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-rw-r--r--doc/supplements/sh/BSP_TIMES247
-rw-r--r--doc/supplements/sh/Makefile156
-rw-r--r--doc/supplements/sh/bsp.t93
-rw-r--r--doc/supplements/sh/callconv.t (renamed from doc/supplements/sh/callconv.texi)0
-rw-r--r--doc/supplements/sh/cpumodel.t68
-rw-r--r--doc/supplements/sh/cputable.t109
-rw-r--r--doc/supplements/sh/fatalerr.t31
-rw-r--r--doc/supplements/sh/intr_NOTIMES.t196
-rw-r--r--doc/supplements/sh/memmodel.t39
-rw-r--r--doc/supplements/sh/preface.texi55
-rw-r--r--doc/supplements/sh/sh.texi120
-rw-r--r--doc/supplements/sh/timeBSP.t108
12 files changed, 1222 insertions, 0 deletions
diff --git a/doc/supplements/sh/BSP_TIMES b/doc/supplements/sh/BSP_TIMES
new file mode 100644
index 0000000000..82b8160aa5
--- /dev/null
+++ b/doc/supplements/sh/BSP_TIMES
@@ -0,0 +1,247 @@
+#
+# CPU MODEL/BSP Timing and Size Information
+#
+# $Id$
+#
+
+#
+# CPU Model Information
+#
+RTEMS_BSP BSPFORTIMES
+RTEMS_CPU_MODEL BSP_CPU_MODEL
+#
+# Interrupt Latency
+#
+# NOTE: In general, the text says it is hand-calculated to be
+# RTEMS_MAXIMUM_DISABLE_PERIOD at RTEMS_MAXIMUM_DISABLE_PERIOD_MHZ
+# Mhz and this was last calculated for Release
+# RTEMS_VERSION_FOR_MAXIMUM_DISABLE_PERIOD.
+#
+RTEMS_MAXIMUM_DISABLE_PERIOD TBD
+RTEMS_MAXIMUM_DISABLE_PERIOD_MHZ 20
+RTEMS_RELEASE_FOR_MAXIMUM_DISABLE_PERIOD 4.0.0
+#
+# Context Switch Times
+#
+RTEMS_NO_FP_CONTEXTS 35
+RTEMS_RESTORE_1ST_FP_TASK 39
+RTEMS_SAVE_INIT_RESTORE_INIT 66
+RTEMS_SAVE_IDLE_RESTORE_INIT 66
+RTEMS_SAVE_IDLE_RESTORE_IDLE 68
+#
+# Task Manager Times
+#
+RTEMS_TASK_CREATE_ONLY 148
+RTEMS_TASK_IDENT_ONLY 350
+RTEMS_TASK_START_ONLY 76
+RTEMS_TASK_RESTART_CALLING_TASK 95
+RTEMS_TASK_RESTART_SUSPENDED_RETURNS_TO_CALLER 89
+RTEMS_TASK_RESTART_BLOCKED_RETURNS_TO_CALLER 124
+RTEMS_TASK_RESTART_READY_RETURNS_TO_CALLER 92
+RTEMS_TASK_RESTART_SUSPENDED_PREEMPTS_CALLER 125
+RTEMS_TASK_RESTART_BLOCKED_PREEMPTS_CALLER 149
+RTEMS_TASK_RESTART_READY_PREEMPTS_CALLER 142
+RTEMS_TASK_DELETE_CALLING_TASK 170
+RTEMS_TASK_DELETE_SUSPENDED_TASK 138
+RTEMS_TASK_DELETE_BLOCKED_TASK 143
+RTEMS_TASK_DELETE_READY_TASK 144
+RTEMS_TASK_SUSPEND_CALLING_TASK 71
+RTEMS_TASK_SUSPEND_RETURNS_TO_CALLER 43
+RTEMS_TASK_RESUME_TASK_READIED_RETURNS_TO_CALLER 45
+RTEMS_TASK_RESUME_TASK_READIED_PREEMPTS_CALLER 67
+RTEMS_TASK_SET_PRIORITY_OBTAIN_CURRENT_PRIORITY 31
+RTEMS_TASK_SET_PRIORITY_RETURNS_TO_CALLER 64
+RTEMS_TASK_SET_PRIORITY_PREEMPTS_CALLER 106
+RTEMS_TASK_MODE_OBTAIN_CURRENT_MODE 14
+RTEMS_TASK_MODE_NO_RESCHEDULE 16
+RTEMS_TASK_MODE_RESCHEDULE_RETURNS_TO_CALLER 23
+RTEMS_TASK_MODE_RESCHEDULE_PREEMPTS_CALLER 60
+RTEMS_TASK_GET_NOTE_ONLY 33
+RTEMS_TASK_SET_NOTE_ONLY 33
+RTEMS_TASK_WAKE_AFTER_YIELD_RETURNS_TO_CALLER 16
+RTEMS_TASK_WAKE_AFTER_YIELD_PREEMPTS_CALLER 56
+RTEMS_TASK_WAKE_WHEN_ONLY 117
+#
+# Interrupt Manager
+#
+RTEMS_INTR_ENTRY_RETURNS_TO_NESTED 12
+RTEMS_INTR_ENTRY_RETURNS_TO_INTERRUPTED_TASK 9
+RTEMS_INTR_ENTRY_RETURNS_TO_PREEMPTING_TASK 9
+RTEMS_INTR_EXIT_RETURNS_TO_NESTED <1
+RTEMS_INTR_EXIT_RETURNS_TO_INTERRUPTED_TASK 8
+RTEMS_INTR_EXIT_RETURNS_TO_PREEMPTING_TASK 54
+#
+# Clock Manager
+#
+RTEMS_CLOCK_SET_ONLY 86
+RTEMS_CLOCK_GET_ONLY 1
+RTEMS_CLOCK_TICK_ONLY 17
+#
+# Timer Manager
+#
+RTEMS_TIMER_CREATE_ONLY 28
+RTEMS_TIMER_IDENT_ONLY 343
+RTEMS_TIMER_DELETE_INACTIVE 43
+RTEMS_TIMER_DELETE_ACTIVE 47
+RTEMS_TIMER_FIRE_AFTER_INACTIVE 58
+RTEMS_TIMER_FIRE_AFTER_ACTIVE 61
+RTEMS_TIMER_FIRE_WHEN_INACTIVE 88
+RTEMS_TIMER_FIRE_WHEN_ACTIVE 88
+RTEMS_TIMER_RESET_INACTIVE 54
+RTEMS_TIMER_RESET_ACTIVE 58
+RTEMS_TIMER_CANCEL_INACTIVE 31
+RTEMS_TIMER_CANCEL_ACTIVE 34
+#
+# Semaphore Manager
+#
+RTEMS_SEMAPHORE_CREATE_ONLY 60
+RTEMS_SEMAPHORE_IDENT_ONLY 367
+RTEMS_SEMAPHORE_DELETE_ONLY 58
+RTEMS_SEMAPHORE_OBTAIN_AVAILABLE 38
+RTEMS_SEMAPHORE_OBTAIN_NOT_AVAILABLE_NO_WAIT 38
+RTEMS_SEMAPHORE_OBTAIN_NOT_AVAILABLE_CALLER_BLOCKS 109
+RTEMS_SEMAPHORE_RELEASE_NO_WAITING_TASKS 44
+RTEMS_SEMAPHORE_RELEASE_TASK_READIED_RETURNS_TO_CALLER 66
+RTEMS_SEMAPHORE_RELEASE_TASK_READIED_PREEMPTS_CALLER 87
+#
+# Message Manager
+#
+RTEMS_MESSAGE_QUEUE_CREATE_ONLY 200
+RTEMS_MESSAGE_QUEUE_IDENT_ONLY 341
+RTEMS_MESSAGE_QUEUE_DELETE_ONLY 80
+RTEMS_MESSAGE_QUEUE_SEND_NO_WAITING_TASKS 97
+RTEMS_MESSAGE_QUEUE_SEND_TASK_READIED_RETURNS_TO_CALLER 101
+RTEMS_MESSAGE_QUEUE_SEND_TASK_READIED_PREEMPTS_CALLER 123
+RTEMS_MESSAGE_QUEUE_URGENT_NO_WAITING_TASKS 96
+RTEMS_MESSAGE_QUEUE_URGENT_TASK_READIED_RETURNS_TO_CALLER 101
+RTEMS_MESSAGE_QUEUE_URGENT_TASK_READIED_PREEMPTS_CALLER 123
+RTEMS_MESSAGE_QUEUE_BROADCAST_NO_WAITING_TASKS 53
+RTEMS_MESSAGE_QUEUE_BROADCAST_TASK_READIED_RETURNS_TO_CALLER 111
+RTEMS_MESSAGE_QUEUE_BROADCAST_TASK_READIED_PREEMPTS_CALLER 133
+RTEMS_MESSAGE_QUEUE_RECEIVE_AVAILABLE 79
+RTEMS_MESSAGE_QUEUE_RECEIVE_NOT_AVAILABLE_NO_WAIT 43
+RTEMS_MESSAGE_QUEUE_RECEIVE_NOT_AVAILABLE_CALLER_BLOCKS 114
+RTEMS_MESSAGE_QUEUE_FLUSH_NO_MESSAGES_FLUSHED 29
+RTEMS_MESSAGE_QUEUE_FLUSH_MESSAGES_FLUSHED 39
+#
+# Event Manager
+#
+RTEMS_EVENT_SEND_NO_TASK_READIED 24
+RTEMS_EVENT_SEND_TASK_READIED_RETURNS_TO_CALLER 60
+RTEMS_EVENT_SEND_TASK_READIED_PREEMPTS_CALLER 84
+RTEMS_EVENT_RECEIVE_OBTAIN_CURRENT_EVENTS 1
+RTEMS_EVENT_RECEIVE_AVAILABLE 28
+RTEMS_EVENT_RECEIVE_NOT_AVAILABLE_NO_WAIT 23
+RTEMS_EVENT_RECEIVE_NOT_AVAILABLE_CALLER_BLOCKS 84
+#
+# Signal Manager
+#
+RTEMS_SIGNAL_CATCH_ONLY 15
+RTEMS_SIGNAL_SEND_RETURNS_TO_CALLER 37
+RTEMS_SIGNAL_SEND_SIGNAL_TO_SELF 55
+RTEMS_SIGNAL_EXIT_ASR_OVERHEAD_RETURNS_TO_CALLING_TASK 37
+RTEMS_SIGNAL_EXIT_ASR_OVERHEAD_RETURNS_TO_PREEMPTING_TASK 54
+#
+# Partition Manager
+#
+RTEMS_PARTITION_CREATE_ONLY 70
+RTEMS_PARTITION_IDENT_ONLY 341
+RTEMS_PARTITION_DELETE_ONLY 42
+RTEMS_PARTITION_GET_BUFFER_AVAILABLE 35
+RTEMS_PARTITION_GET_BUFFER_NOT_AVAILABLE 33
+RTEMS_PARTITION_RETURN_BUFFER_ONLY 43
+#
+# Region Manager
+#
+RTEMS_REGION_CREATE_ONLY 63
+RTEMS_REGION_IDENT_ONLY 348
+RTEMS_REGION_DELETE_ONLY 39
+RTEMS_REGION_GET_SEGMENT_AVAILABLE 52
+RTEMS_REGION_GET_SEGMENT_NOT_AVAILABLE_NO_WAIT 49
+RTEMS_REGION_GET_SEGMENT_NOT_AVAILABLE_CALLER_BLOCKS 123
+RTEMS_REGION_RETURN_SEGMENT_NO_WAITING_TASKS 54
+RTEMS_REGION_RETURN_SEGMENT_TASK_READIED_RETURNS_TO_CALLER 114
+RTEMS_REGION_RETURN_SEGMENT_TASK_READIED_PREEMPTS_CALLER 136
+#
+# Dual-Ported Memory Manager
+#
+RTEMS_PORT_CREATE_ONLY 35
+RTEMS_PORT_IDENT_ONLY 340
+RTEMS_PORT_DELETE_ONLY 39
+RTEMS_PORT_INTERNAL_TO_EXTERNAL_ONLY 26
+RTEMS_PORT_EXTERNAL_TO_INTERNAL_ONLY 27
+#
+# IO Manager
+#
+RTEMS_IO_INITIALIZE_ONLY 4
+RTEMS_IO_OPEN_ONLY 2
+RTEMS_IO_CLOSE_ONLY 1
+RTEMS_IO_READ_ONLY 2
+RTEMS_IO_WRITE_ONLY 3
+RTEMS_IO_CONTROL_ONLY 2
+#
+# Rate Monotonic Manager
+#
+RTEMS_RATE_MONOTONIC_CREATE_ONLY 32
+RTEMS_RATE_MONOTONIC_IDENT_ONLY 341
+RTEMS_RATE_MONOTONIC_CANCEL_ONLY 39
+RTEMS_RATE_MONOTONIC_DELETE_ACTIVE 51
+RTEMS_RATE_MONOTONIC_DELETE_INACTIVE 48
+RTEMS_RATE_MONOTONIC_PERIOD_INITIATE_PERIOD_RETURNS_TO_CALLER 54
+RTEMS_RATE_MONOTONIC_PERIOD_CONCLUDE_PERIOD_CALLER_BLOCKS 74
+RTEMS_RATE_MONOTONIC_PERIOD_OBTAIN_STATUS 31
+#
+# Size Information
+#
+#
+# xxx alloted for numbers
+#
+RTEMS_DATA_SPACE 723
+RTEMS_MINIMUM_CONFIGURATION 18,980
+RTEMS_MAXIMUM_CONFIGURATION 36,438
+# x,xxx alloted for numbers
+RTEMS_CORE_CODE_SIZE 12,674
+RTEMS_INITIALIZATION_CODE_SIZE 970
+RTEMS_TASK_CODE_SIZE 3,562
+RTEMS_INTERRUPT_CODE_SIZE 54
+RTEMS_CLOCK_CODE_SIZE 334
+RTEMS_TIMER_CODE_SIZE 1,110
+RTEMS_SEMAPHORE_CODE_SIZE 1,632
+RTEMS_MESSAGE_CODE_SIZE 1,754
+RTEMS_EVENT_CODE_SIZE 1,000
+RTEMS_SIGNAL_CODE_SIZE 418
+RTEMS_PARTITION_CODE_SIZE 1,164
+RTEMS_REGION_CODE_SIZE 1,494
+RTEMS_DPMEM_CODE_SIZE 724
+RTEMS_IO_CODE_SIZE 686
+RTEMS_FATAL_ERROR_CODE_SIZE 24
+RTEMS_RATE_MONOTONIC_CODE_SIZE 1,212
+RTEMS_MULTIPROCESSING_CODE_SIZE 6.952
+# xxx alloted for numbers
+RTEMS_TIMER_CODE_OPTSIZE 184
+RTEMS_SEMAPHORE_CODE_OPTSIZE 172
+RTEMS_MESSAGE_CODE_OPTSIZE 288
+RTEMS_EVENT_CODE_OPTSIZE 56
+RTEMS_SIGNAL_CODE_OPTSIZE 56
+RTEMS_PARTITION_CODE_OPTSIZE 132
+RTEMS_REGION_CODE_OPTSIZE 160
+RTEMS_DPMEM_CODE_OPTSIZE 132
+RTEMS_IO_CODE_OPTSIZE 00
+RTEMS_RATE_MONOTONIC_CODE_OPTSIZE 184
+RTEMS_MULTIPROCESSING_CODE_OPTSIZE 332
+# xxx alloted for numbers
+RTEMS_BYTES_PER_TASK 400
+RTEMS_BYTES_PER_TIMER 68
+RTEMS_BYTES_PER_SEMAPHORE 124
+RTEMS_BYTES_PER_MESSAGE_QUEUE 148
+RTEMS_BYTES_PER_REGION 144
+RTEMS_BYTES_PER_PARTITION 56
+RTEMS_BYTES_PER_PORT 36
+RTEMS_BYTES_PER_PERIOD 36
+RTEMS_BYTES_PER_EXTENSION 64
+RTEMS_BYTES_PER_FP_TASK 332
+RTEMS_BYTES_PER_NODE 48
+RTEMS_BYTES_PER_GLOBAL_OBJECT 20
+RTEMS_BYTES_PER_PROXY 124
+# x,xxx alloted for numbers
+RTEMS_BYTES_OF_FIXED_SYSTEM_REQUIREMENTS 8,872
diff --git a/doc/supplements/sh/Makefile b/doc/supplements/sh/Makefile
new file mode 100644
index 0000000000..f16827b85a
--- /dev/null
+++ b/doc/supplements/sh/Makefile
@@ -0,0 +1,156 @@
+#
+# COPYRIGHT (c) 1988-1998.
+# On-Line Applications Research Corporation (OAR).
+# All rights reserved.
+#
+# $Id$
+#
+
+PROJECT=sh
+DISTRIBUTION_LEVEL=public
+
+include ../../Make.config
+
+REPLACE=../../tools/word-replace
+
+all: html info ps
+
+dirs:
+ $(make-dirs)
+
+COMMON_FILES=../../common/cpright.texi ../../common/setup.texi
+
+GENERATED_FILES=\
+ cpumodel.texi callconv.texi memmodel.texi intr.texi fatalerr.texi \
+ bsp.texi cputable.texi wksheets.texi timing.texi timeBSP.texi
+
+FILES= $(PROJECT).texi preface.texi \
+ $(COMMON_FILES) $(GENERATED_FILES)
+
+info: dirs c_$(PROJECT)
+ @echo NEED TO INSTALL THE INFO FILES
+ #cp c_$(PROJECT) c_$(PROJECT)-* $(INFO_INSTALL)
+ #cp c_$(PROJECT) c_$(PROJECT)-* $(INFO_INSTALL)
+
+c_$(PROJECT): $(FILES)
+ $(MAKEINFO) $(PROJECT).texi
+
+dvi: $(PROJECT).dvi
+ps: dirs $(PROJECT).ps
+
+$(PROJECT).ps: $(PROJECT).dvi
+ dvips -o $(PROJECT).ps $(PROJECT).dvi
+ cp $(PROJECT).ps $(PS_INSTALL)
+
+$(PROJECT).dvi: $(FILES)
+ $(TEXI2DVI) $(PROJECT).texi
+
+html: dirs $(FILES)
+ -mkdir -p $(WWW_INSTALL)/c_$(PROJECT)
+ $(TEXI2WWW) $(TEXI2WWW_ARGS) -dir $(WWW_INSTALL)/c_$(PROJECT) \
+ $(PROJECT).texi
+
+clean:
+ rm -f *.o $(PROG) *.txt core
+ rm -f *.dvi *.ps *.log *.aux *.cp *.fn *.ky *.pg *.toc *.tp *.vr $(BASE)
+ rm -f $(PROJECT) $(PROJECT)-*
+ rm -f c_$(PROJECT) c_$(PROJECT)-*
+ rm -f wksheets.t wksheets_NOTIMES.t
+ rm -f intr.t
+ rm -f timeBSP_.t timing.t
+ rm -f *.fixed _* $(GENERATED_FILES)
+ rm -f timeBSP_.t timeBSP_.texi
+
+#
+# Chapters which get automatic processing
+#
+cpumodel.texi: cpumodel.t Makefile
+ $(BMENU) -p "Preface" \
+ -u "Top" \
+ -n "Calling Conventions" ${*}.t
+
+callconv.texi: callconv.t Makefile
+ $(BMENU) -p "CPU Model Dependent Features Another Optional Feature" \
+ -u "Top" \
+ -n "Memory Model" ${*}.t
+
+memmodel.texi: memmodel.t Makefile
+ $(BMENU) -p "Calling Conventions User-Provided Routines" \
+ -u "Top" \
+ -n "Interrupt Processing" ${*}.t
+
+# Interrupt Chapter:
+# 1. Replace Times and Sizes
+# 2. Build Node Structure
+intr.t: intr_NOTIMES.t BSP_TIMES
+ ${REPLACE} -p BSP_TIMES intr_NOTIMES.t
+ mv intr_NOTIMES.t.fixed intr.t
+
+intr.texi: intr.t Makefile
+ $(BMENU) -p "Memory Model Flat Memory Model" \
+ -u "Top" \
+ -n "Default Fatal Error Processing" ${*}.t
+
+fatalerr.texi: fatalerr.t Makefile
+ $(BMENU) -p "Interrupt Processing Interrupt Stack" \
+ -u "Top" \
+ -n "Board Support Packages" ${*}.t
+
+bsp.texi: bsp.t Makefile
+ $(BMENU) -p "Default Fatal Error Processing Default Fatal Error Handler Operations" \
+ -u "Top" \
+ -n "Processor Dependent Information Table" ${*}.t
+
+cputable.texi: cputable.t Makefile
+ $(BMENU) -p "Board Support Packages Processor Initialization" \
+ -u "Top" \
+ -n "Memory Requirements" ${*}.t
+
+# Worksheets Chapter:
+# 1. Copy the Shared File
+# 2. Replace Times and Sizes
+# 3. Build Node Structure
+
+wksheets_NOTIMES.t: ../../common/wksheets.t
+ cp ../../common/wksheets.t wksheets_NOTIMES.t
+
+wksheets.t: wksheets_NOTIMES.t BSP_TIMES
+ ${REPLACE} -p BSP_TIMES wksheets_NOTIMES.t
+ mv wksheets_NOTIMES.t.fixed wksheets.t
+
+wksheets.texi: wksheets.t Makefile
+ $(BMENU) -p "Processor Dependent Information Table CPU Dependent Information Table" \
+ -u "Top" \
+ -n "Timing Specification" ${*}.t
+
+# Timing Specification Chapter:
+# 1. Copy the Shared File
+# 3. Build Node Structure
+
+timing.t: ../../common/timing.t
+ cp ../../common/timing.t timing.t
+
+timing.texi: timing.t Makefile
+ $(BMENU) -p "Memory Requirements RTEMS RAM Workspace Worksheet" \
+ -u "Top" \
+ -n "BSP_FOR_TIMES Timing Data" ${*}.t
+
+# Timing Data for BSP Chapter:
+# 1. Copy the Shared File
+# 2. Replace Times and Sizes
+# 3. Build Node Structure
+
+timeBSP_.t: ../../common/timetbl.t timeBSP.t Makefile
+ cat timeBSP.t ../../common/timetbl.t >timeBSP_.t
+ @echo >>timeBSP_.t
+ @echo "@tex" >>timeBSP_.t
+ @echo "\\global\\advance \\smallskipamount by 4pt" >>timeBSP_.t
+ @echo "@end tex" >>timeBSP_.t
+ ${REPLACE} -p BSP_TIMES timeBSP_.t
+ mv timeBSP_.t.fixed timeBSP_.t
+
+timeBSP.texi: timeBSP_.t Makefile
+ $(BMENU) -p "Timing Specification Terminology" \
+ -u "Top" \
+ -n "Command and Variable Index" timeBSP_.t
+ mv timeBSP_.texi timeBSP.texi
diff --git a/doc/supplements/sh/bsp.t b/doc/supplements/sh/bsp.t
new file mode 100644
index 0000000000..1f0de98d9d
--- /dev/null
+++ b/doc/supplements/sh/bsp.t
@@ -0,0 +1,93 @@
+@c
+@c COPYRIGHT (c) 1988-1998.
+@c On-Line Applications Research Corporation (OAR).
+@c All rights reserved.
+@c
+@c $Id$
+@c
+
+@chapter Board Support Packages
+
+@section Introduction
+
+An RTEMS Board Support Package (BSP) must be designed
+to support a particular processor and target board combination.
+This chapter presents a discussion of XXX specific BSP
+issues. For more information on developing a BSP, refer to the
+chapter titled Board Support Packages in the RTEMS
+Applications User's Guide.
+
+@section System Reset
+
+An RTEMS based application is initiated or
+re-initiated when the XXX processor is reset. When the
+XXX is reset, the processor performs the following actions:
+
+@itemize @bullet
+@item The tracing bits of the status register are cleared to
+disable tracing.
+
+@item The supervisor interrupt state is entered by setting the
+supervisor (S) bit and clearing the master/interrupt (M) bit of
+the status register.
+
+@item The interrupt mask of the status register is set to
+level 7 to effectively disable all maskable interrupts.
+
+@item The vector base register (VBR) is set to zero.
+
+@item The cache control register (CACR) is set to zero to
+disable and freeze the processor cache.
+
+@item The interrupt stack pointer (ISP) is set to the value
+stored at vector 0 (bytes 0-3) of the exception vector table
+(EVT).
+
+@item The program counter (PC) is set to the value stored at
+vector 1 (bytes 4-7) of the EVT.
+
+@item The processor begins execution at the address stored in
+the PC.
+@end itemize
+
+@section Processor Initialization
+
+The address of the application's initialization code
+should be stored in the first vector of the EVT which will allow
+the immediate vectoring to the application code. If the
+application requires that the VBR be some value besides zero,
+then it should be set to the required value at this point. All
+tasks share the same XXX's VBR value. Because interrupts
+are enabled automatically by RTEMS as part of the initialize
+executive directive, the VBR MUST be set before this directive
+is invoked to insure correct interrupt vectoring. If processor
+caching is to be utilized, then it should be enabled during the
+reset application initialization code.
+
+In addition to the requirements described in the
+Board Support Packages chapter of the Applications User's
+Manual for the reset code which is executed before the call to
+initialize executive, the XXX version has the following
+specific requirements:
+
+@itemize @bullet
+@item Must leave the S bit of the status register set so that
+the XXX remains in the supervisor state.
+
+@item Must set the M bit of the status register to remove the
+XXX from the interrupt state.
+
+@item Must set the master stack pointer (MSP) such that a
+minimum stack size of MINIMUM_STACK_SIZE bytes is provided for
+the initialize executive directive.
+
+@item Must initialize the XXX's vector table.
+@end itemize
+
+Note that the BSP is not responsible for allocating
+or installing the interrupt stack. RTEMS does this
+automatically as part of initialization. If the BSP does not
+install an interrupt stack and -- for whatever reason -- an
+interrupt occurs before initialize_executive is invoked, then
+the results are unpredictable.
+
diff --git a/doc/supplements/sh/callconv.texi b/doc/supplements/sh/callconv.t
index adde30776c..adde30776c 100644
--- a/doc/supplements/sh/callconv.texi
+++ b/doc/supplements/sh/callconv.t
diff --git a/doc/supplements/sh/cpumodel.t b/doc/supplements/sh/cpumodel.t
new file mode 100644
index 0000000000..3540c1dc02
--- /dev/null
+++ b/doc/supplements/sh/cpumodel.t
@@ -0,0 +1,68 @@
+@c
+@c COPYRIGHT (c) 1988-1998.
+@c On-Line Applications Research Corporation (OAR).
+@c All rights reserved.
+@c
+@c $Id$
+@c
+
+@chapter CPU Model Dependent Features
+
+@section Introduction
+
+Microprocessors are generally classified into
+families with a variety of CPU models or implementations within
+that family. Within a processor family, there is a high level
+of binary compatibility. This family may be based on either an
+architectural specification or on maintaining compatibility with
+a popular processor. Recent microprocessor families such as the
+SPARC or PA-RISC are based on an architectural specification
+which is independent or any particular CPU model or
+implementation. Older families such as the M68xxx and the iX86
+evolved as the manufacturer strived to produce higher
+performance processor models which maintained binary
+compatibility with older models.
+
+RTEMS takes advantage of the similarity of the
+various models within a CPU family. Although the models do vary
+in significant ways, the high level of compatibility makes it
+possible to share the bulk of the CPU dependent executive code
+across the entire family. Each processor family supported by
+RTEMS has a list of features which vary between CPU models
+within a family. For example, the most common model dependent
+feature regardless of CPU family is the presence or absence of a
+floating point unit or coprocessor. When defining the list of
+features present on a particular CPU model, one simply notes
+that floating point hardware is or is not present and defines a
+single constant appropriately. Conditional compilation is
+utilized to include the appropriate source code for this CPU
+model's feature set. It is important to note that this means
+that RTEMS is thus compiled using the appropriate feature set
+and compilation flags optimal for this CPU model used. The
+alternative would be to generate a binary which would execute on
+all family members using only the features which were always
+present.
+
+This chapter presents the set of features which vary
+across SPARC implementations and are of importance to RTEMS.
+The set of CPU model feature macros are defined in the file
+c/src/exec/score/cpu/XXX/XXX.h based upon the particular CPU
+model defined on the compilation command line.
+
+@section CPU Model Name
+
+The macro CPU_MODEL_NAME is a string which designates
+the name of this CPU model. For example, for the MODEL
+processor, this macro is set to the string "XXX".
+
+@section Floating Point Unit
+
+The macro XXX_HAS_FPU is set to 1 to indicate that
+this CPU model has a hardware floating point unit and 0
+otherwise. It does not matter whether the hardware floating
+point support is incorporated on-chip or is an external
+coprocessor.
+
+@section Another Optional Feature
+
+The macro XXX
diff --git a/doc/supplements/sh/cputable.t b/doc/supplements/sh/cputable.t
new file mode 100644
index 0000000000..8018c4c8d3
--- /dev/null
+++ b/doc/supplements/sh/cputable.t
@@ -0,0 +1,109 @@
+@c
+@c COPYRIGHT (c) 1988-1998.
+@c On-Line Applications Research Corporation (OAR).
+@c All rights reserved.
+@c
+@c $Id$
+@c
+
+@chapter Processor Dependent Information Table
+
+@section Introduction
+
+Any highly processor dependent information required
+to describe a processor to RTEMS is provided in the CPU
+Dependent Information Table. This table is not required for all
+processors supported by RTEMS. This chapter describes the
+contents, if any, for a particular processor type.
+
+@section CPU Dependent Information Table
+
+The XXX version of the RTEMS CPU Dependent
+Information Table contains the information required to interface
+a Board Support Package and RTEMS on the XXX. This
+information is provided to allow RTEMS to interoperate
+effectively with the BSP. The C structure definition is given
+here:
+
+@example
+@group
+typedef struct @{
+ void (*pretasking_hook)( void );
+ void (*predriver_hook)( void );
+ void (*postdriver_hook)( void );
+ void (*idle_task)( void );
+ boolean do_zero_of_workspace;
+ unsigned32 idle_task_stack_size;
+ unsigned32 interrupt_stack_size;
+ unsigned32 extra_mpci_receive_server_stack;
+ void * (*stack_allocate_hook)( unsigned32 );
+ void (*stack_free_hook)( void* );
+ /* end of fields required on all CPUs */
+
+ /* XXX CPU family dependent stuff */
+@} rtems_cpu_table;
+@end group
+@end example
+
+@table @code
+@item pretasking_hook
+is the address of the user provided routine which is invoked
+once RTEMS APIs are initialized. This routine will be invoked
+before any system tasks are created. Interrupts are disabled.
+This field may be NULL to indicate that the hook is not utilized.
+
+@item predriver_hook
+is the address of the user provided
+routine that is invoked immediately before the
+the device drivers and MPCI are initialized. RTEMS
+initialization is complete but interrupts and tasking are disabled.
+This field may be NULL to indicate that the hook is not utilized.
+
+@item postdriver_hook
+is the address of the user provided
+routine that is invoked immediately after the
+the device drivers and MPCI are initialized. RTEMS
+initialization is complete but interrupts and tasking are disabled.
+This field may be NULL to indicate that the hook is not utilized.
+
+@item idle_task
+is the address of the optional user
+provided routine which is used as the system's IDLE task. If
+this field is not NULL, then the RTEMS default IDLE task is not
+used. This field may be NULL to indicate that the default IDLE
+is to be used.
+
+@item do_zero_of_workspace
+indicates whether RTEMS should
+zero the Workspace as part of its initialization. If set to
+TRUE, the Workspace is zeroed. Otherwise, it is not.
+
+@item idle_task_stack_size
+is the size of the RTEMS idle task stack in bytes.
+If this number is less than MINIMUM_STACK_SIZE, then the
+idle task's stack will be MINIMUM_STACK_SIZE in byte.
+
+@item interrupt_stack_size
+is the size of the RTEMS
+allocated interrupt stack in bytes. This value must be at least
+as large as MINIMUM_STACK_SIZE.
+
+@item extra_mpci_receive_server_stack
+is the extra stack space allocated for the RTEMS MPCI receive server task
+in bytes. The MPCI receive server may invoke nearly all directives and
+may require extra stack space on some targets.
+
+@item stack_allocate_hook
+is the address of the optional user provided routine which allocates
+memory for task stacks. If this hook is not NULL, then a stack_free_hook
+must be provided as well.
+
+@item stack_free_hook
+is the address of the optional user provided routine which frees
+memory for task stacks. If this hook is not NULL, then a stack_allocate_hook
+must be provided as well.
+
+@item XXX
+is where the CPU family dependent stuff goes.
+
+@end table
diff --git a/doc/supplements/sh/fatalerr.t b/doc/supplements/sh/fatalerr.t
new file mode 100644
index 0000000000..4a3548ed8e
--- /dev/null
+++ b/doc/supplements/sh/fatalerr.t
@@ -0,0 +1,31 @@
+@c
+@c COPYRIGHT (c) 1988-1998.
+@c On-Line Applications Research Corporation (OAR).
+@c All rights reserved.
+@c
+@c $Id$
+@c
+
+@chapter Default Fatal Error Processing
+
+@section Introduction
+
+Upon detection of a fatal error by either the
+application or RTEMS the fatal error manager is invoked. The
+fatal error manager will invoke the user-supplied fatal error
+handlers. If no user-supplied handlers are configured, the
+RTEMS provided default fatal error handler is invoked. If the
+user-supplied fatal error handlers return to the executive the
+default fatal error handler is then invoked. This chapter
+describes the precise operations of the default fatal error
+handler.
+
+@section Default Fatal Error Handler Operations
+
+The default fatal error handler which is invoked by
+the @code{rtems_fatal_error_occurred} directive when there is
+no user handler configured or the user handler returns control to
+RTEMS. The default fatal error handler disables processor interrupts,
+places the error code in @b{XXX}, and executes a @code{XXX}
+instruction to simulate a halt processor instruction.
+
diff --git a/doc/supplements/sh/intr_NOTIMES.t b/doc/supplements/sh/intr_NOTIMES.t
new file mode 100644
index 0000000000..deb645781a
--- /dev/null
+++ b/doc/supplements/sh/intr_NOTIMES.t
@@ -0,0 +1,196 @@
+@c
+@c Interrupt Stack Frame Picture
+@c
+@c COPYRIGHT (c) 1988-1998.
+@c On-Line Applications Research Corporation (OAR).
+@c All rights reserved.
+@c
+@c $Id$
+@c
+
+@chapter Interrupt Processing
+
+@section Introduction
+
+Different types of processors respond to the
+occurrence of an interrupt in its own unique fashion. In
+addition, each processor type provides a control mechanism to
+allow for the proper handling of an interrupt. The processor
+dependent response to the interrupt modifies the current
+execution state and results in a change in the execution stream.
+Most processors require that an interrupt handler utilize some
+special control mechanisms to return to the normal processing
+stream. Although RTEMS hides many of the processor dependent
+details of interrupt processing, it is important to understand
+how the RTEMS interrupt manager is mapped onto the processor's
+unique architecture. Discussed in this chapter are the XXX's
+interrupt response and control mechanisms as they pertain to
+RTEMS.
+
+@section Vectoring of an Interrupt Handler
+
+Depending on whether or not the particular CPU
+supports a separate interrupt stack, the XXX family has two
+different interrupt handling models.
+
+@subsection Models Without Separate Interrupt Stacks
+
+Upon receipt of an interrupt the XXX family
+members without separate interrupt stacks automatically perform
+the following actions:
+
+@itemize @bullet
+@item To Be Written
+@end itemize
+
+@subsection Models With Separate Interrupt Stacks
+
+Upon receipt of an interrupt the XXX family
+members with separate interrupt stacks automatically perform the
+following actions:
+
+@itemize @bullet
+@item saves the current status register (SR),
+
+@item clears the master/interrupt (M) bit of the SR to
+indicate the switch from master state to interrupt state,
+
+@item sets the privilege mode to supervisor,
+
+@item suppresses tracing,
+
+@item sets the interrupt mask level equal to the level of the
+interrupt being serviced,
+
+@item pushes an interrupt stack frame (ISF), which includes
+the program counter (PC), the status register (SR), and the
+format/exception vector offset (FVO) word, onto the supervisor
+and interrupt stacks,
+
+@item switches the current stack to the interrupt stack and
+vectors to an interrupt service routine (ISR). If the ISR was
+installed with the interrupt_catch directive, then the RTEMS
+interrupt handler will begin execution. The RTEMS interrupt
+handler saves all registers which are not preserved according to
+the calling conventions and invokes the application's ISR.
+@end itemize
+
+A nested interrupt is processed similarly by these
+CPU models with the exception that only a single ISF is placed
+on the interrupt stack and the current stack need not be
+switched.
+
+The FVO word in the Interrupt Stack Frame is examined
+by RTEMS to determine when an outer most interrupt is being
+exited. Since the FVO is used by RTEMS for this purpose, the
+user application code MUST NOT modify this field.
+
+The following shows the Interrupt Stack Frame for
+XXX CPU models with separate interrupt stacks:
+
+@ifset use-ascii
+@example
+@group
+ +----------------------+
+ | Status Register | 0x0
+ +----------------------+
+ | Program Counter High | 0x2
+ +----------------------+
+ | Program Counter Low | 0x4
+ +----------------------+
+ | Format/Vector Offset | 0x6
+ +----------------------+
+@end group
+@end example
+@end ifset
+
+@ifset use-tex
+@sp 1
+@tex
+\centerline{\vbox{\offinterlineskip\halign{
+\strut\vrule#&
+\hbox to 2.00in{\enskip\hfil#\hfil}&
+\vrule#&
+\hbox to 0.50in{\enskip\hfil#\hfil}
+\cr
+\multispan{3}\hrulefill\cr
+& Status Register && 0x0\cr
+\multispan{3}\hrulefill\cr
+& Program Counter High && 0x2\cr
+\multispan{3}\hrulefill\cr
+& Program Counter Low && 0x4\cr
+\multispan{3}\hrulefill\cr
+& Format/Vector Offset && 0x6\cr
+\multispan{3}\hrulefill\cr
+}}\hfil}
+@end tex
+@end ifset
+
+@ifset use-html
+@html
+<CENTER>
+ <TABLE COLS=2 WIDTH="40%" BORDER=2>
+<TR><TD ALIGN=center><STRONG>Status Register</STRONG></TD>
+ <TD ALIGN=center>0x0</TD></TR>
+<TR><TD ALIGN=center><STRONG>Program Counter High</STRONG></TD>
+ <TD ALIGN=center>0x2</TD></TR>
+<TR><TD ALIGN=center><STRONG>Program Counter Low</STRONG></TD>
+ <TD ALIGN=center>0x4</TD></TR>
+<TR><TD ALIGN=center><STRONG>Format/Vector Offset</STRONG></TD>
+ <TD ALIGN=center>0x6</TD></TR>
+ </TABLE>
+</CENTER>
+@end html
+@end ifset
+
+@section Interrupt Levels
+
+Eight levels (0-7) of interrupt priorities are
+supported by XXX family members with level seven (7) being
+the highest priority. Level zero (0) indicates that interrupts
+are fully enabled. Interrupt requests for interrupts with
+priorities less than or equal to the current interrupt mask
+level are ignored.
+
+Although RTEMS supports 256 interrupt levels, the
+XXX family only supports eight. RTEMS interrupt levels 0
+through 7 directly correspond to XXX interrupt levels. All
+other RTEMS interrupt levels are undefined and their behavior is
+unpredictable.
+
+@section Disabling of Interrupts by RTEMS
+
+During the execution of directive calls, critical
+sections of code may be executed. When these sections are
+encountered, RTEMS disables interrupts to level seven (7) before
+the execution of this section and restores them to the previous
+level upon completion of the section. RTEMS has been optimized
+to insure that interrupts are disabled for less than
+RTEMS_MAXIMUM_DISABLE_PERIOD microseconds on a
+RTEMS_MAXIMUM_DISABLE_PERIOD_MHZ Mhz XXX with
+zero wait states. These numbers will vary based the
+number of wait states and processor speed present on the target board.
+[NOTE: The maximum period with interrupts disabled is hand calculated. This
+calculation was last performed for Release
+RTEMS_RELEASE_FOR_MAXIMUM_DISABLE_PERIOD.]
+
+Non-maskable interrupts (NMI) cannot be disabled, and
+ISRs which execute at this level MUST NEVER issue RTEMS system
+calls. If a directive is invoked, unpredictable results may
+occur due to the inability of RTEMS to protect its critical
+sections. However, ISRs that make no system calls may safely
+execute as non-maskable interrupts.
+
+@section Interrupt Stack
+
+RTEMS allocates the interrupt stack from the
+Workspace Area. The amount of memory allocated for the
+interrupt stack is determined by the interrupt_stack_size field
+in the CPU Configuration Table. During the initialization
+process, RTEMS will install its interrupt stack.
+
+The XXX port of RTEMS supports a software managed
+dedicated interrupt stack on those CPU models which do not
+support a separate interrupt stack in hardware.
+
+
diff --git a/doc/supplements/sh/memmodel.t b/doc/supplements/sh/memmodel.t
new file mode 100644
index 0000000000..4cb46bab90
--- /dev/null
+++ b/doc/supplements/sh/memmodel.t
@@ -0,0 +1,39 @@
+@c
+@c COPYRIGHT (c) 1988-1998.
+@c On-Line Applications Research Corporation (OAR).
+@c All rights reserved.
+@c
+@c $Id$
+@c
+
+@chapter Memory Model
+
+@section Introduction
+
+A processor may support any combination of memory
+models ranging from pure physical addressing to complex demand
+paged virtual memory systems. RTEMS supports a flat memory
+model which ranges contiguously over the processor's allowable
+address space. RTEMS does not support segmentation or virtual
+memory of any kind. The appropriate memory model for RTEMS
+provided by the targeted processor and related characteristics
+of that model are described in this chapter.
+
+@section Flat Memory Model
+
+The XXX family supports a flat 32-bit address
+space with addresses ranging from 0x00000000 to 0xFFFFFFFF (4
+gigabytes). Each address is represented by a 32-bit value and
+is byte addressable. The address may be used to reference a
+single byte, word (2-bytes), or long word (4 bytes). Memory
+accesses within this address space are performed in big endian
+fashion by the processors in this family.
+
+Some of the XXX family members such as the
+XXX, XXX, and XXX support virtual memory and
+segmentation. The XXX requires external hardware support
+such as the XXX Paged Memory Management Unit coprocessor
+which is typically used to perform address translations for
+these systems. RTEMS does not support virtual memory or
+segmentation on any of the XXX family members.
+
diff --git a/doc/supplements/sh/preface.texi b/doc/supplements/sh/preface.texi
new file mode 100644
index 0000000000..05e8c3c4cd
--- /dev/null
+++ b/doc/supplements/sh/preface.texi
@@ -0,0 +1,55 @@
+@c
+@c COPYRIGHT (c) 1988-1998.
+@c On-Line Applications Research Corporation (OAR).
+@c All rights reserved.
+@c
+@c $Id$
+@c
+
+@ifinfo
+@node Preface, CPU Model Dependent Features, Top, Top
+@end ifinfo
+@unnumbered Preface
+
+The Real Time Executive for Multiprocessor Systems (RTEMS)
+is designed to be portable across multiple processor
+architectures. However, the nature of real-time systems makes
+it essential that the application designer understand certain
+processor dependent implementation details. These processor
+dependencies include calling convention, board support package
+issues, interrupt processing, exact RTEMS memory requirements,
+performance data, header files, and the assembly language
+interface to the executive.
+
+This document discusses the VENDOR XXX
+architecture dependencies in this port of RTEMS. The XXX
+family has a wide variety of CPU models within it. The part
+numbers ...
+
+XXX fill in some things here
+
+It is highly recommended that the XXX
+RTEMS application developer obtain and become familiar with the
+documentation for the processor being used as well as the
+documentation for the family as a whole.
+
+@subheading Architecture Documents
+
+For information on the XXX architecture,
+refer to the following documents available from VENDOR
+(@file{http//www.XXX.com/}):
+
+@itemize @bullet
+@item @cite{XXX Family Reference, VENDOR, PART NUMBER}.
+@end itemize
+
+@subheading MODEL SPECIFIC DOCUMENTS
+
+For information on specific processor models and
+their associated coprocessors, refer to the following documents:
+
+@itemize @bullet
+@item @cite{XXX MODEL Manual, VENDOR, PART NUMBER}.
+@item @cite{XXX MODEL Manual, VENDOR, PART NUMBER}.
+@end itemize
+
diff --git a/doc/supplements/sh/sh.texi b/doc/supplements/sh/sh.texi
new file mode 100644
index 0000000000..0ab844f8cb
--- /dev/null
+++ b/doc/supplements/sh/sh.texi
@@ -0,0 +1,120 @@
+\input ../../texinfo/texinfo @c -*-texinfo-*-
+@c %**start of header
+@setfilename c_sh
+@syncodeindex vr fn
+@synindex ky cp
+@paragraphindent 0
+@c @smallbook
+@c %**end of header
+
+@c
+@c COPYRIGHT (c) 1988-1998.
+@c On-Line Applications Research Corporation (OAR).
+@c All rights reserved.
+@c
+@c $Id$
+@c
+
+@c
+@c Master file for the Template Applications Supplement
+@c
+
+@include ../../common/setup.texi
+
+@ignore
+@ifinfo
+@format
+START-INFO-DIR-ENTRY
+* RTEMS Hitachi SH Applications Supplement (sh):
+END-INFO-DIR-ENTRY
+@end format
+@end ifinfo
+@end ignore
+
+@c
+@c Title Page Stuff
+@c
+
+@set edition @value{RTEMS-EDITION}
+@set version @value{RTEMS-VERSION}
+@set update-date @value{RTEMS-UPDATE-DATE}
+@set update-month @value{RTEMS-UPDATE-MONTH}
+
+@c
+@c I don't really like having a short title page. --joel
+@c
+@c @shorttitlepage RTEMS Hitachi SH Applications Supplement
+
+@setchapternewpage odd
+@settitle RTEMS Hitachi SH Applications Supplement
+@titlepage
+@finalout
+
+@title RTEMS Hitachi SH Applications Supplement
+@subtitle Edition @value{edition}, for RTEMS @value{version}
+@sp 1
+@subtitle @value{update-month}
+@author On-Line Applications Research Corporation
+@page
+
+@include ../../common/cpright.texi
+@end titlepage
+
+@c This prevents a black box from being printed on "overflow" lines.
+@c The alternative is to rework a sentence to avoid this problem.
+
+@include preface.texi
+@include cpumodel.texi
+@include callconv.texi
+@include memmodel.texi
+@include intr.texi
+@include fatalerr.texi
+@include bsp.texi
+@include cputable.texi
+@include wksheets.texi
+@include timing.texi
+@include timeBSP.texi
+@ifinfo
+@node Top, Preface, (dir), (dir)
+@top c_sh
+
+This is the online version of the RTEMS Hitachi SH Applications Supplement.
+
+@menu
+* Preface::
+* CPU Model Dependent Features::
+* Calling Conventions::
+* Memory Model::
+* Interrupt Processing::
+* Default Fatal Error Processing::
+* Board Support Packages::
+* Processor Dependent Information Table::
+* Memory Requirements::
+* Timing Specification::
+* BSP_FOR_TIMES Timing Data::
+* Command and Variable Index::
+* Concept Index::
+@end menu
+
+@end ifinfo
+@c
+@c
+@c Need to copy the emacs stuff and "trailer stuff" (index, toc) into here
+@c
+
+@node Command and Variable Index, Concept Index, BSP_FOR_TIMES Timing Data Rate Monotonic Manager, Top
+@unnumbered Command and Variable Index
+
+There are currently no Command and Variable Index entries.
+
+@c @printindex fn
+
+@node Concept Index, , Command and Variable Index, Top
+@unnumbered Concept Index
+
+There are currently no Concept Index entries.
+@c @printindex cp
+
+@c @contents
+@bye
+
diff --git a/doc/supplements/sh/timeBSP.t b/doc/supplements/sh/timeBSP.t
new file mode 100644
index 0000000000..8b35c5de13
--- /dev/null
+++ b/doc/supplements/sh/timeBSP.t
@@ -0,0 +1,108 @@
+@c
+@c COPYRIGHT (c) 1988-1998.
+@c On-Line Applications Research Corporation (OAR).
+@c All rights reserved.
+@c
+@c $Id$
+@c
+
+@include ../../common/timemac.texi
+@tex
+\global\advance \smallskipamount by -4pt
+@end tex
+
+@chapter BSP_FOR_TIMES Timing Data
+
+@section Introduction
+
+The timing data for the XXX version of RTEMS is
+provided along with the target dependent aspects concerning the
+gathering of the timing data. The hardware platform used to
+gather the times is described to give the reader a better
+understanding of each directive time provided. Also, provided
+is a description of the interrupt latency and the context switch
+times as they pertain to the XXX version of RTEMS.
+
+@section Hardware Platform
+
+All times reported except for the maximum period
+interrupts are disabled by RTEMS were measured using a Motorola
+BSP_FOR_TIMES CPU board. The BSP_FOR_TIMES is a 20Mhz board with one wait
+state dynamic memory and a XXX numeric coprocessor. The
+Zilog 8036 countdown timer on this board was used to measure
+elapsed time with a one-half microsecond resolution. All
+sources of hardware interrupts were disabled, although the
+interrupt level of the XXX allows all interrupts.
+
+The maximum period interrupts are disabled was
+measured by summing the number of CPU cycles required by each
+assembly language instruction executed while interrupts were
+disabled. The worst case times of the XXX microprocessor
+were used for each instruction. Zero wait state memory was
+assumed. The total CPU cycles executed with interrupts
+disabled, including the instructions to disable and enable
+interrupts, was divided by 20 to simulate a 20Mhz XXX. It
+should be noted that the worst case instruction times for the
+XXX assume that the internal cache is disabled and that no
+instructions overlap.
+
+@section Interrupt Latency
+
+The maximum period with interrupts disabled within
+RTEMS is less than RTEMS_MAXIMUM_DISABLE_PERIOD
+microseconds including the instructions
+which disable and re-enable interrupts. The time required for
+the XXX to vector an interrupt and for the RTEMS entry
+overhead before invoking the user's interrupt handler are a
+total of RTEMS_INTR_ENTRY_RETURNS_TO_PREEMPTING_TASK
+microseconds. These combine to yield a worst case
+interrupt latency of less than
+RTEMS_MAXIMUM_DISABLE_PERIOD + RTEMS_INTR_ENTRY_RETURNS_TO_PREEMPTING_TASK
+microseconds at 20Mhz. [NOTE: The maximum period with interrupts
+disabled was last determined for Release
+RTEMS_RELEASE_FOR_MAXIMUM_DISABLE_PERIOD.]
+
+It should be noted again that the maximum period with
+interrupts disabled within RTEMS is hand-timed and based upon
+worst case (i.e. CPU cache disabled and no instruction overlap)
+times for a 20Mhz XXX. The interrupt vector and entry
+overhead time was generated on an BSP_FOR_TIMES benchmark platform
+using the Multiprocessing Communications registers to generate
+as the interrupt source.
+
+@section Context Switch
+
+The RTEMS processor context switch time is RTEMS_NO_FP_CONTEXTS
+microseconds on the BSP_FOR_TIMES benchmark platform when no floating
+point context is saved or restored. Additional execution time
+is required when a TASK_SWITCH user extension is configured.
+The use of the TASK_SWITCH extension is application dependent.
+Thus, its execution time is not considered part of the raw
+context switch time.
+
+Since RTEMS was designed specifically for embedded
+missile applications which are floating point intensive, the
+executive is optimized to avoid unnecessarily saving and
+restoring the state of the numeric coprocessor. The state of
+the numeric coprocessor is only saved when an FLOATING_POINT
+task is dispatched and that task was not the last task to
+utilize the coprocessor. In a system with only one
+FLOATING_POINT task, the state of the numeric coprocessor will
+never be saved or restored. When the first FLOATING_POINT task
+is dispatched, RTEMS does not need to save the current state of
+the numeric coprocessor.
+
+The exact amount of time required to save and restore
+floating point context is dependent on whether an XXX or
+XXX is being used as well as the state of the numeric
+coprocessor. These numeric coprocessors define three operating
+states: initialized, idle, and busy. RTEMS places the
+coprocessor in the initialized state when a task is started or
+restarted. Once the task has utilized the coprocessor, it is in
+the idle state when floating point instructions are not
+executing and the busy state when floating point instructions
+are executing. The state of the coprocessor is task specific.
+
+The following table summarizes the context switch
+times for the BSP_FOR_TIMES benchmark platform:
+