satip-axe/kernel/drivers/stm/mali/common/mali_osk.h
2015-03-26 17:24:57 +01:00

1643 lines
66 KiB
C

/*
* Copyright (C) 2010-2011 ARM Limited. All rights reserved.
*
* This program is free software and is provided to you under the terms of the GNU General Public License version 2
* as published by the Free Software Foundation, and any use by you of this program is subject to the terms of such GNU licence.
*
* A copy of the licence is included with the program, and can also be obtained from Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*/
/**
* @file mali_osk.h
* Defines the OS abstraction layer for the kernel device driver (OSK)
*/
#ifndef __MALI_OSK_H__
#define __MALI_OSK_H__
#ifdef __cplusplus
extern "C"
{
#endif
/**
* @addtogroup uddapi Unified Device Driver (UDD) APIs
*
* @{
*/
/**
* @addtogroup oskapi UDD OS Abstraction for Kernel-side (OSK) APIs
*
* @{
*/
/** @defgroup _mali_osk_miscellaneous OSK Miscellaneous functions, constants and types
* @{ */
/* Define integer types used by OSK. Note: these currently clash with Linux so we only define them if not defined already */
#ifndef __KERNEL__
typedef unsigned char u8;
typedef signed char s8;
typedef unsigned short u16;
typedef signed short s16;
typedef unsigned int u32;
typedef signed int s32;
typedef unsigned long long u64;
#define BITS_PER_LONG (sizeof(long)*8)
#else
/* Ensure Linux types u32, etc. are defined */
#include <linux/types.h>
#endif
/** @brief Mali Boolean type which uses MALI_TRUE and MALI_FALSE
*/
typedef unsigned long mali_bool;
#ifndef MALI_TRUE
#define MALI_TRUE ((mali_bool)1)
#endif
#ifndef MALI_FALSE
#define MALI_FALSE ((mali_bool)0)
#endif
/**
* @brief OSK Error codes
*
* Each OS may use its own set of error codes, and may require that the
* User/Kernel interface take certain error code. This means that the common
* error codes need to be sufficiently rich to pass the correct error code
* thorugh from the OSK to U/K layer, across all OSs.
*
* The result is that some error codes will appear redundant on some OSs.
* Under all OSs, the OSK layer must translate native OS error codes to
* _mali_osk_errcode_t codes. Similarly, the U/K layer must translate from
* _mali_osk_errcode_t codes to native OS error codes.
*/
typedef enum
{
_MALI_OSK_ERR_OK = 0, /**< Success. */
_MALI_OSK_ERR_FAULT = -1, /**< General non-success */
_MALI_OSK_ERR_INVALID_FUNC = -2, /**< Invalid function requested through User/Kernel interface (e.g. bad IOCTL number) */
_MALI_OSK_ERR_INVALID_ARGS = -3, /**< Invalid arguments passed through User/Kernel interface */
_MALI_OSK_ERR_NOMEM = -4, /**< Insufficient memory */
_MALI_OSK_ERR_TIMEOUT = -5, /**< Timeout occurred */
_MALI_OSK_ERR_RESTARTSYSCALL = -6, /**< Special: On certain OSs, must report when an interruptable mutex is interrupted. Ignore otherwise. */
_MALI_OSK_ERR_ITEM_NOT_FOUND = -7, /**< Table Lookup failed */
_MALI_OSK_ERR_BUSY = -8, /**< Device/operation is busy. Try again later */
_MALI_OSK_ERR_UNSUPPORTED = -9, /**< Optional part of the interface used, and is unsupported */
} _mali_osk_errcode_t;
/** @} */ /* end group _mali_osk_miscellaneous */
/** @defgroup _mali_osk_irq OSK IRQ handling
* @{ */
/** @brief Private type for IRQ handling objects */
typedef struct _mali_osk_irq_t_struct _mali_osk_irq_t;
/** @brief Optional function to trigger an irq from a resource
*
* This function is implemented by the common layer to allow probing of a resource's IRQ.
* @param arg resource-specific data */
typedef void (*_mali_osk_irq_trigger_t)( void * arg );
/** @brief Optional function to acknowledge an irq from a resource
*
* This function is implemented by the common layer to allow probing of a resource's IRQ.
* @param arg resource-specific data
* @return _MALI_OSK_ERR_OK if the IRQ was successful, or a suitable _mali_osk_errcode_t on failure. */
typedef _mali_osk_errcode_t (*_mali_osk_irq_ack_t)( void * arg );
/** @brief IRQ 'upper-half' handler callback.
*
* This function is implemented by the common layer to do the initial handling of a
* resource's IRQ. This maps on to the concept of an ISR that does the minimum
* work necessary before handing off to an IST.
*
* The communication of the resource-specific data from the ISR to the IST is
* handled by the OSK implementation.
*
* On most systems, the IRQ upper-half handler executes in IRQ context.
* Therefore, the system may have restrictions about what can be done in this
* context
*
* If an IRQ upper-half handler requires more work to be done than can be
* acheived in an IRQ context, then it may defer the work with
* _mali_osk_irq_schedulework(). Refer to \ref _mali_osk_irq_schedulework() for
* more information.
*
* @param arg resource-specific data
* @return _MALI_OSK_ERR_OK if the IRQ was correctly handled, or a suitable
* _mali_osk_errcode_t otherwise.
*/
typedef _mali_osk_errcode_t (*_mali_osk_irq_uhandler_t)( void * arg );
/** @brief IRQ 'bottom-half' handler callback.
*
* This function is implemented by the common layer to do the deferred handling
* of a resource's IRQ. Usually, this work cannot be carried out in IRQ context
* by the IRQ upper-half handler.
*
* The IRQ bottom-half handler maps on to the concept of an IST that may
* execute some time after the actual IRQ has fired.
*
* All OSK-registered IRQ bottom-half handlers will be serialized, across all
* CPU-cores in the system.
*
* Refer to \ref _mali_osk_irq_schedulework() for more information on the
* IRQ work-queue, and the calling of the IRQ bottom-half handler.
*
* @param arg resource-specific data
*/
typedef void (*_mali_osk_irq_bhandler_t)( void * arg );
/** @} */ /* end group _mali_osk_irq */
/** @defgroup _mali_osk_atomic OSK Atomic counters
* @{ */
/** @brief Public type of atomic counters
*
* This is public for allocation on stack. On systems that support it, this is just a single 32-bit value.
* On others, it could be encapsulating an object stored elsewhere.
*
* Even though the structure has space for a u32, the counters will only
* represent signed 24-bit integers.
*
* Regardless of implementation, the \ref _mali_osk_atomic functions \b must be used
* for all accesses to the variable's value, even if atomicity is not required.
* Do not access u.val or u.obj directly.
*/
typedef struct
{
union
{
u32 val;
void *obj;
} u;
} _mali_osk_atomic_t;
/** @} */ /* end group _mali_osk_atomic */
/** @defgroup _mali_osk_lock OSK Mutual Exclusion Locks
* @{ */
/** @brief OSK Mutual Exclusion Lock flags type
*
* Flags are supplied at the point where the Lock is initialized. Each flag can
* be combined with others using bitwise OR, '|'.
*
* The flags must be sufficiently rich to cope with all our OSs. This means
* that on some OSs, certain flags can be completely ignored. We define a
* number of terms that are significant across all OSs:
*
* - Sleeping/non-sleeping mutexs. Sleeping mutexs can block on waiting, and so
* schedule out the current thread. This is significant on OSs where there are
* situations in which the current thread must not be put to sleep. On OSs
* without this restriction, sleeping and non-sleeping mutexes can be treated
* as the same (if that is required).
* - Interruptable/non-interruptable mutexes. For sleeping mutexes, it may be
* possible for the sleep to be interrupted for a reason other than the thread
* being able to obtain the lock. OSs behaving in this way may provide a
* mechanism to control whether sleeping mutexes can be interrupted. On OSs
* that do not support the concept of interruption, \b or they do not support
* control of mutex interruption, then interruptable mutexes may be treated
* as non-interruptable.
*
* Some constrains apply to the lock type flags:
*
* - Spinlocks are by nature, non-interruptable. Hence, they must always be
* combined with the NONINTERRUPTABLE flag, because it is meaningless to ask
* for a spinlock that is interruptable (and this highlights its
* non-interruptable-ness). For example, on certain OSs they should be used when
* you must not sleep.
* - Reader/writer is an optimization hint, and any type of lock can be
* reader/writer. Since this is an optimization hint, the implementation need
* not respect this for any/all types of lock. For example, on certain OSs,
* there's no interruptable reader/writer mutex. If such a thing were requested
* on that OS, the fact that interruptable was requested takes priority over the
* reader/writer-ness, because reader/writer-ness is not necessary for correct
* operation.
* - Any lock can use the order parameter.
* - A onelock is an optimization hint specific to certain OSs. It can be
* specified when it is known that only one lock will be held by the thread,
* and so can provide faster mutual exclusion. This can be safely ignored if
* such optimization is not required/present.
*
* The absence of any flags (the value 0) results in a sleeping-mutex, which is interruptable.
*/
typedef enum
{
_MALI_OSK_LOCKFLAG_SPINLOCK = 0x1, /**< Specifically, don't sleep on those architectures that require it */
_MALI_OSK_LOCKFLAG_NONINTERRUPTABLE = 0x2, /**< The mutex cannot be interrupted, e.g. delivery of signals on those architectures where this is required */
_MALI_OSK_LOCKFLAG_READERWRITER = 0x4, /**< Optimise for readers/writers */
_MALI_OSK_LOCKFLAG_ORDERED = 0x8, /**< Use the order parameter; otherwise use automatic ordering */
_MALI_OSK_LOCKFLAG_ONELOCK = 0x10, /**< Each thread can only hold one lock at a time */
_MALI_OSK_LOCKFLAG_SPINLOCK_IRQ = 0x20, /**< IRQ version of spinlock */
/** @enum _mali_osk_lock_flags_t
*
* Flags from 0x10000--0x80000000 are RESERVED for User-mode */
} _mali_osk_lock_flags_t;
/** @brief Mutual Exclusion Lock Mode Optimization hint
*
* The lock mode is used to implement the read/write locking of locks specified
* as _MALI_OSK_LOCKFLAG_READERWRITER. In this case, the RO mode can be used
* to allow multiple concurrent readers, but no writers. The RW mode is used for
* writers, and so will wait for all readers to release the lock (if any present).
* Further readers and writers will wait until the writer releases the lock.
*
* The mode is purely an optimization hint: for example, it is permissible for
* all locks to behave in RW mode, regardless of that supplied.
*
* It is an error to attempt to use locks in anything other that RW mode when
* _MALI_OSK_LOCKFLAG_READERWRITER is not supplied.
*
*/
typedef enum
{
_MALI_OSK_LOCKMODE_UNDEF = -1, /**< Undefined lock mode. For internal use only */
_MALI_OSK_LOCKMODE_RW = 0x0, /**< Read-write mode, default. All readers and writers are mutually-exclusive */
_MALI_OSK_LOCKMODE_RO, /**< Read-only mode, to support multiple concurrent readers, but mutual exclusion in the presence of writers. */
/** @enum _mali_osk_lock_mode_t
*
* Lock modes 0x40--0x7F are RESERVED for User-mode */
} _mali_osk_lock_mode_t;
/** @brief Private type for Mutual Exclusion lock objects */
typedef struct _mali_osk_lock_t_struct _mali_osk_lock_t;
/** @} */ /* end group _mali_osk_lock */
/** @defgroup _mali_osk_low_level_memory OSK Low-level Memory Operations
* @{ */
/**
* @brief Private data type for use in IO accesses to/from devices.
*
* This represents some range that is accessible from the device. Examples
* include:
* - Device Registers, which could be readable and/or writeable.
* - Memory that the device has access to, for storing configuration structures.
*
* Access to this range must be made through the _mali_osk_mem_ioread32() and
* _mali_osk_mem_iowrite32() functions.
*/
typedef struct _mali_io_address * mali_io_address;
/** @defgroup _MALI_OSK_CPU_PAGE CPU Physical page size macros.
*
* The order of the page size is supplied for
* ease of use by algorithms that might require it, since it is easier to know
* it ahead of time rather than calculating it.
*
* The Mali Page Mask macro masks off the lower bits of a physical address to
* give the start address of the page for that physical address.
*
* @note The Mali device driver code is designed for systems with 4KB page size.
* Changing these macros will not make the entire Mali device driver work with
* page sizes other than 4KB.
*
* @note The CPU Physical Page Size has been assumed to be the same as the Mali
* Physical Page Size.
*
* @{
*/
/** CPU Page Order, as log to base 2 of the Page size. @see _MALI_OSK_CPU_PAGE_SIZE */
#define _MALI_OSK_CPU_PAGE_ORDER ((u32)12)
/** CPU Page Size, in bytes. */
#define _MALI_OSK_CPU_PAGE_SIZE (((u32)1) << (_MALI_OSK_CPU_PAGE_ORDER))
/** CPU Page Mask, which masks off the offset within a page */
#define _MALI_OSK_CPU_PAGE_MASK (~((((u32)1) << (_MALI_OSK_CPU_PAGE_ORDER)) - ((u32)1)))
/** @} */ /* end of group _MALI_OSK_CPU_PAGE */
/** @defgroup _MALI_OSK_MALI_PAGE Mali Physical Page size macros
*
* Mali Physical page size macros. The order of the page size is supplied for
* ease of use by algorithms that might require it, since it is easier to know
* it ahead of time rather than calculating it.
*
* The Mali Page Mask macro masks off the lower bits of a physical address to
* give the start address of the page for that physical address.
*
* @note The Mali device driver code is designed for systems with 4KB page size.
* Changing these macros will not make the entire Mali device driver work with
* page sizes other than 4KB.
*
* @note The Mali Physical Page Size has been assumed to be the same as the CPU
* Physical Page Size.
*
* @{
*/
/** Mali Page Order, as log to base 2 of the Page size. @see _MALI_OSK_MALI_PAGE_SIZE */
#define _MALI_OSK_MALI_PAGE_ORDER ((u32)12)
/** Mali Page Size, in bytes. */
#define _MALI_OSK_MALI_PAGE_SIZE (((u32)1) << (_MALI_OSK_MALI_PAGE_ORDER))
/** Mali Page Mask, which masks off the offset within a page */
#define _MALI_OSK_MALI_PAGE_MASK (~((((u32)1) << (_MALI_OSK_MALI_PAGE_ORDER)) - ((u32)1)))
/** @} */ /* end of group _MALI_OSK_MALI_PAGE*/
/** @brief flags for mapping a user-accessible memory range
*
* Where a function with prefix '_mali_osk_mem_mapregion' accepts flags as one
* of the function parameters, it will use one of these. These allow per-page
* control over mappings. Compare with the mali_memory_allocation_flag type,
* which acts over an entire range
*
* These may be OR'd together with bitwise OR (|), but must be cast back into
* the type after OR'ing.
*/
typedef enum
{
_MALI_OSK_MEM_MAPREGION_FLAG_OS_ALLOCATED_PHYSADDR = 0x1, /**< Physical address is OS Allocated */
} _mali_osk_mem_mapregion_flags_t;
/** @} */ /* end group _mali_osk_low_level_memory */
/** @defgroup _mali_osk_notification OSK Notification Queues
* @{ */
/** @brief Private type for notification queue objects */
typedef struct _mali_osk_notification_queue_t_struct _mali_osk_notification_queue_t;
/** @brief Public notification data object type */
typedef struct _mali_osk_notification_t_struct
{
u32 notification_type; /**< The notification type */
u32 result_buffer_size; /**< Size of the result buffer to copy to user space */
void * result_buffer; /**< Buffer containing any type specific data */
} _mali_osk_notification_t;
/** @} */ /* end group _mali_osk_notification */
/** @defgroup _mali_osk_timer OSK Timer Callbacks
* @{ */
/** @brief Function to call when a timer expires
*
* When a timer expires, this function is called. Note that on many systems,
* a timer callback will be executed in IRQ context. Therefore, restrictions
* may apply on what can be done inside the timer callback.
*
* If a timer requires more work to be done than can be acheived in an IRQ
* context, then it may defer the work with a work-queue. For example, it may
* use \ref _mali_osk_irq_schedulework() to make use of the IRQ bottom-half handler
* to carry out the remaining work.
*
* Stopping the timer with \ref _mali_osk_timer_del() blocks on compeletion of
* the callback. Therefore, the callback may not obtain any mutexes also held
* by any callers of _mali_osk_timer_del(). Otherwise, a deadlock may occur.
*
* @param arg Function-specific data */
typedef void (*_mali_osk_timer_callback_t)(void * arg );
/** @brief Private type for Timer Callback Objects */
typedef struct _mali_osk_timer_t_struct _mali_osk_timer_t;
/** @} */ /* end group _mali_osk_timer */
/** @addtogroup _mali_osk_list OSK Doubly-Linked Circular Lists
* @{ */
/** @brief Public List objects.
*
* To use, add a _mali_osk_list_t member to the structure that may become part
* of a list. When traversing the _mali_osk_list_t objects, use the
* _MALI_OSK_CONTAINER_OF() macro to recover the structure from its
*_mali_osk_list_t member
*
* Each structure may have multiple _mali_osk_list_t members, so that the
* structure is part of multiple lists. When traversing lists, ensure that the
* correct _mali_osk_list_t member is used, because type-checking will be
* lost by the compiler.
*/
typedef struct _mali_osk_list_s
{
struct _mali_osk_list_s *next;
struct _mali_osk_list_s *prev;
} _mali_osk_list_t;
/** @brief Initialize a list to be a head of an empty list
* @param exp the list to initialize. */
#define _MALI_OSK_INIT_LIST_HEAD(exp) _mali_osk_list_init(exp)
/** @brief Define a list variable, which is uninitialized.
* @param exp the name of the variable that the list will be defined as. */
#define _MALI_OSK_LIST_HEAD(exp) _mali_osk_list_t exp
/** @brief Find the containing structure of another structure
*
* This is the reverse of the operation 'offsetof'. This means that the
* following condition is satisfied:
*
* ptr == _MALI_OSK_CONTAINER_OF( &ptr->member, type, member )
*
* When ptr is of type 'type'.
*
* Its purpose it to recover a larger structure that has wrapped a smaller one.
*
* @note no type or memory checking occurs to ensure that a wrapper structure
* does in fact exist, and that it is being recovered with respect to the
* correct member.
*
* @param ptr the pointer to the member that is contained within the larger
* structure
* @param type the type of the structure that contains the member
* @param member the name of the member in the structure that ptr points to.
* @return a pointer to a \a type object which contains \a member, as pointed
* to by \a ptr.
*/
#define _MALI_OSK_CONTAINER_OF(ptr, type, member) \
((type *)( ((char *)ptr) - offsetof(type,member) ))
/** @brief Find the containing structure of a list
*
* When traversing a list, this is used to recover the containing structure,
* given that is contains a _mali_osk_list_t member.
*
* Each list must be of structures of one type, and must link the same members
* together, otherwise it will not be possible to correctly recover the
* sturctures that the lists link.
*
* @note no type or memory checking occurs to ensure that a structure does in
* fact exist for the list entry, and that it is being recovered with respect
* to the correct list member.
*
* @param ptr the pointer to the _mali_osk_list_t member in this structure
* @param type the type of the structure that contains the member
* @param member the member of the structure that ptr points to.
* @return a pointer to a \a type object which contains the _mali_osk_list_t
* \a member, as pointed to by the _mali_osk_list_t \a *ptr.
*/
#define _MALI_OSK_LIST_ENTRY(ptr, type, member) \
_MALI_OSK_CONTAINER_OF(ptr, type, member)
/** @brief Enumerate a list safely
*
* With this macro, lists can be enumerated in a 'safe' manner. That is,
* entries can be deleted from the list without causing an error during
* enumeration. To achieve this, a 'temporary' pointer is required, which must
* be provided to the macro.
*
* Use it like a 'for()', 'while()' or 'do()' construct, and so it must be
* followed by a statement or compound-statement which will be executed for
* each list entry.
*
* Upon loop completion, providing that an early out was not taken in the
* loop body, then it is guaranteed that ptr->member == list, even if the loop
* body never executed.
*
* @param ptr a pointer to an object of type 'type', which points to the
* structure that contains the currently enumerated list entry.
* @param tmp a pointer to an object of type 'type', which must not be used
* inside the list-execution statement.
* @param list a pointer to a _mali_osk_list_t, from which enumeration will
* begin
* @param type the type of the structure that contains the _mali_osk_list_t
* member that is part of the list to be enumerated.
* @param member the _mali_osk_list_t member of the structure that is part of
* the list to be enumerated.
*/
#define _MALI_OSK_LIST_FOREACHENTRY(ptr, tmp, list, type, member) \
for (ptr = _MALI_OSK_LIST_ENTRY((list)->next, type, member), \
tmp = _MALI_OSK_LIST_ENTRY(ptr->member.next, type, member); \
&ptr->member != (list); \
ptr = tmp, tmp = _MALI_OSK_LIST_ENTRY(tmp->member.next, type, member))
/** @} */ /* end group _mali_osk_list */
/** @addtogroup _mali_osk_miscellaneous
* @{ */
/** @brief The known resource types
*
* @note \b IMPORTANT: these must remain fixed, and only be extended. This is
* because not all systems use a header file for reading in their resources.
* The resources may instead come from a data file where these resources are
* 'hard-coded' in, because there's no easy way of transferring the enum values
* into such data files. E.g. the C-Pre-processor does \em not process enums.
*/
typedef enum _mali_osk_resource_type
{
RESOURCE_TYPE_FIRST =0, /**< Duplicate resource marker for the first resource*/
MEMORY =0, /**< Physically contiguous memory block, not managed by the OS */
OS_MEMORY =1, /**< Memory managed by and shared with the OS */
MALI200 =3, /**< Mali200 Programmable Fragment Shader */
MALIGP2 =4, /**< MaliGP2 Programmable Vertex Shader */
MMU =5, /**< Mali MMU (Memory Management Unit) */
FPGA_FRAMEWORK =6, /**< Mali registers specific to FPGA implementations */
MALI400L2 =7, /**< Mali400 L2 Cache */
MALI300L2 =7, /**< Mali300 L2 Cache */
MALI400GP =8, /**< Mali400 Programmable Vertex Shader Core */
MALI300GP =8, /**< Mali300 Programmable Vertex Shader Core */
MALI400PP =9, /**< Mali400 Programmable Fragment Shader Core */
MALI300PP =9, /**< Mali300 Programmable Fragment Shader Core */
MEM_VALIDATION =10, /**< External Memory Validator */
PMU =11, /**< Power Manangement Unit */
RESOURCE_TYPE_COUNT /**< The total number of known resources */
} _mali_osk_resource_type_t;
/** @brief resource description struct
*
* _mali_osk_resources_init() will enumerate objects of this type. Not all
* members have a valid meaning across all types.
*
* The mmu_id is used to group resources to a certain MMU, since there may be
* more than one MMU in the system, and each resource may be using a different
* MMU:
* - For MMU resources, the setting of mmu_id is a uniquely identifying number.
* - For Other resources, the setting of mmu_id determines which MMU the
* resource uses.
*/
typedef struct _mali_osk_resource
{
_mali_osk_resource_type_t type; /**< type of the resource */
const char * description; /**< short description of the resource */
u32 base; /**< Physical base address of the resource, as seen by Mali resources. */
s32 cpu_usage_adjust; /**< Offset added to the base address of the resource to arrive at the CPU physical address of the resource (if different from the Mali physical address) */
u32 size; /**< Size in bytes of the resource - either the size of its register range, or the size of the memory block. */
u32 irq; /**< IRQ number delivered to the CPU, or -1 to tell the driver to probe for it (if possible) */
u32 flags; /**< Resources-specific flags. */
u32 mmu_id; /**< Identifier for Mali MMU resources. */
u32 alloc_order; /**< Order in which MEMORY/OS_MEMORY resources are used */
} _mali_osk_resource_t;
/** @} */ /* end group _mali_osk_miscellaneous */
#include "mali_kernel_memory_engine.h" /* include for mali_memory_allocation and mali_physical_memory_allocation type */
/** @addtogroup _mali_osk_irq
* @{ */
/** @brief Fake IRQ number for testing purposes
*/
#define _MALI_OSK_IRQ_NUMBER_FAKE ((u32)0xFFFFFFF1)
/** @addtogroup _mali_osk_irq
* @{ */
/** @brief PMM Virtual IRQ number
*/
#define _MALI_OSK_IRQ_NUMBER_PMM ((u32)0xFFFFFFF2)
/** @brief Initialize IRQ handling for a resource
*
* The _mali_osk_irq_t returned must be written into the resource-specific data
* pointed to by data. This is so that the upper and lower handlers can call
* _mali_osk_irq_schedulework().
*
* @note The caller must ensure that the resource does not generate an
* interrupt after _mali_osk_irq_init() finishes, and before the
* _mali_osk_irq_t is written into the resource-specific data. Otherwise,
* the upper-half handler will fail to call _mali_osk_irq_schedulework().
*
* @param irqnum The IRQ number that the resource uses, as seen by the CPU.
* The value -1 has a special meaning which indicates the use of probing, and trigger_func and ack_func must be
* non-NULL.
* @param uhandler The upper-half handler, corresponding to a ISR handler for
* the resource
* @param bhandler The lower-half handler, corresponding to an IST handler for
* the resource
* @param trigger_func Optional: a function to trigger the resource's irq, to
* probe for the interrupt. Use NULL if irqnum != -1.
* @param ack_func Optional: a function to acknowledge the resource's irq, to
* probe for the interrupt. Use NULL if irqnum != -1.
* @param data resource-specific data, which will be passed to uhandler,
* bhandler and (if present) trigger_func and ack_funnc
* @param description textual description of the IRQ resource.
* @return on success, a pointer to a _mali_osk_irq_t object, which represents
* the IRQ handling on this resource. NULL on failure.
*/
_mali_osk_irq_t *_mali_osk_irq_init( u32 irqnum, _mali_osk_irq_uhandler_t uhandler, _mali_osk_irq_bhandler_t bhandler, _mali_osk_irq_trigger_t trigger_func, _mali_osk_irq_ack_t ack_func, void *data, const char *description );
/** @brief Cause a queued, deferred call of the IRQ bottom-half.
*
* _mali_osk_irq_schedulework provides a mechanism for enqueuing deferred calls
* to the IRQ bottom-half handler. The queue is known as the IRQ work-queue.
* After calling _mali_osk_irq_schedulework(), the IRQ bottom-half handler will
* be scheduled to run at some point in the future.
*
* This is called by the IRQ upper-half to defer further processing of
* IRQ-related work to the IRQ bottom-half handler. This is necessary for work
* that cannot be done in an IRQ context by the IRQ upper-half handler. Timer
* callbacks also use this mechanism, because they are treated as though they
* operate in an IRQ context. Refer to \ref _mali_osk_timer_t for more
* information.
*
* Code that operates in a kernel-process context (with no IRQ context
* restrictions) may also enqueue deferred calls to the IRQ bottom-half. The
* advantage over direct calling is that deferred calling allows the caller and
* IRQ bottom half to hold the same mutex, with a guarantee that they will not
* deadlock just by using this mechanism.
*
* _mali_osk_irq_schedulework() places deferred call requests on a queue, to
* allow for more than one thread to make a deferred call. Therfore, if it is
* called 'K' times, then the IRQ bottom-half will be scheduled 'K' times too.
* 'K' is a number that is implementation-specific.
*
* _mali_osk_irq_schedulework() is guaranteed to not block on:
* - enqueuing a deferred call request.
* - the completion of the IRQ bottom-half handler.
*
* This is to prevent deadlock. For example, if _mali_osk_irq_schedulework()
* blocked, then it would cause a deadlock when the following two conditions
* hold:
* - The IRQ bottom-half callback (of type _mali_osk_irq_bhandler_t) locks
* a mutex
* - And, at the same time, the caller of _mali_osk_irq_schedulework() also
* holds the same mutex
*
* @note care must be taken to not overflow the queue that
* _mali_osk_irq_schedulework() operates on. Code must be structured to
* ensure that the number of requests made to the queue is bounded. Otherwise,
* IRQs will be lost.
*
* The queue that _mali_osk_irq_schedulework implements is a FIFO of N-writer,
* 1-reader type. The writers are the callers of _mali_osk_irq_schedulework
* (all OSK-registered IRQ upper-half handlers in the system, watchdog timers,
* callers from a Kernel-process context). The reader is a single thread that
* handles all OSK-registered IRQs.
*
* The consequence of the queue being a 1-reader type is that calling
* _mali_osk_irq_schedulework() on different _mali_osk_irq_t objects causes
* their IRQ bottom-halves to be serialized, across all CPU-cores in the
* system.
*
* @param irq a pointer to the _mali_osk_irq_t object corresponding to the
* resource whose IRQ bottom-half must begin processing.
*/
void _mali_osk_irq_schedulework( _mali_osk_irq_t *irq );
/** @brief Terminate IRQ handling on a resource.
*
* This will disable the interrupt from the device, and then waits for the
* IRQ work-queue to finish the work that is currently in the queue. That is,
* for every deferred call currently in the IRQ work-queue, it waits for each
* of those to be processed by their respective IRQ bottom-half handler.
*
* This function is used to ensure that the bottom-half handler of the supplied
* IRQ object will not be running at the completion of this function call.
* However, the caller must ensure that no other sources could call the
* _mali_osk_irq_schedulework() on the same IRQ object. For example, the
* relevant timers must be stopped.
*
* @note While this function is being called, other OSK-registered IRQs in the
* system may enqueue work for their respective bottom-half handlers. This
* function will not wait for those entries in the work-queue to be flushed.
*
* Since this blocks on the completion of work in the IRQ work-queue, the
* caller of this function \b must \b not hold any mutexes that are taken by
* any OSK-registered IRQ bottom-half handler. To do so may cause a deadlock.
*
* @param irq a pointer to the _mali_osk_irq_t object corresponding to the
* resource whose IRQ handling is to be terminated.
*/
void _mali_osk_irq_term( _mali_osk_irq_t *irq );
/** @brief flushing workqueue.
*
* This will flush the workqueue.
*
* @param irq a pointer to the _mali_osk_irq_t object corresponding to the
* resource whose IRQ handling is to be terminated.
*/
void _mali_osk_flush_workqueue( _mali_osk_irq_t *irq );
/** @} */ /* end group _mali_osk_irq */
/** @addtogroup _mali_osk_atomic
* @{ */
/** @brief Decrement an atomic counter
*
* @note It is an error to decrement the counter beyond -(1<<23)
*
* @param atom pointer to an atomic counter */
void _mali_osk_atomic_dec( _mali_osk_atomic_t *atom );
/** @brief Decrement an atomic counter, return new value
*
* Although the value returned is a u32, only numbers with signed 24-bit
* precision (sign extended to u32) are returned.
*
* @note It is an error to decrement the counter beyond -(1<<23)
*
* @param atom pointer to an atomic counter
* @return The new value, after decrement */
u32 _mali_osk_atomic_dec_return( _mali_osk_atomic_t *atom );
/** @brief Increment an atomic counter
*
* @note It is an error to increment the counter beyond (1<<23)-1
*
* @param atom pointer to an atomic counter */
void _mali_osk_atomic_inc( _mali_osk_atomic_t *atom );
/** @brief Increment an atomic counter, return new value
*
* Although the value returned is a u32, only numbers with signed 24-bit
* precision (sign extended to u32) are returned.
*
* @note It is an error to increment the counter beyond (1<<23)-1
*
* @param atom pointer to an atomic counter */
u32 _mali_osk_atomic_inc_return( _mali_osk_atomic_t *atom );
/** @brief Initialize an atomic counter
*
* The counters have storage for signed 24-bit integers. Initializing to signed
* values requiring more than 24-bits storage will fail.
*
* @note the parameter required is a u32, and so signed integers should be
* cast to u32.
*
* @param atom pointer to an atomic counter
* @param val the value to initialize the atomic counter.
* @return _MALI_OSK_ERR_OK on success, otherwise, a suitable
* _mali_osk_errcode_t on failure.
*/
_mali_osk_errcode_t _mali_osk_atomic_init( _mali_osk_atomic_t *atom, u32 val );
/** @brief Read a value from an atomic counter
*
* Although the value returned is a u32, only numbers with signed 24-bit
* precision (sign extended to u32) are returned.
*
* This can only be safely used to determine the value of the counter when it
* is guaranteed that other threads will not be modifying the counter. This
* makes its usefulness limited.
*
* @param atom pointer to an atomic counter
*/
u32 _mali_osk_atomic_read( _mali_osk_atomic_t *atom );
/** @brief Terminate an atomic counter
*
* @param atom pointer to an atomic counter
*/
void _mali_osk_atomic_term( _mali_osk_atomic_t *atom );
/** @} */ /* end group _mali_osk_atomic */
/** @defgroup _mali_osk_memory OSK Memory Allocation
* @{ */
/** @brief Allocate zero-initialized memory.
*
* Returns a buffer capable of containing at least \a n elements of \a size
* bytes each. The buffer is initialized to zero.
*
* The buffer is suitably aligned for storage and subsequent access of every
* type that the compiler supports. Therefore, the pointer to the start of the
* buffer may be cast into any pointer type, and be subsequently accessed from
* such a pointer, without loss of information.
*
* When the buffer is no longer in use, it must be freed with _mali_osk_free().
* Failure to do so will cause a memory leak.
*
* @note Most toolchains supply memory allocation functions that meet the
* compiler's alignment requirements.
*
* @param n Number of elements to allocate
* @param size Size of each element
* @return On success, the zero-initialized buffer allocated. NULL on failure
*/
void *_mali_osk_calloc( u32 n, u32 size );
/** @brief Allocate memory.
*
* Returns a buffer capable of containing at least \a size bytes. The
* contents of the buffer are undefined.
*
* The buffer is suitably aligned for storage and subsequent access of every
* type that the compiler supports. Therefore, the pointer to the start of the
* buffer may be cast into any pointer type, and be subsequently accessed from
* such a pointer, without loss of information.
*
* When the buffer is no longer in use, it must be freed with _mali_osk_free().
* Failure to do so will cause a memory leak.
*
* @note Most toolchains supply memory allocation functions that meet the
* compiler's alignment requirements.
*
* Remember to free memory using _mali_osk_free().
* @param size Number of bytes to allocate
* @return On success, the buffer allocated. NULL on failure.
*/
void *_mali_osk_malloc( u32 size );
/** @brief Free memory.
*
* Reclaims the buffer pointed to by the parameter \a ptr for the system.
* All memory returned from _mali_osk_malloc() and _mali_osk_calloc()
* must be freed before the application exits. Otherwise,
* a memory leak will occur.
*
* Memory must be freed once. It is an error to free the same non-NULL pointer
* more than once.
*
* It is legal to free the NULL pointer.
*
* @param ptr Pointer to buffer to free
*/
void _mali_osk_free( void *ptr );
/** @brief Copies memory.
*
* Copies the \a len bytes from the buffer pointed by the parameter \a src
* directly to the buffer pointed by \a dst.
*
* It is an error for \a src to overlap \a dst anywhere in \a len bytes.
*
* @param dst Pointer to the destination array where the content is to be
* copied.
* @param src Pointer to the source of data to be copied.
* @param len Number of bytes to copy.
* @return \a dst is always passed through unmodified.
*/
void *_mali_osk_memcpy( void *dst, const void *src, u32 len );
/** @brief Fills memory.
*
* Sets the first \a n bytes of the block of memory pointed to by \a s to
* the specified value
* @param s Pointer to the block of memory to fill.
* @param c Value to be set, passed as u32. Only the 8 Least Significant Bits (LSB)
* are used.
* @param n Number of bytes to be set to the value.
* @return \a s is always passed through unmodified
*/
void *_mali_osk_memset( void *s, u32 c, u32 n );
/** @} */ /* end group _mali_osk_memory */
/** @brief Checks the amount of memory allocated
*
* Checks that not more than \a max_allocated bytes are allocated.
*
* Some OS bring up an interactive out of memory dialogue when the
* system runs out of memory. This can stall non-interactive
* apps (e.g. automated test runs). This function can be used to
* not trigger the OOM dialogue by keeping allocations
* within a certain limit.
*
* @return MALI_TRUE when \a max_allocated bytes are not in use yet. MALI_FALSE
* when at least \a max_allocated bytes are in use.
*/
mali_bool _mali_osk_mem_check_allocated( u32 max_allocated );
/** @addtogroup _mali_osk_lock
* @{ */
/** @brief Initialize a Mutual Exclusion Lock
*
* Locks are created in the signalled (unlocked) state.
*
* initial must be zero, since there is currently no means of expressing
* whether a reader/writer lock should be initially locked as a reader or
* writer. This would require some encoding to be used.
*
* 'Automatic' ordering means that locks must be obtained in the order that
* they were created. For all locks that can be held at the same time, they must
* either all provide the order parameter, or they all must use 'automatic'
* ordering - because there is no way of mixing 'automatic' and 'manual'
* ordering.
*
* @param flags flags combined with bitwise OR ('|'), or zero. There are
* restrictions on which flags can be combined, @see _mali_osk_lock_flags_t.
* @param initial For future expansion into semaphores. SBZ.
* @param order The locking order of the mutex. That is, locks obtained by the
* same thread must have been created with an increasing order parameter, for
* deadlock prevention. Setting to zero causes 'automatic' ordering to be used.
* @return On success, a pointer to a _mali_osk_lock_t object. NULL on failure.
*/
_mali_osk_lock_t *_mali_osk_lock_init( _mali_osk_lock_flags_t flags, u32 initial, u32 order );
/** @brief Wait for a lock to be signalled (obtained)
* After a thread has successfully waited on the lock, the lock is obtained by
* the thread, and is marked as unsignalled. The thread releases the lock by
* signalling it.
*
* In the case of Reader/Writer locks, multiple readers can obtain a lock in
* the absence of writers, which is a performance optimization (providing that
* the readers never write to the protected resource).
*
* To prevent deadlock, locks must always be obtained in the same order.
*
* For locks marked as _MALI_OSK_LOCKFLAG_NONINTERRUPTABLE, it is a
* programming error for the function to exit without obtaining the lock. This
* means that the error code must only be checked for interruptible locks.
*
* @param lock the lock to wait upon (obtain).
* @param mode the mode in which the lock should be obtained. Unless the lock
* was created with _MALI_OSK_LOCKFLAG_READERWRITER, this must be
* _MALI_OSK_LOCKMODE_RW.
* @return On success, _MALI_OSK_ERR_OK. For interruptible locks, a suitable
* _mali_osk_errcode_t will be returned on failure, and the lock will not be
* obtained. In this case, the error code must be propagated up to the U/K
* interface.
*/
_mali_osk_errcode_t _mali_osk_lock_wait( _mali_osk_lock_t *lock, _mali_osk_lock_mode_t mode);
/** @brief Signal (release) a lock
*
* Locks may only be signalled by the thread that originally waited upon the
* lock.
*
* @note In the OSU, a flag exists to allow any thread to signal a
* lock. Such functionality is not present in the OSK.
*
* @param lock the lock to signal (release).
* @param mode the mode in which the lock should be obtained. This must match
* the mode in which the lock was waited upon.
*/
void _mali_osk_lock_signal( _mali_osk_lock_t *lock, _mali_osk_lock_mode_t mode );
/** @brief Terminate a lock
*
* This terminates a lock and frees all associated resources.
*
* It is a programming error to terminate the lock when it is held (unsignalled)
* by a thread.
*
* @param lock the lock to terminate.
*/
void _mali_osk_lock_term( _mali_osk_lock_t *lock );
/** @} */ /* end group _mali_osk_lock */
/** @addtogroup _mali_osk_low_level_memory
* @{ */
/** @brief Issue a memory barrier
*
* This defines an arbitrary memory barrier operation, which affects memory
* mapped by _mali_osk_mem_mapregion. It will not be needed for memory
* mapped through _mali_osk_mem_mapioregion.
*/
void _mali_osk_mem_barrier( void );
/** @brief Map a physically contiguous region into kernel space
*
* This is primarily used for mapping in registers from resources, and Mali-MMU
* page tables. The mapping is only visable from kernel-space.
*
* Access has to go through _mali_osk_mem_ioread32 and _mali_osk_mem_iowrite32
*
* @param phys CPU-physical base address of the memory to map in. This must
* be aligned to the system's page size, which is assumed to be 4K.
* @param size the number of bytes of physically contiguous address space to
* map in
* @param description A textual description of the memory being mapped in.
* @return On success, a Mali IO address through which the mapped-in
* memory/registers can be accessed. NULL on failure.
*/
mali_io_address _mali_osk_mem_mapioregion( u32 phys, u32 size, const char *description );
/** @brief Unmap a physically contiguous address range from kernel space.
*
* The address range should be one previously mapped in through
* _mali_osk_mem_mapioregion.
*
* It is a programming error to do (but not limited to) the following:
* - attempt an unmap twice
* - unmap only part of a range obtained through _mali_osk_mem_mapioregion
* - unmap more than the range obtained through _mali_osk_mem_mapioregion
* - unmap an address range that was not successfully mapped using
* _mali_osk_mem_mapioregion
* - provide a mapping that does not map to phys.
*
* @param phys CPU-physical base address of the memory that was originally
* mapped in. This must be aligned to the system's page size, which is assumed
* to be 4K
* @param size The number of bytes that were originally mapped in.
* @param mapping The Mali IO address through which the mapping is
* accessed.
*/
void _mali_osk_mem_unmapioregion( u32 phys, u32 size, mali_io_address mapping );
/** @brief Allocate and Map a physically contiguous region into kernel space
*
* This is used for allocating physically contiguous regions (such as Mali-MMU
* page tables) and mapping them into kernel space. The mapping is only
* visible from kernel-space.
*
* The alignment of the returned memory is guaranteed to be at least
* _MALI_OSK_CPU_PAGE_SIZE.
*
* Access must go through _mali_osk_mem_ioread32 and _mali_osk_mem_iowrite32
*
* @note This function is primarily to provide support for OSs that are
* incapable of separating the tasks 'allocate physically contiguous memory'
* and 'map it into kernel space'
*
* @param[out] phys CPU-physical base address of memory that was allocated.
* (*phys) will be guaranteed to be aligned to at least
* _MALI_OSK_CPU_PAGE_SIZE on success.
*
* @param[in] size the number of bytes of physically contiguous memory to
* allocate. This must be a multiple of _MALI_OSK_CPU_PAGE_SIZE.
*
* @return On success, a Mali IO address through which the mapped-in
* memory/registers can be accessed. NULL on failure, and (*phys) is unmodified.
*/
mali_io_address _mali_osk_mem_allocioregion( u32 *phys, u32 size );
/** @brief Free a physically contiguous address range from kernel space.
*
* The address range should be one previously mapped in through
* _mali_osk_mem_allocioregion.
*
* It is a programming error to do (but not limited to) the following:
* - attempt a free twice on the same ioregion
* - free only part of a range obtained through _mali_osk_mem_allocioregion
* - free more than the range obtained through _mali_osk_mem_allocioregion
* - free an address range that was not successfully mapped using
* _mali_osk_mem_allocioregion
* - provide a mapping that does not map to phys.
*
* @param phys CPU-physical base address of the memory that was originally
* mapped in, which was aligned to _MALI_OSK_CPU_PAGE_SIZE.
* @param size The number of bytes that were originally mapped in, which was
* a multiple of _MALI_OSK_CPU_PAGE_SIZE.
* @param mapping The Mali IO address through which the mapping is
* accessed.
*/
void _mali_osk_mem_freeioregion( u32 phys, u32 size, mali_io_address mapping );
/** @brief Request a region of physically contiguous memory
*
* This is used to ensure exclusive access to a region of physically contigous
* memory.
*
* It is acceptable to implement this as a stub. However, it is then the job
* of the System Integrator to ensure that no other device driver will be using
* the physical address ranges used by Mali, while the Mali device driver is
* loaded.
*
* @param phys CPU-physical base address of the memory to request. This must
* be aligned to the system's page size, which is assumed to be 4K.
* @param size the number of bytes of physically contiguous address space to
* request.
* @param description A textual description of the memory being requested.
* @return _MALI_OSK_ERR_OK on success. Otherwise, a suitable
* _mali_osk_errcode_t on failure.
*/
_mali_osk_errcode_t _mali_osk_mem_reqregion( u32 phys, u32 size, const char *description );
/** @brief Un-request a region of physically contiguous memory
*
* This is used to release a regious of physically contiguous memory previously
* requested through _mali_osk_mem_reqregion, so that other device drivers may
* use it. This will be called at time of Mali device driver termination.
*
* It is a programming error to attempt to:
* - unrequest a region twice
* - unrequest only part of a range obtained through _mali_osk_mem_reqregion
* - unrequest more than the range obtained through _mali_osk_mem_reqregion
* - unrequest an address range that was not successfully requested using
* _mali_osk_mem_reqregion
*
* @param phys CPU-physical base address of the memory to un-request. This must
* be aligned to the system's page size, which is assumed to be 4K
* @param size the number of bytes of physically contiguous address space to
* un-request.
*/
void _mali_osk_mem_unreqregion( u32 phys, u32 size );
/** @brief Read from a location currently mapped in through
* _mali_osk_mem_mapioregion
*
* This reads a 32-bit word from a 32-bit aligned location. It is a programming
* error to provide unaligned locations, or to read from memory that is not
* mapped in, or not mapped through either _mali_osk_mem_mapioregion() or
* _mali_osk_mem_allocioregion().
*
* @param mapping Mali IO address to read from
* @param offset Byte offset from the given IO address to operate on, must be a multiple of 4
* @return the 32-bit word from the specified location.
*/
u32 _mali_osk_mem_ioread32( volatile mali_io_address mapping, u32 offset );
/** @brief Write to a location currently mapped in through
* _mali_osk_mem_mapioregion
*
* This write a 32-bit word to a 32-bit aligned location. It is a programming
* error to provide unaligned locations, or to write to memory that is not
* mapped in, or not mapped through either _mali_osk_mem_mapioregion() or
* _mali_osk_mem_allocioregion().
*
* @param mapping Mali IO address to write to
* @param offset Byte offset from the given IO address to operate on, must be a multiple of 4
* @param val the 32-bit word to write.
*/
void _mali_osk_mem_iowrite32( volatile mali_io_address mapping, u32 offset, u32 val );
/** @brief Flush all CPU caches
*
* This should only be implemented if flushing of the cache is required for
* memory mapped in through _mali_osk_mem_mapregion.
*/
void _mali_osk_cache_flushall( void );
/** @brief Flush any caches necessary for the CPU and MALI to have the same view of a range of uncached mapped memory
*
* This should only be implemented if your OS doesn't do a full cache flush (inner & outer)
* after allocating uncached mapped memory.
*
* Some OS do not perform a full cache flush (including all outer caches) for uncached mapped memory.
* They zero the memory through a cached mapping, then flush the inner caches but not the outer caches.
* This is required for MALI to have the correct view of the memory.
*/
void _mali_osk_cache_ensure_uncached_range_flushed( void *uncached_mapping, u32 offset, u32 size );
/** @} */ /* end group _mali_osk_low_level_memory */
/** @addtogroup _mali_osk_notification
*
* User space notification framework
*
* Communication with user space of asynchronous events is performed through a
* synchronous call to the \ref u_k_api.
*
* Since the events are asynchronous, the events have to be queued until a
* synchronous U/K API call can be made by user-space. A U/K API call might also
* be received before any event has happened. Therefore the notifications the
* different subsystems wants to send to user space has to be queued for later
* reception, or a U/K API call has to be blocked until an event has occured.
*
* Typical uses of notifications are after running of jobs on the hardware or
* when changes to the system is detected that needs to be relayed to user
* space.
*
* After an event has occured user space has to be notified using some kind of
* message. The notification framework supports sending messages to waiting
* threads or queueing of messages until a U/K API call is made.
*
* The notification queue is a FIFO. There are no restrictions on the numbers
* of readers or writers in the queue.
*
* A message contains what user space needs to identifiy how to handle an
* event. This includes a type field and a possible type specific payload.
*
* A notification to user space is represented by a
* \ref _mali_osk_notification_t object. A sender gets hold of such an object
* using _mali_osk_notification_create(). The buffer given by the
* _mali_osk_notification_t::result_buffer field in the object is used to store
* any type specific data. The other fields are internal to the queue system
* and should not be touched.
*
* @{ */
/** @brief Create a notification object
*
* Returns a notification object which can be added to the queue of
* notifications pending for user space transfer.
*
* The implementation will initialize all members of the
* \ref _mali_osk_notification_t object. In particular, the
* _mali_osk_notification_t::result_buffer member will be initialized to point
* to \a size bytes of storage, and that storage will be suitably aligned for
* storage of any structure. That is, the created buffer meets the same
* requirements as _mali_osk_malloc().
*
* The notification object must be deleted when not in use. Use
* _mali_osk_notification_delete() for deleting it.
*
* @note You \b must \b not call _mali_osk_free() on a \ref _mali_osk_notification_t,
* object, or on a _mali_osk_notification_t::result_buffer. You must only use
* _mali_osk_notification_delete() to free the resources assocaited with a
* \ref _mali_osk_notification_t object.
*
* @param type The notification type
* @param size The size of the type specific buffer to send
* @return Pointer to a notification object with a suitable buffer, or NULL on error.
*/
_mali_osk_notification_t *_mali_osk_notification_create( u32 type, u32 size );
/** @brief Delete a notification object
*
* This must be called to reclaim the resources of a notification object. This
* includes:
* - The _mali_osk_notification_t::result_buffer
* - The \ref _mali_osk_notification_t itself.
*
* A notification object \b must \b not be used after it has been deleted by
* _mali_osk_notification_delete().
*
* In addition, the notification object may not be deleted while it is in a
* queue. That is, if it has been placed on a queue with
* _mali_osk_notification_queue_send(), then it must not be deleted until
* it has been received by a call to _mali_osk_notification_queue_receive().
* Otherwise, the queue may be corrupted.
*
* @param object the notification object to delete.
*/
void _mali_osk_notification_delete( _mali_osk_notification_t *object );
/** @brief Create a notification queue
*
* Creates a notification queue which can be used to queue messages for user
* delivery and get queued messages from
*
* The queue is a FIFO, and has no restrictions on the numbers of readers or
* writers.
*
* When the queue is no longer in use, it must be terminated with
* \ref _mali_osk_notification_queue_term(). Failure to do so will result in a
* memory leak.
*
* @return Pointer to a new notification queue or NULL on error.
*/
_mali_osk_notification_queue_t *_mali_osk_notification_queue_init( void );
/** @brief Destroy a notification queue
*
* Destroys a notification queue and frees associated resources from the queue.
*
* A notification queue \b must \b not be destroyed in the following cases:
* - while there are \ref _mali_osk_notification_t objects in the queue.
* - while there are writers currently acting upon the queue. That is, while
* a thread is currently calling \ref _mali_osk_notification_queue_send() on
* the queue, or while a thread may call
* \ref _mali_osk_notification_queue_send() on the queue in the future.
* - while there are readers currently waiting upon the queue. That is, while
* a thread is currently calling \ref _mali_osk_notification_queue_receive() on
* the queue, or while a thread may call
* \ref _mali_osk_notification_queue_receive() on the queue in the future.
*
* Therefore, all \ref _mali_osk_notification_t objects must be flushed and
* deleted by the code that makes use of the notification queues, since only
* they know the structure of the _mali_osk_notification_t::result_buffer
* (even if it may only be a flat sturcture).
*
* @note Since the queue is a FIFO, the code using notification queues may
* create its own 'flush' type of notification, to assist in flushing the
* queue.
*
* Once the queue has been destroyed, it must not be used again.
*
* @param queue The queue to destroy
*/
void _mali_osk_notification_queue_term( _mali_osk_notification_queue_t *queue );
/** @brief Schedule notification for delivery
*
* When a \ref _mali_osk_notification_t object has been created successfully
* and set up, it may be added to the queue of objects waiting for user space
* transfer.
*
* The sending will not block if the queue is full.
*
* A \ref _mali_osk_notification_t object \b must \b not be put on two different
* queues at the same time, or enqueued twice onto a single queue before
* reception. However, it is acceptable for it to be requeued \em after reception
* from a call to _mali_osk_notification_queue_receive(), even onto the same queue.
*
* Again, requeuing must also not enqueue onto two different queues at the same
* time, or enqueue onto the same queue twice before reception.
*
* @param queue The notification queue to add this notification to
* @param object The entry to add
*/
void _mali_osk_notification_queue_send( _mali_osk_notification_queue_t *queue, _mali_osk_notification_t *object );
#if MALI_STATE_TRACKING
/** @brief Receive a notification from a queue
*
* Check if a notification queue is empty.
*
* @param queue The queue to check.
* @return MALI_TRUE if queue is empty, otherwise MALI_FALSE.
*/
mali_bool _mali_osk_notification_queue_is_empty( _mali_osk_notification_queue_t *queue );
#endif
/** @brief Receive a notification from a queue
*
* Receives a single notification from the given queue.
*
* If no notifciations are ready the thread will sleep until one becomes ready.
* Therefore, notifications may not be received into an
* IRQ or 'atomic' context (that is, a context where sleeping is disallowed).
*
* @param queue The queue to receive from
* @param result Pointer to storage of a pointer of type
* \ref _mali_osk_notification_t*. \a result will be written to such that the
* expression \a (*result) will evaluate to a pointer to a valid
* \ref _mali_osk_notification_t object, or NULL if none were received.
* @return _MALI_OSK_ERR_OK on success. _MALI_OSK_ERR_RESTARTSYSCALL if the sleep was interrupted.
*/
_mali_osk_errcode_t _mali_osk_notification_queue_receive( _mali_osk_notification_queue_t *queue, _mali_osk_notification_t **result );
/** @brief Dequeues a notification from a queue
*
* Receives a single notification from the given queue.
*
* If no notifciations are ready the function call will return an error code.
*
* @param queue The queue to receive from
* @param result Pointer to storage of a pointer of type
* \ref _mali_osk_notification_t*. \a result will be written to such that the
* expression \a (*result) will evaluate to a pointer to a valid
* \ref _mali_osk_notification_t object, or NULL if none were received.
* @return _MALI_OSK_ERR_OK on success, _MALI_OSK_ERR_ITEM_NOT_FOUND if queue was empty.
*/
_mali_osk_errcode_t _mali_osk_notification_queue_dequeue( _mali_osk_notification_queue_t *queue, _mali_osk_notification_t **result );
/** @} */ /* end group _mali_osk_notification */
/** @addtogroup _mali_osk_timer
*
* Timers use the OS's representation of time, which are 'ticks'. This is to
* prevent aliasing problems between the internal timer time, and the time
* asked for.
*
* @{ */
/** @brief Initialize a timer
*
* Allocates resources for a new timer, and initializes them. This does not
* start the timer.
*
* @return a pointer to the allocated timer object, or NULL on failure.
*/
_mali_osk_timer_t *_mali_osk_timer_init(void);
/** @brief Start a timer
*
* It is an error to start a timer without setting the callback via
* _mali_osk_timer_setcallback().
*
* It is an error to use this to start an already started timer.
*
* The timer will expire in \a ticks_to_expire ticks, at which point, the
* callback function will be invoked with the callback-specific data,
* as registered by _mali_osk_timer_setcallback().
*
* @param tim the timer to start
* @param ticks_to_expire the amount of time in ticks for the timer to run
* before triggering.
*/
void _mali_osk_timer_add( _mali_osk_timer_t *tim, u32 ticks_to_expire );
/** @brief Modify a timer
*
* Set the absolute time at which a timer will expire, and start it if it is
* stopped. If \a expiry_tick is in the past (determined by
* _mali_osk_time_after() ), the timer fires immediately.
*
* It is an error to modify a timer without setting the callback via
* _mali_osk_timer_setcallback().
*
* The timer will expire at absolute time \a expiry_tick, at which point, the
* callback function will be invoked with the callback-specific data, as set
* by _mali_osk_timer_setcallback().
*
* @param tim the timer to modify, and start if necessary
* @param expiry_tick the \em absolute time in ticks at which this timer should
* trigger.
*
*/
void _mali_osk_timer_mod( _mali_osk_timer_t *tim, u32 expiry_tick);
/** @brief Stop a timer, and block on its completion.
*
* Stop the timer. When the function returns, it is guaranteed that the timer's
* callback will not be running on any CPU core.
*
* Since stoping the timer blocks on compeletion of the callback, the callback
* may not obtain any mutexes that the caller holds. Otherwise, a deadlock will
* occur.
*
* @note While the callback itself is guaranteed to not be running, work
* enqueued on the IRQ work-queue by the timer (with
* \ref _mali_osk_irq_schedulework()) may still run. The timer callback and IRQ
* bottom-half handler must take this into account.
*
* It is legal to stop an already stopped timer.
*
* @param tim the timer to stop.
*
*/
void _mali_osk_timer_del( _mali_osk_timer_t *tim );
/** @brief Set a timer's callback parameters.
*
* This must be called at least once before a timer is started/modified.
*
* After a timer has been stopped or expires, the callback remains set. This
* means that restarting the timer will call the same function with the same
* parameters on expiry.
*
* @param tim the timer to set callback on.
* @param callback Function to call when timer expires
* @param data Function-specific data to supply to the function on expiry.
*/
void _mali_osk_timer_setcallback( _mali_osk_timer_t *tim, _mali_osk_timer_callback_t callback, void *data );
/** @brief Terminate a timer, and deallocate resources.
*
* The timer must first be stopped by calling _mali_osk_timer_del().
*
* It is a programming error for _mali_osk_timer_term() to be called on:
* - timer that is currently running
* - a timer that is currently executing its callback.
*
* @param tim the timer to deallocate.
*/
void _mali_osk_timer_term( _mali_osk_timer_t *tim );
/** @} */ /* end group _mali_osk_timer */
/** @defgroup _mali_osk_time OSK Time functions
*
* \ref _mali_osk_time use the OS's representation of time, which are
* 'ticks'. This is to prevent aliasing problems between the internal timer
* time, and the time asked for.
*
* OS tick time is measured as a u32. The time stored in a u32 may either be
* an absolute time, or a time delta between two events. Whilst it is valid to
* use math opeartors to \em change the tick value represented as a u32, it
* is often only meaningful to do such operations on time deltas, rather than
* on absolute time. However, it is meaningful to add/subtract time deltas to
* absolute times.
*
* Conversion between tick time and milliseconds (ms) may not be loss-less,
* and are \em implementation \em depenedant.
*
* Code use OS time must take this into account, since:
* - a small OS time may (or may not) be rounded
* - a large time may (or may not) overflow
*
* @{ */
/** @brief Return whether ticka occurs after tickb
*
* Some OSs handle tick 'rollover' specially, and so can be more robust against
* tick counters rolling-over. This function must therefore be called to
* determine if a time (in ticks) really occurs after another time (in ticks).
*
* @param ticka ticka
* @param tickb tickb
* @return non-zero if ticka represents a time that occurs after tickb.
* Zero otherwise.
*/
int _mali_osk_time_after( u32 ticka, u32 tickb );
/** @brief Convert milliseconds to OS 'ticks'
*
* @param ms time interval in milliseconds
* @return the corresponding time interval in OS ticks.
*/
u32 _mali_osk_time_mstoticks( u32 ms );
/** @brief Convert OS 'ticks' to milliseconds
*
* @param ticks time interval in OS ticks.
* @return the corresponding time interval in milliseconds
*/
u32 _mali_osk_time_tickstoms( u32 ticks );
/** @brief Get the current time in OS 'ticks'.
* @return the current time in OS 'ticks'.
*/
u32 _mali_osk_time_tickcount( void );
/** @brief Cause a microsecond delay
*
* The delay will have microsecond resolution, and is necessary for correct
* operation of the driver. At worst, the delay will be \b at least \a usecs
* microseconds, and so may be (significantly) more.
*
* This function may be implemented as a busy-wait, which is the most sensible
* implementation. On OSs where there are situations in which a thread must not
* sleep, this is definitely implemented as a busy-wait.
*
* @param usecs the number of microseconds to wait for.
*/
void _mali_osk_time_ubusydelay( u32 usecs );
/** @brief Return time in nano seconds, since any given reference.
*
* @return Time in nano seconds
*/
u64 _mali_osk_time_get_ns( void );
/** @} */ /* end group _mali_osk_time */
/** @defgroup _mali_osk_math OSK Math
* @{ */
/** @brief Count Leading Zeros (Little-endian)
*
* @note This function must be implemented to support the reference
* implementation of _mali_osk_find_first_zero_bit, as defined in
* mali_osk_bitops.h.
*
* @param val 32-bit words to count leading zeros on
* @return the number of leading zeros.
*/
u32 _mali_osk_clz( u32 val );
/** @} */ /* end group _mali_osk_math */
/** @addtogroup _mali_osk_miscellaneous
* @{ */
/** @brief Output a device driver debug message.
*
* The interpretation of \a fmt is the same as the \c format parameter in
* _mali_osu_vsnprintf().
*
* @param fmt a _mali_osu_vsnprintf() style format string
* @param ... a variable-number of parameters suitable for \a fmt
*/
void _mali_osk_dbgmsg( const char *fmt, ... );
/** @brief Print fmt into buf.
*
* The interpretation of \a fmt is the same as the \c format parameter in
* _mali_osu_vsnprintf().
*
* @param buf a pointer to the result buffer
* @param size the total number of bytes allowed to write to \a buf
* @param fmt a _mali_osu_vsnprintf() style format string
* @param ... a variable-number of parameters suitable for \a fmt
*/
u32 _mali_osk_snprintf( char *buf, u32 size, const char *fmt, ... );
/** @brief Abnormal process abort.
*
* Terminates the caller-process if this function is called.
*
* This function will be called from Debug assert-macros in mali_kernel_common.h.
*
* This function will never return - because to continue from a Debug assert
* could cause even more problems, and hinder debugging of the initial problem.
*
* This function is only used in Debug builds, and is not used in Release builds.
*/
void _mali_osk_abort(void);
/** @brief Sets breakpoint at point where function is called.
*
* This function will be called from Debug assert-macros in mali_kernel_common.h,
* to assist in debugging. If debugging at this level is not required, then this
* function may be implemented as a stub.
*
* This function is only used in Debug builds, and is not used in Release builds.
*/
void _mali_osk_break(void);
/** @brief Return an identificator for calling process.
*
* @return Identificator for calling process.
*/
u32 _mali_osk_get_pid(void);
/** @brief Return an identificator for calling thread.
*
* @return Identificator for calling thread.
*/
u32 _mali_osk_get_tid(void);
/** @} */ /* end group _mali_osk_miscellaneous */
/** @} */ /* end group osuapi */
/** @} */ /* end group uddapi */
#ifdef __cplusplus
}
#endif
#include "mali_osk_specific.h" /* include any per-os specifics */
/* Check standard inlines */
#ifndef MALI_STATIC_INLINE
#error MALI_STATIC_INLINE not defined on your OS
#endif
#ifndef MALI_NON_STATIC_INLINE
#error MALI_NON_STATIC_INLINE not defined on your OS
#endif
#endif /* __MALI_OSK_H__ */