	if (!vka->utspace_free) {
	#ifndef CONFIG_LIB_VKA_ALLOW_MEMORY_LEAKS
	ZF_LOGF("Not implemented");
	/* This terminates the system */
	#endif
	return;
	}

	vka->utspace_free(vka->data, type, size_bits, target);
	}

	static inline uintptr_t vka_utspace_paddr(vka_t *vka, seL4_Word target, seL4_Word type, seL4_Word size_bits)
	{

	if (!vka) {
	ZF_LOGE("vka is NULL");
	return VKA_NO_PADDR;
	}

	if (!vka->utspace_paddr) {
	ZF_LOGE("Not implemented");
	return VKA_NO_PADDR;
	}

	return vka->utspace_paddr(vka->data, target, type, size_bits);
	}