- 22 May, 2014 1 commit
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Vikram Kanigiri authored
The issues addressed in this patch are: 1. Remove meminfo_t from the common interfaces in BL3-x, expecting that platform code will find a suitable mechanism to determine the memory extents in these images and provide it to the BL3-x images. 2. Remove meminfo_t and bl31_plat_params_t from all FVP BL3-x code as the images use link-time information to determine memory extents. meminfo_t is still used by common interface in BL1/BL2 for loading images Change-Id: I4e825ebf6f515b59d84dc2bdddf6edbf15e2d60f
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- 06 May, 2014 2 commits
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Dan Handley authored
Reduce the number of header files included from other header files as much as possible without splitting the files. Use forward declarations where possible. This allows removal of some unnecessary "#ifndef __ASSEMBLY__" statements. Also, review the .c and .S files for which header files really need including and reorder the #include statements alphabetically. Fixes ARM-software/tf-issues#31 Change-Id: Iec92fb976334c77453e010b60bcf56f3be72bd3e
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Dan Handley authored
Add tag names to all unnamed structs in header files. This allows forward declaration of structs, which is necessary to reduce header file nesting (to be implemented in a subsequent commit). Also change the typedef names across the codebase to use the _t suffix to be more conformant with the Linux coding style. The coding style actually prefers us not to use typedefs at all but this is considered a step too far for Trusted Firmware. Also change the IO framework structs defintions to use typedef'd structs to be consistent with the rest of the codebase. Change-Id: I722b2c86fc0d92e4da3b15e5cab20373dd26786f
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- 05 Mar, 2014 1 commit
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Jon Medhurst authored
So it updates each time a bootloader changes, not just when bl*_main.c files are recompiled. Fixes ARM-software/tf-issues#33 Change-Id: Ie8e1a7bd7e1913d2e96ac268606284f76af8c5ab Signed-off-by: Jon Medhurst <tixy@linaro.org>
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- 20 Feb, 2014 3 commits
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Achin Gupta authored
This patch reworks the service provided by the TSP to perform common arithmetic operations on a set of arguments provided by the non-secure world. For a addition, division, subtraction & multiplication operation requested on two arguments in x0 and x1 the steps are: 1. TSPD saves the non-secure context and passes the operation and its arguments to the TSP. 2. TSP asks the TSPD to return the same arguments once again. This exercises an additional SMC path. 3. TSP now has two copies of both x0 and x1. It performs the operation on the corresponding copies i.e. in case of addition it returns x0+x0 and x1+x1. 4. TSPD receives the result, saves the secure context, restores the non-secure context and passes the result back to the non-secure client. Change-Id: I6eebfa2ae0a6f28b1d2e11a31f575c7a4b96724b Co-authored-by: Jeenu Viswambharan <jeenu.viswambharan@arm.com>
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Achin Gupta authored
This patch implements a set of handlers in the SPD which are called by the PSCI runtime service upon receiving a power management operation. These handlers in turn pass control to the Secure Payload image if required before returning control to PSCI. This ensures that the Secure Payload has complete visibility of all power transitions in the system and can prepare accordingly. Change-Id: I2d1dba5629b7cf2d53999d39fe807dfcf3f62fe2
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Achin Gupta authored
This patch adds a simple TSP as the BL3-2 image. The secure payload executes in S-EL1. It paves the way for the addition of the TSP dispatcher runtime service to BL3-1. The TSP and the dispatcher service will serve as an example of the runtime firmware's ability to toggle execution between the non-secure and secure states in response to SMC request from the non-secure state. The TSP will be replaced by a Trusted OS in a real system. The TSP also exports a set of handlers which should be called in response to a PSCI power management event e.g a cpu being suspended or turned off. For now it runs out of Secure DRAM on the ARM FVP port and will be moved to Secure SRAM later. The default translation table setup code assumes that the caller is executing out of secure SRAM. Hence the TSP exports its own translation table setup function. The TSP only services Fast SMCs, is non-reentrant and non-interruptible. It does arithmetic operations on two sets of four operands, one set supplied by the non-secure client, and the other supplied by the TSP dispatcher in EL3. It returns the result according to the Secure Monitor Calling convention standard. This TSP has two functional entry points: - An initial, one-time entry point through which the TSP is initialized and prepares for receiving further requests from secure monitor/dispatcher - A fast SMC service entry point through which the TSP dispatcher requests secure services on behalf of the non-secure client Change-Id: I24377df53399307e2560a025eb2c82ce98ab3931 Co-authored-by: Jeenu Viswambharan <jeenu.viswambharan@arm.com>
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