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arm-trusted-firmware/drivers/arm/ccn/ccn.c
Antonio Nino Diaz 09d40e0e08 Sanitise includes across codebase 
Enforce full include path for includes. Deprecate old paths.

The following folders inside include/lib have been left unchanged:

- include/lib/cpus/${ARCH}
- include/lib/el3_runtime/${ARCH}

The reason for this change is that having a global namespace for
includes isn't a good idea. It defeats one of the advantages of having
folders and it introduces problems that are sometimes subtle (because
you may not know the header you are actually including if there are two
of them).

For example, this patch had to be created because two headers were
called the same way: e0ea0928d5 ("Fix gpio includes of mt8173 platform
to avoid collision."). More recently, this patch has had similar
problems: 46f9b2c3a2 ("drivers: add tzc380 support").

This problem was introduced in commit 4ecca33988 ("Move include and
source files to logical locations"). At that time, there weren't too
many headers so it wasn't a real issue. However, time has shown that
this creates problems.

Platforms that want to preserve the way they include headers may add the
removed paths to PLAT_INCLUDES, but this is discouraged.

Change-Id: I39dc53ed98f9e297a5966e723d1936d6ccf2fc8f
Signed-off-by: Antonio Nino Diaz <antonio.ninodiaz@arm.com>
2019-01-04 10:43:17 +00:00

622 lines
22 KiB
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/*
* Copyright (c) 2015-2018, ARM Limited and Contributors. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <assert.h>
#include <errno.h>
#include <stdbool.h>
#include <arch.h>
#include <common/debug.h>
#include <drivers/arm/ccn.h>
#include <lib/bakery_lock.h>
#include <lib/mmio.h>
#include "ccn_private.h"
static const ccn_desc_t *ccn_plat_desc;
#if defined(IMAGE_BL31) || (defined(AARCH32) && defined(IMAGE_BL32))
DEFINE_BAKERY_LOCK(ccn_lock);
#endif
/*******************************************************************************
* This function takes the base address of the CCN's programmer's view (PV), a
* region ID of one of the 256 regions (0-255) and a register offset within the
* region. It converts the first two parameters into a base address and uses it
* to read the register at the offset.
******************************************************************************/
static inline unsigned long long ccn_reg_read(uintptr_t periphbase,
unsigned int region_id,
unsigned int register_offset)
{
uintptr_t region_base;
assert(periphbase);
assert(region_id < REGION_ID_LIMIT);
region_base = periphbase + region_id_to_base(region_id);
return mmio_read_64(region_base + register_offset);
}
/*******************************************************************************
* This function takes the base address of the CCN's programmer's view (PV), a
* region ID of one of the 256 regions (0-255), a register offset within the
* region and a value. It converts the first two parameters into a base address
* and uses it to write the value in the register at the offset.
******************************************************************************/
static inline void ccn_reg_write(uintptr_t periphbase,
unsigned int region_id,
unsigned int register_offset,
unsigned long long value)
{
uintptr_t region_base;
assert(periphbase);
assert(region_id < REGION_ID_LIMIT);
region_base = periphbase + region_id_to_base(region_id);
mmio_write_64(region_base + register_offset, value);
}
#if ENABLE_ASSERTIONS
typedef struct rn_info {
unsigned char node_desc[MAX_RN_NODES];
} rn_info_t;
/*******************************************************************************
* This function takes the base address of the CCN's programmer's view (PV) and
* the node ID of a Request Node (RN-D or RN-I). It returns the maximum number
* of master interfaces resident on that node. This number is equal to the least
* significant two bits of the node type ID + 1.
******************************************************************************/
static unsigned int ccn_get_rni_mcount(uintptr_t periphbase,
unsigned int rn_id)
{
unsigned int rn_type_id;
/* Use the node id to find the type of RN-I/D node */
rn_type_id = get_node_type(ccn_reg_read(periphbase,
rn_id + RNI_REGION_ID_START,
REGION_ID_OFFSET));
/* Return the number master interfaces based on node type */
return rn_type_id_to_master_cnt(rn_type_id);
}
/*******************************************************************************
* This function reads the CCN registers to find the following information about
* the ACE/ACELite/ACELite+DVM/CHI interfaces resident on the various types of
* Request Nodes (RN-Fs, RN-Is and RN-Ds) in the system:
*
* 1. The total number of such interfaces that this CCN IP supports. This is the
* cumulative number of interfaces across all Request node types. It is
* passed back as the return value of this function.
*
* 2. The maximum number of interfaces of a type resident on a Request node of
* one of the three types. This information is populated in the 'info'
* array provided by the caller as described next.
*
* The array has 64 entries. Each entry corresponds to a Request node. The
* Miscellaneous node's programmer's view has RN-F, RN-I and RN-D ID
* registers. For each RN-I and RN-D ID indicated as being present in these
* registers, its identification register (offset 0xFF00) is read. This
* register specifies the maximum number of master interfaces the node
* supports. For RN-Fs it is assumed that there can be only a single fully
* coherent master resident on each node. The counts for each type of node
* are use to populate the array entry at the index corresponding to the node
* ID i.e. rn_info[node ID] = <number of master interfaces>
******************************************************************************/
static unsigned int ccn_get_rn_master_info(uintptr_t periphbase,
rn_info_t *info)
{
unsigned int num_masters = 0;
rn_types_t rn_type;
assert (info);
for (rn_type = RN_TYPE_RNF; rn_type < NUM_RN_TYPES; rn_type++) {
unsigned int mn_reg_off, node_id;
unsigned long long rn_bitmap;
/*
* RN-F, RN-I, RN-D node registers in the MN region occupy
* contiguous 16 byte apart offsets.
*/
mn_reg_off = MN_RNF_NODEID_OFFSET + (rn_type << 4);
rn_bitmap = ccn_reg_read(periphbase, MN_REGION_ID, mn_reg_off);
FOR_EACH_PRESENT_NODE_ID(node_id, rn_bitmap) {
unsigned int node_mcount;
/*
* A RN-F does not have a node type since it does not
* export a programmer's interface. It can only have a
* single fully coherent master residing on it. If the
* offset of the MN(Miscellaneous Node) register points
* to a RN-I/D node then the master count is set to the
* maximum number of master interfaces that can possibly
* reside on the node.
*/
node_mcount = (mn_reg_off == MN_RNF_NODEID_OFFSET ? 1 :
ccn_get_rni_mcount(periphbase, node_id));
/*
* Use this value to increment the maximum possible
* master interfaces in the system.
*/
num_masters += node_mcount;
/*
* Update the entry in 'info' for this node ID with
* the maximum number of masters than can sit on
* it. This information will be used to validate the
* node information passed by the platform later.
*/
info->node_desc[node_id] = node_mcount;
}
}
return num_masters;
}
/*******************************************************************************
* This function validates parameters passed by the platform (in a debug build).
* It collects information about the maximum number of master interfaces that:
* a) the CCN IP can accommodate and
* b) can exist on each Request node.
* It compares this with the information provided by the platform to determine
* the validity of the latter.
******************************************************************************/
static void __init ccn_validate_plat_params(const ccn_desc_t *plat_desc)
{
unsigned int master_id, num_rn_masters;
rn_info_t info = { {0} };
assert(plat_desc);
assert(plat_desc->periphbase);
assert(plat_desc->master_to_rn_id_map);
assert(plat_desc->num_masters);
assert(plat_desc->num_masters < CCN_MAX_RN_MASTERS);
/*
* Find the number and properties of fully coherent, IO coherent and IO
* coherent + DVM master interfaces
*/
num_rn_masters = ccn_get_rn_master_info(plat_desc->periphbase, &info);
assert(plat_desc->num_masters < num_rn_masters);
/*
* Iterate through the Request nodes specified by the platform.
* Decrement the count of the masters in the 'info' array for each
* Request node encountered. If the count would drop below 0 then the
* platform's view of this aspect of CCN configuration is incorrect.
*/
for (master_id = 0; master_id < plat_desc->num_masters; master_id++) {
unsigned int node_id;
node_id = plat_desc->master_to_rn_id_map[master_id];
assert(node_id < MAX_RN_NODES);
assert(info.node_desc[node_id]);
info.node_desc[node_id]--;
}
}
#endif /* ENABLE_ASSERTIONS */
/*******************************************************************************
* This function validates parameters passed by the platform (in a debug build)
* and initialises its internal data structures. A lock is required to prevent
* simultaneous CCN operations at runtime (only BL31) to add and remove Request
* nodes from coherency.
******************************************************************************/
void __init ccn_init(const ccn_desc_t *plat_desc)
{
#if ENABLE_ASSERTIONS
ccn_validate_plat_params(plat_desc);
#endif
ccn_plat_desc = plat_desc;
}
/*******************************************************************************
* This function converts a bit map of master interface IDs to a bit map of the
* Request node IDs that they reside on.
******************************************************************************/
static unsigned long long ccn_master_to_rn_id_map(unsigned long long master_map)
{
unsigned long long rn_id_map = 0;
unsigned int node_id, iface_id;
assert(master_map);
assert(ccn_plat_desc);
FOR_EACH_PRESENT_MASTER_INTERFACE(iface_id, master_map) {
assert(iface_id < ccn_plat_desc->num_masters);
/* Convert the master ID into the node ID */
node_id = ccn_plat_desc->master_to_rn_id_map[iface_id];
/* Set the bit corresponding to this node ID */
rn_id_map |= (1ULL << node_id);
}
return rn_id_map;
}
/*******************************************************************************
* This function executes the necessary operations to add or remove Request node
* IDs specified in the 'rn_id_map' bitmap from the snoop/DVM domains specified
* in the 'hn_id_map'. The 'region_id' specifies the ID of the first HN-F/MN
* on which the operation should be performed. 'op_reg_offset' specifies the
* type of operation (add/remove). 'stat_reg_offset' specifies the register
* which should be polled to determine if the operation has completed or not.
******************************************************************************/
static void ccn_snoop_dvm_do_op(unsigned long long rn_id_map,
unsigned long long hn_id_map,
unsigned int region_id,
unsigned int op_reg_offset,
unsigned int stat_reg_offset)
{
unsigned int start_region_id;
assert(ccn_plat_desc);
assert(ccn_plat_desc->periphbase);
#if defined(IMAGE_BL31) || (defined(AARCH32) && defined(IMAGE_BL32))
bakery_lock_get(&ccn_lock);
#endif
start_region_id = region_id;
FOR_EACH_PRESENT_REGION_ID(start_region_id, hn_id_map) {
ccn_reg_write(ccn_plat_desc->periphbase,
start_region_id,
op_reg_offset,
rn_id_map);
}
start_region_id = region_id;
FOR_EACH_PRESENT_REGION_ID(start_region_id, hn_id_map) {
WAIT_FOR_DOMAIN_CTRL_OP_COMPLETION(start_region_id,
stat_reg_offset,
op_reg_offset,
rn_id_map);
}
#if defined(IMAGE_BL31) || (defined(AARCH32) && defined(IMAGE_BL32))
bakery_lock_release(&ccn_lock);
#endif
}
/*******************************************************************************
* The following functions provide the boot and runtime API to the platform for
* adding and removing master interfaces from the snoop/DVM domains. A bitmap of
* master interfaces IDs is passed as a parameter. It is converted into a bitmap
* of Request node IDs using the mapping provided by the platform while
* initialising the driver.
* For example, consider a dual cluster system where the clusters have values 0
* & 1 in the affinity level 1 field of their respective MPIDRs. While
* initialising this driver, the platform provides the mapping between each
* cluster and the corresponding Request node. To add or remove a cluster from
* the snoop and dvm domain, the bit position corresponding to the cluster ID
* should be set in the 'master_iface_map' i.e. to remove both clusters the
* bitmap would equal 0x11.
******************************************************************************/
void ccn_enter_snoop_dvm_domain(unsigned long long master_iface_map)
{
unsigned long long rn_id_map;
rn_id_map = ccn_master_to_rn_id_map(master_iface_map);
ccn_snoop_dvm_do_op(rn_id_map,
CCN_GET_HN_NODEID_MAP(ccn_plat_desc->periphbase,
MN_HNF_NODEID_OFFSET),
HNF_REGION_ID_START,
HNF_SDC_SET_OFFSET,
HNF_SDC_STAT_OFFSET);
ccn_snoop_dvm_do_op(rn_id_map,
CCN_GET_MN_NODEID_MAP(ccn_plat_desc->periphbase),
MN_REGION_ID,
MN_DDC_SET_OFFSET,
MN_DDC_STAT_OFFSET);
}
void ccn_exit_snoop_dvm_domain(unsigned long long master_iface_map)
{
unsigned long long rn_id_map;
rn_id_map = ccn_master_to_rn_id_map(master_iface_map);
ccn_snoop_dvm_do_op(rn_id_map,
CCN_GET_HN_NODEID_MAP(ccn_plat_desc->periphbase,
MN_HNF_NODEID_OFFSET),
HNF_REGION_ID_START,
HNF_SDC_CLR_OFFSET,
HNF_SDC_STAT_OFFSET);
ccn_snoop_dvm_do_op(rn_id_map,
CCN_GET_MN_NODEID_MAP(ccn_plat_desc->periphbase),
MN_REGION_ID,
MN_DDC_CLR_OFFSET,
MN_DDC_STAT_OFFSET);
}
void ccn_enter_dvm_domain(unsigned long long master_iface_map)
{
unsigned long long rn_id_map;
rn_id_map = ccn_master_to_rn_id_map(master_iface_map);
ccn_snoop_dvm_do_op(rn_id_map,
CCN_GET_MN_NODEID_MAP(ccn_plat_desc->periphbase),
MN_REGION_ID,
MN_DDC_SET_OFFSET,
MN_DDC_STAT_OFFSET);
}
void ccn_exit_dvm_domain(unsigned long long master_iface_map)
{
unsigned long long rn_id_map;
rn_id_map = ccn_master_to_rn_id_map(master_iface_map);
ccn_snoop_dvm_do_op(rn_id_map,
CCN_GET_MN_NODEID_MAP(ccn_plat_desc->periphbase),
MN_REGION_ID,
MN_DDC_CLR_OFFSET,
MN_DDC_STAT_OFFSET);
}
/*******************************************************************************
* This function returns the run mode of all the L3 cache partitions in the
* system. The state is expected to be one of NO_L3, SF_ONLY, L3_HAM or
* L3_FAM. Instead of comparing the states reported by all HN-Fs, the state of
* the first present HN-F node is reported. Since the driver does not export an
* interface to program them seperately, there is no reason to perform this
* check. An HN-F could report that the L3 cache is transitioning from one mode
* to another e.g. HNF_PM_NOL3_2_SFONLY. In this case, the function waits for
* the transition to complete and reports the final state.
******************************************************************************/
unsigned int ccn_get_l3_run_mode(void)
{
unsigned long long hnf_pstate_stat;
assert(ccn_plat_desc);
assert(ccn_plat_desc->periphbase);
/*
* Wait for a L3 cache paritition to enter any run mode. The pstate
* parameter is read from an HN-F P-state status register. A non-zero
* value in bits[1:0] means that the cache is transitioning to a run
* mode.
*/
do {
hnf_pstate_stat = ccn_reg_read(ccn_plat_desc->periphbase,
HNF_REGION_ID_START,
HNF_PSTATE_STAT_OFFSET);
} while (hnf_pstate_stat & 0x3);
return PSTATE_TO_RUN_MODE(hnf_pstate_stat);
}
/*******************************************************************************
* This function sets the run mode of all the L3 cache partitions in the
* system to one of NO_L3, SF_ONLY, L3_HAM or L3_FAM depending upon the state
* specified by the 'mode' argument.
******************************************************************************/
void ccn_set_l3_run_mode(unsigned int mode)
{
unsigned long long mn_hnf_id_map, hnf_pstate_stat;
unsigned int region_id;
assert(ccn_plat_desc);
assert(ccn_plat_desc->periphbase);
assert(mode <= CCN_L3_RUN_MODE_FAM);
mn_hnf_id_map = ccn_reg_read(ccn_plat_desc->periphbase,
MN_REGION_ID,
MN_HNF_NODEID_OFFSET);
region_id = HNF_REGION_ID_START;
/* Program the desired run mode */
FOR_EACH_PRESENT_REGION_ID(region_id, mn_hnf_id_map) {
ccn_reg_write(ccn_plat_desc->periphbase,
region_id,
HNF_PSTATE_REQ_OFFSET,
mode);
}
/* Wait for the caches to transition to the run mode */
region_id = HNF_REGION_ID_START;
FOR_EACH_PRESENT_REGION_ID(region_id, mn_hnf_id_map) {
/*
* Wait for a L3 cache paritition to enter a target run
* mode. The pstate parameter is read from an HN-F P-state
* status register.
*/
do {
hnf_pstate_stat = ccn_reg_read(ccn_plat_desc->periphbase,
region_id,
HNF_PSTATE_STAT_OFFSET);
} while (((hnf_pstate_stat & HNF_PSTATE_MASK) >> 2) != mode);
}
}
/*******************************************************************************
* This function configures system address map and provides option to enable the
* 3SN striping mode of Slave node operation. The Slave node IDs and the Top
* Address bit1 and bit0 are provided as parameters to this function. This
* configuration is needed only if network contains a single SN-F or 3 SN-F and
* must be completed before the first request by the system to normal memory.
******************************************************************************/
void ccn_program_sys_addrmap(unsigned int sn0_id,
unsigned int sn1_id,
unsigned int sn2_id,
unsigned int top_addr_bit0,
unsigned int top_addr_bit1,
unsigned char three_sn_en)
{
unsigned long long mn_hnf_id_map, hnf_sam_ctrl_value;
unsigned int region_id;
assert(ccn_plat_desc);
assert(ccn_plat_desc->periphbase);
mn_hnf_id_map = ccn_reg_read(ccn_plat_desc->periphbase,
MN_REGION_ID,
MN_HNF_NODEID_OFFSET);
region_id = HNF_REGION_ID_START;
hnf_sam_ctrl_value = MAKE_HNF_SAM_CTRL_VALUE(sn0_id,
sn1_id,
sn2_id,
top_addr_bit0,
top_addr_bit1,
three_sn_en);
FOR_EACH_PRESENT_REGION_ID(region_id, mn_hnf_id_map) {
/* Program the SAM control register */
ccn_reg_write(ccn_plat_desc->periphbase,
region_id,
HNF_SAM_CTRL_OFFSET,
hnf_sam_ctrl_value);
}
}
/*******************************************************************************
* This function returns the part0 id from the peripheralID 0 register
* in CCN. This id can be used to distinguish the CCN variant present in the
* system.
******************************************************************************/
int ccn_get_part0_id(uintptr_t periphbase)
{
assert(periphbase);
return (int)(mmio_read_64(periphbase
+ MN_PERIPH_ID_0_1_OFFSET) & 0xFF);
}
/*******************************************************************************
* This function returns the region id corresponding to a node_id of node_type.
******************************************************************************/
static unsigned int get_region_id_for_node(node_types_t node_type,
unsigned int node_id)
{
unsigned int mn_reg_off, region_id;
unsigned long long node_bitmap;
unsigned int loc_node_id, node_pos_in_map = 0;
assert(node_type < NUM_NODE_TYPES);
assert(node_id < MAX_RN_NODES);
switch (node_type) {
case NODE_TYPE_RNI:
region_id = RNI_REGION_ID_START;
break;
case NODE_TYPE_HNF:
region_id = HNF_REGION_ID_START;
break;
case NODE_TYPE_HNI:
region_id = HNI_REGION_ID_START;
break;
case NODE_TYPE_SN:
region_id = SBSX_REGION_ID_START;
break;
default:
ERROR("Un-supported Node Type = %d.\n", node_type);
assert(false);
return REGION_ID_LIMIT;
}
/*
* RN-I, HN-F, HN-I, SN node registers in the MN region
* occupy contiguous 16 byte apart offsets.
*
* RN-F and RN-D node are not supported as
* none of them exposes any memory map to
* configure any of their offset registers.
*/
mn_reg_off = MN_RNF_NODEID_OFFSET + (node_type << 4);
node_bitmap = ccn_reg_read(ccn_plat_desc->periphbase,
MN_REGION_ID, mn_reg_off);
assert((node_bitmap & (1ULL << (node_id))) != 0U);
FOR_EACH_PRESENT_NODE_ID(loc_node_id, node_bitmap) {
INFO("Index = %u with loc_nod=%u and input nod=%u\n",
node_pos_in_map, loc_node_id, node_id);
if (loc_node_id == node_id)
break;
node_pos_in_map++;
}
if (node_pos_in_map == CCN_MAX_RN_MASTERS) {
ERROR("Node Id = %d, is not found.\n", node_id);
assert(false);
return REGION_ID_LIMIT;
}
/*
* According to section 3.1.1 in CCN specification, region offset for
* the RN-I components is calculated as (128 + NodeID of RN-I).
*/
if (node_type == NODE_TYPE_RNI)
region_id += node_id;
else
region_id += node_pos_in_map;
return region_id;
}
/*******************************************************************************
* This function sets the value 'val' to the register at register_offset from
* the base address pointed to by the region_id.
* where, region id is mapped to a node_id of node_type.
******************************************************************************/
void ccn_write_node_reg(node_types_t node_type, unsigned int node_id,
unsigned int reg_offset, unsigned long long val)
{
unsigned int region_id = get_region_id_for_node(node_type, node_id);
if (reg_offset > REGION_ID_OFFSET) {
ERROR("Invalid Register offset 0x%x is provided.\n",
reg_offset);
assert(false);
return;
}
/* Setting the value of Auxilary Control Register of the Node */
ccn_reg_write(ccn_plat_desc->periphbase, region_id, reg_offset, val);
VERBOSE("Value is successfully written at address 0x%lx.\n",
(ccn_plat_desc->periphbase
+ region_id_to_base(region_id))
+ reg_offset);
}
/*******************************************************************************
* This function read the value 'val' stored in the register at register_offset
* from the base address pointed to by the region_id.
* where, region id is mapped to a node_id of node_type.
******************************************************************************/
unsigned long long ccn_read_node_reg(node_types_t node_type,
unsigned int node_id,
unsigned int reg_offset)
{
unsigned long long val;
unsigned int region_id = get_region_id_for_node(node_type, node_id);
if (reg_offset > REGION_ID_OFFSET) {
ERROR("Invalid Register offset 0x%x is provided.\n",
reg_offset);
assert(false);
return ULL(0);
}
/* Setting the value of Auxilary Control Register of the Node */
val = ccn_reg_read(ccn_plat_desc->periphbase, region_id, reg_offset);
VERBOSE("Value is successfully read from address 0x%lx.\n",
(ccn_plat_desc->periphbase
+ region_id_to_base(region_id))
+ reg_offset);
return val;
}
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