doc: implimenters: fix spelling

Signed-off-by: Mike Holmes <mike.holmes@linaro.org>

---
 doc/implementers-guide/implementers-guide.adoc | 26 +++++++++++++-------------
 1 file changed, 13 insertions(+), 13 deletions(-)

-- 
2.7.4

Thanks!

On Fri, Aug 5, 2016 at 10:37 AM, Mike Holmes <mike.holmes@linaro.org> wrote:

> Signed-off-by: Mike Holmes <mike.holmes@linaro.org>

>


Reviewed-by: Bill Fischofer <bill.fischofer@linaro.org>



> ---

>  doc/implementers-guide/implementers-guide.adoc | 26

> +++++++++++++-------------

>  1 file changed, 13 insertions(+), 13 deletions(-)

>

> diff --git a/doc/implementers-guide/implementers-guide.adoc

> b/doc/implementers-guide/implementers-guide.adoc

> index 5c0e864..0e2edc0 100644

> --- a/doc/implementers-guide/implementers-guide.adoc

> +++ b/doc/implementers-guide/implementers-guide.adoc

> @@ -29,7 +29,7 @@ mapping of the ODP APIs to a specific target platform.

> This is the focus of

>  this document.

>

>  - A Validation Test Suite. This is an independent set of routines that

> when

> -run against an ODP implmenetation verifies that it correctly implements

> all of

> +run against an ODP implementation verifies that it correctly implements

> all of

>  the defined ODP APIs at a functional level. The test suite is used by

>  implementers to self-certify their ODP implementation as well as by

>  third-parties to verify an implementation's claim to be ODP API compliant.

> @@ -39,18 +39,18 @@ fully defined in the _ODP User's Guide_

>

>  === Organization of this Document

>  This document is designed to serve two purposes. Its larger purpose is to

> -provide guidenace and practical advice for those wishing to implement ODP

> on

> +provide guidance and practical advice for those wishing to implement ODP

> on

>  their platform. To help with this, as well as to provide deeper insight

> into

>  how to think about ODP from an implementer's standpoint, this document

> also

>  discusses in some depth the design and organization of a specific ODP

>  implementation: the odp-linux reference implementation distributed as

> part of

>  the main ODP git repository. By grounding theory in practice and

> discussing

>  a particular example implementation, it is hoped this will provide

> insight into

> -the tradeoffs implementers should consider in approaching how to best

> implement

> +the trade-offs implementers should consider in approaching how to best

> implement

>  ODP on their platforms.

>

>  The section <<include_structure>> discusses the layout of the ODP include

> tree

> -from an implementer's perspective. Although implementers have wide

> lattitude

> +from an implementer's perspective. Although implementers have wide

> latitude

>  in how they organize their ODP implementations, it is recommended that

> this

>  layout be be observed by other implementations. Doing so both simplifies

> code

>  sharing with the odp-linux reference implementation and also ensure ease

> of

> @@ -637,7 +637,7 @@ It is recommended that however a platform wishes to

> represent ODP abstract

>  types, that it do so in a strongly typed manner. Using strong types means

>  that an application that tries to pass a variable of type `odp_packet_t`

> to

>  an API that expects an argument of type `odp_queue_t`, for example, will

> result

> -in a compililation error rather than some difficult to debug runtime

> failure.

> +in a compilation error rather than some difficult to debug runtime

> failure.

>

>  The *odp-linux* reference implementation defines all ODP abstract types

> strongly

>  using a set of utility macros contained in

> @@ -653,13 +653,13 @@ implementations choose typdefs and representations

> that permit the

>  implementation to realize ODP APIs efficiently. This typically means that

> the

>  handles defined by typedefs are either a pointer to an

> implementation-defined

>  struct or else an index into an implementation-defined resource table.

> The two

> -LNG-provided ODP reference implemnetations illustrate both of these

> approaches.

> +LNG-provided ODP reference implementations illustrate both of these

> approaches.

>  The *odp-dpdk* implementation follows the former approach (pointers) as

> this

>  offers the highest performance. For example, in *odp-dpdk* an

>  `odp_packet_t` is a pointer to an `rte_mbuf` struct, which is how DPDK

>  represents packets. The *odp-linux* implementation, by contrast, uses

> indices

>  as this permits more robust validation support while still being highly

> -efficient. In general, software-based implemnetations will typically favor

> +efficient. In general, software-based implementations will typically favor

>  pointers while hardware-based implementations will typically favor

> indices.

>

>  === ABI Considerations

> @@ -670,13 +670,13 @@ portability guarantees provided by APIs to permit

> binary portability as well.

>

>  It is important to note that ODP neither defines nor prohibits the

> specification

>  of ABIs. This is because ODP itself is an _Abstract API Specification_. As

> -noted earlier, abstract APIs cannot be compiled in the absense of

> completion

> +noted earlier, abstract APIs cannot be compiled in the absence of

> completion

>  by an implementation that instantiates them, so the question of ABIs is

>  really a question of representation agreement between multiple ODP

>  implementations. If two or more ODP implementations agree on things like

>  typedefs, endianness, alignments, etc., then they are defining an ABI

> which

> -would permit ODP applications compiled to that common set of instantations

> -to interoperate at a binary as well as source level.

> +would permit ODP applications compiled to that common set of

> instantiations

> +to inter operate at a binary as well as source level.

>

>  ==== Traditional ABI

>  ABIs can be defined at two levels. The simplest ABI is within a specific

> @@ -692,7 +692,7 @@ of typedefs, etc. so that the resulting output from

> compilation is directly

>  executable on any platform that subscribes to that ABI. Adding a new

> platform

>  in this approach simply requires that platform to accept the existing ABI

>  specification. Note that since the output of compilation in a traditional

> ABI

> -is a ISA-specific binary that applications cannot offer binary compability

> +is a ISA-specific binary that applications cannot offer binary

> compatibility

>  across platforms that use different ISAs.

>

>  ==== Bitcode based ABI

> @@ -716,9 +716,9 @@ library system selects the appropriate managed binary

> for that target platform

>  and loads and runs it.

>

>  Adding a new platform in this approach involves adding the definition for

> that

> -platform to the libary system so that a managed binary for it can be

> created

> +platform to the library system so that a managed binary for it can be

> created

>  and deployed as needed. This occurs without developer involvement since

> the

> -bitcode format that is input to this backend process is indepentent of the

> +bitcode format that is input to this backend process is independent of the

>  specific target platform. Note also that since bitcode is not tied to any

> ISA,

>  applications using bitcode ABIs are binary portable between platforms

> that use

>  different ISAs. This occurs without loss of efficiency because the

> process of

> --

> 2.7.4

>

>

Merged,
Maxim.

On 08/05/16 18:43, Bill Fischofer wrote:
> Thanks!

>

> On Fri, Aug 5, 2016 at 10:37 AM, Mike Holmes <mike.holmes@linaro.org> wrote:

>

>> Signed-off-by: Mike Holmes <mike.holmes@linaro.org>

>>

> Reviewed-by: Bill Fischofer <bill.fischofer@linaro.org>

>

>

>> ---

>>   doc/implementers-guide/implementers-guide.adoc | 26

>> +++++++++++++-------------

>>   1 file changed, 13 insertions(+), 13 deletions(-)

>>

>> diff --git a/doc/implementers-guide/implementers-guide.adoc

>> b/doc/implementers-guide/implementers-guide.adoc

>> index 5c0e864..0e2edc0 100644

>> --- a/doc/implementers-guide/implementers-guide.adoc

>> +++ b/doc/implementers-guide/implementers-guide.adoc

>> @@ -29,7 +29,7 @@ mapping of the ODP APIs to a specific target platform.

>> This is the focus of

>>   this document.

>>

>>   - A Validation Test Suite. This is an independent set of routines that

>> when

>> -run against an ODP implmenetation verifies that it correctly implements

>> all of

>> +run against an ODP implementation verifies that it correctly implements

>> all of

>>   the defined ODP APIs at a functional level. The test suite is used by

>>   implementers to self-certify their ODP implementation as well as by

>>   third-parties to verify an implementation's claim to be ODP API compliant.

>> @@ -39,18 +39,18 @@ fully defined in the _ODP User's Guide_

>>

>>   === Organization of this Document

>>   This document is designed to serve two purposes. Its larger purpose is to

>> -provide guidenace and practical advice for those wishing to implement ODP

>> on

>> +provide guidance and practical advice for those wishing to implement ODP

>> on

>>   their platform. To help with this, as well as to provide deeper insight

>> into

>>   how to think about ODP from an implementer's standpoint, this document

>> also

>>   discusses in some depth the design and organization of a specific ODP

>>   implementation: the odp-linux reference implementation distributed as

>> part of

>>   the main ODP git repository. By grounding theory in practice and

>> discussing

>>   a particular example implementation, it is hoped this will provide

>> insight into

>> -the tradeoffs implementers should consider in approaching how to best

>> implement

>> +the trade-offs implementers should consider in approaching how to best

>> implement

>>   ODP on their platforms.

>>

>>   The section <<include_structure>> discusses the layout of the ODP include

>> tree

>> -from an implementer's perspective. Although implementers have wide

>> lattitude

>> +from an implementer's perspective. Although implementers have wide

>> latitude

>>   in how they organize their ODP implementations, it is recommended that

>> this

>>   layout be be observed by other implementations. Doing so both simplifies

>> code

>>   sharing with the odp-linux reference implementation and also ensure ease

>> of

>> @@ -637,7 +637,7 @@ It is recommended that however a platform wishes to

>> represent ODP abstract

>>   types, that it do so in a strongly typed manner. Using strong types means

>>   that an application that tries to pass a variable of type `odp_packet_t`

>> to

>>   an API that expects an argument of type `odp_queue_t`, for example, will

>> result

>> -in a compililation error rather than some difficult to debug runtime

>> failure.

>> +in a compilation error rather than some difficult to debug runtime

>> failure.

>>

>>   The *odp-linux* reference implementation defines all ODP abstract types

>> strongly

>>   using a set of utility macros contained in

>> @@ -653,13 +653,13 @@ implementations choose typdefs and representations

>> that permit the

>>   implementation to realize ODP APIs efficiently. This typically means that

>> the

>>   handles defined by typedefs are either a pointer to an

>> implementation-defined

>>   struct or else an index into an implementation-defined resource table.

>> The two

>> -LNG-provided ODP reference implemnetations illustrate both of these

>> approaches.

>> +LNG-provided ODP reference implementations illustrate both of these

>> approaches.

>>   The *odp-dpdk* implementation follows the former approach (pointers) as

>> this

>>   offers the highest performance. For example, in *odp-dpdk* an

>>   `odp_packet_t` is a pointer to an `rte_mbuf` struct, which is how DPDK

>>   represents packets. The *odp-linux* implementation, by contrast, uses

>> indices

>>   as this permits more robust validation support while still being highly

>> -efficient. In general, software-based implemnetations will typically favor

>> +efficient. In general, software-based implementations will typically favor

>>   pointers while hardware-based implementations will typically favor

>> indices.

>>

>>   === ABI Considerations

>> @@ -670,13 +670,13 @@ portability guarantees provided by APIs to permit

>> binary portability as well.

>>

>>   It is important to note that ODP neither defines nor prohibits the

>> specification

>>   of ABIs. This is because ODP itself is an _Abstract API Specification_. As

>> -noted earlier, abstract APIs cannot be compiled in the absense of

>> completion

>> +noted earlier, abstract APIs cannot be compiled in the absence of

>> completion

>>   by an implementation that instantiates them, so the question of ABIs is

>>   really a question of representation agreement between multiple ODP

>>   implementations. If two or more ODP implementations agree on things like

>>   typedefs, endianness, alignments, etc., then they are defining an ABI

>> which

>> -would permit ODP applications compiled to that common set of instantations

>> -to interoperate at a binary as well as source level.

>> +would permit ODP applications compiled to that common set of

>> instantiations

>> +to inter operate at a binary as well as source level.

>>

>>   ==== Traditional ABI

>>   ABIs can be defined at two levels. The simplest ABI is within a specific

>> @@ -692,7 +692,7 @@ of typedefs, etc. so that the resulting output from

>> compilation is directly

>>   executable on any platform that subscribes to that ABI. Adding a new

>> platform

>>   in this approach simply requires that platform to accept the existing ABI

>>   specification. Note that since the output of compilation in a traditional

>> ABI

>> -is a ISA-specific binary that applications cannot offer binary compability

>> +is a ISA-specific binary that applications cannot offer binary

>> compatibility

>>   across platforms that use different ISAs.

>>

>>   ==== Bitcode based ABI

>> @@ -716,9 +716,9 @@ library system selects the appropriate managed binary

>> for that target platform

>>   and loads and runs it.

>>

>>   Adding a new platform in this approach involves adding the definition for

>> that

>> -platform to the libary system so that a managed binary for it can be

>> created

>> +platform to the library system so that a managed binary for it can be

>> created

>>   and deployed as needed. This occurs without developer involvement since

>> the

>> -bitcode format that is input to this backend process is indepentent of the

>> +bitcode format that is input to this backend process is independent of the

>>   specific target platform. Note also that since bitcode is not tied to any

>> ISA,

>>   applications using bitcode ABIs are binary portable between platforms

>> that use

>>   different ISAs. This occurs without loss of efficiency because the

>> process of

>> --

>> 2.7.4

>>

>>