cpu/resctrl/internal.h

/* SPDX-License-Identifier: GPL-2.0 */
#ifndef _ASM_X86_RESCTRL_INTERNAL_H
#define _ASM_X86_RESCTRL_INTERNAL_H

#include <linux/sched.h>
#include <linux/kernfs.h>
#include <linux/fs_context.h>
#include <linux/jump_label.h>

#define MSR_IA32_L3_QOS_CFG		0xc81
#define MSR_IA32_L2_QOS_CFG		0xc82
#define MSR_IA32_L3_CBM_BASE		0xc90
#define MSR_IA32_L2_CBM_BASE		0xd10
#define MSR_IA32_MBA_THRTL_BASE		0xd50
#define MSR_IA32_MBA_BW_BASE		0xc0000200

#define MSR_IA32_QM_CTR			0x0c8e
#define MSR_IA32_QM_EVTSEL		0x0c8d

#define L3_QOS_CDP_ENABLE		0x01ULL

#define L2_QOS_CDP_ENABLE		0x01ULL

/*
 * Event IDs are used to program IA32_QM_EVTSEL before reading event
 * counter from IA32_QM_CTR
 */
#define QOS_L3_OCCUP_EVENT_ID		0x01
#define QOS_L3_MBM_TOTAL_EVENT_ID	0x02
#define QOS_L3_MBM_LOCAL_EVENT_ID	0x03

#define CQM_LIMBOCHECK_INTERVAL	1000

#define MBM_CNTR_WIDTH_BASE		24
#define MBM_OVERFLOW_INTERVAL		1000
#define MAX_MBA_BW			100u
#define MBA_IS_LINEAR			0x4
#define MBA_MAX_MBPS			U32_MAX
#define MAX_MBA_BW_AMD			0x800
#define MBM_CNTR_WIDTH_OFFSET_AMD	20

#define RMID_VAL_ERROR			BIT_ULL(63)
#define RMID_VAL_UNAVAIL		BIT_ULL(62)
/*
 * With the above fields in use 62 bits remain in MSR_IA32_QM_CTR for
 * data to be returned. The counter width is discovered from the hardware
 * as an offset from MBM_CNTR_WIDTH_BASE.
 */
#define MBM_CNTR_WIDTH_OFFSET_MAX (62 - MBM_CNTR_WIDTH_BASE)


struct rdt_fs_context {
	struct kernfs_fs_context	kfc;
	bool				enable_cdpl2;
	bool				enable_cdpl3;
	bool				enable_mba_mbps;
};

static inline struct rdt_fs_context *rdt_fc2context(struct fs_context *fc)
{
	struct kernfs_fs_context *kfc = fc->fs_private;

	return container_of(kfc, struct rdt_fs_context, kfc);
}

DECLARE_STATIC_KEY_FALSE(rdt_enable_key);
DECLARE_STATIC_KEY_FALSE(rdt_mon_enable_key);

/**
 * struct mon_evt - Entry in the event list of a resource
 * @evtid:		event id
 * @name:		name of the event
 */
struct mon_evt {
	u32			evtid;
	char			*name;
	struct list_head	list;
};

/**
 * struct mon_data_bits - Monitoring details for each event file
 * @rid:               Resource id associated with the event file.
 * @evtid:             Event id associated with the event file
 * @domid:             The domain to which the event file belongs
 */
union mon_data_bits {
	void *priv;
	struct {
		unsigned int rid	: 10;
		unsigned int evtid	: 8;
		unsigned int domid	: 14;
	} u;
};

struct rmid_read {
	struct rdtgroup		*rgrp;
	struct rdt_resource	*r;
	struct rdt_domain	*d;
	int			evtid;
	bool			first;
	u64			val;
};

extern unsigned int resctrl_cqm_threshold;
extern bool rdt_alloc_capable;
extern bool rdt_mon_capable;
extern unsigned int rdt_mon_features;

enum rdt_group_type {
	RDTCTRL_GROUP = 0,
	RDTMON_GROUP,
	RDT_NUM_GROUP,
};

/**
 * enum rdtgrp_mode - Mode of a RDT resource group
 * @RDT_MODE_SHAREABLE: This resource group allows sharing of its allocations
 * @RDT_MODE_EXCLUSIVE: No sharing of this resource group's allocations allowed
 * @RDT_MODE_PSEUDO_LOCKSETUP: Resource group will be used for Pseudo-Locking
 * @RDT_MODE_PSEUDO_LOCKED: No sharing of this resource group's allocations
 *                          allowed AND the allocations are Cache Pseudo-Locked
 *
 * The mode of a resource group enables control over the allowed overlap
 * between allocations associated with different resource groups (classes
 * of service). User is able to modify the mode of a resource group by
 * writing to the "mode" resctrl file associated with the resource group.
 *
 * The "shareable", "exclusive", and "pseudo-locksetup" modes are set by
 * writing the appropriate text to the "mode" file. A resource group enters
 * "pseudo-locked" mode after the schemata is written while the resource
 * group is in "pseudo-locksetup" mode.
 */
enum rdtgrp_mode {
	RDT_MODE_SHAREABLE = 0,
	RDT_MODE_EXCLUSIVE,
	RDT_MODE_PSEUDO_LOCKSETUP,
	RDT_MODE_PSEUDO_LOCKED,

	/* Must be last */
	RDT_NUM_MODES,
};

/**
 * struct mongroup - store mon group's data in resctrl fs.
 * @mon_data_kn		kernlfs node for the mon_data directory
 * @parent:			parent rdtgrp
 * @crdtgrp_list:		child rdtgroup node list
 * @rmid:			rmid for this rdtgroup
 */
struct mongroup {
	struct kernfs_node	*mon_data_kn;
	struct rdtgroup		*parent;
	struct list_head	crdtgrp_list;
	u32			rmid;
};

/**
 * struct pseudo_lock_region - pseudo-lock region information
 * @r:			RDT resource to which this pseudo-locked region
 *			belongs
 * @d:			RDT domain to which this pseudo-locked region
 *			belongs
 * @cbm:		bitmask of the pseudo-locked region
 * @lock_thread_wq:	waitqueue used to wait on the pseudo-locking thread
 *			completion
 * @thread_done:	variable used by waitqueue to test if pseudo-locking
 *			thread completed
 * @cpu:		core associated with the cache on which the setup code
 *			will be run
 * @line_size:		size of the cache lines
 * @size:		size of pseudo-locked region in bytes
 * @kmem:		the kernel memory associated with pseudo-locked region
 * @minor:		minor number of character device associated with this
 *			region
 * @debugfs_dir:	pointer to this region's directory in the debugfs
 *			filesystem
 * @pm_reqs:		Power management QoS requests related to this region
 */
struct pseudo_lock_region {
	struct rdt_resource	*r;
	struct rdt_domain	*d;
	u32			cbm;
	wait_queue_head_t	lock_thread_wq;
	int			thread_done;
	int			cpu;
	unsigned int		line_size;
	unsigned int		size;
	void			*kmem;
	unsigned int		minor;
	struct dentry		*debugfs_dir;
	struct list_head	pm_reqs;
};

/**
 * struct rdtgroup - store rdtgroup's data in resctrl file system.
 * @kn:				kernfs node
 * @rdtgroup_list:		linked list for all rdtgroups
 * @closid:			closid for this rdtgroup
 * @cpu_mask:			CPUs assigned to this rdtgroup
 * @flags:			status bits
 * @waitcount:			how many cpus expect to find this
 *				group when they acquire rdtgroup_mutex
 * @type:			indicates type of this rdtgroup - either
 *				monitor only or ctrl_mon group
 * @mon:			mongroup related data
 * @mode:			mode of resource group
 * @plr:			pseudo-locked region
 */
struct rdtgroup {
	struct kernfs_node		*kn;
	struct list_head		rdtgroup_list;
	u32				closid;
	struct cpumask			cpu_mask;
	int				flags;
	atomic_t			waitcount;
	enum rdt_group_type		type;
	struct mongroup			mon;
	enum rdtgrp_mode		mode;
	struct pseudo_lock_region	*plr;
};

/* rdtgroup.flags */
#define	RDT_DELETED		1

/* rftype.flags */
#define RFTYPE_FLAGS_CPUS_LIST	1

/*
 * Define the file type flags for base and info directories.
 */
#define RFTYPE_INFO			BIT(0)
#define RFTYPE_BASE			BIT(1)
#define RF_CTRLSHIFT			4
#define RF_MONSHIFT			5
#define RF_TOPSHIFT			6
#define RFTYPE_CTRL			BIT(RF_CTRLSHIFT)
#define RFTYPE_MON			BIT(RF_MONSHIFT)
#define RFTYPE_TOP			BIT(RF_TOPSHIFT)
#define RFTYPE_RES_CACHE		BIT(8)
#define RFTYPE_RES_MB			BIT(9)
#define RF_CTRL_INFO			(RFTYPE_INFO | RFTYPE_CTRL)
#define RF_MON_INFO			(RFTYPE_INFO | RFTYPE_MON)
#define RF_TOP_INFO			(RFTYPE_INFO | RFTYPE_TOP)
#define RF_CTRL_BASE			(RFTYPE_BASE | RFTYPE_CTRL)

/* List of all resource groups */
extern struct list_head rdt_all_groups;

extern int max_name_width, max_data_width;

int __init rdtgroup_init(void);
void __exit rdtgroup_exit(void);

/**
 * struct rftype - describe each file in the resctrl file system
 * @name:	File name
 * @mode:	Access mode
 * @kf_ops:	File operations
 * @flags:	File specific RFTYPE_FLAGS_* flags
 * @fflags:	File specific RF_* or RFTYPE_* flags
 * @seq_show:	Show content of the file
 * @write:	Write to the file
 */
struct rftype {
	char			*name;
	umode_t			mode;
	const struct kernfs_ops	*kf_ops;
	unsigned long		flags;
	unsigned long		fflags;

	int (*seq_show)(struct kernfs_open_file *of,
			struct seq_file *sf, void *v);
	/*
	 * write() is the generic write callback which maps directly to
	 * kernfs write operation and overrides all other operations.
	 * Maximum write size is determined by ->max_write_len.
	 */
	ssize_t (*write)(struct kernfs_open_file *of,
			 char *buf, size_t nbytes, loff_t off);
};

/**
 * struct mbm_state - status for each MBM counter in each domain
 * @chunks:	Total data moved (multiply by rdt_group.mon_scale to get bytes)
 * @prev_msr	Value of IA32_QM_CTR for this RMID last time we read it
 * @prev_bw_msr:Value of previous IA32_QM_CTR for bandwidth counting
 * @prev_bw	The most recent bandwidth in MBps
 * @delta_bw	Difference between the current and previous bandwidth
 * @delta_comp	Indicates whether to compute the delta_bw
 */
struct mbm_state {
	u64	chunks;
	u64	prev_msr;
	u64	prev_bw_msr;
	u32	prev_bw;
	u32	delta_bw;
	bool	delta_comp;
};

/**
 * struct rdt_domain - group of cpus sharing an RDT resource
 * @list:	all instances of this resource
 * @id:		unique id for this instance
 * @cpu_mask:	which cpus share this resource
 * @rmid_busy_llc:
 *		bitmap of which limbo RMIDs are above threshold
 * @mbm_total:	saved state for MBM total bandwidth
 * @mbm_local:	saved state for MBM local bandwidth
 * @mbm_over:	worker to periodically read MBM h/w counters
 * @cqm_limbo:	worker to periodically read CQM h/w counters
 * @mbm_work_cpu:
 *		worker cpu for MBM h/w counters
 * @cqm_work_cpu:
 *		worker cpu for CQM h/w counters
 * @ctrl_val:	array of cache or mem ctrl values (indexed by CLOSID)
 * @mbps_val:	When mba_sc is enabled, this holds the bandwidth in MBps
 * @new_ctrl:	new ctrl value to be loaded
 * @have_new_ctrl: did user provide new_ctrl for this domain
 * @plr:	pseudo-locked region (if any) associated with domain
 */
struct rdt_domain {
	struct list_head		list;
	int				id;
	struct cpumask			cpu_mask;
	unsigned long			*rmid_busy_llc;
	struct mbm_state		*mbm_total;
	struct mbm_state		*mbm_local;
	struct delayed_work		mbm_over;
	struct delayed_work		cqm_limbo;
	int				mbm_work_cpu;
	int				cqm_work_cpu;
	u32				*ctrl_val;
	u32				*mbps_val;
	u32				new_ctrl;
	bool				have_new_ctrl;
	struct pseudo_lock_region	*plr;
};

/**
 * struct msr_param - set a range of MSRs from a domain
 * @res:       The resource to use
 * @low:       Beginning index from base MSR
 * @high:      End index
 */
struct msr_param {
	struct rdt_resource	*res;
	int			low;
	int			high;
};

/**
 * struct rdt_cache - Cache allocation related data
 * @cbm_len:		Length of the cache bit mask
 * @min_cbm_bits:	Minimum number of consecutive bits to be set
 * @cbm_idx_mult:	Multiplier of CBM index
 * @cbm_idx_offset:	Offset of CBM index. CBM index is computed by:
 *			closid * cbm_idx_multi + cbm_idx_offset
 *			in a cache bit mask
 * @shareable_bits:	Bitmask of shareable resource with other
 *			executing entities
 * @arch_has_sparse_bitmaps:	True if a bitmap like f00f is valid.
 * @arch_has_empty_bitmaps:	True if the '0' bitmap is valid.
 * @arch_has_per_cpu_cfg:	True if QOS_CFG register for this cache
 *				level has CPU scope.
 */
struct rdt_cache {
	unsigned int	cbm_len;
	unsigned int	min_cbm_bits;
	unsigned int	cbm_idx_mult;
	unsigned int	cbm_idx_offset;
	unsigned int	shareable_bits;
	bool		arch_has_sparse_bitmaps;
	bool		arch_has_empty_bitmaps;
	bool		arch_has_per_cpu_cfg;
};

/**
 * enum membw_throttle_mode - System's memory bandwidth throttling mode
 * @THREAD_THROTTLE_UNDEFINED:	Not relevant to the system
 * @THREAD_THROTTLE_MAX:	Memory bandwidth is throttled at the core
 *				always using smallest bandwidth percentage
 *				assigned to threads, aka "max throttling"
 * @THREAD_THROTTLE_PER_THREAD:	Memory bandwidth is throttled at the thread
 */
enum membw_throttle_mode {
	THREAD_THROTTLE_UNDEFINED = 0,
	THREAD_THROTTLE_MAX,
	THREAD_THROTTLE_PER_THREAD,
};

/**
 * struct rdt_membw - Memory bandwidth allocation related data
 * @min_bw:		Minimum memory bandwidth percentage user can request
 * @bw_gran:		Granularity at which the memory bandwidth is allocated
 * @delay_linear:	True if memory B/W delay is in linear scale
 * @arch_needs_linear:	True if we can't configure non-linear resources
 * @throttle_mode:	Bandwidth throttling mode when threads request
 *			different memory bandwidths
 * @mba_sc:		True if MBA software controller(mba_sc) is enabled
 * @mb_map:		Mapping of memory B/W percentage to memory B/W delay
 */
struct rdt_membw {
	u32				min_bw;
	u32				bw_gran;
	u32				delay_linear;
	bool				arch_needs_linear;
	enum membw_throttle_mode	throttle_mode;
	bool				mba_sc;
	u32				*mb_map;
};

static inline bool is_llc_occupancy_enabled(void)
{
	return (rdt_mon_features & (1 << QOS_L3_OCCUP_EVENT_ID));
}

static inline bool is_mbm_total_enabled(void)
{
	return (rdt_mon_features & (1 << QOS_L3_MBM_TOTAL_EVENT_ID));
}

static inline bool is_mbm_local_enabled(void)
{
	return (rdt_mon_features & (1 << QOS_L3_MBM_LOCAL_EVENT_ID));
}

static inline bool is_mbm_enabled(void)
{
	return (is_mbm_total_enabled() || is_mbm_local_enabled());
}

static inline bool is_mbm_event(int e)
{
	return (e >= QOS_L3_MBM_TOTAL_EVENT_ID &&
		e <= QOS_L3_MBM_LOCAL_EVENT_ID);
}

struct rdt_parse_data {
	struct rdtgroup		*rdtgrp;
	char			*buf;
};

/**
 * struct rdt_resource - attributes of an RDT resource
 * @rid:		The index of the resource
 * @alloc_enabled:	Is allocation enabled on this machine
 * @mon_enabled:	Is monitoring enabled for this feature
 * @alloc_capable:	Is allocation available on this machine
 * @mon_capable:	Is monitor feature available on this machine
 * @name:		Name to use in "schemata" file
 * @num_closid:		Number of CLOSIDs available
 * @cache_level:	Which cache level defines scope of this resource
 * @default_ctrl:	Specifies default cache cbm or memory B/W percent.
 * @msr_base:		Base MSR address for CBMs
 * @msr_update:		Function pointer to update QOS MSRs
 * @data_width:		Character width of data when displaying
 * @domains:		All domains for this resource
 * @cache:		Cache allocation related data
 * @format_str:		Per resource format string to show domain value
 * @parse_ctrlval:	Per resource function pointer to parse control values
 * @evt_list:		List of monitoring events
 * @num_rmid:		Number of RMIDs available
 * @mon_scale:		cqm counter * mon_scale = occupancy in bytes
 * @fflags:		flags to choose base and info files
 */
struct rdt_resource {
	int			rid;
	bool			alloc_enabled;
	bool			mon_enabled;
	bool			alloc_capable;
	bool			mon_capable;
	char			*name;
	int			num_closid;
	int			cache_level;
	u32			default_ctrl;
	unsigned int		msr_base;
	void (*msr_update)	(struct rdt_domain *d, struct msr_param *m,
				 struct rdt_resource *r);
	int			data_width;
	struct list_head	domains;
	struct rdt_cache	cache;
	struct rdt_membw	membw;
	const char		*format_str;
	int (*parse_ctrlval)(struct rdt_parse_data *data,
			     struct rdt_resource *r,
			     struct rdt_domain *d);
	struct list_head	evt_list;
	int			num_rmid;
	unsigned int		mon_scale;
	unsigned int		mbm_width;
	unsigned long		fflags;
};

int parse_cbm(struct rdt_parse_data *data, struct rdt_resource *r,
	      struct rdt_domain *d);
int parse_bw(struct rdt_parse_data *data, struct rdt_resource *r,
	     struct rdt_domain *d);

extern struct mutex rdtgroup_mutex;

extern struct rdt_resource rdt_resources_all[];
extern struct rdtgroup rdtgroup_default;
DECLARE_STATIC_KEY_FALSE(rdt_alloc_enable_key);

extern struct dentry *debugfs_resctrl;

enum {
	RDT_RESOURCE_L3,
	RDT_RESOURCE_L3DATA,
	RDT_RESOURCE_L3CODE,
	RDT_RESOURCE_L2,
	RDT_RESOURCE_L2DATA,
	RDT_RESOURCE_L2CODE,
	RDT_RESOURCE_MBA,

	/* Must be the last */
	RDT_NUM_RESOURCES,
};

#define for_each_rdt_resource(r)					      \
	for (r = rdt_resources_all; r < rdt_resources_all + RDT_NUM_RESOURCES;\
	     r++)

#define for_each_capable_rdt_resource(r)				      \
	for (r = rdt_resources_all; r < rdt_resources_all + RDT_NUM_RESOURCES;\
	     r++)							      \
		if (r->alloc_capable || r->mon_capable)

#define for_each_alloc_capable_rdt_resource(r)				      \
	for (r = rdt_resources_all; r < rdt_resources_all + RDT_NUM_RESOURCES;\
	     r++)							      \
		if (r->alloc_capable)

#define for_each_mon_capable_rdt_resource(r)				      \
	for (r = rdt_resources_all; r < rdt_resources_all + RDT_NUM_RESOURCES;\
	     r++)							      \
		if (r->mon_capable)

#define for_each_alloc_enabled_rdt_resource(r)				      \
	for (r = rdt_resources_all; r < rdt_resources_all + RDT_NUM_RESOURCES;\
	     r++)							      \
		if (r->alloc_enabled)

#define for_each_mon_enabled_rdt_resource(r)				      \
	for (r = rdt_resources_all; r < rdt_resources_all + RDT_NUM_RESOURCES;\
	     r++)							      \
		if (r->mon_enabled)

/* CPUID.(EAX=10H, ECX=ResID=1).EAX */
union cpuid_0x10_1_eax {
	struct {
		unsigned int cbm_len:5;
	} split;
	unsigned int full;
};

/* CPUID.(EAX=10H, ECX=ResID=3).EAX */
union cpuid_0x10_3_eax {
	struct {
		unsigned int max_delay:12;
	} split;
	unsigned int full;
};

/* CPUID.(EAX=10H, ECX=ResID).EDX */
union cpuid_0x10_x_edx {
	struct {
		unsigned int cos_max:16;
	} split;
	unsigned int full;
};

void rdt_last_cmd_clear(void);
void rdt_last_cmd_puts(const char *s);
__printf(1, 2)
void rdt_last_cmd_printf(const char *fmt, ...);

void rdt_ctrl_update(void *arg);
struct rdtgroup *rdtgroup_kn_lock_live(struct kernfs_node *kn);
void rdtgroup_kn_unlock(struct kernfs_node *kn);
int rdtgroup_kn_mode_restrict(struct rdtgroup *r, const char *name);
int rdtgroup_kn_mode_restore(struct rdtgroup *r, const char *name,
			     umode_t mask);
struct rdt_domain *rdt_find_domain(struct rdt_resource *r, int id,
				   struct list_head **pos);
ssize_t rdtgroup_schemata_write(struct kernfs_open_file *of,
				char *buf, size_t nbytes, loff_t off);
int rdtgroup_schemata_show(struct kernfs_open_file *of,
			   struct seq_file *s, void *v);
bool rdtgroup_cbm_overlaps(struct rdt_resource *r, struct rdt_domain *d,
			   unsigned long cbm, int closid, bool exclusive);
unsigned int rdtgroup_cbm_to_size(struct rdt_resource *r, struct rdt_domain *d,
				  unsigned long cbm);
enum rdtgrp_mode rdtgroup_mode_by_closid(int closid);
int rdtgroup_tasks_assigned(struct rdtgroup *r);
int rdtgroup_locksetup_enter(struct rdtgroup *rdtgrp);
int rdtgroup_locksetup_exit(struct rdtgroup *rdtgrp);
bool rdtgroup_cbm_overlaps_pseudo_locked(struct rdt_domain *d, unsigned long cbm);
bool rdtgroup_pseudo_locked_in_hierarchy(struct rdt_domain *d);
int rdt_pseudo_lock_init(void);
void rdt_pseudo_lock_release(void);
int rdtgroup_pseudo_lock_create(struct rdtgroup *rdtgrp);
void rdtgroup_pseudo_lock_remove(struct rdtgroup *rdtgrp);
struct rdt_domain *get_domain_from_cpu(int cpu, struct rdt_resource *r);
int update_domains(struct rdt_resource *r, int closid);
int closids_supported(void);
void closid_free(int closid);
int alloc_rmid(void);
void free_rmid(u32 rmid);
int rdt_get_mon_l3_config(struct rdt_resource *r);
void mon_event_count(void *info);
int rdtgroup_mondata_show(struct seq_file *m, void *arg);
void rmdir_mondata_subdir_allrdtgrp(struct rdt_resource *r,
				    unsigned int dom_id);
void mkdir_mondata_subdir_allrdtgrp(struct rdt_resource *r,
				    struct rdt_domain *d);
void mon_event_read(struct rmid_read *rr, struct rdt_resource *r,
		    struct rdt_domain *d, struct rdtgroup *rdtgrp,
		    int evtid, int first);
void mbm_setup_overflow_handler(struct rdt_domain *dom,
				unsigned long delay_ms);
void mbm_handle_overflow(struct work_struct *work);
void __init intel_rdt_mbm_apply_quirk(void);
bool is_mba_sc(struct rdt_resource *r);
void setup_default_ctrlval(struct rdt_resource *r, u32 *dc, u32 *dm);
u32 delay_bw_map(unsigned long bw, struct rdt_resource *r);
void cqm_setup_limbo_handler(struct rdt_domain *dom, unsigned long delay_ms);
void cqm_handle_limbo(struct work_struct *work);
bool has_busy_rmid(struct rdt_resource *r, struct rdt_domain *d);
void __check_limbo(struct rdt_domain *d, bool force_free);
void rdt_domain_reconfigure_cdp(struct rdt_resource *r);
void __init thread_throttle_mode_init(void);

#endif /* _ASM_X86_RESCTRL_INTERNAL_H */