- 21 Apr, 2016 1 commit
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Sandrine Bailleux authored
The CPU errata build flags don't enable errata, they enable errata workarounds. Change-Id: Ica65689d1205fc54eee9081a73442144b973400f
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- 13 Apr, 2016 1 commit
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Soby Mathew authored
The AArch32 long descriptor format and the AArch64 descriptor format correspond to each other which allows possible sharing of xlat_tables library code between AArch64 and AArch32. This patch refactors the xlat_tables library code to seperate the common functionality from architecture specific code. Prior to this patch, all of the xlat_tables library code were in `lib/aarch64/xlat_tables.c` file. The refactored code is now in `lib/xlat_tables/` directory. The AArch64 specific programming for xlat_tables is in `lib/xlat_tables/aarch64/xlat_tables.c` and the rest of the code common to AArch64 and AArch32 is in `lib/xlat_tables/xlat_tables_common.c`. Also the data types used in xlat_tables library APIs are reworked to make it compatible between AArch64 and AArch32. The `lib/aarch64/xlat_tables.c` file now includes the new xlat_tables library files to retain compatibility for existing platform ports. The macros related to xlat_tables library are also moved from `include/lib/aarch64/arch.h` to the header `include/lib/xlat_tables.h`. NOTE: THE `lib/aarch64/xlat_tables.c` FILE IS DEPRECATED AND PLATFORM PORTS ARE EXPECTED TO INCLUDE THE NEW XLAT_TABLES LIBRARY FILES IN THEIR MAKEFILES. Change-Id: I3d17217d24aaf3a05a4685d642a31d4d56255a0f
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- 31 Mar, 2016 1 commit
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Antonio Nino Diaz authored
lib/aarch64/xlat_helpers.c defines helper functions to build translation descriptors, but no common code or upstream platform port uses them. As the rest of the xlat_tables code evolves, there may be conflicts with these helpers, therefore this code should be removed. Change-Id: I9f5be99720f929264818af33db8dada785368711
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- 22 Mar, 2016 1 commit
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Soby Mathew authored
The assembler helper function `print_revision_warning` is used when a CPU specific operation is enabled in the debug build (e.g. an errata workaround) but doesn't apply to the executing CPU's revision/part number. However, in some cases the system integrator may want a single binary to support multiple platforms with different IP versions, only some of which contain a specific erratum. In this case, the warning can be emitted very frequently when CPUs are being powered on/off. This patch modifies this warning print behaviour so that it is emitted only when LOG_LEVEL >= LOG_LEVEL_VERBOSE. The `debug.h` header file now contains guard macros so that it can be included in assembly code. Change-Id: Ic6e7a07f128dcdb8498a5bfdae920a8feeea1345
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- 07 Mar, 2016 1 commit
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Kristina Martsenko authored
The current translation table code maps in a series of regions, zeroing the unmapped table entries before and in between the mapped regions. It doesn't, however, zero the unmapped entries after the last mapped region, leaving those entries at whatever value that memory has initially. This is bad because those values can look like valid translation table entries, pointing to valid physical addresses. The CPU is allowed to do speculative reads from any such addresses. If the addresses point to device memory, the results can be unpredictable. This patch zeroes the translation table entries following the last mapped region, ensuring all table entries are either valid or zero (invalid). In addition, it limits the value of ADDR_SPACE_SIZE to those allowed by the architecture and supported by the current code (see D4.2.5 in the Architecture Reference Manual). This simplifies this patch a lot and ensures existing code doesn't do unexpected things. Change-Id: Ic28b6c3f89d73ef58fa80319a9466bb2c7131c21
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- 03 Mar, 2016 1 commit
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Sandrine Bailleux authored
At the moment, the memory translation library allows to create memory mappings of 2 types: - Device nGnRE memory (named MT_DEVICE in the library); - Normal, Inner Write-back non-transient, Outer Write-back non-transient memory (named MT_MEMORY in the library). As a consequence, the library code treats the memory type field as a boolean: everything that is not device memory is normal memory and vice-versa. In reality, the ARMv8 architecture allows up to 8 types of memory to be used at a single time for a given exception level. This patch reworks the memory attributes such that the memory type is now defined as an integer ranging from 0 to 7 instead of a boolean. This makes it possible to extend the list of memory types supported by the memory translation library. The priority system dictating memory attributes for overlapping memory regions has been extended to cope with these changes but the algorithm at its core has been preserved. When a memory region is re-mapped with different memory attributes, the memory translation library examines the former attributes and updates them only if the new attributes create a more restrictive mapping. This behaviour is unchanged, only the manipulation of the value has been modified to cope with the new format. This patch also introduces a new type of memory mapping in the memory translation library: MT_NON_CACHEABLE, meaning Normal, Inner Non-cacheable, Outer Non-cacheable memory. This can be useful to map a non-cacheable memory region, such as a DMA buffer for example. The rules around the Execute-Never (XN) bit in a translation table for an MT_NON_CACHEABLE memory mapping have been aligned on the rules used for MT_MEMORY mappings: - If the memory is read-only then it is also executable (XN = 0); - If the memory is read-write then it is not executable (XN = 1). The shareability field for MT_NON_CACHEABLE mappings is always set as 'Outer-Shareable'. Note that this is not strictly needed since shareability is only relevant if the memory is a Normal Cacheable memory type, but this is to align with the existing device memory mappings setup. All Device and Normal Non-cacheable memory regions are always treated as Outer Shareable, regardless of the translation table shareability attributes. This patch also removes the 'ATTR_SO' and 'ATTR_SO_INDEX' #defines. They were introduced to map memory as Device nGnRnE (formerly called "Strongly-Ordered" memory in the ARMv7 architecture) but were not used anywhere in the code base. Removing them avoids any confusion about the memory types supported by the library. Upstream platforms do not currently use the MT_NON_CACHEABLE memory type. NOTE: THIS CHANGE IS SOURCE COMPATIBLE BUT PLATFORMS THAT RELY ON THE BINARY VALUES OF `mmap_attr_t` or the `attr` argument of `mmap_add_region()` MAY BE BROKEN. Change-Id: I717d6ed79b4c845a04e34132432f98b93d661d79
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- 26 Feb, 2016 1 commit
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Antonio Nino Diaz authored
All C files of stdlib were included into std.c, which was the file that the Makefile actually compiled. This is a poor way of compiling all the files and, while it may work fine most times, it's discouraged. In this particular case, each C file included its own headers, which were later included into std.c. For example, this caused problems because a duplicated typedef of u_short in both subr_prf.c and types.h. While that may require an issue on its own, this kind of problems are avoided if all C files are as independent as possible. Change-Id: I9a7833fd2933003f19a5d7db921ed8542ea2d04a
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- 08 Feb, 2016 2 commits
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Sandrine Bailleux authored
In the Cortex-A35/A53/A57 CPUs library code, some of the CPU specific reset operations are skipped if they have already been applied in a previous invocation of the reset handler. This precaution is not required, as all these operations can be reapplied safely. This patch removes the unneeded test-before-set instructions in the reset handler for these CPUs. Change-Id: Ib175952c814dc51f1b5125f76ed6c06a22b95167
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Sandrine Bailleux authored
The LDNP/STNP instructions as implemented on Cortex-A53 and Cortex-A57 do not behave in a way most programmers expect, and will most probably result in a significant speed degradation to any code that employs them. The ARMv8-A architecture (see Document ARM DDI 0487A.h, section D3.4.3) allows cores to ignore the non-temporal hint and treat LDNP/STNP as LDP/STP instead. This patch introduces 2 new build flags: A53_DISABLE_NON_TEMPORAL_HINT and A57_DISABLE_NON_TEMPORAL_HINT to enforce this behaviour on Cortex-A53 and Cortex-A57. They are enabled by default. The string printed in debug builds when a specific CPU errata workaround is compiled in but skipped at runtime has been generalised, so that it can be reused for the non-temporal hint use case as well. Change-Id: I3e354f4797fd5d3959872a678e160322b13867a1
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- 01 Feb, 2016 1 commit
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Soby Mathew authored
The debug prints used to debug translation table setup in xlat_tables.c used the `printf()` standard library function instead of the stack optimized `tf_printf()` API. DEBUG_XLAT_TABLE option was used to enable debug logs within xlat_tables.c and it configured a much larger stack size for the platform in case it was enabled. This patch modifies these debug prints within xlat_tables.c to use tf_printf() and modifies the format specifiers to be compatible with tf_printf(). The debug prints are now enabled if the VERBOSE prints are enabled in Trusted Firmware via LOG_LEVEL build option. The much larger stack size definition when DEBUG_XLAT_TABLE is defined is no longer required and the platform ports are modified to remove this stack size definition. Change-Id: I2f7d77ea12a04b827fa15e2adc3125b1175e4c23
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- 14 Jan, 2016 1 commit
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Soren Brinkmann authored
Migrate all direct usage of __attribute__ to usage of their corresponding macros from cdefs.h. e.g.: - __attribute__((unused)) -> __unused Signed-off-by: Soren Brinkmann <soren.brinkmann@xilinx.com>
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- 12 Jan, 2016 1 commit
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Sandrine Bailleux authored
This patch adds support for ARM Cortex-A35 processor in the CPU specific framework, as described in the Cortex-A35 TRM (r0p0). Change-Id: Ief930a0bdf6cd82f6cb1c3b106f591a71c883464
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- 14 Sep, 2015 1 commit
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Achin Gupta authored
On the ARMv8 architecture, cache maintenance operations by set/way on the last level of integrated cache do not affect the system cache. This means that such a flush or clean operation could result in the data being pushed out to the system cache rather than main memory. Another CPU could access this data before it enables its data cache or MMU. Such accesses could be serviced from the main memory instead of the system cache. If the data in the sysem cache has not yet been flushed or evicted to main memory then there could be a loss of coherency. The only mechanism to guarantee that the main memory will be updated is to use cache maintenance operations to the PoC by MVA(See section D3.4.11 (System level caches) of ARMv8-A Reference Manual (Issue A.g/ARM DDI0487A.G). This patch removes the reliance of Trusted Firmware on the flush by set/way operation to ensure visibility of data in the main memory. Cache maintenance operations by MVA are now used instead. The following are the broad category of changes: 1. The RW areas of BL2/BL31/BL32 are invalidated by MVA before the C runtime is initialised. This ensures that any stale cache lines at any level of cache are removed. 2. Updates to global data in runtime firmware (BL31) by the primary CPU are made visible to secondary CPUs using a cache clean operation by MVA. 3. Cache maintenance by set/way operations are only used prior to power down. NOTE: NON-UPSTREAM TRUSTED FIRMWARE CODE SHOULD MAKE EQUIVALENT CHANGES IN ORDER TO FUNCTION CORRECTLY ON PLATFORMS WITH SUPPORT FOR SYSTEM CACHES. Fixes ARM-software/tf-issues#205 Change-Id: I64f1b398de0432813a0e0881d70f8337681f6e9a
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- 11 Sep, 2015 1 commit
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Andrew Thoelke authored
This patch unifies the bakery lock api's across coherent and normal memory implementation of locks by using same data type `bakery_lock_t` and similar arguments to functions. A separate section `bakery_lock` has been created and used to allocate memory for bakery locks using `DEFINE_BAKERY_LOCK`. When locks are allocated in normal memory, each lock for a core has to spread across multiple cache lines. By using the total size allocated in a separate cache line for a single core at compile time, the memory for other core locks is allocated at link time by multiplying the single core locks size with (PLATFORM_CORE_COUNT - 1). The normal memory lock algorithm now uses lock address instead of the `id` in the per_cpu_data. For locks allocated in coherent memory, it moves locks from tzfw_coherent_memory to bakery_lock section. The bakery locks are allocated as part of bss or in coherent memory depending on usage of coherent memory. Both these regions are initialised to zero as part of run_time_init before locks are used. Hence, bakery_lock_init() is made an empty function as the lock memory is already initialised to zero. The above design lead to the removal of psci bakery locks from non_cpu_power_pd_node to psci_locks. NOTE: THE BAKERY LOCK API WHEN USE_COHERENT_MEM IS NOT SET HAS CHANGED. THIS IS A BREAKING CHANGE FOR ALL PLATFORM PORTS THAT ALLOCATE BAKERY LOCKS IN NORMAL MEMORY. Change-Id: Ic3751c0066b8032dcbf9d88f1d4dc73d15f61d8b
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- 13 Aug, 2015 1 commit
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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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- 05 Aug, 2015 1 commit
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Jimmy Huang authored
- Apply a53 errata #826319 to revision <= r0p2 - Apply a53 errata #836870 to revision <= r0p3 - Update docs/cpu-specific-build-macros.md for newly added errata build flags Change-Id: I44918e36b47dca1fa29695b68700ff9bf888865e Signed-off-by: Jimmy Huang <jimmy.huang@mediatek.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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- 16 Jul, 2015 1 commit
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Juan Castillo authored
The return value from the SYS_WRITE semihosting operation is 0 if the call is successful or the number of bytes not written, if there is an error. The implementation of the write function in the semihosting driver treats the return value as the number of bytes written, which is wrong. This patch fixes it. Change-Id: Id39dac3d17b5eac557408b8995abe90924c85b85
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- 13 Apr, 2015 1 commit
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Soby Mathew authored
This patch fixes an issue in the cpu specific register reporting of FVP AEM model whereby crash reporting itself triggers an exception thus resulting in recursive crash prints. The input to the 'size_controlled_print' in the crash reporting framework should be a NULL terminated string. As there were no cpu specific register to be reported on FVP AEM model, the issue was caused by passing 0 instead of NULL terminated string to the above mentioned function. Change-Id: I664427b22b89977b389175dfde84c815f02c705a
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- 08 Apr, 2015 1 commit
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Kévin Petit authored
In order for the symbol table in the ELF file to contain the size of functions written in assembly, it is necessary to report it to the assembler using the .size directive. To fulfil the above requirements, this patch introduces an 'endfunc' macro which contains the .endfunc and .size directives. It also adds a .func directive to the 'func' assembler macro. The .func/.endfunc have been used so the assembler can fail if endfunc is omitted. Fixes ARM-Software/tf-issues#295 Change-Id: If8cb331b03d7f38fe7e3694d4de26f1075b278fc Signed-off-by: Kévin Petit <kevin.petit@arm.com>
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- 27 Mar, 2015 2 commits
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Soby Mathew authored
This patch removes the `owner` field in bakery_lock_t structure which is the data structure used in the bakery lock implementation that uses coherent memory. The assertions to protect against recursive lock acquisition were based on the 'owner' field. They are now done based on the bakery lock ticket number. These assertions are also added to the bakery lock implementation that uses normal memory as well. Change-Id: If4850a00dffd3977e218c0f0a8d145808f36b470
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Soby Mathew authored
This patch optimizes the data structure used with the bakery lock implementation for coherent memory to save memory and minimize memory accesses. These optimizations were already part of the bakery lock implementation for normal memory and this patch now implements it for the coherent memory implementation as well. Also included in the patch is a cleanup to use the do-while loop while waiting for other contenders to finish choosing their tickets. Change-Id: Iedb305473133dc8f12126726d8329b67888b70f1
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- 18 Mar, 2015 1 commit
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Vikram Kanigiri authored
This patch adds support for ARM Cortex-A72 processor in the CPU specific framework. Change-Id: I5986855fc1b875aadf3eba8c36e989d8a05e5175
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- 16 Mar, 2015 1 commit
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Vikram Kanigiri authored
This patch defines the ARRAY_SIZE macro for calculating number of elements in an array and uses it where appropriate. Change-Id: I72746a9229f0b259323972b498b9a3999731bc9b
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- 13 Mar, 2015 1 commit
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Vikram Kanigiri authored
The cpu-ops pointer was initialized before enabling the data cache in the cold and warm boot paths. This required a DCIVAC cache maintenance operation to invalidate any stale cache lines resident in other cpus. This patch moves this initialization to the bl31_arch_setup() function which is always called after the data cache and MMU has been enabled. This change removes the need: 1. for the DCIVAC cache maintenance operation. 2. to initialise the CPU ops upon resumption from a PSCI CPU_SUSPEND call since memory contents are always preserved in this case. Change-Id: Ibb2fa2f7460d1a1f1e721242025e382734c204c6
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- 30 Jan, 2015 1 commit
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Soby Mathew authored
The CPU specific reset handlers no longer have the freedom of using any general purpose register because it is being invoked by the BL3-1 entry point in addition to BL1. The Cortex-A57 CPU specific reset handler was overwriting x20 register which was being used by the BL3-1 entry point to save the entry point information. This patch fixes this bug by reworking the register allocation in the Cortex-A57 reset handler to avoid using x20. The patch also explicitly mentions the register clobber list for each of the callee functions invoked by the reset handler Change-Id: I28fcff8e742aeed883eaec8f6c4ee2bd3fce30df
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- 28 Jan, 2015 1 commit
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Juan Castillo authored
This patch adds the missing features to the C library included in the Trusted Firmware to build PolarSSL: - strcasecmp() function - exit() function - sscanf()* function - time.h header file (and its dependencies) * NOTE: the sscanf() function is not a real implementation. It just returns the number of expected arguments by counting the number of '%' characters present in the formar string. This return value is good enough for PolarSSL because during the certificate parsing only the return value is checked. The certificate validity period is ignored. Change-Id: I43bb3742f26f0bd458272fccc3d72a7f2176ab3d
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- 26 Jan, 2015 1 commit
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Yatharth Kochar authored
This patch adds support to call the reset_handler() function in BL3-1 in the cold and warm boot paths when another Boot ROM reset_handler() has already run. This means the BL1 and BL3-1 versions of the CPU and platform specific reset handlers may execute different code to each other. This enables a developer to perform additional actions or undo actions already performed during the first call of the reset handlers e.g. apply additional errata workarounds. Typically, the reset handler will be first called from the BL1 Boot ROM. Any additional functionality can be added to the reset handler when it is called from BL3-1 resident in RW memory. The constant FIRST_RESET_HANDLER_CALL is used to identify whether this is the first version of the reset handler code to be executed or an overridden version of the code. The Cortex-A57 errata workarounds are applied only if they have not already been applied. Fixes ARM-software/tf-issue#275 Change-Id: Id295f106e4fda23d6736debdade2ac7f2a9a9053
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- 22 Jan, 2015 2 commits
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Soby Mathew authored
This patch moves the bakery locks out of coherent memory to normal memory. This implies that the lock information needs to be placed on a separate cache line for each cpu. Hence the bakery_lock_info_t structure is allocated in the per-cpu data so as to minimize memory wastage. A similar platform per-cpu data is introduced for the platform locks. As a result of the above changes, the bakery lock api is completely changed. Earlier, a reference to the lock structure was passed to the lock implementation. Now a unique-id (essentially an index into the per-cpu data array) and an offset into the per-cpu data for bakery_info_t needs to be passed to the lock implementation. Change-Id: I1e76216277448713c6c98b4c2de4fb54198b39e0
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Soby Mathew authored
This patch is an optimization in the bakery_lock_get() function which removes the wfe() when waiting for other contenders to choose their ticket i.e when their `entering` flag is set. Since the time taken to execute bakery_get_ticket() by other contenders is bounded, this wait is a bounded time wait. Hence the removal of wfe() and the corresponding sev() and dsb() in bakery_get_ticket() may result in better time performance during lock acquisition. Change-Id: I141bb21294226b54cb6e89e7cac0175c553afd8d
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- 13 Jan, 2015 1 commit
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Soby Mathew authored
This patch fixes a crash due to corruption of cpu_ops data structure. During the secondary CPU boot, after the cpu_ops has been initialized in the per cpu-data, the dcache lines need to invalidated so that the update in memory can be seen later on when the dcaches are turned ON. Also, after initializing the psci per cpu data, the dcache lines are flushed so that they are written back to memory and dirty dcache lines are avoided. Fixes ARM-Software/tf-issues#271 Change-Id: Ia90f55e9882690ead61226eea5a5a9146d35f313
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- 10 Nov, 2014 1 commit
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Achin Gupta authored
This patch fixes a bug in the bakery lock implementation where a data synchronisation barrier instruction is not issued before sending an event as mandated by the ARMv8 ARM. This can cause a event to be signalled before the related memory accesses have completed resulting in erroneous execution. Fixes ARM-software/tf-issues#272 Change-Id: I5ce02bf70afb001d967b9fa4c3f77442931d5349
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- 29 Oct, 2014 4 commits
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Soby Mathew authored
This patch optimizes the Cortex-A57 cluster power down sequence by not flushing the Level1 data cache. The L1 data cache and the L2 unified cache are inclusive. A flush of the L2 by set/way flushes any dirty lines from the L1 as well. This is a known safe deviation from the Cortex-A57 TRM defined power down sequence. This optimization can be enabled by the platform through the 'SKIP_A57_L1_FLUSH_PWR_DWN' build flag. Each Cortex-A57 based platform must make its own decision on whether to use the optimization. This patch also renames the cpu-errata-workarounds.md to cpu-specific-build-macros.md as this facilitates documentation of both CPU Specific errata and CPU Specific Optimization build macros. Change-Id: I299b9fe79e9a7e08e8a0dffb7d345f9a00a71480
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Soby Mathew authored
This the patch replaces the DSB SY with DSB ISH after disabling L2 prefetches during the Cortex-A57 power down sequence. Change-Id: I048d12d830c1b974b161224eff079fb9f8ecf52d
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Soby Mathew authored
Prior to this patch, the errata workarounds were applied for any version of the CPU in the release build and in the debug build an assert failure resulted when the revision did not match. This patch applies errata workarounds in the Cortex-A57 reset handler only if the 'variant' and 'revision' fields read from the MIDR_EL1 match. In the debug build, a warning message is printed for each errata workaround which is not applied. The patch modifies the register usage in 'reset_handler` so as to adhere to ARM procedure calling standards. Fixes ARM-software/tf-issues#242 Change-Id: I51b1f876474599db885afa03346e38a476f84c29
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Soby Mathew authored
This patch adds level specific cache maintenance functions to cache_helpers.S. The new functions 'dcsw_op_levelx', where '1 <= x <= 3', allow to perform cache maintenance by set/way for that particular level of cache. With this patch, functions to support cache maintenance upto level 3 have been implemented since it is the highest cache level for most ARM SoCs. These functions are now utilized in CPU specific power down sequences to implement them as mandated by processor specific technical reference manual. Change-Id: Icd90ce6b51cff5a12863bcda01b93601417fd45c
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- 20 Aug, 2014 4 commits
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Soby Mathew authored
This patch adds workarounds for selected errata which affect the Cortex-A57 r0p0 part. Each workaround has a build time flag which should be used by the platform port to enable or disable the corresponding workaround. The workarounds are disabled by default. An assertion is raised if the platform enables a workaround which does not match the CPU revision at runtime. Change-Id: I9ae96b01c6ff733d04dc733bd4e67dbf77b29fb0
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Soby Mathew authored
This patch adds handlers for dumping Cortex-A57 and Cortex-A53 specific register state to the CPU specific operations framework. The contents of CPUECTLR_EL1 are dumped currently. Change-Id: I63d3dbfc4ac52fef5e25a8cf6b937c6f0975c8ab
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Soby Mathew authored
This patch adds CPU core and cluster power down sequences to the CPU specific operations framework introduced in a earlier patch. Cortex-A53, Cortex-A57 and generic AEM sequences have been added. The latter is suitable for the Foundation and Base AEM FVPs. A pointer to each CPU's operations structure is saved in the per-cpu data so that it can be easily accessed during power down seqeunces. An optional platform API has been introduced to allow a platform to disable the Accelerator Coherency Port (ACP) during a cluster power down sequence. The weak definition of this function (plat_disable_acp()) does not take any action. It should be overriden with a strong definition if the ACP is present on a platform. Change-Id: I8d09bd40d2f528a28d2d3f19b77101178778685d
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Soby Mathew authored
This patch adds an optional platform API (plat_reset_handler) which allows the platform to perform any actions immediately after a cold or warm reset e.g. implement errata workarounds. The function is called with MMU and caches turned off. This API is weakly defined and does nothing by default but can be overriden by a platform with a strong definition. Change-Id: Ib0acdccbd24bc756528a8bd647df21e8d59707ff
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