3 config ARMV8_SPL_EXCEPTION_VECTORS
4 bool "Install crash dump exception vectors"
8 The default exception vector table is only used for the crash
9 dump, but still takes quite a lot of space in the image size.
11 Say N here if you are running out of code space in the image
12 and want to save some space at the cost of less debugging info.
14 config ARMV8_MULTIENTRY
15 bool "Enable multiple CPUs to enter into U-Boot"
17 config ARMV8_SET_SMPEN
18 bool "Enable data coherency with other cores in cluster"
20 Say Y here if there is not any trust firmware to set
21 CPUECTLR_EL1.SMPEN bit before U-Boot.
23 For A53, it enables data coherency with other cores in the
24 cluster, and for A57/A72, it enables receiving of instruction
25 cache and TLB maintenance operations.
26 Cortex A53/57/72 cores require CPUECTLR_EL1.SMPEN set even
27 for single core systems. Unfortunately write access to this
28 register may be controlled by EL3/EL2 firmware. To be more
29 precise, by default (if there is EL2/EL3 firmware running)
30 this register is RO for NS EL1.
31 This switch can be used to avoid writing to CPUECTLR_EL1,
32 it can be safely enabled when EL2/EL3 initialized SMPEN bit
33 or when CPU implementation doesn't include that register.
35 config ARMV8_SPIN_TABLE
36 bool "Support spin-table enable method"
37 depends on ARMV8_MULTIENTRY && OF_LIBFDT
39 Say Y here to support "spin-table" enable method for booting Linux.
41 To use this feature, you must do:
42 - Specify enable-method = "spin-table" in each CPU node in the
43 Device Tree you are using to boot the kernel
44 - Bring secondary CPUs into U-Boot proper in a board specific
45 manner. This must be done *after* relocation. Otherwise, the
46 secondary CPUs will spin in unprotected memory area because the
47 master CPU protects the relocated spin code.
49 U-Boot automatically does:
50 - Set "cpu-release-addr" property of each CPU node
51 (overwrites it if already exists).
52 - Reserve the code for the spin-table and the release address
53 via a /memreserve/ region in the Device Tree.
55 menu "ARMv8 secure monitor firmware"
56 config ARMV8_SEC_FIRMWARE_SUPPORT
57 bool "Enable ARMv8 secure monitor firmware framework support"
61 This framework is aimed at making secure monitor firmware load
63 Note: Only FIT format image is supported.
64 You should prepare and provide the below information:
65 - Address of secure firmware.
66 - Address to hold the return address from secure firmware.
67 - Secure firmware FIT image related information.
68 Such as: SEC_FIRMWARE_FIT_IMAGE and SEC_FIRMEWARE_FIT_CNF_NAME
69 - The target exception level that secure monitor firmware will
72 config SPL_ARMV8_SEC_FIRMWARE_SUPPORT
73 bool "Enable ARMv8 secure monitor firmware framework support for SPL"
77 Say Y here to support this framework in SPL phase.
79 config SEC_FIRMWARE_ARMV8_PSCI
80 bool "PSCI implementation in secure monitor firmware"
81 depends on ARMV8_SEC_FIRMWARE_SUPPORT || SPL_ARMV8_SEC_FIRMWARE_SUPPORT
83 This config enables the ARMv8 PSCI implementation in secure monitor
84 firmware. This is a private PSCI implementation and different from
85 those implemented under the common ARMv8 PSCI framework.
87 config ARMV8_SEC_FIRMWARE_ERET_ADDR_REVERT
88 bool "ARMv8 secure monitor firmware ERET address byteorder swap"
89 depends on ARMV8_SEC_FIRMWARE_SUPPORT || SPL_ARMV8_SEC_FIRMWARE_SUPPORT
91 Say Y here when the endianness of the register or memory holding the
92 Secure firmware exception return address is different with core's.
97 bool "Use PSCI for reset and shutdown"
99 select ARM_SMCCC if OF_CONTROL
100 depends on !ARCH_EXYNOS7 && !ARCH_BCM283X && \
101 !TARGET_LS2080A_SIMU && !TARGET_LS2080AQDS && \
102 !TARGET_LS2080ARDB && !TARGET_LS2080A_EMU && \
103 !TARGET_LS1088ARDB && !TARGET_LS1088AQDS && \
104 !TARGET_LS1012ARDB && !TARGET_LS1012AFRDM && \
105 !TARGET_LS1012A2G5RDB && !TARGET_LS1012AQDS && \
106 !TARGET_LS1012AFRWY && \
107 !TARGET_LS1043ARDB && !TARGET_LS1043AQDS && \
108 !TARGET_LS1046ARDB && !TARGET_LS1046AQDS && \
109 !TARGET_LS2081ARDB && \
110 !ARCH_UNIPHIER && !TARGET_S32V234EVB
112 Most armv8 systems have PSCI support enabled in EL3, either through
113 ARM Trusted Firmware or other firmware.
115 On these systems, we do not need to implement system reset manually,
116 but can instead rely on higher level firmware to deal with it.
118 Select Y here to make use of PSCI calls for system reset
121 bool "Enable PSCI support" if EXPERT
124 PSCI is Power State Coordination Interface defined by ARM.
125 The PSCI in U-boot provides a general framework and each platform
126 can implement their own specific PSCI functions.
127 Say Y here to enable PSCI support on ARMv8 platform.
129 config ARMV8_PSCI_NR_CPUS
130 int "Maximum supported CPUs for PSCI"
131 depends on ARMV8_PSCI
134 The maximum number of CPUs supported in the PSCI firmware.
135 It is no problem to set a larger value than the number of CPUs in
136 the actual hardware implementation.
138 config ARMV8_PSCI_CPUS_PER_CLUSTER
139 int "Number of CPUs per cluster"
140 depends on ARMV8_PSCI
143 The number of CPUs per cluster, suppose each cluster has same number
144 of CPU cores, platforms with asymmetric clusters don't apply here.
145 A value 0 or no definition of it works for single cluster system.
146 System with multi-cluster should difine their own exact value.
148 config ARMV8_EA_EL3_FIRST
149 bool "External aborts and SError interrupt exception are taken in EL3"
152 Exception handling at all exception levels for External Abort and
153 SError interrupt exception are taken in EL3.
155 if SYS_HAS_ARMV8_SECURE_BASE
157 config ARMV8_SECURE_BASE
158 hex "Secure address for PSCI image"
159 depends on ARMV8_PSCI
161 Address for placing the PSCI text, data and stack sections.
162 If not defined, the PSCI sections are placed together with the u-boot
163 but platform can choose to place PSCI code image separately in other
164 places such as some secure RAM built-in SOC etc.