X-Git-Url: http://pilppa.org/gitweb/gitweb.cgi?a=blobdiff_plain;f=Documentation%2FDocBook%2Fkernel-api.tmpl;h=b7b1482f6e04ebda24e665d0734fb4786bfc197a;hb=9afd561acabe5059ff16d163a176e2350269aba5;hp=f31601e8bd89acba6eaef4d27c5bd45eb2928edf;hpb=f6866fecd6fd8e44a6715da09844a4fd1b8484da;p=linux-2.6-omap-h63xx.git

diff --git a/Documentation/DocBook/kernel-api.tmpl b/Documentation/DocBook/kernel-api.tmpl
index f31601e8bd8..b7b1482f6e0 100644
--- a/Documentation/DocBook/kernel-api.tmpl
+++ b/Documentation/DocBook/kernel-api.tmpl
@@ -119,7 +119,7 @@ X!Ilib/string.c
 !Elib/string.c
      </sect1>
      <sect1><title>Bit Operations</title>
-!Iinclude/asm-x86/bitops_32.h
+!Iinclude/asm-x86/bitops.h
      </sect1>
   </chapter>
 
@@ -297,11 +297,6 @@ X!Earch/x86/kernel/mca_32.c
 !Ikernel/acct.c
   </chapter>
 
-  <chapter id="pmfuncs">
-     <title>Power Management</title>
-!Ekernel/power/pm.c
-  </chapter>
-
   <chapter id="devdrivers">
      <title>Device drivers infrastructure</title>
      <sect1><title>Device Drivers Base</title>
@@ -361,12 +356,14 @@ X!Edrivers/pnp/system.c
   <chapter id="blkdev">
      <title>Block Devices</title>
 !Eblock/blk-core.c
+!Iblock/blk-core.c
 !Eblock/blk-map.c
 !Iblock/blk-sysfs.c
 !Eblock/blk-settings.c
 !Eblock/blk-exec.c
 !Eblock/blk-barrier.c
 !Eblock/blk-tag.c
+!Iblock/blk-tag.c
   </chapter>
 
   <chapter id="chrdev">
@@ -648,4 +645,58 @@ X!Idrivers/video/console/fonts.c
 !Edrivers/i2c/i2c-core.c
   </chapter>
 
+  <chapter id="clk">
+     <title>Clock Framework</title>
+
+     <para>
+	The clock framework defines programming interfaces to support
+	software management of the system clock tree.
+	This framework is widely used with System-On-Chip (SOC) platforms
+	to support power management and various devices which may need
+	custom clock rates.
+	Note that these "clocks" don't relate to timekeeping or real
+	time clocks (RTCs), each of which have separate frameworks.
+	These <structname>struct clk</structname> instances may be used
+	to manage for example a 96 MHz signal that is used to shift bits
+	into and out of peripherals or busses, or otherwise trigger
+	synchronous state machine transitions in system hardware.
+     </para>
+
+     <para>
+	Power management is supported by explicit software clock gating:
+	unused clocks are disabled, so the system doesn't waste power
+	changing the state of transistors that aren't in active use.
+	On some systems this may be backed by hardware clock gating,
+	where clocks are gated without being disabled in software.
+	Sections of chips that are powered but not clocked may be able
+	to retain their last state.
+	This low power state is often called a <emphasis>retention
+	mode</emphasis>.
+	This mode still incurs leakage currents, especially with finer
+	circuit geometries, but for CMOS circuits power is mostly used
+	by clocked state changes.
+     </para>
+
+     <para>
+	Power-aware drivers only enable their clocks when the device
+	they manage is in active use.  Also, system sleep states often
+	differ according to which clock domains are active:  while a
+	"standby" state may allow wakeup from several active domains, a
+	"mem" (suspend-to-RAM) state may require a more wholesale shutdown
+	of clocks derived from higher speed PLLs and oscillators, limiting
+	the number of possible wakeup event sources.  A driver's suspend
+	method may need to be aware of system-specific clock constraints
+	on the target sleep state.
+     </para>
+
+     <para>
+        Some platforms support programmable clock generators.  These
+	can be used by external chips of various kinds, such as other
+	CPUs, multimedia codecs, and devices with strict requirements
+	for interface clocking.
+     </para>
+
+!Iinclude/linux/clk.h
+  </chapter>
+
 </book>