xref: /freebsd/sys/dev/isci/scil/sci_overview.h (revision ae7e8a02e6e93455e026036132c4d053b2c12ad9)
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56 #ifndef _SCI_OVERVIEW_H_
57 #define _SCI_OVERVIEW_H_
58 
59 /**
60 @mainpage The Intel Storage Controller Interface (SCI)
61 
62 SCI provides a common interface across intel storage controller hardware.
63 This includes abstracting differences between Physical PCI functions and
64 Virtual PCI functions.  The SCI is comprised of four primary components:
65 -# SCI Base classes
66 -# SCI Core
67 -# SCI Framework
68 
69 It is important to recognize that no component, object, or functionality in
70 SCI directly allocates memory from the operating system.  It is expected that
71 the SCI User (OS specific driver code) allocates and frees all memory from
72 and to the operating system itself.
73 
74 The C language is utilized to implement SCI.  Although C is not an object
75 oriented language the SCI driver components, methods, and structures are
76 modeled and organized following object oriented principles.
77 
78 The Unified Modeling Language is utilized to present graphical depictions
79 of the SCI classes and their relationships.
80 
81 The following figure denotes the meanings of the colors utilized in UML
82 diagrams throughout this document.
83 @image latex object_color_key.eps "Object Color Legend" width=8cm
84 
85 The following figure denotes the meanings for input and output arrows that
86 are utilized to define parameters for methods defined in this specification.
87 @image latex arrow_image.eps "Method Parameter Symbol Definition"
88 
89 @page abbreviations_section Abbreviations
90 
91 - ATA: Advanced Technology Attachment
92 - IAF: Identify Address Frame
93 - SAS: Serial Attached SCSI
94 - SAT: SCSI to ATA Translation
95 - SATA: Serial ATA
96 - SCI: Storage Controller Interface
97 - SCIC: SCI Core
98 - SCIF: SCI Framework
99 - SCU: Storage Controller Unit
100 - SDS: SCU Driver Standard (i.e. non-virtualization)
101 - SDV: SCU Driver Virtualized
102 - SDVP: SDV Physical (PCI function)
103 - SDVV: SDV Virtual (PCI function)
104 - SGE: Scatter-Gather Element
105 - SGL: Scatter-Gather List
106 - SGPIO: Serial General Purpose Input/Output
107 - SSC: Spread Spectrum Clocking
108 
109 @page definitions_section Definitions
110 
111 - <b>construct</b> - The term "construct" is utilized throughout the
112   interface to indicate when an object is being created.  Typically construct
113   methods perform pure memory initialization.  No "construct" method ever
114   performs memory allocation.  It is incumbent upon the SCI user to provide
115   the necessary memory.
116 - <b>initialize</b> - The term "initialize" is utilized throughout the
117   interface to indicate when an object is performing actions on other objects
118   or on physical resources in an attempt to allow these resources to become
119   operational.
120 - <b>protected</b> - The term "protected" is utilized to denote a method
121   defined in this standard that MUST NOT be invoked directly by operating
122   system specific driver code.
123 - <b>SCI Component</b> - An SCI component is one of: SCI base classes, Core,
124   or Framework.
125 - <b>SCI User</b> - The user callbacks for each SCI Component represent the
126   dependencies that the SCI component implementation has upon the operating
127   system/environment specific portion of the driver.  It is essentially a
128   set of functions or macro definitions that are specific to a particular
129   operating system.
130 - <b>THIN</b> - A term utilized to describe an SCI Component implementation
131   that is built to conserve memory.
132 
133 @page inheritance SCI Inheritance Hierarchy
134 
135 This section describes the inheritance (i.e. "is-a") relationships between
136 the various objects in SCI.  Due to various operating environment requirements
137 the programming language employed for the SCI driver is C.  As a result, one
138 might be curious how inheritance shall be applied in such an environment.
139 The SCI driver source shall maintain generalization relationships by ensuring
140 that child object structures shall contain an instance of their parent's
141 structure as the very first member of their structure.  As a result, parent
142 object methods can be invoked with a child structure parameter.  This works
143 since casting of the child structure to the parent structure inside the parent
144 method will yield correct access to the parent structure fields.
145 
146 Consider the following example:
147 <pre>
148 typedef struct SCI_OBJECT
149 {
150    U32 object_type;
151 };
152 
153 typedef struct SCI_CONTROLLER
154 {
155    U32 state;
156 
157 } SCI_CONTROLLER_T;
158 
159 typedef struct SCIC_CONTROLLER
160 {
161    SCI_CONTROLLER_T parent;
162    U32 type;
163 
164 } SCIC_CONTROLLER_T;
165 </pre>
166 
167 With the above structure orientation, a user would be allowed to perform
168 method invocations in a manner similar to the following:
169 <pre>
170 SCIC_CONTROLLER_T scic_controller;
171 scic_controller_initialize((SCIC_CONTROLLER_T*) &scic_controller);
172 
173 // OR
174 
175 sci_object_get_association(&scic_controller);
176 </pre>
177 @note The actual interface will not require type casting.
178 
179 The following diagram graphically depicts the inheritance relationships
180 between the various objects defined in the Storage Controller Interface.
181 @image latex inheritance.eps "SCI Inheritance Hierarchy" width=16cm
182 
183 @page sci_classes SCI Classes
184 
185 This section depicts the common classes and utility functions across the
186 entire set of SCI Components.  Descriptions about each of the specific
187 objects will be found in the header file definition in the File Documentation
188 section.
189 
190 The following is a list of features that can be found in the SCI base classes:
191 -# Logging utility methods, constants, and type definitions
192 -# Memory Descriptor object methods common to the core and framework.
193 -# Controller object methods common to SCI derived controller objects.
194 -# Library object methods common to SCI derived library objects.
195 -# Storage standard (e.g. SAS, SATA) defined constants, structures, etc.
196 -# Standard types utilized by SCI sub-components.
197 -# The ability to associate/link SCI objects together or to user objects.
198 
199 SCI class methods can be overridden by sub-classes in the SCI Core,
200 SCI Framework, etc.  SCI class methods that MUST NOT be invoked directly
201 by operating system specific driver code shall be adorned with a
202 <code>[protected]</code> keyword.  These <code>[protected]</code> API are still
203 defined as part of the specification in order to demonstrate commonality across
204 components as well as provide a common description of related methods.  If
205 these methods are invoked directly by operating system specific code, the
206 operation of the driver as a whole is not specified or supported.
207 
208 The following UML diagram graphically depicts the SCI base classes and their
209 relationships to one another.
210 @image latex sci_base_classes.eps "SCI Classes" width=4cm
211 
212 @page associations_section Associations
213 The sci_object class provides functionality common to all SCI objects.
214 An important feature provided by this base class is the means by which to
215 associate one object to another.  An SCI object can be made to have an
216 association to another SCI object.  Additionally, an SCI object can be
217 made to have an association to a non-SCI based object.  For example, an SCI
218 Framework library can have it's association set to an operating system
219 specific adapter/device driver structure.
220 
221 Simply put, the association that an object has is a handle (i.e. a void pointer)
222 to a user structure.  This enables the user of the SCI object to
223 easily determine it's own associated structure. This association is useful
224 because the user is now enabled to easily determine their pertinent information
225 inside of their SCI user callback methods.
226 
227 Setting an association within an SCI object is generally optional.  The
228 primary case in which an association is not optional is in the case of IO
229 request objects.  These associations are necessary in order  to fill
230 to fill in appropriate information for an IO request (i.e. CDB address, size,
231 SGL information, etc.) in an efficient manner.
232 
233 In the case of other objects, the user is free to not create associations.
234 When the user chooses not to create an association, the user is responsible for
235 being able to determine their data structures based on the SCI object handles.
236 Additionally, the user may be forced to invoke additional functionality in
237 situations where the SCI Framework is employed.  If the user does not
238 establish proper associations between objects (i.e. SCIC Library to SCIF Library), then the framework is unable to automate interactions.  Users should
239 strongly consider establishing associations between SCI Framework objects and
240 OS Driver related structures.
241 
242 Example Associations:
243 - The user might set the scif_controller association to their adapter or
244 controller object.
245 - The user might set the scif_domain association to their SCSI bus object.
246 
247 If SCIF is being utilized, then the framework will set the associations
248 in the core.  In this situation, the user should only set the associations
249 in the framework objects, unless otherwise directed.
250 */
251 
252 #endif // _SCI_OVERVIEW_H_
253 
254