On 01/30/2012 05:33 AM, Maxime Coquelin wrote:
> Signed-off-by: Maxime Coquelin <[email protected]>
> ---
> Documentation/pasr.txt | 183 ++++++++++++++++++++++++++++++++++++++++++++++++
> 1 files changed, 183 insertions(+), 0 deletions(-)
> create mode 100644 Documentation/pasr.txt
>
> diff --git a/Documentation/pasr.txt b/Documentation/pasr.txt
> new file mode 100644
> index 0000000..d40e3f6
> --- /dev/null
> +++ b/Documentation/pasr.txt
> @@ -0,0 +1,183 @@
> +Partial Array Self-Refresh Framework
> +
> +(C) 2012 Maxime Coquelin <[email protected]>, ST-Ericsson.
> +
> +CONTENT
> +1. Introduction
> +2. Command-line parameters
> +3. Allocators patching
> +4. PASR platform drivers
> +
> +
> +1. Introduction
> +
> +PASR Frameworks brings support for the Partial Array Self-Refresh DDR power
The PASR framework brings support
> +management feature. PASR has been introduced in LP-DDR2, and is also present
was introduced in LP-DDR2 and is also present
> +in DDR3.
> +
> +PASR provides 4 modes:
> +
> +* Single-Ended: Only 1/1, 1/2, 1/4 or 1/8 are refreshed, masking starting at
> + the end of the DDR die.
> +
> +* Double-Ended: Same as Single-Ended, but refresh-masking does not start
> + necessairly at the end of the DDR die.
necessarily
> +
> +* Bank-Selective: Refresh of each bank of a die can be masked or unmasked via
> + a dedicated DDR register (MR16). This mode is convenient for DDR configured
> + in BRC (Bank-Row-Column) mode.
> +
> +* Segment-Selective: Refresh of each segment of a die can be masked or unmasked
> + via a dedicated DDR register (MR17). This mode is convenient for DDR configured
> + in RBC (Row-Bank-Column) mode.
> +
> +The role of this framework is to stop the refresh of unused memory to enhance
> +DDR power consumption.
> +
> +It supports Bank-Selective and Segment-Selective modes, as the more adapted to
> +modern OSes.
huh? parse error above.
> +
> +At early boot stage, a representation of the physical DDR layout is built:
> +
> + Die 0
> +_______________________________
> +| I--------------------------I |
> +| I Bank or Segment 0 I |
> +| I--------------------------I |
> +| I--------------------------I |
> +| I Bank or Segment 1 I |
> +| I--------------------------I |
> +| I--------------------------I |
> +| I Bank or Segment ... I |
> +| I--------------------------I |
> +| I--------------------------I |
> +| I Bank or Segment n I |
> +| I--------------------------I |
> +|______________________________|
> + ...
> +
> + Die n
> +_______________________________
> +| I--------------------------I |
> +| I Bank or Segment 0 I |
> +| I--------------------------I |
> +| I--------------------------I |
> +| I Bank or Segment 1 I |
> +| I--------------------------I |
> +| I--------------------------I |
> +| I Bank or Segment ... I |
> +| I--------------------------I |
> +| I--------------------------I |
> +| I Bank or Segment n I |
> +| I--------------------------I |
> +|______________________________|
> +
> +The first level is a table where elements represent a die:
> +* Base address,
> +* Number of segments,
> +* Table representing banks/segments,
> +* MR16/MR17 refresh mask,
> +* DDR Controller callback to update MR16/MR17 refresh mask.
> +
> +The second level is the section tables representing the banks or segments,
> +depending on hardware configuration:
> +* Base address,
> +* Unused memory size counter,
> +* Possible pointer to another section it depends on (E.g. Interleaving)
> +
> +When some memory becomes unused, the allocator owning this memory calls the PASR
> +Framework's pasr_put(phys_addr, size) function. The framework finds the
> +sections impacted and updates their counters accordingly.
> +If a section counter reach the section size, the refresh of the section is
reaches
> +masked. If the corresponding section has a dependency with another section
> +(E.g. because of DDR interleaving, see figure below), it checks the "paired" section is also
it checks if the "paired" section is also
> +unused before updating the refresh mask.
> +
> +When some unused memory is requested by the allocator, the allocator owning
> +this memory calls the PASR Framework's pasr_get(phys_addr, size) function. The
> +framework find the section impacted and updates their counters accordingly.
finds and updates its counter accordingly.
or
find the sections impacted and updates their counters accordingly.
> +If before the update, the section counter was to the section size, the refrewh
was equal to the section size, the refresh
> +of the section is unmasked. If the corresponding section has a dependency with
> +another section, it also unmask the refresh of the other section.
unmasks
> +
> +Interleaving example:
> +
> + Die 0
> +_______________________________
> +| I--------------------------I |
> +| I Bank or Segment 0 I |<----|
> +| I--------------------------I | |
> +| I--------------------------I | |
> +| I Bank or Segment 1 I | |
> +| I--------------------------I | |
> +| I--------------------------I | |
> +| I Bank or Segment ... I | |
> +| I--------------------------I | |
> +| I--------------------------I | |
> +| I Bank or Segment n I | |
> +| I--------------------------I | |
> +|______________________________| |
> + |
> + Die 1 |
> +_______________________________ |
> +| I--------------------------I | |
> +| I Bank or Segment 0 I |<----|
> +| I--------------------------I |
> +| I--------------------------I |
> +| I Bank or Segment 1 I |
> +| I--------------------------I |
> +| I--------------------------I |
> +| I Bank or Segment ... I |
> +| I--------------------------I |
> +| I--------------------------I |
> +| I Bank or Segment n I |
> +| I--------------------------I |
> +|______________________________|
> +
> +In the above example, bank 0 of die 0 is interleaved with bank0 of die 0.
bank 0 of die 1.
> +The interleaving is done in HW by inverting some addresses lines. The goal is
in hardware
> +to improve DDR bandwidth.
> +Practically, one buffer seen as contiguous by the kernel might be spread
> +into two DDR dies physically.
> +
> +
> +2. Command-line parameters
> +
> +To buid the DDR physical layout representation, two parameters are requested:
build
> +
> +* ddr_die (mandatory): Should be added for every DDR dies present in the system.
die
> + - Usage: ddr_die=xxx[M|G]@yyy[M|G] where xxx represents the size and yyy
> + the base address of the die. E.g.: ddr_die=512M@0 ddr_die=512M@512M
> +
> +* interleaved (optionnal): Should be added for every interleaved dependencies.
(optional): for all interleaved dependencies.
> + - Usage: interleaved=xxx[M|G]@yyy[M|G]:zzz[M|G] where xxx is the size of
> + the interleaved area between the adresses yyy and zzz. E.g
> + interleaved=256M@0:512M
> +
> +
> +3. Allocator patching
> +
> +Any allocators might call the PASR Framework for DDR power savings. Currently,
> +only Linux Buddy allocator is patched, but HWMEM and PMEM physically
only the Linux Buddy
> +contiguous memory allocators will follow.
> +
> +Linux Buddy allocator porting uses Buddy specificities to reduce the overhead
> +induced by the PASR Framework counter updates. Indeed, the PASR Framework is
> +called only when MAX_ORDER (4MB page blocs by default) buddies are
blocks
> +inserted/removed from the free lists.
> +
> +To port PASR FW into a new allocator:
the PASR framework
> +
> +* Call pasr_put(phys_addr, size) each time a memory chunk becomes unused.
> +* Call pasr_get(phys_addr, size) each time a memory chunk becomes used.
> +
> +4. PASR platform drivers
> +
> +The MR16/MR17 PASR mask registers are generally accessible through the DDR
> +controller. At probe time, the DDR controller driver should register the
> +callback used by PASR Framework to apply the refresh mask for every DDR die
> +using pasr_register_mask_function(die_addr, callback, cookie).
> +
> +The callback passed to apply mask must not sleep since it can me called in
can be
> +interrupt contexts.
> +
--
~Randy
*** Remember to use Documentation/SubmitChecklist when testing your code ***
On 02/02/2012 04:51 AM, Randy Dunlap wrote:
> On 01/30/2012 05:33 AM, Maxime Coquelin wrote:
>> Signed-off-by: Maxime Coquelin<[email protected]>
>> ---
>> Documentation/pasr.txt | 183 ++++++++++++++++++++++++++++++++++++++++++++++++
>> 1 files changed, 183 insertions(+), 0 deletions(-)
>> create mode 100644 Documentation/pasr.txt
>>
>> diff --git a/Documentation/pasr.txt b/Documentation/pasr.txt
>> new file mode 100644
>> index 0000000..d40e3f6
>> --- /dev/null
>> +++ b/Documentation/pasr.txt
>> @@ -0,0 +1,183 @@
>> +Partial Array Self-Refresh Framework
>> +
>> +(C) 2012 Maxime Coquelin<[email protected]>, ST-Ericsson.
>> +
>> +CONTENT
>> +1. Introduction
>> +2. Command-line parameters
>> +3. Allocators patching
>> +4. PASR platform drivers
>> +
>> +
>> +1. Introduction
>> +
>> +PASR Frameworks brings support for the Partial Array Self-Refresh DDR power
> The PASR framework brings support
>
>> +management feature. PASR has been introduced in LP-DDR2, and is also present
> was introduced in LP-DDR2 and is also present
>
>
>> +in DDR3.
>> +
>> +PASR provides 4 modes:
>> +
>> +* Single-Ended: Only 1/1, 1/2, 1/4 or 1/8 are refreshed, masking starting at
>> + the end of the DDR die.
>> +
>> +* Double-Ended: Same as Single-Ended, but refresh-masking does not start
>> + necessairly at the end of the DDR die.
> necessarily
>
>> +
>> +* Bank-Selective: Refresh of each bank of a die can be masked or unmasked via
>> + a dedicated DDR register (MR16). This mode is convenient for DDR configured
>> + in BRC (Bank-Row-Column) mode.
>> +
>> +* Segment-Selective: Refresh of each segment of a die can be masked or unmasked
>> + via a dedicated DDR register (MR17). This mode is convenient for DDR configured
>> + in RBC (Row-Bank-Column) mode.
>> +
>> +The role of this framework is to stop the refresh of unused memory to enhance
>> +DDR power consumption.
>> +
>> +It supports Bank-Selective and Segment-Selective modes, as the more adapted to
>> +modern OSes.
> huh? parse error above.
>
>> +
>> +At early boot stage, a representation of the physical DDR layout is built:
>> +
>> + Die 0
>> +_______________________________
>> +| I--------------------------I |
>> +| I Bank or Segment 0 I |
>> +| I--------------------------I |
>> +| I--------------------------I |
>> +| I Bank or Segment 1 I |
>> +| I--------------------------I |
>> +| I--------------------------I |
>> +| I Bank or Segment ... I |
>> +| I--------------------------I |
>> +| I--------------------------I |
>> +| I Bank or Segment n I |
>> +| I--------------------------I |
>> +|______________________________|
>> + ...
>> +
>> + Die n
>> +_______________________________
>> +| I--------------------------I |
>> +| I Bank or Segment 0 I |
>> +| I--------------------------I |
>> +| I--------------------------I |
>> +| I Bank or Segment 1 I |
>> +| I--------------------------I |
>> +| I--------------------------I |
>> +| I Bank or Segment ... I |
>> +| I--------------------------I |
>> +| I--------------------------I |
>> +| I Bank or Segment n I |
>> +| I--------------------------I |
>> +|______________________________|
>> +
>> +The first level is a table where elements represent a die:
>> +* Base address,
>> +* Number of segments,
>> +* Table representing banks/segments,
>> +* MR16/MR17 refresh mask,
>> +* DDR Controller callback to update MR16/MR17 refresh mask.
>> +
>> +The second level is the section tables representing the banks or segments,
>> +depending on hardware configuration:
>> +* Base address,
>> +* Unused memory size counter,
>> +* Possible pointer to another section it depends on (E.g. Interleaving)
>> +
>> +When some memory becomes unused, the allocator owning this memory calls the PASR
>> +Framework's pasr_put(phys_addr, size) function. The framework finds the
>> +sections impacted and updates their counters accordingly.
>> +If a section counter reach the section size, the refresh of the section is
> reaches
>
>> +masked. If the corresponding section has a dependency with another section
>> +(E.g. because of DDR interleaving, see figure below), it checks the "paired" section is also
> it checks if the "paired" section is also
>
>> +unused before updating the refresh mask.
>> +
>> +When some unused memory is requested by the allocator, the allocator owning
>> +this memory calls the PASR Framework's pasr_get(phys_addr, size) function. The
>> +framework find the section impacted and updates their counters accordingly.
> finds and updates its counter accordingly.
> or
> find the sections impacted and updates their counters accordingly.
>
>
>> +If before the update, the section counter was to the section size, the refrewh
> was equal to the section size, the refresh
>
>> +of the section is unmasked. If the corresponding section has a dependency with
>> +another section, it also unmask the refresh of the other section.
> unmasks
>
>> +
>> +Interleaving example:
>> +
>> + Die 0
>> +_______________________________
>> +| I--------------------------I |
>> +| I Bank or Segment 0 I |<----|
>> +| I--------------------------I | |
>> +| I--------------------------I | |
>> +| I Bank or Segment 1 I | |
>> +| I--------------------------I | |
>> +| I--------------------------I | |
>> +| I Bank or Segment ... I | |
>> +| I--------------------------I | |
>> +| I--------------------------I | |
>> +| I Bank or Segment n I | |
>> +| I--------------------------I | |
>> +|______________________________| |
>> + |
>> + Die 1 |
>> +_______________________________ |
>> +| I--------------------------I | |
>> +| I Bank or Segment 0 I |<----|
>> +| I--------------------------I |
>> +| I--------------------------I |
>> +| I Bank or Segment 1 I |
>> +| I--------------------------I |
>> +| I--------------------------I |
>> +| I Bank or Segment ... I |
>> +| I--------------------------I |
>> +| I--------------------------I |
>> +| I Bank or Segment n I |
>> +| I--------------------------I |
>> +|______________________________|
>> +
>> +In the above example, bank 0 of die 0 is interleaved with bank0 of die 0.
> bank 0 of die 1.
>
>> +The interleaving is done in HW by inverting some addresses lines. The goal is
> in hardware
>
>> +to improve DDR bandwidth.
>> +Practically, one buffer seen as contiguous by the kernel might be spread
>> +into two DDR dies physically.
>> +
>> +
>> +2. Command-line parameters
>> +
>> +To buid the DDR physical layout representation, two parameters are requested:
> build
>
>> +
>> +* ddr_die (mandatory): Should be added for every DDR dies present in the system.
> die
>
>> + - Usage: ddr_die=xxx[M|G]@yyy[M|G] where xxx represents the size and yyy
>> + the base address of the die. E.g.: ddr_die=512M@0 ddr_die=512M@512M
>> +
>> +* interleaved (optionnal): Should be added for every interleaved dependencies.
> (optional): for all interleaved dependencies.
>
>
>> + - Usage: interleaved=xxx[M|G]@yyy[M|G]:zzz[M|G] where xxx is the size of
>> + the interleaved area between the adresses yyy and zzz. E.g
>> + interleaved=256M@0:512M
>> +
>> +
>> +3. Allocator patching
>> +
>> +Any allocators might call the PASR Framework for DDR power savings. Currently,
>> +only Linux Buddy allocator is patched, but HWMEM and PMEM physically
> only the Linux Buddy
>
>> +contiguous memory allocators will follow.
>> +
>> +Linux Buddy allocator porting uses Buddy specificities to reduce the overhead
>> +induced by the PASR Framework counter updates. Indeed, the PASR Framework is
>> +called only when MAX_ORDER (4MB page blocs by default) buddies are
> blocks
>
>> +inserted/removed from the free lists.
>> +
>> +To port PASR FW into a new allocator:
> the PASR framework
>
>> +
>> +* Call pasr_put(phys_addr, size) each time a memory chunk becomes unused.
>> +* Call pasr_get(phys_addr, size) each time a memory chunk becomes used.
>> +
>> +4. PASR platform drivers
>> +
>> +The MR16/MR17 PASR mask registers are generally accessible through the DDR
>> +controller. At probe time, the DDR controller driver should register the
>> +callback used by PASR Framework to apply the refresh mask for every DDR die
>> +using pasr_register_mask_function(die_addr, callback, cookie).
>> +
>> +The callback passed to apply mask must not sleep since it can me called in
> can be
>
>> +interrupt contexts.
>> +
>
Thanks Randy for the review.
Regards,
Maxime