1. 27 Apr, 2018 1 commit
    • Masahiro Yamada's avatar
      types: use int-ll64 for both aarch32 and aarch64 · 0a2d5b43
      Masahiro Yamada authored
      Since commit 031dbb12
      
       ("AArch32: Add essential Arch helpers"),
      it is difficult to use consistent format strings for printf() family
      between aarch32 and aarch64.
      
      For example, uint64_t is defined as 'unsigned long long' for aarch32
      and as 'unsigned long' for aarch64.  Likewise, uintptr_t is defined
      as 'unsigned int' for aarch32, and as 'unsigned long' for aarch64.
      
      A problem typically arises when you use printf() in common code.
      
      One solution could be, to cast the arguments to a type long enough
      for both architectures.  For example, if 'val' is uint64_t type,
      like this:
      
        printf("val = %llx\n", (unsigned long long)val);
      
      Or, somebody may suggest to use a macro provided by <inttypes.h>,
      like this:
      
        printf("val = %" PRIx64 "\n", val);
      
      But, both would make the code ugly.
      
      The solution adopted in Linux kernel is to use the same typedefs for
      all architectures.  The fixed integer types in the kernel-space have
      been unified into int-ll64, like follows:
      
          typedef signed char           int8_t;
          typedef unsigned char         uint8_t;
      
          typedef signed short          int16_t;
          typedef unsigned short        uint16_t;
      
          typedef signed int            int32_t;
          typedef unsigned int          uint32_t;
      
          typedef signed long long      int64_t;
          typedef unsigned long long    uint64_t;
      
      [ Linux commit: 0c79a8e29b5fcbcbfd611daf9d500cfad8370fcf ]
      
      This gets along with the codebase shared between 32 bit and 64 bit,
      with the data model called ILP32, LP64, respectively.
      
      The width for primitive types is defined as follows:
      
                         ILP32           LP64
          int            32              32
          long           32              64
          long long      64              64
          pointer        32              64
      
      'long long' is 64 bit for both, so it is used for defining uint64_t.
      'long' has the same width as pointer, so for uintptr_t.
      
      We still need an ifdef conditional for (s)size_t.
      
      All 64 bit architectures use "unsigned long" size_t, and most 32 bit
      architectures use "unsigned int" size_t.  H8/300, S/390 are known as
      exceptions; they use "unsigned long" size_t despite their architecture
      is 32 bit.
      
      One idea for simplification might be to define size_t as 'unsigned long'
      across architectures, then forbid the use of "%z" string format.
      However, this would cause a distortion between size_t and sizeof()
      operator.  We have unknowledge about the native type of sizeof(), so
      we need a guess of it anyway.  I want the following formula to always
      return 1:
      
        __builtin_types_compatible_p(size_t, typeof(sizeof(int)))
      
      Fortunately, ARM is probably a majority case.  As far as I know, all
      32 bit ARM compilers use "unsigned int" size_t.
      Signed-off-by: default avatarMasahiro Yamada <yamada.masahiro@socionext.com>
      0a2d5b43
  2. 15 Jun, 2017 1 commit
    • Anthony Zhou's avatar
      Tegra186: mce: fix MISRA defects · ab712fd8
      Anthony Zhou authored
      
      
      Main fixes:
      
      * Added explicit casts (e.g. 0U) to integers in order for them to be
        compatible with whatever operation they're used in [Rule 10.1]
      * Force operands of an operator to the same type category [Rule 10.4]
      * Added curly braces ({}) around if/while statements in order to
        make them compound [Rule 15.6]
      * Added parentheses [Rule 12.1]
      * Voided non C-library functions whose return types are not used [Rule 17.7]
      
      Change-Id: I91404edec2e2194b1ce2672d2a3fc6a1f5bf41f1
      Signed-off-by: default avatarAnthony Zhou <anzhou@nvidia.com>
      Signed-off-by: default avatarVarun Wadekar <vwadekar@nvidia.com>
      ab712fd8
  3. 03 May, 2017 1 commit
  4. 07 Apr, 2017 1 commit
  5. 05 Apr, 2017 3 commits
  6. 30 Mar, 2017 3 commits
    • Varun Wadekar's avatar
      Tegra186: mce: read MCE's firmware version on "real" platforms · 524bd090
      Varun Wadekar authored
      
      
      This patch runs the MCE firmware's version check only if the underlying
      platform has the capability to the run the firmware. MCE firmware is not
      running on simulation platforms, identified by v0.3 or v0.6, read from the
      Tegra Chip ID value.
      
      Change-Id: I3b1788b1ee2a0d4464017bb879ac5792cb7022b8
      Signed-off-by: default avatarVarun Wadekar <vwadekar@nvidia.com>
      524bd090
    • Varun Wadekar's avatar
      Tegra186: mce: Uncore Perfmon ARI Programming · c11e0ddf
      Varun Wadekar authored
      
      
      Uncore perfmon appears to the CPU as a set of uncore perfmon registers
      which can be read and written using the ARI interface. The MCE code
      sequence handles reads and writes to these registers by manipulating
      the underlying T186 uncore hardware.
      
      To access an uncore perfmon register, CPU software writes the ARI
      request registers to specify
      
      * whether the operation is a read or a write,
      * which uncore perfmon register to access,
      * the uncore perfmon unit, group, and counter number (if necessary),
      * the data to write (if the operation is a write).
      
      It then initiates an ARI request to run the uncore perfmon sequence in
      the MCE and reads the resulting value of the uncore perfmon register
      and any status information from the ARI response registers.
      
      The NS world's MCE driver issues MCE_CMD_UNCORE_PERFMON_REQ command
      for the EL3 layer to start the entire sequence. Once the request
      completes, the NS world would receive the command status in the X0
      register and the command data in the X1 register.
      
      Change-Id: I20bf2eca2385f7c8baa81e9445617ae711ecceea
      Signed-off-by: default avatarVarun Wadekar <vwadekar@nvidia.com>
      c11e0ddf
    • Varun Wadekar's avatar
      Tegra186: mce: add the mce_update_cstate_info() helper function · 87a1df73
      Varun Wadekar authored
      
      
      This patch adds a helper function to the MCE driver to allow its
      clients to issue UPDATE_CSTATE_INFO requests, without having to
      setup the CPU context struct.
      
      We introduced a struct to encapsulate the request parameters, that
      clients can pass on to the MCE driver. The MCE driver gets the
      parameters from the struct and programs the hardware accordingly.
      
      Change-Id: I02bce57506c4ccd90da82127805d6b564375cbf1
      Signed-off-by: default avatarVarun Wadekar <vwadekar@nvidia.com>
      87a1df73
  7. 23 Mar, 2017 3 commits
    • Varun Wadekar's avatar
      Tegra186: enable support for simulation environment · abd3a91d
      Varun Wadekar authored
      
      
      The Tegra simulation environment has limited capabilities. This patch
      checks the chip's major and minor versions to decide the features to
      enable/disable - MCE firmware version checking is disabled and limited
      Memory Controller settings are enabled
      
      Change-Id: I258a807cc3b83cdff14a9975b4ab4f9d1a9d7dcf
      Signed-off-by: default avatarVarun Wadekar <vwadekar@nvidia.com>
      abd3a91d
    • Varun Wadekar's avatar
      Tegra186: check MCE firmware version during boot · 5cb89c56
      Varun Wadekar authored
      
      
      This patch checks that the system is running with the supported MCE
      firmware during boot. In case the firmware version does not match the
      interface header version, then the system halts.
      
      Change-Id: Ib82013fd1c1668efd6f0e4f36cd3662d339ac076
      Signed-off-by: default avatarVarun Wadekar <vwadekar@nvidia.com>
      5cb89c56
    • Varun Wadekar's avatar
      Tegra186: mce: enable LATIC for chip verification · 66ec1125
      Varun Wadekar authored
      
      
      This patch adds a new interface to allow for making an ARI call that
      will enable LATIC for the chip verification software harness.
      
      LATIC allows some MINI ISMs to be read in the CCPLEX. The ISMs are
      used for various measurements relevant ot particular locations in
      Silicon. They are small counters which can be polled to determine
      how fast a particular location in the Silicon is.
      
      Original change by Guy Sotomayor <gsotomayor@nvidia.com>
      
      Change-Id: Ifb49b8863a009d4cdd5d1ba38a23b5374500a4b3
      Signed-off-by: default avatarVarun Wadekar <vwadekar@nvidia.com>
      66ec1125
  8. 22 Mar, 2017 1 commit
    • Varun Wadekar's avatar
      Tegra186: implement support for System Suspend · 50402b17
      Varun Wadekar authored
      
      
      This patch adds the chip level support for System Suspend entry
      and exit. As part of the entry sequence we first query the MCE
      firmware to check if it is safe to enter system suspend. Once
      we get a green light, we save hardware block settings and enter
      the power state. As expected, all the hardware settings are
      restored once we exit the power state.
      
      Change-Id: I6d192d7568d6a555eb10efdfd45f6d79c20f74ea
      Signed-off-by: default avatarVarun Wadekar <vwadekar@nvidia.com>
      50402b17
  9. 20 Mar, 2017 1 commit
    • Varun Wadekar's avatar
      Tegra186: mce: driver for the CPU complex power manager block · 7808b06b
      Varun Wadekar authored
      
      
      The CPU Complex (CCPLEX) Power Manager (Denver MCE, or DMCE) is an
      offload engine for BPMP to do voltage related sequencing and for
      hardware requests to be handled in a better latency than BPMP-firmware.
      
      There are two interfaces to the MCEs - Abstract Request Interface (ARI)
      and the traditional NVGINDEX/NVGDATA interface.
      
      MCE supports various commands which can be used by CPUs - ARM as well
      as Denver, for power management and reset functionality. Since the
      linux kernel is the master for all these scenarios, each MCE command
      can be issued by a corresponding SMC. These SMCs have been moved to
      SiP SMC space as they are specific to the Tegra186 SoC.
      
      Change-Id: I67bee83d2289a8ab63bc5556e5744e5043803e51
      Signed-off-by: default avatarVarun Wadekar <vwadekar@nvidia.com>
      Signed-off-by: default avatarVarun Wadekar <vwadekar@nvidia.com>
      7808b06b