提交 11f1ceca 编写于 作者: G Georgi Djakov 提交者: Greg Kroah-Hartman

interconnect: Add generic on-chip interconnect API

This patch introduces a new API to get requirements and configure the
interconnect buses across the entire chipset to fit with the current
demand.

The API is using a consumer/provider-based model, where the providers are
the interconnect buses and the consumers could be various drivers.
The consumers request interconnect resources (path) between endpoints and
set the desired constraints on this data flow path. The providers receive
requests from consumers and aggregate these requests for all master-slave
pairs on that path. Then the providers configure each node along the path
to support a bandwidth that satisfies all bandwidth requests that cross
through that node. The topology could be complicated and multi-tiered and
is SoC specific.
Reviewed-by: NEvan Green <evgreen@chromium.org>
Signed-off-by: NGeorgi Djakov <georgi.djakov@linaro.org>
Signed-off-by: NGreg Kroah-Hartman <gregkh@linuxfoundation.org>
上级 2ca46ed2
.. SPDX-License-Identifier: GPL-2.0
=====================================
GENERIC SYSTEM INTERCONNECT SUBSYSTEM
=====================================
Introduction
------------
This framework is designed to provide a standard kernel interface to control
the settings of the interconnects on an SoC. These settings can be throughput,
latency and priority between multiple interconnected devices or functional
blocks. This can be controlled dynamically in order to save power or provide
maximum performance.
The interconnect bus is hardware with configurable parameters, which can be
set on a data path according to the requests received from various drivers.
An example of interconnect buses are the interconnects between various
components or functional blocks in chipsets. There can be multiple interconnects
on an SoC that can be multi-tiered.
Below is a simplified diagram of a real-world SoC interconnect bus topology.
::
+----------------+ +----------------+
| HW Accelerator |--->| M NoC |<---------------+
+----------------+ +----------------+ |
| | +------------+
+-----+ +-------------+ V +------+ | |
| DDR | | +--------+ | PCIe | | |
+-----+ | | Slaves | +------+ | |
^ ^ | +--------+ | | C NoC |
| | V V | |
+------------------+ +------------------------+ | | +-----+
| |-->| |-->| |-->| CPU |
| |-->| |<--| | +-----+
| Mem NoC | | S NoC | +------------+
| |<--| |---------+ |
| |<--| |<------+ | | +--------+
+------------------+ +------------------------+ | | +-->| Slaves |
^ ^ ^ ^ ^ | | +--------+
| | | | | | V
+------+ | +-----+ +-----+ +---------+ +----------------+ +--------+
| CPUs | | | GPU | | DSP | | Masters |-->| P NoC |-->| Slaves |
+------+ | +-----+ +-----+ +---------+ +----------------+ +--------+
|
+-------+
| Modem |
+-------+
Terminology
-----------
Interconnect provider is the software definition of the interconnect hardware.
The interconnect providers on the above diagram are M NoC, S NoC, C NoC, P NoC
and Mem NoC.
Interconnect node is the software definition of the interconnect hardware
port. Each interconnect provider consists of multiple interconnect nodes,
which are connected to other SoC components including other interconnect
providers. The point on the diagram where the CPUs connect to the memory is
called an interconnect node, which belongs to the Mem NoC interconnect provider.
Interconnect endpoints are the first or the last element of the path. Every
endpoint is a node, but not every node is an endpoint.
Interconnect path is everything between two endpoints including all the nodes
that have to be traversed to reach from a source to destination node. It may
include multiple master-slave pairs across several interconnect providers.
Interconnect consumers are the entities which make use of the data paths exposed
by the providers. The consumers send requests to providers requesting various
throughput, latency and priority. Usually the consumers are device drivers, that
send request based on their needs. An example for a consumer is a video decoder
that supports various formats and image sizes.
Interconnect providers
----------------------
Interconnect provider is an entity that implements methods to initialize and
configure interconnect bus hardware. The interconnect provider drivers should
be registered with the interconnect provider core.
.. kernel-doc:: include/linux/interconnect-provider.h
Interconnect consumers
----------------------
Interconnect consumers are the clients which use the interconnect APIs to
get paths between endpoints and set their bandwidth/latency/QoS requirements
for these interconnect paths.
.. kernel-doc:: include/linux/interconnect.h
...@@ -228,4 +228,6 @@ source "drivers/siox/Kconfig" ...@@ -228,4 +228,6 @@ source "drivers/siox/Kconfig"
source "drivers/slimbus/Kconfig" source "drivers/slimbus/Kconfig"
source "drivers/interconnect/Kconfig"
endmenu endmenu
...@@ -186,3 +186,4 @@ obj-$(CONFIG_MULTIPLEXER) += mux/ ...@@ -186,3 +186,4 @@ obj-$(CONFIG_MULTIPLEXER) += mux/
obj-$(CONFIG_UNISYS_VISORBUS) += visorbus/ obj-$(CONFIG_UNISYS_VISORBUS) += visorbus/
obj-$(CONFIG_SIOX) += siox/ obj-$(CONFIG_SIOX) += siox/
obj-$(CONFIG_GNSS) += gnss/ obj-$(CONFIG_GNSS) += gnss/
obj-$(CONFIG_INTERCONNECT) += interconnect/
menuconfig INTERCONNECT
tristate "On-Chip Interconnect management support"
help
Support for management of the on-chip interconnects.
This framework is designed to provide a generic interface for
managing the interconnects in a SoC.
If unsure, say no.
# SPDX-License-Identifier: GPL-2.0
icc-core-objs := core.o
obj-$(CONFIG_INTERCONNECT) += icc-core.o
// SPDX-License-Identifier: GPL-2.0
/*
* Interconnect framework core driver
*
* Copyright (c) 2017-2019, Linaro Ltd.
* Author: Georgi Djakov <georgi.djakov@linaro.org>
*/
#include <linux/device.h>
#include <linux/idr.h>
#include <linux/init.h>
#include <linux/interconnect.h>
#include <linux/interconnect-provider.h>
#include <linux/list.h>
#include <linux/module.h>
#include <linux/mutex.h>
#include <linux/slab.h>
#include <linux/overflow.h>
static DEFINE_IDR(icc_idr);
static LIST_HEAD(icc_providers);
static DEFINE_MUTEX(icc_lock);
/**
* struct icc_req - constraints that are attached to each node
* @req_node: entry in list of requests for the particular @node
* @node: the interconnect node to which this constraint applies
* @dev: reference to the device that sets the constraints
* @avg_bw: an integer describing the average bandwidth in kBps
* @peak_bw: an integer describing the peak bandwidth in kBps
*/
struct icc_req {
struct hlist_node req_node;
struct icc_node *node;
struct device *dev;
u32 avg_bw;
u32 peak_bw;
};
/**
* struct icc_path - interconnect path structure
* @num_nodes: number of hops (nodes)
* @reqs: array of the requests applicable to this path of nodes
*/
struct icc_path {
size_t num_nodes;
struct icc_req reqs[];
};
static struct icc_node *node_find(const int id)
{
return idr_find(&icc_idr, id);
}
static struct icc_path *path_init(struct device *dev, struct icc_node *dst,
ssize_t num_nodes)
{
struct icc_node *node = dst;
struct icc_path *path;
int i;
path = kzalloc(struct_size(path, reqs, num_nodes), GFP_KERNEL);
if (!path)
return ERR_PTR(-ENOMEM);
path->num_nodes = num_nodes;
for (i = num_nodes - 1; i >= 0; i--) {
node->provider->users++;
hlist_add_head(&path->reqs[i].req_node, &node->req_list);
path->reqs[i].node = node;
path->reqs[i].dev = dev;
/* reference to previous node was saved during path traversal */
node = node->reverse;
}
return path;
}
static struct icc_path *path_find(struct device *dev, struct icc_node *src,
struct icc_node *dst)
{
struct icc_path *path = ERR_PTR(-EPROBE_DEFER);
struct icc_node *n, *node = NULL;
struct list_head traverse_list;
struct list_head edge_list;
struct list_head visited_list;
size_t i, depth = 1;
bool found = false;
INIT_LIST_HEAD(&traverse_list);
INIT_LIST_HEAD(&edge_list);
INIT_LIST_HEAD(&visited_list);
list_add(&src->search_list, &traverse_list);
src->reverse = NULL;
do {
list_for_each_entry_safe(node, n, &traverse_list, search_list) {
if (node == dst) {
found = true;
list_splice_init(&edge_list, &visited_list);
list_splice_init(&traverse_list, &visited_list);
break;
}
for (i = 0; i < node->num_links; i++) {
struct icc_node *tmp = node->links[i];
if (!tmp) {
path = ERR_PTR(-ENOENT);
goto out;
}
if (tmp->is_traversed)
continue;
tmp->is_traversed = true;
tmp->reverse = node;
list_add_tail(&tmp->search_list, &edge_list);
}
}
if (found)
break;
list_splice_init(&traverse_list, &visited_list);
list_splice_init(&edge_list, &traverse_list);
/* count the hops including the source */
depth++;
} while (!list_empty(&traverse_list));
out:
/* reset the traversed state */
list_for_each_entry_reverse(n, &visited_list, search_list)
n->is_traversed = false;
if (found)
path = path_init(dev, dst, depth);
return path;
}
/*
* We want the path to honor all bandwidth requests, so the average and peak
* bandwidth requirements from each consumer are aggregated at each node.
* The aggregation is platform specific, so each platform can customize it by
* implementing its own aggregate() function.
*/
static int aggregate_requests(struct icc_node *node)
{
struct icc_provider *p = node->provider;
struct icc_req *r;
node->avg_bw = 0;
node->peak_bw = 0;
hlist_for_each_entry(r, &node->req_list, req_node)
p->aggregate(node, r->avg_bw, r->peak_bw,
&node->avg_bw, &node->peak_bw);
return 0;
}
static int apply_constraints(struct icc_path *path)
{
struct icc_node *next, *prev = NULL;
int ret = -EINVAL;
int i;
for (i = 0; i < path->num_nodes; i++) {
next = path->reqs[i].node;
/*
* Both endpoints should be valid master-slave pairs of the
* same interconnect provider that will be configured.
*/
if (!prev || next->provider != prev->provider) {
prev = next;
continue;
}
/* set the constraints */
ret = next->provider->set(prev, next);
if (ret)
goto out;
prev = next;
}
out:
return ret;
}
/**
* icc_set_bw() - set bandwidth constraints on an interconnect path
* @path: reference to the path returned by icc_get()
* @avg_bw: average bandwidth in kilobytes per second
* @peak_bw: peak bandwidth in kilobytes per second
*
* This function is used by an interconnect consumer to express its own needs
* in terms of bandwidth for a previously requested path between two endpoints.
* The requests are aggregated and each node is updated accordingly. The entire
* path is locked by a mutex to ensure that the set() is completed.
* The @path can be NULL when the "interconnects" DT properties is missing,
* which will mean that no constraints will be set.
*
* Returns 0 on success, or an appropriate error code otherwise.
*/
int icc_set_bw(struct icc_path *path, u32 avg_bw, u32 peak_bw)
{
struct icc_node *node;
size_t i;
int ret;
if (!path)
return 0;
mutex_lock(&icc_lock);
for (i = 0; i < path->num_nodes; i++) {
node = path->reqs[i].node;
/* update the consumer request for this path */
path->reqs[i].avg_bw = avg_bw;
path->reqs[i].peak_bw = peak_bw;
/* aggregate requests for this node */
aggregate_requests(node);
}
ret = apply_constraints(path);
if (ret)
pr_debug("interconnect: error applying constraints (%d)\n",
ret);
mutex_unlock(&icc_lock);
return ret;
}
EXPORT_SYMBOL_GPL(icc_set_bw);
/**
* icc_get() - return a handle for path between two endpoints
* @dev: the device requesting the path
* @src_id: source device port id
* @dst_id: destination device port id
*
* This function will search for a path between two endpoints and return an
* icc_path handle on success. Use icc_put() to release
* constraints when they are not needed anymore.
* If the interconnect API is disabled, NULL is returned and the consumer
* drivers will still build. Drivers are free to handle this specifically,
* but they don't have to.
*
* Return: icc_path pointer on success, ERR_PTR() on error or NULL if the
* interconnect API is disabled.
*/
struct icc_path *icc_get(struct device *dev, const int src_id, const int dst_id)
{
struct icc_node *src, *dst;
struct icc_path *path = ERR_PTR(-EPROBE_DEFER);
mutex_lock(&icc_lock);
src = node_find(src_id);
if (!src)
goto out;
dst = node_find(dst_id);
if (!dst)
goto out;
path = path_find(dev, src, dst);
if (IS_ERR(path))
dev_err(dev, "%s: invalid path=%ld\n", __func__, PTR_ERR(path));
out:
mutex_unlock(&icc_lock);
return path;
}
EXPORT_SYMBOL_GPL(icc_get);
/**
* icc_put() - release the reference to the icc_path
* @path: interconnect path
*
* Use this function to release the constraints on a path when the path is
* no longer needed. The constraints will be re-aggregated.
*/
void icc_put(struct icc_path *path)
{
struct icc_node *node;
size_t i;
int ret;
if (!path || WARN_ON(IS_ERR(path)))
return;
ret = icc_set_bw(path, 0, 0);
if (ret)
pr_err("%s: error (%d)\n", __func__, ret);
mutex_lock(&icc_lock);
for (i = 0; i < path->num_nodes; i++) {
node = path->reqs[i].node;
hlist_del(&path->reqs[i].req_node);
if (!WARN_ON(!node->provider->users))
node->provider->users--;
}
mutex_unlock(&icc_lock);
kfree(path);
}
EXPORT_SYMBOL_GPL(icc_put);
static struct icc_node *icc_node_create_nolock(int id)
{
struct icc_node *node;
/* check if node already exists */
node = node_find(id);
if (node)
return node;
node = kzalloc(sizeof(*node), GFP_KERNEL);
if (!node)
return ERR_PTR(-ENOMEM);
id = idr_alloc(&icc_idr, node, id, id + 1, GFP_KERNEL);
if (id < 0) {
WARN(1, "%s: couldn't get idr\n", __func__);
kfree(node);
return ERR_PTR(id);
}
node->id = id;
return node;
}
/**
* icc_node_create() - create a node
* @id: node id
*
* Return: icc_node pointer on success, or ERR_PTR() on error
*/
struct icc_node *icc_node_create(int id)
{
struct icc_node *node;
mutex_lock(&icc_lock);
node = icc_node_create_nolock(id);
mutex_unlock(&icc_lock);
return node;
}
EXPORT_SYMBOL_GPL(icc_node_create);
/**
* icc_node_destroy() - destroy a node
* @id: node id
*/
void icc_node_destroy(int id)
{
struct icc_node *node;
mutex_lock(&icc_lock);
node = node_find(id);
if (node) {
idr_remove(&icc_idr, node->id);
WARN_ON(!hlist_empty(&node->req_list));
}
mutex_unlock(&icc_lock);
kfree(node);
}
EXPORT_SYMBOL_GPL(icc_node_destroy);
/**
* icc_link_create() - create a link between two nodes
* @node: source node id
* @dst_id: destination node id
*
* Create a link between two nodes. The nodes might belong to different
* interconnect providers and the @dst_id node might not exist (if the
* provider driver has not probed yet). So just create the @dst_id node
* and when the actual provider driver is probed, the rest of the node
* data is filled.
*
* Return: 0 on success, or an error code otherwise
*/
int icc_link_create(struct icc_node *node, const int dst_id)
{
struct icc_node *dst;
struct icc_node **new;
int ret = 0;
if (!node->provider)
return -EINVAL;
mutex_lock(&icc_lock);
dst = node_find(dst_id);
if (!dst) {
dst = icc_node_create_nolock(dst_id);
if (IS_ERR(dst)) {
ret = PTR_ERR(dst);
goto out;
}
}
new = krealloc(node->links,
(node->num_links + 1) * sizeof(*node->links),
GFP_KERNEL);
if (!new) {
ret = -ENOMEM;
goto out;
}
node->links = new;
node->links[node->num_links++] = dst;
out:
mutex_unlock(&icc_lock);
return ret;
}
EXPORT_SYMBOL_GPL(icc_link_create);
/**
* icc_link_destroy() - destroy a link between two nodes
* @src: pointer to source node
* @dst: pointer to destination node
*
* Return: 0 on success, or an error code otherwise
*/
int icc_link_destroy(struct icc_node *src, struct icc_node *dst)
{
struct icc_node **new;
size_t slot;
int ret = 0;
if (IS_ERR_OR_NULL(src))
return -EINVAL;
if (IS_ERR_OR_NULL(dst))
return -EINVAL;
mutex_lock(&icc_lock);
for (slot = 0; slot < src->num_links; slot++)
if (src->links[slot] == dst)
break;
if (WARN_ON(slot == src->num_links)) {
ret = -ENXIO;
goto out;
}
src->links[slot] = src->links[--src->num_links];
new = krealloc(src->links, src->num_links * sizeof(*src->links),
GFP_KERNEL);
if (new)
src->links = new;
out:
mutex_unlock(&icc_lock);
return ret;
}
EXPORT_SYMBOL_GPL(icc_link_destroy);
/**
* icc_node_add() - add interconnect node to interconnect provider
* @node: pointer to the interconnect node
* @provider: pointer to the interconnect provider
*/
void icc_node_add(struct icc_node *node, struct icc_provider *provider)
{
mutex_lock(&icc_lock);
node->provider = provider;
list_add_tail(&node->node_list, &provider->nodes);
mutex_unlock(&icc_lock);
}
EXPORT_SYMBOL_GPL(icc_node_add);
/**
* icc_node_del() - delete interconnect node from interconnect provider
* @node: pointer to the interconnect node
*/
void icc_node_del(struct icc_node *node)
{
mutex_lock(&icc_lock);
list_del(&node->node_list);
mutex_unlock(&icc_lock);
}
EXPORT_SYMBOL_GPL(icc_node_del);
/**
* icc_provider_add() - add a new interconnect provider
* @provider: the interconnect provider that will be added into topology
*
* Return: 0 on success, or an error code otherwise
*/
int icc_provider_add(struct icc_provider *provider)
{
if (WARN_ON(!provider->set))
return -EINVAL;
mutex_lock(&icc_lock);
INIT_LIST_HEAD(&provider->nodes);
list_add_tail(&provider->provider_list, &icc_providers);
mutex_unlock(&icc_lock);
dev_dbg(provider->dev, "interconnect provider added to topology\n");
return 0;
}
EXPORT_SYMBOL_GPL(icc_provider_add);
/**
* icc_provider_del() - delete previously added interconnect provider
* @provider: the interconnect provider that will be removed from topology
*
* Return: 0 on success, or an error code otherwise
*/
int icc_provider_del(struct icc_provider *provider)
{
mutex_lock(&icc_lock);
if (provider->users) {
pr_warn("interconnect provider still has %d users\n",
provider->users);
mutex_unlock(&icc_lock);
return -EBUSY;
}
if (!list_empty(&provider->nodes)) {
pr_warn("interconnect provider still has nodes\n");
mutex_unlock(&icc_lock);
return -EBUSY;
}
list_del(&provider->provider_list);
mutex_unlock(&icc_lock);
return 0;
}
EXPORT_SYMBOL_GPL(icc_provider_del);
MODULE_AUTHOR("Georgi Djakov <georgi.djakov@linaro.org>");
MODULE_DESCRIPTION("Interconnect Driver Core");
MODULE_LICENSE("GPL v2");
/* SPDX-License-Identifier: GPL-2.0 */
/*
* Copyright (c) 2018, Linaro Ltd.
* Author: Georgi Djakov <georgi.djakov@linaro.org>
*/
#ifndef __LINUX_INTERCONNECT_PROVIDER_H
#define __LINUX_INTERCONNECT_PROVIDER_H
#include <linux/interconnect.h>
#define icc_units_to_bps(bw) ((bw) * 1000ULL)
struct icc_node;
/**
* struct icc_provider - interconnect provider (controller) entity that might
* provide multiple interconnect controls
*
* @provider_list: list of the registered interconnect providers
* @nodes: internal list of the interconnect provider nodes
* @set: pointer to device specific set operation function
* @aggregate: pointer to device specific aggregate operation function
* @dev: the device this interconnect provider belongs to
* @users: count of active users
* @data: pointer to private data
*/
struct icc_provider {
struct list_head provider_list;
struct list_head nodes;
int (*set)(struct icc_node *src, struct icc_node *dst);
int (*aggregate)(struct icc_node *node, u32 avg_bw, u32 peak_bw,
u32 *agg_avg, u32 *agg_peak);
struct device *dev;
int users;
void *data;
};
/**
* struct icc_node - entity that is part of the interconnect topology
*
* @id: platform specific node id
* @name: node name used in debugfs
* @links: a list of targets pointing to where we can go next when traversing
* @num_links: number of links to other interconnect nodes
* @provider: points to the interconnect provider of this node
* @node_list: the list entry in the parent provider's "nodes" list
* @search_list: list used when walking the nodes graph
* @reverse: pointer to previous node when walking the nodes graph
* @is_traversed: flag that is used when walking the nodes graph
* @req_list: a list of QoS constraint requests associated with this node
* @avg_bw: aggregated value of average bandwidth requests from all consumers
* @peak_bw: aggregated value of peak bandwidth requests from all consumers
* @data: pointer to private data
*/
struct icc_node {
int id;
const char *name;
struct icc_node **links;
size_t num_links;
struct icc_provider *provider;
struct list_head node_list;
struct list_head search_list;
struct icc_node *reverse;
u8 is_traversed:1;
struct hlist_head req_list;
u32 avg_bw;
u32 peak_bw;
void *data;
};
#if IS_ENABLED(CONFIG_INTERCONNECT)
struct icc_node *icc_node_create(int id);
void icc_node_destroy(int id);
int icc_link_create(struct icc_node *node, const int dst_id);
int icc_link_destroy(struct icc_node *src, struct icc_node *dst);
void icc_node_add(struct icc_node *node, struct icc_provider *provider);
void icc_node_del(struct icc_node *node);
int icc_provider_add(struct icc_provider *provider);
int icc_provider_del(struct icc_provider *provider);
#else
static inline struct icc_node *icc_node_create(int id)
{
return ERR_PTR(-ENOTSUPP);
}
void icc_node_destroy(int id)
{
}
static inline int icc_link_create(struct icc_node *node, const int dst_id)
{
return -ENOTSUPP;
}
int icc_link_destroy(struct icc_node *src, struct icc_node *dst)
{
return -ENOTSUPP;
}
void icc_node_add(struct icc_node *node, struct icc_provider *provider)
{
}
void icc_node_del(struct icc_node *node)
{
}
static inline int icc_provider_add(struct icc_provider *provider)
{
return -ENOTSUPP;
}
static inline int icc_provider_del(struct icc_provider *provider)
{
return -ENOTSUPP;
}
#endif /* CONFIG_INTERCONNECT */
#endif /* __LINUX_INTERCONNECT_PROVIDER_H */
/* SPDX-License-Identifier: GPL-2.0 */
/*
* Copyright (c) 2018-2019, Linaro Ltd.
* Author: Georgi Djakov <georgi.djakov@linaro.org>
*/
#ifndef __LINUX_INTERCONNECT_H
#define __LINUX_INTERCONNECT_H
#include <linux/mutex.h>
#include <linux/types.h>
/* macros for converting to icc units */
#define Bps_to_icc(x) ((x) / 1000)
#define kBps_to_icc(x) (x)
#define MBps_to_icc(x) ((x) * 1000)
#define GBps_to_icc(x) ((x) * 1000 * 1000)
#define bps_to_icc(x) (1)
#define kbps_to_icc(x) ((x) / 8 + ((x) % 8 ? 1 : 0))
#define Mbps_to_icc(x) ((x) * 1000 / 8)
#define Gbps_to_icc(x) ((x) * 1000 * 1000 / 8)
struct icc_path;
struct device;
#if IS_ENABLED(CONFIG_INTERCONNECT)
struct icc_path *icc_get(struct device *dev, const int src_id,
const int dst_id);
void icc_put(struct icc_path *path);
int icc_set_bw(struct icc_path *path, u32 avg_bw, u32 peak_bw);
#else
static inline struct icc_path *icc_get(struct device *dev, const int src_id,
const int dst_id)
{
return NULL;
}
static inline void icc_put(struct icc_path *path)
{
}
static inline int icc_set_bw(struct icc_path *path, u32 avg_bw, u32 peak_bw)
{
return 0;
}
#endif /* CONFIG_INTERCONNECT */
#endif /* __LINUX_INTERCONNECT_H */
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