Kconfig
5.95 KB
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config FSL_SDK_DPA
bool "Freescale Datapath Queue and Buffer management"
depends on !FSL_DPAA
select FSL_QMAN_FQ_LOOKUP if PPC64
select FSL_QMAN_FQ_LOOKUP if ARM64
menu "Freescale Datapath QMan/BMan options"
depends on FSL_SDK_DPA
config FSL_DPA_CHECKING
bool "additional driver checking"
default n
help
Compiles in additional checks to sanity-check the drivers and any
use of it by other code. Not recommended for performance.
config FSL_DPA_CAN_WAIT
bool
default y
config FSL_DPA_CAN_WAIT_SYNC
bool
default y
config FSL_DPA_PIRQ_FAST
bool
default y
config FSL_DPA_PIRQ_SLOW
bool
default y
config FSL_DPA_PORTAL_SHARE
bool
default y
config FSL_SDK_BMAN
bool "Freescale Buffer Manager (BMan) support"
default y
if FSL_SDK_BMAN
config FSL_BMAN_CONFIG
bool "BMan device management"
default y
help
If this linux image is running natively, you need this option. If this
linux image is running as a guest OS under the hypervisor, only one
guest OS ("the control plane") needs this option.
config FSL_BMAN_TEST
tristate "BMan self-tests"
default n
help
This option compiles self-test code for BMan.
config FSL_BMAN_TEST_HIGH
bool "BMan high-level self-test"
depends on FSL_BMAN_TEST
default y
help
This requires the presence of cpu-affine portals, and performs
high-level API testing with them (whichever portal(s) are affine to
the cpu(s) the test executes on).
config FSL_BMAN_TEST_THRESH
bool "BMan threshold test"
depends on FSL_BMAN_TEST
default y
help
Multi-threaded (SMP) test of BMan pool depletion. A pool is seeded
before multiple threads (one per cpu) create pool objects to track
depletion state changes. The pool is then drained to empty by a
"drainer" thread, and the other threads that they observe exactly
the depletion state changes that are expected.
config FSL_BMAN_DEBUGFS
tristate "BMan debugfs interface"
depends on DEBUG_FS
default y
help
This option compiles debugfs code for BMan.
endif # FSL_SDK_BMAN
config FSL_SDK_QMAN
bool "Freescale Queue Manager (QMan) support"
default y
if FSL_SDK_QMAN
config FSL_QMAN_POLL_LIMIT
int
default 32
config FSL_QMAN_CONFIG
bool "QMan device management"
default y
help
If this linux image is running natively, you need this option. If this
linux image is running as a guest OS under the hypervisor, only one
guest OS ("the control plane") needs this option.
config FSL_QMAN_TEST
tristate "QMan self-tests"
default n
help
This option compiles self-test code for QMan.
config FSL_QMAN_TEST_STASH_POTATO
bool "QMan 'hot potato' data-stashing self-test"
depends on FSL_QMAN_TEST
default y
help
This performs a "hot potato" style test enqueuing/dequeuing a frame
across a series of FQs scheduled to different portals (and cpus), with
DQRR, data and context stashing always on.
config FSL_QMAN_TEST_HIGH
bool "QMan high-level self-test"
depends on FSL_QMAN_TEST
default y
help
This requires the presence of cpu-affine portals, and performs
high-level API testing with them (whichever portal(s) are affine to
the cpu(s) the test executes on).
config FSL_QMAN_DEBUGFS
tristate "QMan debugfs interface"
depends on DEBUG_FS
default y
help
This option compiles debugfs code for QMan.
# H/w settings that can be hard-coded for now.
config FSL_QMAN_FQD_SZ
int "size of Frame Queue Descriptor region"
default 10
help
This is the size of the FQD region defined as: PAGE_SIZE * (2^value)
ex: 10 => PAGE_SIZE * (2^10)
Note: Default device-trees now require minimum Kconfig setting of 10.
config FSL_QMAN_PFDR_SZ
int "size of the PFDR pool"
default 13
help
This is the size of the PFDR pool defined as: PAGE_SIZE * (2^value)
ex: 13 => PAGE_SIZE * (2^13)
# Corenet initiator settings. Stash request queues are 4-deep to match cores'
# ability to snart. Stash priority is 3, other priorities are 2.
config FSL_QMAN_CI_SCHED_CFG_SRCCIV
int
depends on FSL_QMAN_CONFIG
default 4
config FSL_QMAN_CI_SCHED_CFG_SRQ_W
int
depends on FSL_QMAN_CONFIG
default 3
config FSL_QMAN_CI_SCHED_CFG_RW_W
int
depends on FSL_QMAN_CONFIG
default 2
config FSL_QMAN_CI_SCHED_CFG_BMAN_W
int
depends on FSL_QMAN_CONFIG
default 2
# portal interrupt settings
config FSL_QMAN_PIRQ_DQRR_ITHRESH
int
default 12
config FSL_QMAN_PIRQ_MR_ITHRESH
int
default 4
config FSL_QMAN_PIRQ_IPERIOD
int
default 100
# 64 bit kernel support
config FSL_QMAN_FQ_LOOKUP
bool
default n
config QMAN_CEETM_UPDATE_PERIOD
int "Token update period for shaping, in nanoseconds"
default 1000
help
Traffic shaping works by performing token calculations (using
credits) on shaper instances periodically. This update period
sets the granularity for how often those token rate credit
updates are performed, and thus determines the accuracy and
range of traffic rates that can be configured by users. The
reference manual recommends a 1 microsecond period as providing
a good balance between granularity and range.
Unless you know what you are doing, leave this value at its default.
config FSL_QMAN_INIT_TIMEOUT
int "timeout for qman init stage, in seconds"
default 10
help
The timeout setting to quit the initialization loop for non-control
partition in case the control partition fails to boot-up.
endif # FSL_SDK_QMAN
config FSL_USDPAA
bool "Freescale USDPAA process driver"
depends on FSL_SDK_DPA
default y
help
This driver provides user-space access to kernel-managed
resource interfaces for USDPAA applications, on the assumption
that each process will open this device once. Specifically, this
device exposes functionality that would be awkward if exposed
via the portal devices - ie. this device exposes functionality
that is inherently process-wide rather than portal-specific.
This device is necessary for obtaining access to DMA memory and
for allocation of Qman and Bman resources. In short, if you wish
to use USDPAA applications, you need this.
If unsure, say Y.
endmenu