doc/README.xtensa - github/trini/u-boot - Gitiles

 U-Boot for the Xtensa Architecture
 ==================================

 Xtensa Architecture and Diamond Cores
 -------------------------------------

 Xtensa is a configurable processor architecture from Tensilica, Inc.
 Diamond Cores are pre-configured instances available for license and
 SoC cores in the same manner as ARM, MIPS, etc.

 Xtensa licensees create their own Xtensa cores with selected features
 and custom instructions, registers and co-processors. The custom core
 is configured with Tensilica tools and built with Tensilica's Xtensa
 Processor Generator.

 There are an effectively infinite number of CPUs in the Xtensa
 architecture family. It is, however, not feasible to support individual
 Xtensa CPUs in U-Boot. Therefore, there is only a single 'xtensa' CPU
 in the cpu tree of U-Boot.

 In the same manner as the Linux port to Xtensa, U-Boot adapts to an
 individual Xtensa core configuration using a set of macros provided with
 the particular core. This is part of what is known as the hardware
 abstraction layer (HAL). For the purpose of U-Boot, the HAL consists only
 of a few header files. These provide CPP macros that customize sources,
 Makefiles, and the linker script.


 Adding support for an additional processor configuration
 --------------------------------------------------------

 The header files for one particular processor configuration are inside
 a variant-specific directory located in the arch/xtensa/include/asm
 directory. The name of that directory starts with 'arch-' followed by
 the name for the processor configuration, for example, arch-dc233c for
 the Diamond DC233 processor.

     core.h	Definitions for the core itself.

 The following files are part of the overlay but not used by U-Boot.

     tie.h	Co-processors and custom extensions defined
 		in the Tensilica Instruction Extension (TIE)
 		language.
     tie-asm.h	Assembly macros to access custom-defined registers
 		and states.


 Global Data Pointer, Exported Function Stubs, and the ABI
 ---------------------------------------------------------

 To support standalone applications launched with the "go" command,
 U-Boot provides a jump table of entrypoints to exported functions
 (grep for EXPORT_FUNC). The implementation for Xtensa depends on
 which ABI (or function calling convention) is used.

 Windowed ABI presents unique difficulties with the approach based on
 keeping global data pointer in dedicated register. Because the register
 window rotates during a call, there is no register that is constantly
 available for the gd pointer. Therefore, on xtensa gd is a simple
 global variable. Another difficulty arises from the requirement to have
 an 'entry' at the beginning of a function, which rotates the register
 file and reserves a stack frame. This is an integral part of the
 windowed ABI implemented in hardware. It makes using a jump table to an
 arbitrary (separately compiled) function a bit tricky. Use of a simple
 wrapper is also very tedious due to the need to move all possible
 register arguments and adjust the stack to handle arguments that cannot
 be passed in registers. The most efficient approach is to have the jump
 table perform the 'entry' so as to pretend it's the start of the real
 function. This requires decoding the target function's 'entry'
 instruction to determine the stack frame size, and adjusting the stack
 pointer accordingly, then jumping into the target function just after
 the 'entry'. Decoding depends on the processor's endianness so uses the
 HAL. The implementation (12 instructions) is in examples/stubs.c.


 Access to Invalid Memory Addresses
 ----------------------------------

 U-Boot does not check if memory addresses given as arguments to commands
 such as "md" are valid. There are two possible types of invalid
 addresses: an area of physical address space may not be mapped to RAM
 or peripherals, or in the presence of MMU an area of virtual address
 space may not be mapped to physical addresses.

 Accessing first type of invalid addresses may result in hardware lockup,
 reading of meaningless data, written data being ignored or an exception,
 depending on the CPU wiring to the system. Accessing second type of
 invalid addresses always ends with an exception.

 U-Boot for Xtensa provides a special memory exception handler that
 reports such access attempts and resets the board.


 ------------------------------------------------------------------------------
 Chris Zankel
 Ross Morley
	U-Boot for the Xtensa Architecture
	==================================

	Xtensa Architecture and Diamond Cores
	-------------------------------------

	Xtensa is a configurable processor architecture from Tensilica, Inc.
	Diamond Cores are pre-configured instances available for license and
	SoC cores in the same manner as ARM, MIPS, etc.

	Xtensa licensees create their own Xtensa cores with selected features
	and custom instructions, registers and co-processors. The custom core
	is configured with Tensilica tools and built with Tensilica's Xtensa
	Processor Generator.

	There are an effectively infinite number of CPUs in the Xtensa
	architecture family. It is, however, not feasible to support individual
	Xtensa CPUs in U-Boot. Therefore, there is only a single 'xtensa' CPU
	in the cpu tree of U-Boot.

	In the same manner as the Linux port to Xtensa, U-Boot adapts to an
	individual Xtensa core configuration using a set of macros provided with
	the particular core. This is part of what is known as the hardware
	abstraction layer (HAL). For the purpose of U-Boot, the HAL consists only
	of a few header files. These provide CPP macros that customize sources,
	Makefiles, and the linker script.


	Adding support for an additional processor configuration
	--------------------------------------------------------

	The header files for one particular processor configuration are inside
	a variant-specific directory located in the arch/xtensa/include/asm
	directory. The name of that directory starts with 'arch-' followed by
	the name for the processor configuration, for example, arch-dc233c for
	the Diamond DC233 processor.

	core.h Definitions for the core itself.

	The following files are part of the overlay but not used by U-Boot.

	tie.h Co-processors and custom extensions defined
	in the Tensilica Instruction Extension (TIE)
	language.
	tie-asm.h Assembly macros to access custom-defined registers
	and states.


	Global Data Pointer, Exported Function Stubs, and the ABI
	---------------------------------------------------------

	To support standalone applications launched with the "go" command,
	U-Boot provides a jump table of entrypoints to exported functions
	(grep for EXPORT_FUNC). The implementation for Xtensa depends on
	which ABI (or function calling convention) is used.

	Windowed ABI presents unique difficulties with the approach based on
	keeping global data pointer in dedicated register. Because the register
	window rotates during a call, there is no register that is constantly
	available for the gd pointer. Therefore, on xtensa gd is a simple
	global variable. Another difficulty arises from the requirement to have
	an 'entry' at the beginning of a function, which rotates the register
	file and reserves a stack frame. This is an integral part of the
	windowed ABI implemented in hardware. It makes using a jump table to an
	arbitrary (separately compiled) function a bit tricky. Use of a simple
	wrapper is also very tedious due to the need to move all possible
	register arguments and adjust the stack to handle arguments that cannot
	be passed in registers. The most efficient approach is to have the jump
	table perform the 'entry' so as to pretend it's the start of the real
	function. This requires decoding the target function's 'entry'
	instruction to determine the stack frame size, and adjusting the stack
	pointer accordingly, then jumping into the target function just after
	the 'entry'. Decoding depends on the processor's endianness so uses the
	HAL. The implementation (12 instructions) is in examples/stubs.c.


	Access to Invalid Memory Addresses
	----------------------------------

	U-Boot does not check if memory addresses given as arguments to commands
	such as "md" are valid. There are two possible types of invalid
	addresses: an area of physical address space may not be mapped to RAM
	or peripherals, or in the presence of MMU an area of virtual address
	space may not be mapped to physical addresses.

	Accessing first type of invalid addresses may result in hardware lockup,
	reading of meaningless data, written data being ignored or an exception,
	depending on the CPU wiring to the system. Accessing second type of
	invalid addresses always ends with an exception.

	U-Boot for Xtensa provides a special memory exception handler that
	reports such access attempts and resets the board.


	------------------------------------------------------------------------------
	Chris Zankel
	Ross Morley