[GitHub/mt8127/android_kernel_alcatel_ttab.git] / Documentation / arm / tcm.txt

ARM TCM (Tightly-Coupled Memory) handling in Linux
----
Written by Linus Walleij <linus.walleij@stericsson.com>

Some ARM SoC:s have a so-called TCM (Tightly-Coupled Memory).
This is usually just a few (4-64) KiB of RAM inside the ARM
processor.

Due to being embedded inside the CPU The TCM has a
Harvard-architecture, so there is an ITCM (instruction TCM)
and a DTCM (data TCM). The DTCM can not contain any
instructions, but the ITCM can actually contain data.
The size of DTCM or ITCM is minimum 4KiB so the typical
minimum configuration is 4KiB ITCM and 4KiB DTCM.

ARM CPU:s have special registers to read out status, physical
location and size of TCM memories. arch/arm/include/asm/cputype.h
defines a CPUID_TCM register that you can read out from the
system control coprocessor. Documentation from ARM can be found
at http://infocenter.arm.com, search for "TCM Status Register"
to see documents for all CPUs. Reading this register you can
determine if ITCM (bits 1-0) and/or DTCM (bit 17-16) is present
in the machine.

There is further a TCM region register (search for "TCM Region
Registers" at the ARM site) that can report and modify the location
size of TCM memories at runtime. This is used to read out and modify
TCM location and size. Notice that this is not a MMU table: you
actually move the physical location of the TCM around. At the
place you put it, it will mask any underlying RAM from the
CPU so it is usually wise not to overlap any physical RAM with
the TCM.

The TCM memory can then be remapped to another address again using
the MMU, but notice that the TCM if often used in situations where
the MMU is turned off. To avoid confusion the current Linux
implementation will map the TCM 1 to 1 from physical to virtual
memory in the location specified by the kernel. Currently Linux
will map ITCM to 0xfffe0000 and on, and DTCM to 0xfffe8000 and
on, supporting a maximum of 32KiB of ITCM and 32KiB of DTCM.

Newer versions of the region registers also support dividing these
TCMs in two separate banks, so for example an 8KiB ITCM is divided
into two 4KiB banks with its own control registers. The idea is to
be able to lock and hide one of the banks for use by the secure
world (TrustZone).

TCM is used for a few things:

- FIQ and other interrupt handlers that need deterministic
  timing and cannot wait for cache misses.

- Idle loops where all external RAM is set to self-refresh
  retention mode, so only on-chip RAM is accessible by
  the CPU and then we hang inside ITCM waiting for an
  interrupt.

- Other operations which implies shutting off or reconfiguring
  the external RAM controller.

There is an interface for using TCM on the ARM architecture
in <asm/tcm.h>. Using this interface it is possible to:

- Define the physical address and size of ITCM and DTCM.

- Tag functions to be compiled into ITCM.

- Tag data and constants to be allocated to DTCM and ITCM.

- Have the remaining TCM RAM added to a special
  allocation pool with gen_pool_create() and gen_pool_add()
  and provice tcm_alloc() and tcm_free() for this
  memory. Such a heap is great for things like saving
  device state when shutting off device power domains.

A machine that has TCM memory shall select HAVE_TCM from
arch/arm/Kconfig for itself. Code that needs to use TCM shall
#include <asm/tcm.h>

Functions to go into itcm can be tagged like this:
int __tcmfunc foo(int bar);

Since these are marked to become long_calls and you may want
to have functions called locally inside the TCM without
wasting space, there is also the __tcmlocalfunc prefix that
will make the call relative.

Variables to go into dtcm can be tagged like this:
int __tcmdata foo;

Constants can be tagged like this:
int __tcmconst foo;

To put assembler into TCM just use
.section ".tcm.text" or .section ".tcm.data"
respectively.

Example code:

#include <asm/tcm.h>

/* Uninitialized data */
static u32 __tcmdata tcmvar;
/* Initialized data */
static u32 __tcmdata tcmassigned = 0x2BADBABEU;
/* Constant */
static const u32 __tcmconst tcmconst = 0xCAFEBABEU;

static void __tcmlocalfunc tcm_to_tcm(void)
{
	int i;
	for (i = 0; i < 100; i++)
		tcmvar ++;
}

static void __tcmfunc hello_tcm(void)
{
	/* Some abstract code that runs in ITCM */
	int i;
	for (i = 0; i < 100; i++) {
		tcmvar ++;
	}
	tcm_to_tcm();
}

static void __init test_tcm(void)
{
	u32 *tcmem;
	int i;

	hello_tcm();
	printk("Hello TCM executed from ITCM RAM\n");

	printk("TCM variable from testrun: %u @ %p\n", tcmvar, &tcmvar);
	tcmvar = 0xDEADBEEFU;
	printk("TCM variable: 0x%x @ %p\n", tcmvar, &tcmvar);

	printk("TCM assigned variable: 0x%x @ %p\n", tcmassigned, &tcmassigned);

	printk("TCM constant: 0x%x @ %p\n", tcmconst, &tcmconst);

	/* Allocate some TCM memory from the pool */
	tcmem = tcm_alloc(20);
	if (tcmem) {
		printk("TCM Allocated 20 bytes of TCM @ %p\n", tcmem);
		tcmem[0] = 0xDEADBEEFU;
		tcmem[1] = 0x2BADBABEU;
		tcmem[2] = 0xCAFEBABEU;
		tcmem[3] = 0xDEADBEEFU;
		tcmem[4] = 0x2BADBABEU;
		for (i = 0; i < 5; i++)
			printk("TCM tcmem[%d] = %08x\n", i, tcmem[i]);
		tcm_free(tcmem, 20);
	}
}
Commit	Line	Data
bc581770 LW	1	ARM TCM (Tightly-Coupled Memory) handling in Linux
	2	----
	3	Written by Linus Walleij <linus.walleij@stericsson.com>
	4
	5	Some ARM SoC:s have a so-called TCM (Tightly-Coupled Memory).
	6	This is usually just a few (4-64) KiB of RAM inside the ARM
	7	processor.
	8
	9	Due to being embedded inside the CPU The TCM has a
	10	Harvard-architecture, so there is an ITCM (instruction TCM)
	11	and a DTCM (data TCM). The DTCM can not contain any
	12	instructions, but the ITCM can actually contain data.
	13	The size of DTCM or ITCM is minimum 4KiB so the typical
	14	minimum configuration is 4KiB ITCM and 4KiB DTCM.
	15
	16	ARM CPU:s have special registers to read out status, physical
	17	location and size of TCM memories. arch/arm/include/asm/cputype.h
	18	defines a CPUID_TCM register that you can read out from the
	19	system control coprocessor. Documentation from ARM can be found
	20	at http://infocenter.arm.com, search for "TCM Status Register"
	21	to see documents for all CPUs. Reading this register you can
1dbd30e9 LW	22	determine if ITCM (bits 1-0) and/or DTCM (bit 17-16) is present
1dbd30e9 LW	23	in the machine.
bc581770 LW	24
	25	There is further a TCM region register (search for "TCM Region
	26	Registers" at the ARM site) that can report and modify the location
	27	size of TCM memories at runtime. This is used to read out and modify
	28	TCM location and size. Notice that this is not a MMU table: you
	29	actually move the physical location of the TCM around. At the
	30	place you put it, it will mask any underlying RAM from the
	31	CPU so it is usually wise not to overlap any physical RAM with
610ea6c6	32	the TCM.
bc581770	33
610ea6c6 LW	34	The TCM memory can then be remapped to another address again using
	35	the MMU, but notice that the TCM if often used in situations where
	36	the MMU is turned off. To avoid confusion the current Linux
	37	implementation will map the TCM 1 to 1 from physical to virtual
1dbd30e9 LW	38	memory in the location specified by the kernel. Currently Linux
	39	will map ITCM to 0xfffe0000 and on, and DTCM to 0xfffe8000 and
	40	on, supporting a maximum of 32KiB of ITCM and 32KiB of DTCM.
	41
	42	Newer versions of the region registers also support dividing these
	43	TCMs in two separate banks, so for example an 8KiB ITCM is divided
	44	into two 4KiB banks with its own control registers. The idea is to
	45	be able to lock and hide one of the banks for use by the secure
	46	world (TrustZone).
bc581770 LW	47
	48	TCM is used for a few things:
	49
	50	- FIQ and other interrupt handlers that need deterministic
	51	timing and cannot wait for cache misses.
	52
	53	- Idle loops where all external RAM is set to self-refresh
	54	retention mode, so only on-chip RAM is accessible by
	55	the CPU and then we hang inside ITCM waiting for an
	56	interrupt.
	57
	58	- Other operations which implies shutting off or reconfiguring
	59	the external RAM controller.
	60
	61	There is an interface for using TCM on the ARM architecture
	62	in <asm/tcm.h>. Using this interface it is possible to:
	63
	64	- Define the physical address and size of ITCM and DTCM.
	65
	66	- Tag functions to be compiled into ITCM.
	67
	68	- Tag data and constants to be allocated to DTCM and ITCM.
	69
	70	- Have the remaining TCM RAM added to a special
	71	allocation pool with gen_pool_create() and gen_pool_add()
	72	and provice tcm_alloc() and tcm_free() for this
	73	memory. Such a heap is great for things like saving
	74	device state when shutting off device power domains.
	75
1dbd30e9 LW	76	A machine that has TCM memory shall select HAVE_TCM from
	77	arch/arm/Kconfig for itself. Code that needs to use TCM shall
	78	#include <asm/tcm.h>
bc581770 LW	79
	80	Functions to go into itcm can be tagged like this:
	81	int __tcmfunc foo(int bar);
	82
1dbd30e9 LW	83	Since these are marked to become long_calls and you may want
	84	to have functions called locally inside the TCM without
	85	wasting space, there is also the __tcmlocalfunc prefix that
	86	will make the call relative.
	87
bc581770 LW	88	Variables to go into dtcm can be tagged like this:
	89	int __tcmdata foo;
	90
	91	Constants can be tagged like this:
	92	int __tcmconst foo;
	93
	94	To put assembler into TCM just use
	95	.section ".tcm.text" or .section ".tcm.data"
	96	respectively.
	97
	98	Example code:
	99
	100	#include <asm/tcm.h>
	101
	102	/* Uninitialized data */
	103	static u32 __tcmdata tcmvar;
	104	/* Initialized data */
	105	static u32 __tcmdata tcmassigned = 0x2BADBABEU;
	106	/* Constant */
	107	static const u32 __tcmconst tcmconst = 0xCAFEBABEU;
	108
	109	static void __tcmlocalfunc tcm_to_tcm(void)
	110	{
	111	int i;
	112	for (i = 0; i < 100; i++)
	113	tcmvar ++;
	114	}
	115
	116	static void __tcmfunc hello_tcm(void)
	117	{
	118	/* Some abstract code that runs in ITCM */
	119	int i;
	120	for (i = 0; i < 100; i++) {
	121	tcmvar ++;
	122	}
	123	tcm_to_tcm();
	124	}
	125
	126	static void __init test_tcm(void)
	127	{
	128	u32 *tcmem;
	129	int i;
	130
	131	hello_tcm();
	132	printk("Hello TCM executed from ITCM RAM\n");
	133
	134	printk("TCM variable from testrun: %u @ %p\n", tcmvar, &tcmvar);
	135	tcmvar = 0xDEADBEEFU;
	136	printk("TCM variable: 0x%x @ %p\n", tcmvar, &tcmvar);
	137
	138	printk("TCM assigned variable: 0x%x @ %p\n", tcmassigned, &tcmassigned);
	139
	140	printk("TCM constant: 0x%x @ %p\n", tcmconst, &tcmconst);
	141
	142	/* Allocate some TCM memory from the pool */
	143	tcmem = tcm_alloc(20);
	144	if (tcmem) {
	145	printk("TCM Allocated 20 bytes of TCM @ %p\n", tcmem);
	146	tcmem[0] = 0xDEADBEEFU;
	147	tcmem[1] = 0x2BADBABEU;
	148	tcmem[2] = 0xCAFEBABEU;
	149	tcmem[3] = 0xDEADBEEFU;
	150	tcmem[4] = 0x2BADBABEU;
	151	for (i = 0; i < 5; i++)
152	printk("TCM tcmem[%d] = %08x\n", i, tcmem[i]);
153	tcm_free(tcmem, 20);
154	}
155	}