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/* SPDX-License-Identifier: GPL-2.0-only OR MIT */
/* Copyright (c) 2023 Imagination Technologies Ltd. */
#ifndef PVR_DEVICE_H
#define PVR_DEVICE_H
#include "pvr_ccb.h"
#include "pvr_device_info.h"
#include "pvr_fw.h"
#include "pvr_params.h"
#include "pvr_rogue_fwif_stream.h"
#include "pvr_stream.h"
#include <drm/drm_device.h>
#include <drm/drm_file.h>
#include <drm/drm_mm.h>
#include <linux/bits.h>
#include <linux/compiler_attributes.h>
#include <linux/compiler_types.h>
#include <linux/io.h>
#include <linux/iopoll.h>
#include <linux/kernel.h>
#include <linux/math.h>
#include <linux/mutex.h>
#include <linux/spinlock_types.h>
#include <linux/timer.h>
#include <linux/types.h>
#include <linux/wait.h>
#include <linux/workqueue.h>
#include <linux/xarray.h>
/* Forward declaration from <linux/clk.h>. */
struct clk;
/* Forward declaration from <linux/firmware.h>. */
struct firmware;
/**
* struct pvr_gpu_id - Hardware GPU ID information for a PowerVR device
* @b: Branch ID.
* @v: Version ID.
* @n: Number of scalable units.
* @c: Config ID.
*/
struct pvr_gpu_id {
u16 b, v, n, c;
};
/**
* struct pvr_fw_version - Firmware version information
* @major: Major version number.
* @minor: Minor version number.
*/
struct pvr_fw_version {
u16 major, minor;
};
/**
* struct pvr_device - powervr-specific wrapper for &struct drm_device
*/
struct pvr_device {
/**
* @base: The underlying &struct drm_device.
*
* Do not access this member directly, instead call
* from_pvr_device().
*/
struct drm_device base;
/** @gpu_id: GPU ID detected at runtime. */
struct pvr_gpu_id gpu_id;
/**
* @features: Hardware feature information.
*
* Do not access this member directly, instead use PVR_HAS_FEATURE()
* or PVR_FEATURE_VALUE() macros.
*/
struct pvr_device_features features;
/**
* @quirks: Hardware quirk information.
*
* Do not access this member directly, instead use PVR_HAS_QUIRK().
*/
struct pvr_device_quirks quirks;
/**
* @enhancements: Hardware enhancement information.
*
* Do not access this member directly, instead use
* PVR_HAS_ENHANCEMENT().
*/
struct pvr_device_enhancements enhancements;
/** @fw_version: Firmware version detected at runtime. */
struct pvr_fw_version fw_version;
/** @regs_resource: Resource representing device control registers. */
struct resource *regs_resource;
/**
* @regs: Device control registers.
*
* These are mapped into memory when the device is initialized; that
* location is where this pointer points.
*/
void __iomem *regs;
/**
* @core_clk: General core clock.
*
* This is the primary clock used by the entire GPU core.
*/
struct clk *core_clk;
/**
* @sys_clk: Optional system bus clock.
*
* This may be used on some platforms to provide an independent clock to the SoC Interface
* (SOCIF). If present, this needs to be enabled/disabled together with @core_clk.
*/
struct clk *sys_clk;
/**
* @mem_clk: Optional memory clock.
*
* This may be used on some platforms to provide an independent clock to the Memory
* Interface (MEMIF). If present, this needs to be enabled/disabled together with @core_clk.
*/
struct clk *mem_clk;
/** @irq: IRQ number. */
int irq;
/** @fwccb: Firmware CCB. */
struct pvr_ccb fwccb;
/**
* @kernel_vm_ctx: Virtual memory context used for kernel mappings.
*
* This is used for mappings in the firmware address region when a META firmware processor
* is in use.
*
* When a MIPS firmware processor is in use, this will be %NULL.
*/
struct pvr_vm_context *kernel_vm_ctx;
/** @fw_dev: Firmware related data. */
struct pvr_fw_device fw_dev;
/**
* @params: Device-specific parameters.
*
* The values of these parameters are initialized from the
* defaults specified as module parameters. They may be
* modified at runtime via debugfs (if enabled).
*/
struct pvr_device_params params;
/** @stream_musthave_quirks: Bit array of "must-have" quirks for stream commands. */
u32 stream_musthave_quirks[PVR_STREAM_TYPE_MAX][PVR_STREAM_EXTHDR_TYPE_MAX];
/**
* @mmu_flush_cache_flags: Records which MMU caches require flushing
* before submitting the next job.
*/
atomic_t mmu_flush_cache_flags;
/**
* @ctx_ids: Array of contexts belonging to this device. Array members
* are of type "struct pvr_context *".
*
* This array is used to allocate IDs used by the firmware.
*/
struct xarray ctx_ids;
/**
* @free_list_ids: Array of free lists belonging to this device. Array members
* are of type "struct pvr_free_list *".
*
* This array is used to allocate IDs used by the firmware.
*/
struct xarray free_list_ids;
/**
* @job_ids: Array of jobs belonging to this device. Array members
* are of type "struct pvr_job *".
*/
struct xarray job_ids;
/**
* @queues: Queue-related fields.
*/
struct {
/** @queues.active: Active queue list. */
struct list_head active;
/** @queues.idle: Idle queue list. */
struct list_head idle;
/** @queues.lock: Lock protecting access to the active/idle
* lists. */
struct mutex lock;
} queues;
/**
* @watchdog: Watchdog for communications with firmware.
*/
struct {
/** @watchdog.work: Work item for watchdog callback. */
struct delayed_work work;
/**
* @watchdog.old_kccb_cmds_executed: KCCB command execution
* count at last watchdog poll.
*/
u32 old_kccb_cmds_executed;
/**
* @watchdog.kccb_stall_count: Number of watchdog polls
* KCCB has been stalled for.
*/
u32 kccb_stall_count;
} watchdog;
/**
* @kccb: Circular buffer for communications with firmware.
*/
struct {
/** @kccb.ccb: Kernel CCB. */
struct pvr_ccb ccb;
/** @kccb.rtn_q: Waitqueue for KCCB command return waiters. */
wait_queue_head_t rtn_q;
/** @kccb.rtn_obj: Object representing KCCB return slots. */
struct pvr_fw_object *rtn_obj;
/**
* @kccb.rtn: Pointer to CPU mapping of KCCB return slots.
* Must be accessed by READ_ONCE()/WRITE_ONCE().
*/
u32 *rtn;
/** @kccb.slot_count: Total number of KCCB slots available. */
u32 slot_count;
/** @kccb.reserved_count: Number of KCCB slots reserved for
* future use. */
u32 reserved_count;
/**
* @kccb.waiters: List of KCCB slot waiters.
*/
struct list_head waiters;
/** @kccb.fence_ctx: KCCB fence context. */
struct {
/** @kccb.fence_ctx.id: KCCB fence context ID
* allocated with dma_fence_context_alloc(). */
u64 id;
/** @kccb.fence_ctx.seqno: Sequence number incremented
* each time a fence is created. */
atomic_t seqno;
/**
* @kccb.fence_ctx.lock: Lock used to synchronize
* access to fences allocated by this context.
*/
spinlock_t lock;
} fence_ctx;
} kccb;
/**
* @lost: %true if the device has been lost.
*
* This variable is set if the device has become irretrievably unavailable, e.g. if the
* firmware processor has stopped responding and can not be revived via a hard reset.
*/
bool lost;
/**
* @reset_sem: Reset semaphore.
*
* GPU reset code will lock this for writing. Any code that submits commands to the firmware
* that isn't in an IRQ handler or on the scheduler workqueue must lock this for reading.
* Once this has been successfully locked, &pvr_dev->lost _must_ be checked, and -%EIO must
* be returned if it is set.
*/
struct rw_semaphore reset_sem;
/** @sched_wq: Workqueue for schedulers. */
struct workqueue_struct *sched_wq;
/**
* @ctx_list_lock: Lock to be held when accessing the context list in
* struct pvr_file.
*/
spinlock_t ctx_list_lock;
};
/**
* struct pvr_file - powervr-specific data to be assigned to &struct
* drm_file.driver_priv
*/
struct pvr_file {
/**
* @file: A reference to the parent &struct drm_file.
*
* Do not access this member directly, instead call from_pvr_file().
*/
struct drm_file *file;
/**
* @pvr_dev: A reference to the powervr-specific wrapper for the
* associated device. Saves on repeated calls to to_pvr_device().
*/
struct pvr_device *pvr_dev;
/**
* @ctx_handles: Array of contexts belonging to this file. Array members
* are of type "struct pvr_context *".
*
* This array is used to allocate handles returned to userspace.
*/
struct xarray ctx_handles;
/**
* @free_list_handles: Array of free lists belonging to this file. Array
* members are of type "struct pvr_free_list *".
*
* This array is used to allocate handles returned to userspace.
*/
struct xarray free_list_handles;
/**
* @hwrt_handles: Array of HWRT datasets belonging to this file. Array
* members are of type "struct pvr_hwrt_dataset *".
*
* This array is used to allocate handles returned to userspace.
*/
struct xarray hwrt_handles;
/**
* @vm_ctx_handles: Array of VM contexts belonging to this file. Array
* members are of type "struct pvr_vm_context *".
*
* This array is used to allocate handles returned to userspace.
*/
struct xarray vm_ctx_handles;
/** @contexts: PVR context list. */
struct list_head contexts;
};
/**
* PVR_HAS_FEATURE() - Tests whether a PowerVR device has a given feature
* @pvr_dev: [IN] Target PowerVR device.
* @feature: [IN] Hardware feature name.
*
* Feature names are derived from those found in &struct pvr_device_features by
* dropping the 'has_' prefix, which is applied by this macro.
*
* Return:
* * true if the named feature is present in the hardware
* * false if the named feature is not present in the hardware
*/
#define PVR_HAS_FEATURE(pvr_dev, feature) ((pvr_dev)->features.has_##feature)
/**
* PVR_FEATURE_VALUE() - Gets a PowerVR device feature value
* @pvr_dev: [IN] Target PowerVR device.
* @feature: [IN] Feature name.
* @value_out: [OUT] Feature value.
*
* This macro will get a feature value for those features that have values.
* If the feature is not present, nothing will be stored to @value_out.
*
* Feature names are derived from those found in &struct pvr_device_features by
* dropping the 'has_' prefix.
*
* Return:
* * 0 on success, or
* * -%EINVAL if the named feature is not present in the hardware
*/
#define PVR_FEATURE_VALUE(pvr_dev, feature, value_out) \
({ \
struct pvr_device *_pvr_dev = pvr_dev; \
int _ret = -EINVAL; \
if (_pvr_dev->features.has_##feature) { \
*(value_out) = _pvr_dev->features.feature; \
_ret = 0; \
} \
_ret; \
})
/**
* PVR_HAS_QUIRK() - Tests whether a physical device has a given quirk
* @pvr_dev: [IN] Target PowerVR device.
* @quirk: [IN] Hardware quirk name.
*
* Quirk numbers are derived from those found in #pvr_device_quirks by
* dropping the 'has_brn' prefix, which is applied by this macro.
*
* Returns
* * true if the quirk is present in the hardware, or
* * false if the quirk is not present in the hardware.
*/
#define PVR_HAS_QUIRK(pvr_dev, quirk) ((pvr_dev)->quirks.has_brn##quirk)
/**
* PVR_HAS_ENHANCEMENT() - Tests whether a physical device has a given
* enhancement
* @pvr_dev: [IN] Target PowerVR device.
* @enhancement: [IN] Hardware enhancement name.
*
* Enhancement numbers are derived from those found in #pvr_device_enhancements
* by dropping the 'has_ern' prefix, which is applied by this macro.
*
* Returns
* * true if the enhancement is present in the hardware, or
* * false if the enhancement is not present in the hardware.
*/
#define PVR_HAS_ENHANCEMENT(pvr_dev, enhancement) ((pvr_dev)->enhancements.has_ern##enhancement)
#define from_pvr_device(pvr_dev) (&(pvr_dev)->base)
#define to_pvr_device(drm_dev) container_of_const(drm_dev, struct pvr_device, base)
#define from_pvr_file(pvr_file) ((pvr_file)->file)
#define to_pvr_file(file) ((file)->driver_priv)
/**
* PVR_PACKED_BVNC() - Packs B, V, N and C values into a 64-bit unsigned integer
* @b: Branch ID.
* @v: Version ID.
* @n: Number of scalable units.
* @c: Config ID.
*
* The packed layout is as follows:
*
* +--------+--------+--------+-------+
* | 63..48 | 47..32 | 31..16 | 15..0 |
* +========+========+========+=======+
* | B | V | N | C |
* +--------+--------+--------+-------+
*
* pvr_gpu_id_to_packed_bvnc() should be used instead of this macro when a
* &struct pvr_gpu_id is available in order to ensure proper type checking.
*
* Return: Packed BVNC.
*/
/* clang-format off */
#define PVR_PACKED_BVNC(b, v, n, c) \
((((u64)(b) & GENMASK_ULL(15, 0)) << 48) | \
(((u64)(v) & GENMASK_ULL(15, 0)) << 32) | \
(((u64)(n) & GENMASK_ULL(15, 0)) << 16) | \
(((u64)(c) & GENMASK_ULL(15, 0)) << 0))
/* clang-format on */
/**
* pvr_gpu_id_to_packed_bvnc() - Packs B, V, N and C values into a 64-bit
* unsigned integer
* @gpu_id: GPU ID.
*
* The packed layout is as follows:
*
* +--------+--------+--------+-------+
* | 63..48 | 47..32 | 31..16 | 15..0 |
* +========+========+========+=======+
* | B | V | N | C |
* +--------+--------+--------+-------+
*
* This should be used in preference to PVR_PACKED_BVNC() when a &struct
* pvr_gpu_id is available in order to ensure proper type checking.
*
* Return: Packed BVNC.
*/
static __always_inline u64
pvr_gpu_id_to_packed_bvnc(struct pvr_gpu_id *gpu_id)
{
return PVR_PACKED_BVNC(gpu_id->b, gpu_id->v, gpu_id->n, gpu_id->c);
}
static __always_inline void
packed_bvnc_to_pvr_gpu_id(u64 bvnc, struct pvr_gpu_id *gpu_id)
{
gpu_id->b = (bvnc & GENMASK_ULL(63, 48)) >> 48;
gpu_id->v = (bvnc & GENMASK_ULL(47, 32)) >> 32;
gpu_id->n = (bvnc & GENMASK_ULL(31, 16)) >> 16;
gpu_id->c = bvnc & GENMASK_ULL(15, 0);
}
int pvr_device_init(struct pvr_device *pvr_dev);
void pvr_device_fini(struct pvr_device *pvr_dev);
void pvr_device_reset(struct pvr_device *pvr_dev);
bool
pvr_device_has_uapi_quirk(struct pvr_device *pvr_dev, u32 quirk);
bool
pvr_device_has_uapi_enhancement(struct pvr_device *pvr_dev, u32 enhancement);
bool
pvr_device_has_feature(struct pvr_device *pvr_dev, u32 feature);
/**
* PVR_CR_FIELD_GET() - Extract a single field from a PowerVR control register
* @val: Value of the target register.
* @field: Field specifier, as defined in "pvr_rogue_cr_defs.h".
*
* Return: The extracted field.
*/
#define PVR_CR_FIELD_GET(val, field) FIELD_GET(~ROGUE_CR_##field##_CLRMSK, val)
/**
* pvr_cr_read32() - Read a 32-bit register from a PowerVR device
* @pvr_dev: Target PowerVR device.
* @reg: Target register.
*
* Return: The value of the requested register.
*/
static __always_inline u32
pvr_cr_read32(struct pvr_device *pvr_dev, u32 reg)
{
return ioread32(pvr_dev->regs + reg);
}
/**
* pvr_cr_read64() - Read a 64-bit register from a PowerVR device
* @pvr_dev: Target PowerVR device.
* @reg: Target register.
*
* Return: The value of the requested register.
*/
static __always_inline u64
pvr_cr_read64(struct pvr_device *pvr_dev, u32 reg)
{
return ioread64(pvr_dev->regs + reg);
}
/**
* pvr_cr_write32() - Write to a 32-bit register in a PowerVR device
* @pvr_dev: Target PowerVR device.
* @reg: Target register.
* @val: Value to write.
*/
static __always_inline void
pvr_cr_write32(struct pvr_device *pvr_dev, u32 reg, u32 val)
{
iowrite32(val, pvr_dev->regs + reg);
}
/**
* pvr_cr_write64() - Write to a 64-bit register in a PowerVR device
* @pvr_dev: Target PowerVR device.
* @reg: Target register.
* @val: Value to write.
*/
static __always_inline void
pvr_cr_write64(struct pvr_device *pvr_dev, u32 reg, u64 val)
{
iowrite64(val, pvr_dev->regs + reg);
}
/**
* pvr_cr_poll_reg32() - Wait for a 32-bit register to match a given value by
* polling
* @pvr_dev: Target PowerVR device.
* @reg_addr: Address of register.
* @reg_value: Expected register value (after masking).
* @reg_mask: Mask of bits valid for comparison with @reg_value.
* @timeout_usec: Timeout length, in us.
*
* Returns:
* * 0 on success, or
* * -%ETIMEDOUT on timeout.
*/
static __always_inline int
pvr_cr_poll_reg32(struct pvr_device *pvr_dev, u32 reg_addr, u32 reg_value,
u32 reg_mask, u64 timeout_usec)
{
u32 value;
return readl_poll_timeout(pvr_dev->regs + reg_addr, value,
(value & reg_mask) == reg_value, 0, timeout_usec);
}
/**
* pvr_cr_poll_reg64() - Wait for a 64-bit register to match a given value by
* polling
* @pvr_dev: Target PowerVR device.
* @reg_addr: Address of register.
* @reg_value: Expected register value (after masking).
* @reg_mask: Mask of bits valid for comparison with @reg_value.
* @timeout_usec: Timeout length, in us.
*
* Returns:
* * 0 on success, or
* * -%ETIMEDOUT on timeout.
*/
static __always_inline int
pvr_cr_poll_reg64(struct pvr_device *pvr_dev, u32 reg_addr, u64 reg_value,
u64 reg_mask, u64 timeout_usec)
{
u64 value;
return readq_poll_timeout(pvr_dev->regs + reg_addr, value,
(value & reg_mask) == reg_value, 0, timeout_usec);
}
/**
* pvr_round_up_to_cacheline_size() - Round up a provided size to be cacheline
* aligned
* @pvr_dev: Target PowerVR device.
* @size: Initial size, in bytes.
*
* Returns:
* * Size aligned to cacheline size.
*/
static __always_inline size_t
pvr_round_up_to_cacheline_size(struct pvr_device *pvr_dev, size_t size)
{
u16 slc_cacheline_size_bits = 0;
u16 slc_cacheline_size_bytes;
WARN_ON(!PVR_HAS_FEATURE(pvr_dev, slc_cache_line_size_bits));
PVR_FEATURE_VALUE(pvr_dev, slc_cache_line_size_bits,
&slc_cacheline_size_bits);
slc_cacheline_size_bytes = slc_cacheline_size_bits / 8;
return round_up(size, slc_cacheline_size_bytes);
}
/**
* DOC: IOCTL validation helpers
*
* To validate the constraints imposed on IOCTL argument structs, a collection
* of macros and helper functions exist in ``pvr_device.h``.
*
* Of the current helpers, it should only be necessary to call
* PVR_IOCTL_UNION_PADDING_CHECK() directly. This macro should be used once in
* every code path which extracts a union member from a struct passed from
* userspace.
*/
/**
* pvr_ioctl_union_padding_check() - Validate that the implicit padding between
* the end of a union member and the end of the union itself is zeroed.
* @instance: Pointer to the instance of the struct to validate.
* @union_offset: Offset into the type of @instance of the target union. Must
* be 64-bit aligned.
* @union_size: Size of the target union in the type of @instance. Must be
* 64-bit aligned.
* @member_size: Size of the target member in the target union specified by
* @union_offset and @union_size. It is assumed that the offset of the target
* member is zero relative to @union_offset. Must be 64-bit aligned.
*
* You probably want to use PVR_IOCTL_UNION_PADDING_CHECK() instead of calling
* this function directly, since that macro abstracts away much of the setup,
* and also provides some static validation. See its docs for details.
*
* Return:
* * %true if every byte between the end of the used member of the union and
* the end of that union is zeroed, or
* * %false otherwise.
*/
static __always_inline bool
pvr_ioctl_union_padding_check(void *instance, size_t union_offset,
size_t union_size, size_t member_size)
{
/*
* void pointer arithmetic is technically illegal - cast to a byte
* pointer so this addition works safely.
*/
void *padding_start = ((u8 *)instance) + union_offset + member_size;
size_t padding_size = union_size - member_size;
return mem_is_zero(padding_start, padding_size);
}
/**
* PVR_STATIC_ASSERT_64BIT_ALIGNED() - Inline assertion for 64-bit alignment.
* @static_expr_: Target expression to evaluate.
*
* If @static_expr_ does not evaluate to a constant integer which would be a
* 64-bit aligned address (i.e. a multiple of 8), compilation will fail.
*
* Return:
* The value of @static_expr_.
*/
#define PVR_STATIC_ASSERT_64BIT_ALIGNED(static_expr_) \
({ \
static_assert(((static_expr_) & (sizeof(u64) - 1)) == 0); \
(static_expr_); \
})
/**
* PVR_IOCTL_UNION_PADDING_CHECK() - Validate that the implicit padding between
* the end of a union member and the end of the union itself is zeroed.
* @struct_instance_: An expression which evaluates to a pointer to a UAPI data
* struct.
* @union_: The name of the union member of @struct_instance_ to check. If the
* union member is nested within the type of @struct_instance_, this may
* contain the member access operator (".").
* @member_: The name of the member of @union_ to assess.
*
* This is a wrapper around pvr_ioctl_union_padding_check() which performs
* alignment checks and simplifies things for the caller.
*
* Return:
* * %true if every byte in @struct_instance_ between the end of @member_ and
* the end of @union_ is zeroed, or
* * %false otherwise.
*/
#define PVR_IOCTL_UNION_PADDING_CHECK(struct_instance_, union_, member_) \
({ \
typeof(struct_instance_) __instance = (struct_instance_); \
size_t __union_offset = PVR_STATIC_ASSERT_64BIT_ALIGNED( \
offsetof(typeof(*__instance), union_)); \
size_t __union_size = PVR_STATIC_ASSERT_64BIT_ALIGNED( \
sizeof(__instance->union_)); \
size_t __member_size = PVR_STATIC_ASSERT_64BIT_ALIGNED( \
sizeof(__instance->union_.member_)); \
pvr_ioctl_union_padding_check(__instance, __union_offset, \
__union_size, __member_size); \
})
#define PVR_FW_PROCESSOR_TYPE_META 0
#define PVR_FW_PROCESSOR_TYPE_MIPS 1
#define PVR_FW_PROCESSOR_TYPE_RISCV 2
#endif /* PVR_DEVICE_H */