- 13 Aug, 2015 12 commits
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Soby Mathew authored
As per PSCI1.0 specification, the error code to be returned when an invalid non secure entrypoint address is specified by the PSCI client for CPU_SUSPEND, CPU_ON or SYSTEM_SUSPEND must be PSCI_E_INVALID_ADDRESS. The current PSCI implementation returned PSCI_E_INVAL_PARAMS. This patch rectifies this error and also implements a common helper function to validate the entrypoint information to be used across these PSCI API implementations. Change-Id: I52d697d236c8bf0cd3297da4008c8e8c2399b170
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Sandrine Bailleux authored
Since there is a unique warm reset entry point, the FVP and Juno port can use a single mailbox instead of maintaining one per core. The mailbox gets programmed only once when plat_setup_psci_ops() is invoked during PSCI initialization. This means mailbox is not zeroed out during wakeup. Change-Id: Ieba032a90b43650f970f197340ebb0ce5548d432
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Soby Mathew authored
This patch adds support to the Juno and FVP ports for composite power states with both the original and extended state-id power-state formats. Both the platform ports use the recommended state-id encoding as specified in Section 6.5 of the PSCI specification (ARM DEN 0022C). The platform build flag ARM_RECOM_STATE_ID_ENC is used to include this support. By default, to maintain backwards compatibility, the original power state parameter format is used and the state-id field is expected to be zero. Change-Id: Ie721b961957eaecaca5bf417a30952fe0627ef10
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Soby Mathew authored
This patch migrates ARM reference platforms, Juno and FVP, to the new platform API mandated by the new PSCI power domain topology and composite power state frameworks. The platform specific makefiles now exports the build flag ENABLE_PLAT_COMPAT=0 to disable the platform compatibility layer. Change-Id: I3040ed7cce446fc66facaee9c67cb54a8cd7ca29
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Soby Mathew authored
This patch migrates the rest of Trusted Firmware excluding Secure Payload and the dispatchers to the new platform and context management API. The per-cpu data framework APIs which took MPIDRs as their arguments are deleted and only the ones which take core index as parameter are retained. Change-Id: I839d05ad995df34d2163a1cfed6baa768a5a595d
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Soby Mathew authored
This patch defines deprecated platform APIs to enable Trusted Firmware components like Secure Payload and their dispatchers(SPD) to continue to build and run when platform compatibility is disabled. This decouples the migration of platform ports to the new platform API from SPD and enables them to be migrated independently. The deprecated platform APIs defined in this patch are : platform_get_core_pos(), platform_get_stack() and platform_set_stack(). The patch also deprecates MPIDR based context management helpers like cm_get_context_by_mpidr(), cm_set_context_by_mpidr() and cm_init_context(). A mechanism to deprecate APIs and identify callers of these APIs during build is introduced, which is controlled by the build flag WARN_DEPRECATED. If WARN_DEPRECATED is defined to 1, the users of the deprecated APIs will be flagged either as a link error for assembly files or compile time warning for C files during build. Change-Id: Ib72c7d5dc956e1a74d2294a939205b200f055613
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Soby Mathew authored
This commit does the switch to the new PSCI framework implementation replacing the existing files in PSCI folder with the ones in PSCI1.0 folder. The corresponding makefiles are modified as required for the new implementation. The platform.h header file is also is switched to the new one as required by the new frameworks. The build flag ENABLE_PLAT_COMPAT defaults to 1 to enable compatibility layer which let the existing platform ports to continue to build and run with minimal changes. The default weak implementation of platform_get_core_pos() is now removed from platform_helpers.S and is provided by the compatibility layer. Note: The Secure Payloads and their dispatchers still use the old platform and framework APIs and hence it is expected that the ENABLE_PLAT_COMPAT build flag will remain enabled in subsequent patch. The compatibility for SPDs using the older APIs on platforms migrated to the new APIs will be added in the following patch. Change-Id: I18c51b3a085b564aa05fdd98d11c9f3335712719
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Soby Mathew authored
The new PSCI topology framework and PSCI extended State framework introduces a breaking change in the platform port APIs. To ease the migration of the platform ports to the new porting interface, a compatibility layer is introduced which essentially defines the new platform API in terms of the old API. The old PSCI helpers to retrieve the power-state, its associated fields and the highest coordinated physical OFF affinity level of a core are also implemented for compatibility. This allows the existing platform ports to work with the new PSCI framework without significant rework. This layer will be enabled by default once the switch to the new PSCI framework is done and is controlled by the build flag ENABLE_PLAT_COMPAT. Change-Id: I4b17cac3a4f3375910a36dba6b03d8f1700d07e3
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Sandrine Bailleux authored
There used to be 2 warm reset entry points: - the "on finisher", for when the core has been turned on using a PSCI CPU_ON call; - the "suspend finisher", entered upon resumption from a previous PSCI CPU_SUSPEND call. The appropriate warm reset entry point used to be programmed into the mailboxes by the power management hooks. However, it is not required to provide this information to the PSCI entry point code, as it can figure it out by itself. By querying affinity info state, a core is able to determine on which execution path it is. If the state is ON_PENDING then it means it's been turned on else it is resuming from suspend. This patch unifies the 2 warm reset entry points into a single one: psci_entrypoint(). The patch also implements the necessary logic to distinguish between the 2 types of warm resets in the power up finisher. The plat_setup_psci_ops() API now takes the secure entry point as an additional parameter to enable the platforms to configure their mailbox. The platform hooks `pwr_domain_on` and `pwr_domain_suspend` no longer take secure entry point as a parameter. Change-Id: I7d1c93787b54213aefdbc046b8cd66a555dfbfd9
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Soby Mathew authored
The state-id field in the power-state parameter of a CPU_SUSPEND call can be used to describe composite power states specific to a platform. The current PSCI implementation does not interpret the state-id field. It relies on the target power level and the state type fields in the power-state parameter to perform state coordination and power management operations. The framework introduced in this patch allows the PSCI implementation to intepret generic global states like RUN, RETENTION or OFF from the State-ID to make global state coordination decisions and reduce the complexity of platform ports. It adds support to involve the platform in state coordination which facilitates the use of composite power states and improves the support for entering standby states at multiple power domains. The patch also includes support for extended state-id format for the power state parameter as specified by PSCIv1.0. The PSCI implementation now defines a generic representation of the power-state parameter. It depends on the platform port to convert the power-state parameter (possibly encoding a composite power state) passed in a CPU_SUSPEND call to this representation via the `validate_power_state()` plat_psci_ops handler. It is an array where each index corresponds to a power level. Each entry contains the local power state the power domain at that power level could enter. The meaning of the local power state values is platform defined, and may vary between levels in a single platform. The PSCI implementation constrains the values only so that it can classify the state as RUN, RETENTION or OFF as required by the specification: * zero means RUN * all OFF state values at all levels must be higher than all RETENTION state values at all levels * the platform provides PLAT_MAX_RET_STATE and PLAT_MAX_OFF_STATE values to the framework The platform also must define the macros PLAT_MAX_RET_STATE and PLAT_MAX_OFF_STATE which lets the PSCI implementation find out which power domains have been requested to enter a retention or power down state. The PSCI implementation does not interpret the local power states defined by the platform. The only constraint is that the PLAT_MAX_RET_STATE < PLAT_MAX_OFF_STATE. For a power domain tree, the generic implementation maintains an array of local power states. These are the states requested for each power domain by all the cores contained within the domain. During a request to place multiple power domains in a low power state, the platform is passed an array of requested power-states for each power domain through the plat_get_target_pwr_state() API. It coordinates amongst these states to determine a target local power state for the power domain. A default weak implementation of this API is provided in the platform layer which returns the minimum of the requested power-states back to the PSCI state coordination. Finally, the plat_psci_ops power management handlers are passed the target local power states for each affected power domain using the generic representation described above. The platform executes operations specific to these target states. The platform power management handler for placing a power domain in a standby state (plat_pm_ops_t.pwr_domain_standby()) is now only used as a fast path for placing a core power domain into a standby or retention state should now be used to only place the core power domain in a standby or retention state. The extended state-id power state format can be enabled by setting the build flag PSCI_EXTENDED_STATE_ID=1 and it is disabled by default. Change-Id: I9d4123d97e179529802c1f589baaa4101759d80c
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Soby Mathew authored
This patch removes the assumption in the current PSCI implementation that MPIDR based affinity levels map directly to levels in a power domain tree. This enables PSCI generic code to support complex power domain topologies as envisaged by PSCIv1.0 specification. The platform interface for querying the power domain topology has been changed such that: 1. The generic PSCI code does not generate MPIDRs and use them to query the platform about the number of power domains at a particular power level. The platform now provides a description of the power domain tree on the SoC through a data structure. The existing platform APIs to provide the same information have been removed. 2. The linear indices returned by plat_core_pos_by_mpidr() and plat_my_core_pos() are used to retrieve core power domain nodes from the power domain tree. Power domains above the core level are accessed using a 'parent' field in the tree node descriptors. The platform describes the power domain tree in an array of 'unsigned char's. The first entry in the array specifies the number of power domains at the highest power level implemented in the system. Each susbsequent entry corresponds to a power domain and contains the number of power domains that are its direct children. This array is exported to the generic PSCI implementation via the new `plat_get_power_domain_tree_desc()` platform API. The PSCI generic code uses this array to populate its internal power domain tree using the Breadth First Search like algorithm. The tree is split into two arrays: 1. An array that contains all the core power domain nodes 2. An array that contains all the other power domain nodes A separate array for core nodes allows certain core specific optimisations to be implemented e.g. remove the bakery lock, re-use per-cpu data framework for storing some information. Entries in the core power domain array are allocated such that the array index of the domain is equal to the linear index returned by plat_core_pos_by_mpidr() and plat_my_core_pos() for the MPIDR corresponding to that domain. This relationship is key to be able to use an MPIDR to find the corresponding core power domain node, traverse to higher power domain nodes and index into arrays that contain core specific information. An introductory document has been added to briefly describe the new interface. Change-Id: I4b444719e8e927ba391cae48a23558308447da13
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Soby Mathew authored
This patch introduces new platform APIs and context management helper APIs to support the new topology framework based on linear core position. This framework will be introduced in the follwoing patch and it removes the assumption that the MPIDR based affinity levels map directly to levels in a power domain tree. The new platforms APIs and context management helpers based on core position are as described below: * plat_my_core_pos() and plat_core_pos_by_mpidr() These 2 new mandatory platform APIs are meant to replace the existing 'platform_get_core_pos()' API. The 'plat_my_core_pos()' API returns the linear index of the calling core and 'plat_core_pos_by_mpidr()' returns the linear index of a core specified by its MPIDR. The latter API will also validate the MPIDR passed as an argument and will return an error code (-1) if an invalid MPIDR is passed as the argument. This enables the caller to safely convert an MPIDR of another core to its linear index without querying the PSCI topology tree e.g. during a call to PSCI CPU_ON. Since the 'plat_core_pos_by_mpidr()' API verifies an MPIDR, which is always platform specific, it is no longer possible to maintain a default implementation of this API. Also it might not be possible for a platform port to verify an MPIDR before the C runtime has been setup or the topology has been initialized. This would prevent 'plat_core_pos_by_mpidr()' from being callable prior to topology setup. As a result, the generic Trusted Firmware code does not call this API before the topology setup has been done. The 'plat_my_core_pos' API should be able to run without a C runtime. Since this API needs to return a core position which is equal to the one returned by 'plat_core_pos_by_mpidr()' API for the corresponding MPIDR, this too cannot have default implementation and is a mandatory API for platform ports. These APIs will be implemented by the ARM reference platform ports later in the patch stack. * plat_get_my_stack() and plat_set_my_stack() These APIs are the stack management APIs which set/return stack addresses appropriate for the calling core. These replace the 'platform_get_stack()' and 'platform_set_stack()' APIs. A default weak MP version and a global UP version of these APIs are provided for the platforms. * Context management helpers based on linear core position A set of new context management(CM) helpers viz cm_get_context_by_index(), cm_set_context_by_index(), cm_init_my_context() and cm_init_context_by_index() are defined which are meant to replace the old helpers which took MPIDR as argument. The old CM helpers are implemented based on the new helpers to allow for code consolidation and will be deprecated once the switch to the new framework is done. Change-Id: I89758632b370c2812973a4b2efdd9b81a41f9b69
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- 05 Aug, 2015 3 commits
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Soby Mathew authored
As per Section 4.2.2. in the PSCI specification, the term "affinity" is used in the context of describing the hierarchical arrangement of cores. This often, but not always, maps directly to the processor power domain topology of the system. The current PSCI implementation assumes that this is always the case i.e. MPIDR based levels of affinity always map to levels in a power domain topology tree. This patch is the first in a series of patches which remove this assumption. It removes all occurences of the terms "affinity instances and levels" when used to describe the power domain topology. Only the terminology is changed in this patch. Subsequent patches will implement functional changes to remove the above mentioned assumption. Change-Id: Iee162f051b228828310610c5a320ff9d31009b4e
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Soby Mathew authored
This patch optimizes the invocation of the platform power management hooks for ON, OFF and SUSPEND such that they are called only for the highest affinity level which will be powered off/on. Earlier, the hooks were being invoked for all the intermediate levels as well. This patch requires that the platforms migrate to the new semantics of the PM hooks. It also removes the `state` parameter from the pm hooks as the `afflvl` parameter now indicates the highest affinity level for which power management operations are required. Change-Id: I57c87931d8a2723aeade14acc710e5b78ac41732
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Soby Mathew authored
This patch creates a copy of the existing PSCI files and related psci.h and platform.h header files in a new `PSCI1.0` directory. The changes for the new PSCI power domain topology and extended state-ID frameworks will be added incrementally to these files. This incremental approach will aid in review and in understanding the changes better. Once all the changes have been introduced, these files will replace the existing PSCI files. Change-Id: Ibb8a52e265daa4204e34829ed050bddd7e3316ff
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- 09 Jul, 2015 1 commit
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Juan Castillo authored
This patch changes the type of the base address parameter in the ARM device driver APIs to uintptr_t (GIC, CCI, TZC400, PL011). The uintptr_t type allows coverage of the whole memory space and to perform arithmetic operations on the addresses. ARM platform code has also been updated to use uintptr_t as GIC base address in the configuration. Fixes ARM-software/tf-issues#214 Change-Id: I1b87daedadcc8b63e8f113477979675e07d788f1
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- 25 Jun, 2015 7 commits
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Juan Castillo authored
The authentication framework deprecates plat_match_rotpk() in favour of plat_get_rotpk_info(). This patch removes plat_match_rotpk() from the platform port. Change-Id: I2250463923d3ef15496f9c39678b01ee4b33883b
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Juan Castillo authored
This patch modifies the Trusted Board Boot implementation to use the new authentication framework, making use of the authentication module, the cryto module and the image parser module to authenticate the images in the Chain of Trust. A new function 'load_auth_image()' has been implemented. When TBB is enabled, this function will call the authentication module to authenticate parent images following the CoT up to the root of trust to finally load and authenticate the requested image. The platform is responsible for picking up the right makefiles to build the corresponding cryptographic and image parser libraries. ARM platforms use the mbedTLS based libraries. The platform may also specify what key algorithm should be used to sign the certificates. This is done by declaring the 'KEY_ALG' variable in the platform makefile. FVP and Juno use ECDSA keys. On ARM platforms, BL2 and BL1-RW regions have been increased 4KB each to accommodate the ECDSA code. REMOVED BUILD OPTIONS: * 'AUTH_MOD' Change-Id: I47d436589fc213a39edf5f5297bbd955f15ae867
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Juan Castillo authored
This patch adds a CoT based on the Trusted Board Boot Requirements document*. The CoT consists of an array of authentication image descriptors indexed by the image identifiers. A new header file with TBBR image identifiers has been added. Platforms that use the TBBR (i.e. ARM platforms) may reuse these definitions as part of their platform porting. PLATFORM PORT - IMPORTANT: Default image IDs have been removed from the platform common definitions file (common_def.h). As a consequence, platforms that used those common definitons must now either include the IDs provided by the TBBR header file or define their own IDs. *The NVCounter authentication method has not been implemented yet. Change-Id: I7c4d591863ef53bb0cd4ce6c52a60b06fa0102d5
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Juan Castillo authored
This patch adds the following mbedTLS based libraries: * Cryptographic library It is used by the crypto module to verify a digital signature and a hash. This library relies on mbedTLS to perform the cryptographic operations. mbedTLS sources must be obtained separately. Two key algorithms are currently supported: * RSA-2048 * ECDSA-SECP256R1 The platform is responsible for picking up the required algorithm by defining the 'MBEDTLS_KEY_ALG' variable in the platform makefile. Available options are: * 'rsa' (for RSA-2048) (default option) * 'ecdsa' (for ECDSA-SECP256R1) Hash algorithm currently supported is SHA-256. * Image parser library Used by the image parser module to extract the authentication parameters stored in X509v3 certificates. Change-Id: I597c4be3d29287f2f18b82846973afc142ee0bf0
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Juan Castillo authored
This patch adds the authentication framework that will be used as the base to implement Trusted Board Boot in the Trusted Firmware. The framework comprises the following modules: - Image Parser Module (IPM) This module is responsible for interpreting images, check their integrity and extract authentication information from them during Trusted Board Boot. The module currently supports three types of images i.e. raw binaries, X509v3 certificates and any type specific to a platform. An image parser library must be registered for each image type (the only exception is the raw image parser, which is included in the main module by default). Each parser library (if used) must export a structure in a specific linker section which contains function pointers to: 1. Initialize the library 2. Check the integrity of the image type supported by the library 3. Extract authentication information from the image - Cryptographic Module (CM) This module is responsible for verifying digital signatures and hashes. It relies on an external cryptographic library to perform the cryptographic operations. To register a cryptographic library, the library must use the REGISTER_CRYPTO_LIB macro, passing function pointers to: 1. Initialize the library 2. Verify a digital signature 3. Verify a hash Failing to register a cryptographic library will generate a build time error. - Authentication Module (AM) This module provides methods to authenticate an image, like hash comparison or digital signatures. It uses the image parser module to extract authentication parameters, the crypto module to perform cryptographic operations and the Chain of Trust to authenticate the images. The Chain of Trust (CoT) is a data structure that defines the dependencies between images and the authentication methods that must be followed to authenticate an image. The Chain of Trust, when added, must provide a header file named cot_def.h with the following definitions: - COT_MAX_VERIFIED_PARAMS Integer value indicating the maximum number of authentication parameters an image can present. This value will be used by the authentication module to allocate the memory required to load the parameters in the image descriptor. Change-Id: Ied11bd5cd410e1df8767a1df23bb720ce7e58178
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Juan Castillo authored
This patch extends the platform port by adding an API that returns either the Root of Trust public key (ROTPK) or its hash. This is usually stored in ROM or eFUSE memory. The ROTPK returned must be encoded in DER format according to the following ASN.1 structure: SubjectPublicKeyInfo ::= SEQUENCE { algorithm AlgorithmIdentifier, subjectPublicKey BIT STRING } In case the platform returns a hash of the key: DigestInfo ::= SEQUENCE { digestAlgorithm AlgorithmIdentifier, keyDigest OCTET STRING } An implementation for ARM development platforms is provided in this patch. When TBB is enabled, the ROTPK hash location must be specified using the build option 'ARM_ROTPK_LOCATION'. Available options are: - 'regs' : return the ROTPK hash stored in the Trusted root-key storage registers. - 'devel_rsa' : return a ROTPK hash embedded in the BL1 and BL2 binaries. This hash has been obtained from the development RSA public key located in 'plat/arm/board/common/rotpk'. On FVP, the number of MMU tables has been increased to map and access the ROTPK registers. A new file 'board_common.mk' has been added to improve code sharing in the ARM develelopment platforms. Change-Id: Ib25862e5507d1438da10773e62bd338da8f360bf
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Juan Castillo authored
The Trusted firmware code identifies BL images by name. The platform port defines a name for each image e.g. the IO framework uses this mechanism in the platform function plat_get_image_source(). For a given image name, it returns the handle to the image file which involves comparing images names. In addition, if the image is packaged in a FIP, a name comparison is required to find the UUID for the image. This method is not optimal. This patch changes the interface between the generic and platform code with regard to identifying images. The platform port must now allocate a unique number (ID) for every image. The generic code will use the image ID instead of the name to access its attributes. As a result, the plat_get_image_source() function now takes an image ID as an input parameter. The organisation of data structures within the IO framework has been rationalised to use an image ID as an index into an array which contains attributes of the image such as UUID and name. This prevents the name comparisons. A new type 'io_uuid_spec_t' has been introduced in the IO framework to specify images identified by UUID (i.e. when the image is contained in a FIP file). There is no longer need to maintain a look-up table [iname_name --> uuid] in the io_fip driver code. Because image names are no longer mandatory in the platform port, the debug messages in the generic code will show the image identifier instead of the file name. The platforms that support semihosting to load images (i.e. FVP) must provide the file names as definitions private to the platform. The ARM platform ports and documentation have been updated accordingly. All ARM platforms reuse the image IDs defined in the platform common code. These IDs will be used to access other attributes of an image in subsequent patches. IMPORTANT: applying this patch breaks compatibility for platforms that use TF BL1 or BL2 images or the image loading code. The platform port must be updated to match the new interface. Change-Id: I9c1b04cb1a0684c6ee65dee66146dd6731751ea5
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- 24 Jun, 2015 1 commit
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Sandrine Bailleux authored
This patch fixes the build time condition deciding whether the read-write data should be relocated from ROM to RAM. It was incorrectly using __DATA_ROM_START__, which is a linker symbol and not a compiler build flag. As a result, the relocation code was always compiled out. This bug has been introduced by the following patch: "Rationalize reset handling code" Change-Id: I1c8d49de32f791551ab4ac832bd45101d6934045
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- 22 Jun, 2015 1 commit
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Soby Mathew authored
This patch adds support for SYSTEM_SUSPEND API as mentioned in the PSCI 1.0 specification. This API, on being invoked on the last running core on a supported platform, will put the system into a low power mode with memory retention. The psci_afflvl_suspend() internal API has been reused as most of the actions to suspend a system are the same as invoking the PSCI CPU_SUSPEND API with the target affinity level as 'system'. This API needs the 'power state' parameter for the target low power state. This parameter is not passed by the caller of the SYSTEM_SUSPEND API. Hence, the platform needs to implement the get_sys_suspend_power_state() platform function to provide this information. Also, the platform also needs to add support for suspending the system to the existing 'plat_pm_ops' functions: affinst_suspend() and affinst_suspend_finish(). Change-Id: Ib6bf10809cb4e9b92f463755608889aedd83cef5
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- 18 Jun, 2015 2 commits
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Ryan Harkin authored
Add SP804 delay timer support to the FVP BSP. This commit simply provides the 3 constants needed by the SP804 delay timer driver and calls sp804_timer_init() in bl2_platform_setup(). The BSP does not currently use the delay timer functions. Note that the FVP SP804 is a normal world accessible peripheral and should not be used by the secure world after transition to the normal world. Change-Id: I5f91d2ac9eb336fd81943b3bb388860dfb5f2b39 Co-authored-by: Dan Handley <dan.handley@arm.com>
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Ryan Harkin authored
Add a delay timer driver for the ARM SP804 dual timer. This driver only uses the first timer, called timer 1 in the SP804 Technical Reference Manual (ARM DDI 0271D). To use this driver, the BSP must provide three constants: * The base address of the SP804 dual timer * The clock multiplier * The clock divider The BSP is responsible for calling sp804_timer_init(). The SP804 driver instantiates a constant timer_ops_t and calls the generic timer_init(). Change-Id: I49ba0a52bdf6072f403d1d0a20e305151d4bc086 Co-authored-by: Dan Handley <dan.handley@arm.com>
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- 17 Jun, 2015 1 commit
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Ryan Harkin authored
The API is simple. The BSP or specific timer driver creates an instance of timer_ops_t, fills in the timer specific data, then calls timer_init(). The timer specific data includes a function pointer to return the timer value and a clock multiplier/divider. The ratio of the multiplier and the divider is the clock frequency in MHz. After that, mdelay() or udelay() can be called to delay execution for the specified time (milliseconds or microseconds, respectively). Change-Id: Icf8a295e1d25874f789bf28b7412156329dc975c Co-authored-by: Dan Handley <dan.handley@arm.com>
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- 09 Jun, 2015 2 commits
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Sandrine Bailleux authored
For CSS based platforms, the constants MHU_SECURE_BASE and MHU_SECURE_SIZE used to define the extents of the Trusted Mailboxes. As such, they were misnamed because the mailboxes are completely unrelated to the MHU hardware. This patch removes the MHU_SECURE_BASE and MHU_SECURE_SIZE #defines. The address of the Trusted Mailboxes is now relative to the base of the Trusted SRAM. This patch also introduces a new constant, SCP_COM_SHARED_MEM_BASE, which is the address of the first memory region used for communication between AP and SCP. This is used by the BOM and SCPI protocols. Change-Id: Ib200f057b19816bf05e834d111271c3ea777291f
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Sandrine Bailleux authored
Add a comment explaining what the SCP boot configuration information is on CSS based platforms like Juno. Also express its address relatively to the base of the Trusted SRAM rather than hard-coding it. Change-Id: I82cf708a284c8b8212933074ea8c37bdf48b403b
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- 04 Jun, 2015 2 commits
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Sandrine Bailleux authored
The attempt to run the CPU reset code as soon as possible after reset results in highly complex conditional code relating to the RESET_TO_BL31 option. This patch relaxes this requirement a little. In the BL1, BL3-1 and PSCI entrypoints code, the sequence of operations is now as follows: 1) Detect whether it is a cold or warm boot; 2) For cold boot, detect whether it is the primary or a secondary CPU. This is needed to handle multiple CPUs entering cold reset simultaneously; 3) Run the CPU init code. This patch also abstracts the EL3 registers initialisation done by the BL1, BL3-1 and PSCI entrypoints into common code. This improves code re-use and consolidates the code flows for different types of systems. NOTE: THE FUNCTION plat_secondary_cold_boot() IS NOW EXPECTED TO NEVER RETURN. THIS PATCH FORCES PLATFORM PORTS THAT RELIED ON THE FORMER RETRY LOOP AT THE CALL SITE TO MODIFY THEIR IMPLEMENTATION. OTHERWISE, SECONDARY CPUS WILL PANIC. Change-Id: If5ecd74d75bee700b1bd718d23d7556b8f863546
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Sandrine Bailleux authored
This patch removes the FIRST_RESET_HANDLER_CALL build flag and its use in ARM development platforms. If a different reset handling behavior is required between the first and subsequent invocations of the reset handling code, this should be detected at runtime. On Juno, the platform reset handler is now always compiled in. This means it is now executed twice on the cold boot path, first in BL1 then in BL3-1, and it has the same behavior in both cases. It is also executed twice on the warm boot path, first in BL1 then in the PSCI entrypoint code. Also update the documentation to reflect this change. NOTE: THIS PATCH MAY FORCE PLATFORM PORTS THAT USE THE FIRST_RESET_HANDLER_CALL BUILD OPTION TO FIX THEIR RESET HANDLER. Change-Id: Ie5c17dbbd0932f5fa3b446efc6e590798a5beae2
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- 29 May, 2015 1 commit
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Varun Wadekar authored
This patch adds driver for the 16550 UART interface. The driver is exposed as a console, which platforms can use to dump their boot/crash logs. Signed-off-by: Varun Wadekar <vwadekar@nvidia.com>
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- 27 May, 2015 1 commit
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Soby Mathew authored
This patch fixes the incorrect bit width used to extract the primary cpu id from `ap_data` exported by scp at SCP_BOOT_CFG_ADDR in platform_is_primary_cpu(). Change-Id: I14abb361685f31164ecce0755fc1a145903b27aa
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- 19 May, 2015 1 commit
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Achin Gupta authored
The ARM GIC driver treats the entire contents of the GICC_HPPIR as the interrupt ID instead of just bits[9:0]. This could result in an SGI being treated as a Group 1 interrupt on a GICv2 system. This patch introduces a mask to retrieve only the ID from a read of GICC_HPPIR, GICC_IAR and similar registers. The value read from these registers is masked with this constant prior to use as an interrupt ID. Fixes ARM-software/tf-issues#306 Change-Id: Ie3885157de33b71df9781a41f6ef015a30c4608d
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- 28 Apr, 2015 3 commits
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Dan Handley authored
Major update to the FVP platform port to use the common platform code in (include/)plat/arm/* and (include/)plat/common/*. This mainly consists of removing duplicated code but also introduces some small behavioural changes where there was unnecessary variation between the FVP and Juno ports. See earlier commit titled `Add common ARM and CSS platform code` for details. Also add support for Foundation FVP version 9.1 during FVP config setup to prevent a warning being emitted in the console. Change-Id: I254ca854987642ce09d1b924c9fd410a6e13e3bc
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Dan Handley authored
This major change pulls out the common functionality from the FVP and Juno platform ports into the following categories: * (include/)plat/common. Common platform porting functionality that typically may be used by all platforms. * (include/)plat/arm/common. Common platform porting functionality that may be used by all ARM standard platforms. This includes all ARM development platforms like FVP and Juno but may also include non-ARM-owned platforms. * (include/)plat/arm/board/common. Common platform porting functionality for ARM development platforms at the board (off SoC) level. * (include/)plat/arm/css/common. Common platform porting functionality at the ARM Compute SubSystem (CSS) level. Juno is an example of a CSS-based platform. * (include/)plat/arm/soc/common. Common platform porting functionality at the ARM SoC level, which is not already defined at the ARM CSS level. No guarantees are made about the backward compatibility of functionality provided in (include/)plat/arm. Also remove any unnecessary variation between the ARM development platform ports, including: * Unify the way BL2 passes `bl31_params_t` to BL3-1. Use the Juno implementation, which copies the information from BL2 memory instead of expecting it to persist in shared memory. * Unify the TZC configuration. There is no need to add a region for SCP in Juno; it's enough to simply not allow any access to this reserved region. Also set region 0 to provide no access by default instead of assuming this is the case. * Unify the number of memory map regions required for ARM development platforms, although the actual ranges mapped for each platform may be different. For the FVP port, this reduces the mapped peripheral address space. These latter changes will only be observed when the platform ports are migrated to use the new common platform code in subsequent patches. Change-Id: Id9c269dd3dc6e74533d0e5116fdd826d53946dc8
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Dan Handley authored
Add extern declarations of linker symbols to bl_common.h. These are used by platform ports to determine the memory layout of BL images. Adding the declarations to this file facilitates removal of these declarations from the platform porting source files in subsequent patches. Also remove the linker symbol declarations from common TSP source code. Change-Id: I8ed0426bc815317c4536b588e4e78bc15b4fe91c
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- 27 Apr, 2015 2 commits
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Dan Handley authored
Some assembly files containing macros are included like header files into other assembly files. This will cause assembler errors if they are included multiple times. Add header guards to assembly macro files to avoid assembler errors. Change-Id: Ia632e767ed7df7bf507b294982b8d730a6f8fe69
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Dan Handley authored
The required platform constant PLATFORM_CACHE_LINE_SIZE is unnecessary since CACHE_WRITEBACK_GRANULE effectively provides the same information. CACHE_WRITEBACK_GRANULE is preferred since this is an architecturally defined term and allows comparison with the corresponding hardware register value. Replace all usage of PLATFORM_CACHE_LINE_SIZE with CACHE_WRITEBACK_GRANULE. Also, add a runtime assert in BL1 to check that the provided CACHE_WRITEBACK_GRANULE matches the value provided in CTR_EL0. Change-Id: If87286be78068424217b9f3689be358356500dcd
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