- 05 Sep, 2018 3 commits
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Varun Wadekar authored
For Denver CPUs, this approach enables the mitigation during EL3 initialization, following every PE reset. No mechanism is provided to disable the mitigation at runtime. This approach permanently mitigates the EL3 software stack only. Other software components are responsible to enable it for their exception levels. TF-A implements this approach for the Denver CPUs with DENVER_MIDR_PN3 and earlier: * By setting bit 11 (Disable speculative store buffering) of `ACTLR_EL3` * By setting bit 9 (Disable speculative memory disambiguation) of `ACTLR_EL3` TF-A implements this approach for the Denver CPUs with DENVER_MIDR_PN4 and later: * By setting bit 18 (Disable speculative store buffering) of `ACTLR_EL3` * By setting bit 17 (Disable speculative memory disambiguation) of `ACTLR_EL3` Change-Id: If1de96605ce3f7b0aff5fab2c828e5aecb687555 Signed-off-by: Varun Wadekar <vwadekar@nvidia.com>
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Varun Wadekar authored
Denver CPUs expect the power state field to be reset to 'C1' during boot. This patch updates the reset handler to reset the ACTLR_.PMSTATE field to 'C1' state during CPU boot. Change-Id: I7cb629627a4dd1a30ec5cbb3a5e90055244fe30c Signed-off-by: Varun Wadekar <vwadekar@nvidia.com>
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Varun Wadekar authored
The current functions to disable and enable Dynamic Code Optimizer (DCO) assume that all denver cores are in the same cluster. They ignore AFF1 field of the mpidr_el1 register, which leads to incorect logical core id calculation. This patch calls the platform handler, plat_my_core_pos(), to get the logical core id to disable/enable DCO for the core. Original change by: Krishna Sitaraman <ksitaraman@nvidia.com> Change-Id: I45fbd1f1eb032cc1db677a4fdecc554548b4a830 Signed-off-by: Varun Wadekar <vwadekar@nvidia.com>
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- 17 Aug, 2018 1 commit
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Varun Wadekar authored
This patch uses the 'declare_cpu_ops_wa' macro, to set the check function, to report that Denver cores are mitigated. Denver cores are vulnerable to this anomaly and require the mitigation to be enabled always. Change-Id: I1bb6eefdec8c01fb8b645e112f8d04d4bb8811ef Signed-off-by: Varun Wadekar <vwadekar@nvidia.com>
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- 11 Jul, 2018 1 commit
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Roberto Vargas authored
Check_vector_size checks if the size of the vector fits in the size reserved for it. This check creates problems in the Clang assembler. A new macro, end_vector_entry, is added and check_vector_size is deprecated. This new macro fills the current exception vector until the next exception vector. If the size of the current vector is bigger than 32 instructions then it gives an error. Change-Id: Ie8545cf1003a1e31656a1018dd6b4c28a4eaf671 Signed-off-by: Roberto Vargas <roberto.vargas@arm.com>
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- 15 May, 2018 1 commit
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Varun Wadekar authored
Flush the indirect branch predictor and RSB on entry to EL3 by issuing a newly added instruction for Denver CPUs. Support for this operation can be determined by comparing bits 19:16 of ID_AFR0_EL1 with 0b0001. To achieve this without performing any branch instruction, a per-cpu vbar is installed which executes the workaround and then branches off to the corresponding vector entry in the main vector table. A side effect of this change is that the main vbar is configured before any reset handling. This is to allow the per-cpu reset function to override the vbar setting. Change-Id: Ief493cd85935bab3cfee0397e856db5101bc8011 Signed-off-by: Varun Wadekar <vwadekar@nvidia.com>
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- 03 May, 2017 1 commit
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dp-arm authored
To make software license auditing simpler, use SPDX[0] license identifiers instead of duplicating the license text in every file. NOTE: Files that have been imported by FreeBSD have not been modified. [0]: https://spdx.org/ Change-Id: I80a00e1f641b8cc075ca5a95b10607ed9ed8761a Signed-off-by: dp-arm <dimitris.papastamos@arm.com>
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- 28 Feb, 2017 1 commit
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Varun Wadekar authored
This patch removes unnecessary `isb` from the enable DCO sequence as there is no need to synchronize this operation. Change-Id: I0191e684bbc7fdba635c3afbc4e4ecd793b6f06f Signed-off-by: Varun Wadekar <vwadekar@nvidia.com>
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- 23 Feb, 2017 1 commit
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Varun Wadekar authored
This patch moves the code to disable DCO operations out from common CPU files. This allows the platform code to call thsi API as and when required. There are certain CPU power down states which require the DCO to be kept ON and platforms can decide selectively now. Change-Id: Icb946fe2545a7d8c5903c420d1ee169c4921a2d1 Signed-off-by: Varun Wadekar <vwadekar@nvidia.com>
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- 22 Feb, 2017 1 commit
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Varun Wadekar authored
This patch adds support for all variants of the Denver CPUs. The variants export their cpu_ops to allow all Denver platforms to run the Trusted Firmware stack. Change-Id: I1488813ddfd506ffe363d8a32cda1b575e437035 Signed-off-by: Varun Wadekar <vwadekar@nvidia.com>
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- 15 Dec, 2016 1 commit
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Jeenu Viswambharan authored
Various CPU drivers in ARM Trusted Firmware register functions to handle power-down operations. At present, separate functions are registered to power down individual cores and clusters. This scheme operates on the basis of core and cluster, and doesn't cater for extending the hierarchy for power-down operations. For example, future CPUs might support multiple threads which might need powering down individually. This patch therefore reworks the CPU operations framework to allow for registering power down handlers on specific level basis. Henceforth: - Generic code invokes CPU power down operations by the level required. - CPU drivers explicitly mention CPU_NO_RESET_FUNC when the CPU has no reset function. - CPU drivers register power down handlers as a list: a mandatory handler for level 0, and optional handlers for higher levels. All existing CPU drivers are adapted to the new CPU operations framework without needing any functional changes within. Also update firmware design guide. Change-Id: I1826842d37a9e60a9e85fdcee7b4b8f6bc1ad043 Signed-off-by: Jeenu Viswambharan <jeenu.viswambharan@arm.com>
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- 24 Jul, 2015 1 commit
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Varun Wadekar authored
Denver is NVIDIA's own custom-designed, 64-bit, dual-core CPU which is fully ARMv8 architecture compatible. Each of the two Denver cores implements a 7-way superscalar microarchitecture (up to 7 concurrent micro-ops can be executed per clock), and includes a 128KB 4-way L1 instruction cache, a 64KB 4-way L1 data cache, and a 2MB 16-way L2 cache, which services both cores. Denver implements an innovative process called Dynamic Code Optimization, which optimizes frequently used software routines at runtime into dense, highly tuned microcode-equivalent routines. These are stored in a dedicated, 128MB main-memory-based optimization cache. After being read into the instruction cache, the optimized micro-ops are executed, re-fetched and executed from the instruction cache as long as needed and capacity allows. Effectively, this reduces the need to re-optimize the software routines. Instead of using hardware to extract the instruction-level parallelism (ILP) inherent in the code, Denver extracts the ILP once via software techniques, and then executes those routines repeatedly, thus amortizing the cost of ILP extraction over the many execution instances. Denver also features new low latency power-state transitions, in addition to extensive power-gating and dynamic voltage and clock scaling based on workloads. Signed-off-by: Varun Wadekar <vwadekar@nvidia.com>
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