- 02 Mar, 2017 1 commit
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Jeenu Viswambharan authored
The current PSCI implementation can apply certain optimizations upon the assumption that all PSCI participants are cache-coherent. - Skip performing cache maintenance during power-up. - Skip performing cache maintenance during power-down: At present, on the power-down path, CPU driver disables caches and MMU, and performs cache maintenance in preparation for powering down the CPU. This means that PSCI must perform additional cache maintenance on the extant stack for correct functioning. If all participating CPUs are cache-coherent, CPU driver would neither disable MMU nor perform cache maintenance. The CPU being powered down, therefore, remain cache-coherent throughout all PSCI call paths. This in turn means that PSCI cache maintenance operations are not required during power down. - Choose spin locks instead of bakery locks: The current PSCI implementation must synchronize both cache-coherent and non-cache-coherent participants. Mutual exclusion primitives are not guaranteed to function on non-coherent memory. For this reason, the current PSCI implementation had to resort to bakery locks. If all participants are cache-coherent, the implementation can enable MMU and data caches early, and substitute bakery locks for spin locks. Spin locks make use of architectural mutual exclusion primitives, and are lighter and faster. The optimizations are applied when HW_ASSISTED_COHERENCY build option is enabled, as it's expected that all PSCI participants are cache-coherent in those systems. Change-Id: Iac51c3ed318ea7e2120f6b6a46fd2db2eae46ede Signed-off-by:Jeenu Viswambharan <jeenu.viswambharan@arm.com>
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- 28 Sep, 2016 1 commit
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Soby Mathew authored
This patch adds the PSCI library integration guide for AArch32 ARMv8-A systems `psci-lib-integration-guide.md` to the documentation. The patch also adds appropriate reference to the new document in the `firmware-design.md` document. Change-Id: I2d5b5c6b612452371713399702e318e3c73a8ee0
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