drivers/brcmstb/s3.c - kernel/bruno - Git at Google

 /*
  * Copyright (C) 2011 Broadcom Corporation
  *
  * This program is free software; you can redistribute it and/or modify
  * it under the terms of the GNU General Public License version 2 as
  * published by the Free Software Foundation.
  *
  * This program is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
  * GNU General Public License for more details.
  *
  * You should have received a copy of the GNU General Public License
  * along with this program; if not, write to the Free Software
  * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
  */

 #include <linux/kernel.h>
 #include <linux/types.h>
 #include <linux/compiler.h>

 #include <asm/mipsregs.h>
 #include <linux/brcmstb/brcmstb.h>
 #include <asm/tlbflush.h>
 #include <asm/sections.h>
 #include <asm/cpu-features.h>
 #include <asm/bmips.h>

 #define MAX_GP_REGS	16
 #define MAX_CP0_REGS	32
 #define MAX_IO_REGS	(256 - MAX_GP_REGS - MAX_CP0_REGS)

 #if 0
 #define DBG		printk
 #else
 #define DBG(...)	do { } while (0)
 #endif

 #define CALCULATE_MEM_HASH		(1)
 #define WARM_BOOT_MAGIC_WORD		(0x5AFEB007)
 #define CFE_PARAMETER_BLOCK		(0)
 #define AUTHENTICATION_REGION_SIZE	(16*1024*1024)

 #define AON_CTRL_HASH_START_INDEX	(CFE_PARAMETER_BLOCK+5)
 #define AON_SAVE_CPB(idx, val) \
 	BDEV_WR_RB(AON_RAM_BASE + ((CFE_PARAMETER_BLOCK+idx)<<2), val)
 #define AON_READ_CPB(idx) \
 	BDEV_RD(AON_RAM_BASE + ((CFE_PARAMETER_BLOCK+idx)<<2))
 #define AON_SAVE_HASH(idx, val) \
 	BDEV_WR_RB(AON_RAM_BASE + ((AON_CTRL_HASH_START_INDEX+idx)<<2), val)
 #define AON_READ_HASH(idx) \
 	BDEV_RD(AON_RAM_BASE + ((AON_CTRL_HASH_START_INDEX+idx)<<2))

 struct cp0_value {
 	u32	value;
 	u32	index;
 	u32	select;
 };

 struct	brcm_pm_s3_context {
 	u32			gp_regs[MAX_GP_REGS];
 	struct cp0_value	cp0_regs[MAX_CP0_REGS];
 	int			cp0_regs_idx;
 	u32			memc0_rts[NUM_MEMC_CLIENTS];
 	u32			relo_vector_control_0;
 	u32			relo_vector_control_1;
 	u32			sc_boot_vec;
 };

 struct brcm_pm_s3_context s3_context;

 asmlinkage int brcm_pm_s3_standby_asm(unsigned long options,
 	void (*dram_encoder_start)(void), int dcache_linesz);
 extern int s3_reentry;

 extern void bmips_enable_xks01(void);

 static void __raw_uart_putc(char c);

 static void brcm_pm_dump_context(struct brcm_pm_s3_context *cxt);

 #define CPO_SAVE_INFO(cxt, ci, idx, _select) \
 do { \
 	cxt->cp0_regs[ci].index = idx; \
 	cxt->cp0_regs[ci].select = _select; \
 	cxt->cp0_regs[ci++].value = read_c0_reg(idx, _select); \
 } while (0);
 #define read_c0_reg(n, s)	__read_32bit_c0_register($##n, s)
 #define write_c0_reg(n, s, v)	__write_32bit_c0_register($##n, s, v)

 static __maybe_unused void brcm_pm_init_cp0_context(
 		struct brcm_pm_s3_context *cxt)
 {
 	cxt->cp0_regs_idx = 0;
 }

 static __maybe_unused void brcm_pm_save_cp0_context(
 		struct brcm_pm_s3_context *cxt)
 {
 	int ci = cxt->cp0_regs_idx;
 	void __iomem *cbr;

 	/* Generic MIPS */

 	CPO_SAVE_INFO(cxt, ci, 4, 0); /* context */
 	CPO_SAVE_INFO(cxt, ci, 4, 2); /* userlocal */
 	CPO_SAVE_INFO(cxt, ci, 5, 0); /* pagemask */
 	CPO_SAVE_INFO(cxt, ci, 7, 0); /* hwrena */
 	CPO_SAVE_INFO(cxt, ci, 11, 0); /* compare */
 	CPO_SAVE_INFO(cxt, ci, 12, 0); /* status */

 	/* Broadcom specific */

 	CPO_SAVE_INFO(cxt, ci, 22, 0); /* config */
 	CPO_SAVE_INFO(cxt, ci, 22, 1); /* mode */
 	CPO_SAVE_INFO(cxt, ci, 22, 3); /* eDSP */

 	switch (current_cpu_type()) {
 	case CPU_BMIPS4380:
 		cbr = BMIPS_GET_CBR();
 		cxt->relo_vector_control_1 =
 			__raw_readl(cbr + BMIPS_RELO_VECTOR_CONTROL_1);
 		/* falls through */
 	case CPU_BMIPS3300:
 	case CPU_BMIPS4350:
 		cbr = BMIPS_GET_CBR();
 		cxt->relo_vector_control_0 =
 			__raw_readl(cbr + BMIPS_RELO_VECTOR_CONTROL_0);
 		break;
 	case CPU_BMIPS5000:
 		CPO_SAVE_INFO(cxt, ci, 22, 4); /* bootvec */
 		CPO_SAVE_INFO(cxt, ci, 15, 1); /* ebase */
 		cxt->sc_boot_vec = bmips_read_zscm_reg(0xa0);
 		break;
 	}

 	cxt->cp0_regs_idx = ci;
 }

 static __maybe_unused void brcm_pm_restore_cp0_context(
 		struct brcm_pm_s3_context *cxt)
 {
 	int ci = cxt->cp0_regs_idx;
 	void __iomem *cbr;

 	/* Broadcom specific */

 	switch (current_cpu_type()) {
 	case CPU_BMIPS4380:
 		cbr = BMIPS_GET_CBR();
 		__raw_writel(cxt->relo_vector_control_1,
 			cbr + BMIPS_RELO_VECTOR_CONTROL_1);
 		/* falls through */
 	case CPU_BMIPS3300:
 	case CPU_BMIPS4350:
 		cbr = BMIPS_GET_CBR();
 		__raw_writel(cxt->relo_vector_control_0,
 			cbr + BMIPS_RELO_VECTOR_CONTROL_0);
 		break;
 	case CPU_BMIPS5000:
 		bmips_write_zscm_reg(0xa0, cxt->sc_boot_vec);
 		write_c0_reg(15, 1, cxt->cp0_regs[--ci].value); /* ebase */
 		write_c0_reg(22, 4, cxt->cp0_regs[--ci].value); /* bootvec */
 		break;
 	}

 	write_c0_reg(22, 3, cxt->cp0_regs[--ci].value); /* eDSP */
 	write_c0_reg(22, 1, cxt->cp0_regs[--ci].value); /* mode */
 	write_c0_reg(22, 0, cxt->cp0_regs[--ci].value); /* config */

 	/* Generic MIPS */

 	write_c0_reg(12, 0, cxt->cp0_regs[--ci].value); /* status */
 	write_c0_reg(11, 0, cxt->cp0_regs[--ci].value); /* compare */
 	write_c0_reg(7, 0, cxt->cp0_regs[--ci].value); /* hwrena */
 	write_c0_reg(5, 0, cxt->cp0_regs[--ci].value); /* pagemask */
 	write_c0_reg(4, 2, cxt->cp0_regs[--ci].value); /* userlocal */
 	write_c0_reg(4, 0, cxt->cp0_regs[--ci].value); /* context */
 }

 static __maybe_unused void brcm_pm_cmp_context(
 		struct brcm_pm_s3_context *cxt,
 		struct brcm_pm_s3_context *cxt2, const char* title)
 {
 	int i;
 	int identical = 1;
 	if (title)
 		DBG("%s\n", title);
 	if (cxt->cp0_regs_idx != cxt2->cp0_regs_idx) {
 		identical = 0;
 		DBG("CP0 reg # is different: %d %d\n",
 			cxt->cp0_regs_idx, cxt2->cp0_regs_idx);
 	} else {
 		for (i = 0; i < cxt->cp0_regs_idx; i++) {
 			if (cxt->cp0_regs[i].value
 					!= cxt2->cp0_regs[i].value) {
 				identical = 0;
 				DBG("\tCP0[%02d.%01d]:  %08x != %08x\n",
 					cxt->cp0_regs[i].index,
 					cxt->cp0_regs[i].select,
 					cxt->cp0_regs[i].value,
 					cxt2->cp0_regs[i].value);
 			}
 		}
 	}
 	if (identical)
 		DBG("Contexts are identical\n");
 	else {
 		brcm_pm_dump_context(cxt);
 		brcm_pm_dump_context(cxt2);
 	}
 }

 static void brcm_pm_dump_context(struct brcm_pm_s3_context *cxt)
 {
 	int i;
 	DBG("CPO:\n");
 	for (i = 0; i < cxt->cp0_regs_idx; i++) {
 		DBG("[%02d.%0d]=%08x ",
 			cxt->cp0_regs[i].index,
 			cxt->cp0_regs[i].select,
 			cxt->cp0_regs[i].value);
 		if (i%8 == 7)
 			DBG("\n");
 	}
 	DBG("\n\n");
 }

 /***********************************************************************
  * Encryption setup for S3 suspend
  ***********************************************************************/
 #if CALCULATE_MEM_HASH
 /*
  * Default scheme encrypts specified memory region and writes encoded data
  * to a temporary buffer, overwriting previous data on every block write.
  * Upon encoding final block, last 16 bytes are stored into AON, then
  * entire temporary buffer is wiped out
  * Bootloader will repeat encoding immediately after S3 wakeup to see
  * if hash value matches.
  * brcm_pm_s3_tmpbuf - temporary buffer
  * hash_pointer - pointer to location in memory where hash value is located
  * after encoding
  */
 static char __section(.s3_enc_tmpbuf) brcm_pm_s3_tmpbuf[PAGE_SIZE*16];
 static u32 *hash_pointer;

 #define MEM_ENCRYPTED_START_ADDR	(0x80000000)
 #define MEM_ENCRYPTED_LEN		(1*1024*1024)
 #define	S3_HASH_LEN			16

 #define MAX_TRANSFER_SIZE_MB		(16)
 #define MAX_TRANSFER_SIZE		(MAX_TRANSFER_SIZE_MB*1024*1024)

 #define AES_CBC_ENCRYPTION_KEY_SLOT	(5)
 #define AES_CBC_DECRYPTION_KEY_SLOT	(6)

 /*
  * brcm_pm_dram_encoder_set_area
  * Generates a list of descriptors needed to encrypt area
  * VA _begin.._begin+len-1 into PA outbuf..outbuf+out_len-1
  * On return out_len is the length of the last transfer, this
  * can be used as an offset into the outbuf to extract hash
  */
 static struct brcm_mem_transfer *brcm_pm_dram_encoder_set_area(void *_begin,
 	u32 len, dma_addr_t outbuf, u32 *out_len,
 	struct brcm_mem_transfer *next)
 {
 	int num_descr = (len + *out_len - 1) / *out_len;
 	struct brcm_mem_transfer *xfer, *x, *last_x;
 	void *_end = _begin + len;

 	BUG_ON(*out_len > MAX_TRANSFER_SIZE);

 	xfer = kzalloc(num_descr * sizeof(struct brcm_mem_transfer),
 		GFP_ATOMIC);

 	if (!xfer) {
 		printk(KERN_ERR "%s: out of memory\n", __func__);
 		return NULL;
 	}

 	last_x = x = xfer;
 	while (_begin < _end) {
 		dma_addr_t pa_src = virt_to_phys(_begin);
 		if (_begin + *out_len > _end)
 			*out_len = _end - _begin;
 		/* workaround - M2M DMA does not like 0 address */
 		x->len		= *out_len;
 		if (!pa_src) {
 			pa_src += 0x10;
 			x->len -= 0x10;
 		}
 		x->pa_src	= pa_src;
 		x->pa_dst	= outbuf;
 		x->mode		= BRCM_MEM_DMA_SCRAM_BLOCK;
 		x->key		= AES_CBC_ENCRYPTION_KEY_SLOT;
 		x->next		= x + 1;
 		last_x = x;
 		x++;
 		_begin += *out_len;
 	}
 	last_x->next = next;

 	return xfer;
 }

 static void brcm_pm_dram_encoder_free_area(struct brcm_mem_transfer *xfer)
 {
 	kfree(xfer);
 }

 /* Memory region over which M2M DMA calculates MAC cannot be modified
    after a call to brcm_pm_dram_encoder_start() */
 void brcm_pm_dram_encode(void)
 {
 	u32 *hp = hash_pointer;
 	u32 outbuflen = sizeof(brcm_pm_s3_tmpbuf);
 	uint32_t tmp0, tmp1;
 	/* clear temporary buffer */
 	memset(brcm_pm_s3_tmpbuf, 0, sizeof(brcm_pm_s3_tmpbuf));
 	_dma_cache_wback_inv(0, ~0);
 	/* start M2M encoder */
 	brcm_pm_dram_encoder_start();
 	/* save hash in AON register */
 	AON_SAVE_HASH(0, *hp++);
 	AON_SAVE_HASH(1, *hp++);
 	AON_SAVE_HASH(2, *hp++);
 	AON_SAVE_HASH(3, *hp++);

 	/* clear temporary buffer
 	 * cannot use library function because it will use memory (stack) */
 	__asm__ __volatile__(
 	"	.set	noreorder\n"
 	"	la	%0, brcm_pm_s3_tmpbuf\n"
 	"	move	%1, $0\n"
 	"1:	sw	$0, 0(%0)\n"
 	"	addi	%0, 4\n"
 	"	addi	%1, 4\n"
 	"	bne	%2, %1, 1b\n"
 	"	nop\n"
 	: "=&r" (tmp0), "=&r" (tmp1)
 	: "r" (outbuflen));
 }
 #else
 #define brcm_pm_dram_encode	NULL
 #endif

 int brcm_pm_s3_standby(int dcache_linesz, unsigned long options)
 {
 	int retval = 0;
 	unsigned long flags;
 #if CALCULATE_MEM_HASH
 	int r1_len, r2_len, total_len;
 	struct brcm_mem_transfer *xfer[3] = {0};
 	u32 outlen = sizeof(brcm_pm_s3_tmpbuf);
 	u32 outbuflen = outlen, tmp, ii;
 	u32 region_size = AUTHENTICATION_REGION_SIZE;
 	void *src;
 	u32 hash[4];

 	/*
 	 * We are using bi-directional mapping to avoid synchronizing cache
 	 * after encoding
 	 */
 	dma_addr_t pa_dst = dma_map_single(NULL, brcm_pm_s3_tmpbuf,
 		outbuflen, DMA_BIDIRECTIONAL);

 	if (dma_mapping_error(NULL, pa_dst)) {
 		printk(KERN_ERR "%s: cannot remap temp buffer\n", __func__);
 		return -1;
 	}

 	if (region_size < brcm_min_auth_region_size)
 		region_size = brcm_min_auth_region_size;

 	printk(KERN_DEBUG "Authentication region size: 0x%08x\n", region_size);
 	printk(KERN_DEBUG "Output buffer  : 0x%08x-0x%08x (0x%08x)\n",
 	       (u32)brcm_pm_s3_tmpbuf,
 	       (u32)brcm_pm_s3_tmpbuf + outlen, outlen);

 	/* We add areas to the head of the list - in reverse order
 	 * of M2M DMA execution */

 	/* This region starts from _text and bypasses temporary
 	 * output buffer */
 	src = _text;
 	/* check if in/out regions overlap */
 	if (brcm_pm_s3_tmpbuf >= (char *)(src + region_size) ||
 	    brcm_pm_s3_tmpbuf + outlen <= (char *)src) {
 		/* non-overlapping case */
 		r1_len = region_size;
 		r2_len = 0;
 	} else {
 		/* need to cut out the output buffer */
 		r1_len = (int)(brcm_pm_s3_tmpbuf - (char *)src);
 		r2_len = region_size - r1_len;
 	}
 	total_len = r1_len + r2_len;

 	xfer[0] = brcm_pm_dram_encoder_set_area((void *)src, r1_len,
 		pa_dst, &outlen, NULL);
 	if (!xfer[0]) {
 		printk(KERN_ERR "%s: cannot setup M2M DMA [0]\n", __func__);
 		goto _failed;
 	}

 	printk(KERN_DEBUG "Region 0       : 0x%08x-0x%08x (0x%08x)\n",
 		(u32)src, (u32)src + r1_len, r1_len);

 	if (r2_len > 0) {
 		outlen = outbuflen;
 		src = (void *)((u32)(brcm_pm_s3_tmpbuf + outbuflen));
 		xfer[1] = xfer[0];
 		xfer[0] = brcm_pm_dram_encoder_set_area(src, r2_len,
 			pa_dst, &outlen, xfer[1]);
 		if (!xfer[0]) {
 			printk(KERN_ERR "%s: cannot setup M2M DMA [1]\n",
 			       __func__);
 			goto _failed;
 		}
 		printk(KERN_DEBUG "Region 1       : 0x%08x-0x%08x (0x%08x)\n",
 			(u32)src, (u32)(src + r2_len), r2_len);
 	}

 	/* First descriptor must include kernel reentry point
 	 * We are processing one output buffer worth of data */
 	src = (void *)((u32)(&s3_reentry) & ~(PAGE_SIZE-1));
 	tmp = outbuflen;
 	xfer[2] = brcm_pm_dram_encoder_set_area((void *)src, outbuflen,
 		pa_dst, &tmp, xfer[0]);
 	if (!xfer[2]) {
 		printk(KERN_ERR "%s: cannot setup M2M DMA [2]\n", __func__);
 		goto _failed;
 	}
 	printk(KERN_DEBUG "Region 2       : 0x%08x-0x%08x (0x%08x)\n",
 		(u32)src, (u32)src + outbuflen, outbuflen);
 	total_len += outbuflen;
 	if (brcm_pm_dram_encoder_prepare(xfer[2])) {
 		printk(KERN_ERR "%s: cannot initialize M2M DMA\n", __func__);
 		goto _failed;
 	}

 	hash_pointer = (u32 *)(brcm_pm_s3_tmpbuf +
 		(outlen - S3_HASH_LEN + outbuflen) % outbuflen);

 	/* M2M DMA descriptor address */
 	if (brcm_pm_hash_enabled)
 		AON_SAVE_CPB(2, BDEV_RD(BCHP_MEM_DMA_0_FIRST_DESC));
 	else
 		AON_SAVE_CPB(2, 0);
 	/* Encryption key slot */
 	AON_SAVE_CPB(3, AES_CBC_ENCRYPTION_KEY_SLOT);
 	/* Address of hash */
 	AON_SAVE_CPB(4, (u32)hash_pointer);
 	/* Total authentication region size */
 	AON_SAVE_CPB(9, total_len);
 	printk(KERN_DEBUG "Encryption slot: %d\n",
 	       AES_CBC_ENCRYPTION_KEY_SLOT);
 	printk(KERN_DEBUG "Hash pointer   : 0x%p\n", hash_pointer);
 	printk(KERN_DEBUG "Total length   : 0x%08x\n", (u32)total_len);
 	printk(KERN_DEBUG "Reentry point  : 0x%p\n", &s3_reentry);
 #else
 	AON_SAVE_CPB(2, 0);
 #endif

 	/* Warm Boot Magic Word */
 	AON_SAVE_CPB(0, WARM_BOOT_MAGIC_WORD);
 	/* Kernel Reentry Address */
 	AON_SAVE_CPB(1, (u32)&s3_reentry);

 	/* clear RESET_HISTORY */
 	BDEV_WR_F_RB(AON_CTRL_RESET_CTRL, clear_reset_history, 1);

 	local_irq_save(flags);
 	/* save CP0 context */
 	brcm_pm_init_cp0_context(&s3_context);
 	brcm_pm_save_cp0_context(&s3_context);

 	/* inhibit DDR_RSTb pulse */
 	BDEV_UNSET(BCHP_DDR40_PHY_CONTROL_REGS_0_STANDBY_CONTROL, 0x0f);
 	BDEV_SET(BCHP_DDR40_PHY_CONTROL_REGS_0_STANDBY_CONTROL, BIT(5) | 0x05);

 	/* save RTS */
 	brcm_pm_save_restore_rts(BCHP_MEMC_ARB_0_REG_START,
 		s3_context.memc0_rts, 0);

 	/* save I/O context */

 	local_flush_tlb_all();
 	_dma_cache_wback_inv(0, ~0);

 	retval = brcm_pm_s3_standby_asm(options, brcm_pm_dram_encode,
 		dcache_linesz);

 	/* CPU reconfiguration */
 	local_flush_tlb_all();
 	brcmstb_cpu_setup();
 	cpumask_clear(&bmips_booted_mask);

 	/* restore RTS */
 	brcm_pm_save_restore_rts(BCHP_MEMC_ARB_0_REG_START,
 		s3_context.memc0_rts, 1);

 	/* restore I/O context */
 	board_pinmux_setup();
 	ebi_restore_settings();

 	/* restore CP0 context */
 	brcm_pm_restore_cp0_context(&s3_context);

 #if defined(BCHP_IRQ0_UART_IRQEN_uarta_MASK)
 	/* 3548 style - separate register */
 	BDEV_WR(BCHP_IRQ0_UART_IRQEN, BCHP_IRQ0_UART_IRQEN_uarta_MASK |
 		BCHP_IRQ0_UART_IRQEN_uartb_MASK |
 		BCHP_IRQ0_UART_IRQEN_uartc_MASK);
 	BDEV_WR(BCHP_IRQ0_IRQEN, 0);
 #elif defined(BCHP_IRQ0_IRQEN_uarta_irqen_MASK)
 	/* 7405 style - shared with L2 */
 	BDEV_WR(BCHP_IRQ0_IRQEN, BCHP_IRQ0_IRQEN_uarta_irqen_MASK
 		| BCHP_IRQ0_IRQEN_uartb_irqen_MASK
 #if defined(BCHP_IRQ0_IRQEN_uartc_irqen_MASK)
 		| BCHP_IRQ0_IRQEN_uartc_irqen_MASK
 #endif
 		);
 #endif

 	local_irq_restore(flags);

 #if defined(CONFIG_BRCM_HAS_PCIE) && defined(CONFIG_PCI)
 	BDEV_WR_F_RB(WKTMR_EVENT, wktmr_alarm_event, 1);
 	BDEV_WR_F_RB(WKTMR_PRESCALER, wktmr_prescaler, WKTMR_FREQ);

 	if (brcm_pcie_enabled) {
 		brcm_early_pcie_setup();
 		brcm_setup_pcie_bridge();
 	}
 #endif

 #if CALCULATE_MEM_HASH
 	for (ii = 0; ii < 4; ii++)
 		hash[ii] = AON_READ_HASH(ii);
 	printk(KERN_DEBUG "hash: %08x:%08x:%08x:%08x\n",
 	       hash[0], hash[1], hash[2], hash[3]);

 	brcm_pm_dram_encoder_complete(xfer[0]);
 _failed:
 	for (ii = 0; ii < 3; ii++)
 		brcm_pm_dram_encoder_free_area(xfer[ii]);
 	dma_unmap_single(NULL, pa_dst, outbuflen, DMA_BIDIRECTIONAL);

 #endif

 	return retval;
 }

 static void __maybe_unused __raw_uart_putc(char c)
 {
 	while (!(BDEV_RD(BCHP_UARTA_LSR) & BCHP_UARTA_LSR_THRE_MASK))
 		;
 	BDEV_WR_RB(BCHP_UARTA_THR, (u32)c);
 }
	/*
	* Copyright (C) 2011 Broadcom Corporation
	*
	* This program is free software; you can redistribute it and/or modify
	* it under the terms of the GNU General Public License version 2 as
	* published by the Free Software Foundation.
	*
	* This program is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	* GNU General Public License for more details.
	*
	* You should have received a copy of the GNU General Public License
	* along with this program; if not, write to the Free Software
	* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
	*/

	#include <linux/kernel.h>
	#include <linux/types.h>
	#include <linux/compiler.h>

	#include <asm/mipsregs.h>
	#include <linux/brcmstb/brcmstb.h>
	#include <asm/tlbflush.h>
	#include <asm/sections.h>
	#include <asm/cpu-features.h>
	#include <asm/bmips.h>

	#define MAX_GP_REGS 16
	#define MAX_CP0_REGS 32
	#define MAX_IO_REGS (256 - MAX_GP_REGS - MAX_CP0_REGS)

	#if 0
	#define DBG printk
	#else
	#define DBG(...) do { } while (0)
	#endif

	#define CALCULATE_MEM_HASH (1)
	#define WARM_BOOT_MAGIC_WORD (0x5AFEB007)
	#define CFE_PARAMETER_BLOCK (0)
	#define AUTHENTICATION_REGION_SIZE (1610241024)

	#define AON_CTRL_HASH_START_INDEX (CFE_PARAMETER_BLOCK+5)
	#define AON_SAVE_CPB(idx, val) \
	BDEV_WR_RB(AON_RAM_BASE + ((CFE_PARAMETER_BLOCK+idx)<<2), val)
	#define AON_READ_CPB(idx) \
	BDEV_RD(AON_RAM_BASE + ((CFE_PARAMETER_BLOCK+idx)<<2))
	#define AON_SAVE_HASH(idx, val) \
	BDEV_WR_RB(AON_RAM_BASE + ((AON_CTRL_HASH_START_INDEX+idx)<<2), val)
	#define AON_READ_HASH(idx) \
	BDEV_RD(AON_RAM_BASE + ((AON_CTRL_HASH_START_INDEX+idx)<<2))

	struct cp0_value {
	u32 value;
	u32 index;
	u32 select;
	};

	struct brcm_pm_s3_context {
	u32 gp_regs[MAX_GP_REGS];
	struct cp0_value cp0_regs[MAX_CP0_REGS];
	int cp0_regs_idx;
	u32 memc0_rts[NUM_MEMC_CLIENTS];
	u32 relo_vector_control_0;
	u32 relo_vector_control_1;
	u32 sc_boot_vec;
	};

	struct brcm_pm_s3_context s3_context;

	asmlinkage int brcm_pm_s3_standby_asm(unsigned long options,
	void (*dram_encoder_start)(void), int dcache_linesz);
	extern int s3_reentry;

	extern void bmips_enable_xks01(void);

	static void __raw_uart_putc(char c);

	static void brcm_pm_dump_context(struct brcm_pm_s3_context *cxt);

	#define CPO_SAVE_INFO(cxt, ci, idx, _select) \
	do { \
	cxt->cp0_regs[ci].index = idx; \
	cxt->cp0_regs[ci].select = _select; \
	cxt->cp0_regs[ci++].value = read_c0_reg(idx, _select); \
	} while (0);
	#define read_c0_reg(n, s) __read_32bit_c0_register($##n, s)
	#define write_c0_reg(n, s, v) __write_32bit_c0_register($##n, s, v)

	static __maybe_unused void brcm_pm_init_cp0_context(
	struct brcm_pm_s3_context *cxt)
	{
	cxt->cp0_regs_idx = 0;
	}

	static __maybe_unused void brcm_pm_save_cp0_context(
	struct brcm_pm_s3_context *cxt)
	{
	int ci = cxt->cp0_regs_idx;
	void __iomem *cbr;

	/* Generic MIPS */

	CPO_SAVE_INFO(cxt, ci, 4, 0); /* context */
	CPO_SAVE_INFO(cxt, ci, 4, 2); /* userlocal */
	CPO_SAVE_INFO(cxt, ci, 5, 0); /* pagemask */
	CPO_SAVE_INFO(cxt, ci, 7, 0); /* hwrena */
	CPO_SAVE_INFO(cxt, ci, 11, 0); /* compare */
	CPO_SAVE_INFO(cxt, ci, 12, 0); /* status */

	/* Broadcom specific */

	CPO_SAVE_INFO(cxt, ci, 22, 0); /* config */
	CPO_SAVE_INFO(cxt, ci, 22, 1); /* mode */
	CPO_SAVE_INFO(cxt, ci, 22, 3); /* eDSP */

	switch (current_cpu_type()) {
	case CPU_BMIPS4380:
	cbr = BMIPS_GET_CBR();
	cxt->relo_vector_control_1 =
	__raw_readl(cbr + BMIPS_RELO_VECTOR_CONTROL_1);
	/* falls through */
	case CPU_BMIPS3300:
	case CPU_BMIPS4350:
	cbr = BMIPS_GET_CBR();
	cxt->relo_vector_control_0 =
	__raw_readl(cbr + BMIPS_RELO_VECTOR_CONTROL_0);
	break;
	case CPU_BMIPS5000:
	CPO_SAVE_INFO(cxt, ci, 22, 4); /* bootvec */
	CPO_SAVE_INFO(cxt, ci, 15, 1); /* ebase */
	cxt->sc_boot_vec = bmips_read_zscm_reg(0xa0);
	break;
	}

	cxt->cp0_regs_idx = ci;
	}

	static __maybe_unused void brcm_pm_restore_cp0_context(
	struct brcm_pm_s3_context *cxt)
	{
	int ci = cxt->cp0_regs_idx;
	void __iomem *cbr;

	/* Broadcom specific */

	switch (current_cpu_type()) {
	case CPU_BMIPS4380:
	cbr = BMIPS_GET_CBR();
	__raw_writel(cxt->relo_vector_control_1,
	cbr + BMIPS_RELO_VECTOR_CONTROL_1);
	/* falls through */
	case CPU_BMIPS3300:
	case CPU_BMIPS4350:
	cbr = BMIPS_GET_CBR();
	__raw_writel(cxt->relo_vector_control_0,
	cbr + BMIPS_RELO_VECTOR_CONTROL_0);
	break;
	case CPU_BMIPS5000:
	bmips_write_zscm_reg(0xa0, cxt->sc_boot_vec);
	write_c0_reg(15, 1, cxt->cp0_regs[--ci].value); /* ebase */
	write_c0_reg(22, 4, cxt->cp0_regs[--ci].value); /* bootvec */
	break;
	}

	write_c0_reg(22, 3, cxt->cp0_regs[--ci].value); /* eDSP */
	write_c0_reg(22, 1, cxt->cp0_regs[--ci].value); /* mode */
	write_c0_reg(22, 0, cxt->cp0_regs[--ci].value); /* config */

	/* Generic MIPS */

	write_c0_reg(12, 0, cxt->cp0_regs[--ci].value); /* status */
	write_c0_reg(11, 0, cxt->cp0_regs[--ci].value); /* compare */
	write_c0_reg(7, 0, cxt->cp0_regs[--ci].value); /* hwrena */
	write_c0_reg(5, 0, cxt->cp0_regs[--ci].value); /* pagemask */
	write_c0_reg(4, 2, cxt->cp0_regs[--ci].value); /* userlocal */
	write_c0_reg(4, 0, cxt->cp0_regs[--ci].value); /* context */
	}

	static __maybe_unused void brcm_pm_cmp_context(
	struct brcm_pm_s3_context *cxt,
	struct brcm_pm_s3_context cxt2, const char title)
	{
	int i;
	int identical = 1;
	if (title)
	DBG("%s\n", title);
	if (cxt->cp0_regs_idx != cxt2->cp0_regs_idx) {
	identical = 0;
	DBG("CP0 reg # is different: %d %d\n",
	cxt->cp0_regs_idx, cxt2->cp0_regs_idx);
	} else {
	for (i = 0; i < cxt->cp0_regs_idx; i++) {
	if (cxt->cp0_regs[i].value
	!= cxt2->cp0_regs[i].value) {
	identical = 0;
	DBG("\tCP0[%02d.%01d]: %08x != %08x\n",
	cxt->cp0_regs[i].index,
	cxt->cp0_regs[i].select,
	cxt->cp0_regs[i].value,
	cxt2->cp0_regs[i].value);
	}
	}
	}
	if (identical)
	DBG("Contexts are identical\n");
	else {
	brcm_pm_dump_context(cxt);
	brcm_pm_dump_context(cxt2);
	}
	}

	static void brcm_pm_dump_context(struct brcm_pm_s3_context *cxt)
	{
	int i;
	DBG("CPO:\n");
	for (i = 0; i < cxt->cp0_regs_idx; i++) {
	DBG("[%02d.%0d]=%08x ",
	cxt->cp0_regs[i].index,
	cxt->cp0_regs[i].select,
	cxt->cp0_regs[i].value);
	if (i%8 == 7)
	DBG("\n");
	}
	DBG("\n\n");
	}

	/***********************************************************************
	* Encryption setup for S3 suspend
	***********************************************************************/
	#if CALCULATE_MEM_HASH
	/*
	* Default scheme encrypts specified memory region and writes encoded data
	* to a temporary buffer, overwriting previous data on every block write.
	* Upon encoding final block, last 16 bytes are stored into AON, then
	* entire temporary buffer is wiped out
	* Bootloader will repeat encoding immediately after S3 wakeup to see
	* if hash value matches.
	* brcm_pm_s3_tmpbuf - temporary buffer
	* hash_pointer - pointer to location in memory where hash value is located
	* after encoding
	*/
	static char __section(.s3_enc_tmpbuf) brcm_pm_s3_tmpbuf[PAGE_SIZE*16];
	static u32 *hash_pointer;

	#define MEM_ENCRYPTED_START_ADDR (0x80000000)
	#define MEM_ENCRYPTED_LEN (110241024)
	#define S3_HASH_LEN 16

	#define MAX_TRANSFER_SIZE_MB (16)
	#define MAX_TRANSFER_SIZE (MAX_TRANSFER_SIZE_MB10241024)

	#define AES_CBC_ENCRYPTION_KEY_SLOT (5)
	#define AES_CBC_DECRYPTION_KEY_SLOT (6)

	/*
	* brcm_pm_dram_encoder_set_area
	* Generates a list of descriptors needed to encrypt area
	* VA _begin.._begin+len-1 into PA outbuf..outbuf+out_len-1
	* On return out_len is the length of the last transfer, this
	* can be used as an offset into the outbuf to extract hash
	*/
	static struct brcm_mem_transfer brcm_pm_dram_encoder_set_area(void _begin,
	u32 len, dma_addr_t outbuf, u32 *out_len,
	struct brcm_mem_transfer *next)
	{
	int num_descr = (len + out_len - 1) / out_len;
	struct brcm_mem_transfer xfer, x, *last_x;
	void *_end = _begin + len;

	BUG_ON(*out_len > MAX_TRANSFER_SIZE);

	xfer = kzalloc(num_descr * sizeof(struct brcm_mem_transfer),
	GFP_ATOMIC);

	if (!xfer) {
	printk(KERN_ERR "%s: out of memory\n", __func__);
	return NULL;
	}

	last_x = x = xfer;
	while (_begin < _end) {
	dma_addr_t pa_src = virt_to_phys(_begin);
	if (_begin + *out_len > _end)
	*out_len = _end - _begin;
	/* workaround - M2M DMA does not like 0 address */
	x->len = *out_len;
	if (!pa_src) {
	pa_src += 0x10;
	x->len -= 0x10;
	}
	x->pa_src = pa_src;
	x->pa_dst = outbuf;
	x->mode = BRCM_MEM_DMA_SCRAM_BLOCK;
	x->key = AES_CBC_ENCRYPTION_KEY_SLOT;
	x->next = x + 1;
	last_x = x;
	x++;
	_begin += *out_len;
	}
	last_x->next = next;

	return xfer;
	}

	static void brcm_pm_dram_encoder_free_area(struct brcm_mem_transfer *xfer)
	{
	kfree(xfer);
	}

	/* Memory region over which M2M DMA calculates MAC cannot be modified
	after a call to brcm_pm_dram_encoder_start() */
	void brcm_pm_dram_encode(void)
	{
	u32 *hp = hash_pointer;
	u32 outbuflen = sizeof(brcm_pm_s3_tmpbuf);
	uint32_t tmp0, tmp1;
	/* clear temporary buffer */
	memset(brcm_pm_s3_tmpbuf, 0, sizeof(brcm_pm_s3_tmpbuf));
	_dma_cache_wback_inv(0, ~0);
	/* start M2M encoder */
	brcm_pm_dram_encoder_start();
	/* save hash in AON register */
	AON_SAVE_HASH(0, *hp++);
	AON_SAVE_HASH(1, *hp++);
	AON_SAVE_HASH(2, *hp++);
	AON_SAVE_HASH(3, *hp++);

	/* clear temporary buffer
	* cannot use library function because it will use memory (stack) */
	__asm__ __volatile__(
	" .set noreorder\n"
	" la %0, brcm_pm_s3_tmpbuf\n"
	" move %1, $0\n"
	"1: sw $0, 0(%0)\n"
	" addi %0, 4\n"
	" addi %1, 4\n"
	" bne %2, %1, 1b\n"
	" nop\n"
	: "=&r" (tmp0), "=&r" (tmp1)
	: "r" (outbuflen));
	}
	#else
	#define brcm_pm_dram_encode NULL
	#endif

	int brcm_pm_s3_standby(int dcache_linesz, unsigned long options)
	{
	int retval = 0;
	unsigned long flags;
	#if CALCULATE_MEM_HASH
	int r1_len, r2_len, total_len;
	struct brcm_mem_transfer *xfer[3] = {0};
	u32 outlen = sizeof(brcm_pm_s3_tmpbuf);
	u32 outbuflen = outlen, tmp, ii;
	u32 region_size = AUTHENTICATION_REGION_SIZE;
	void *src;
	u32 hash[4];

	/*
	* We are using bi-directional mapping to avoid synchronizing cache
	* after encoding
	*/
	dma_addr_t pa_dst = dma_map_single(NULL, brcm_pm_s3_tmpbuf,
	outbuflen, DMA_BIDIRECTIONAL);

	if (dma_mapping_error(NULL, pa_dst)) {
	printk(KERN_ERR "%s: cannot remap temp buffer\n", __func__);
	return -1;
	}

	if (region_size < brcm_min_auth_region_size)
	region_size = brcm_min_auth_region_size;

	printk(KERN_DEBUG "Authentication region size: 0x%08x\n", region_size);
	printk(KERN_DEBUG "Output buffer : 0x%08x-0x%08x (0x%08x)\n",
	(u32)brcm_pm_s3_tmpbuf,
	(u32)brcm_pm_s3_tmpbuf + outlen, outlen);

	/* We add areas to the head of the list - in reverse order
	* of M2M DMA execution */

	/* This region starts from _text and bypasses temporary
	* output buffer */
	src = _text;
	/* check if in/out regions overlap */
	if (brcm_pm_s3_tmpbuf >= (char *)(src + region_size) \|\|
	brcm_pm_s3_tmpbuf + outlen <= (char *)src) {
	/* non-overlapping case */
	r1_len = region_size;
	r2_len = 0;
	} else {
	/* need to cut out the output buffer */
	r1_len = (int)(brcm_pm_s3_tmpbuf - (char *)src);
	r2_len = region_size - r1_len;
	}
	total_len = r1_len + r2_len;

	xfer[0] = brcm_pm_dram_encoder_set_area((void *)src, r1_len,
	pa_dst, &outlen, NULL);
	if (!xfer[0]) {
	printk(KERN_ERR "%s: cannot setup M2M DMA [0]\n", __func__);
	goto _failed;
	}

	printk(KERN_DEBUG "Region 0 : 0x%08x-0x%08x (0x%08x)\n",
	(u32)src, (u32)src + r1_len, r1_len);

	if (r2_len > 0) {
	outlen = outbuflen;
	src = (void *)((u32)(brcm_pm_s3_tmpbuf + outbuflen));
	xfer[1] = xfer[0];
	xfer[0] = brcm_pm_dram_encoder_set_area(src, r2_len,
	pa_dst, &outlen, xfer[1]);
	if (!xfer[0]) {
	printk(KERN_ERR "%s: cannot setup M2M DMA [1]\n",
	__func__);
	goto _failed;
	}
	printk(KERN_DEBUG "Region 1 : 0x%08x-0x%08x (0x%08x)\n",
	(u32)src, (u32)(src + r2_len), r2_len);
	}

	/* First descriptor must include kernel reentry point
	* We are processing one output buffer worth of data */
	src = (void *)((u32)(&s3_reentry) & ~(PAGE_SIZE-1));
	tmp = outbuflen;
	xfer[2] = brcm_pm_dram_encoder_set_area((void *)src, outbuflen,
	pa_dst, &tmp, xfer[0]);
	if (!xfer[2]) {
	printk(KERN_ERR "%s: cannot setup M2M DMA [2]\n", __func__);
	goto _failed;
	}
	printk(KERN_DEBUG "Region 2 : 0x%08x-0x%08x (0x%08x)\n",
	(u32)src, (u32)src + outbuflen, outbuflen);
	total_len += outbuflen;
	if (brcm_pm_dram_encoder_prepare(xfer[2])) {
	printk(KERN_ERR "%s: cannot initialize M2M DMA\n", __func__);
	goto _failed;
	}

	hash_pointer = (u32 *)(brcm_pm_s3_tmpbuf +
	(outlen - S3_HASH_LEN + outbuflen) % outbuflen);

	/* M2M DMA descriptor address */
	if (brcm_pm_hash_enabled)
	AON_SAVE_CPB(2, BDEV_RD(BCHP_MEM_DMA_0_FIRST_DESC));
	else
	AON_SAVE_CPB(2, 0);
	/* Encryption key slot */
	AON_SAVE_CPB(3, AES_CBC_ENCRYPTION_KEY_SLOT);
	/* Address of hash */
	AON_SAVE_CPB(4, (u32)hash_pointer);
	/* Total authentication region size */
	AON_SAVE_CPB(9, total_len);
	printk(KERN_DEBUG "Encryption slot: %d\n",
	AES_CBC_ENCRYPTION_KEY_SLOT);
	printk(KERN_DEBUG "Hash pointer : 0x%p\n", hash_pointer);
	printk(KERN_DEBUG "Total length : 0x%08x\n", (u32)total_len);
	printk(KERN_DEBUG "Reentry point : 0x%p\n", &s3_reentry);
	#else
	AON_SAVE_CPB(2, 0);
	#endif

	/* Warm Boot Magic Word */
	AON_SAVE_CPB(0, WARM_BOOT_MAGIC_WORD);
	/* Kernel Reentry Address */
	AON_SAVE_CPB(1, (u32)&s3_reentry);

	/* clear RESET_HISTORY */
	BDEV_WR_F_RB(AON_CTRL_RESET_CTRL, clear_reset_history, 1);

	local_irq_save(flags);
	/* save CP0 context */
	brcm_pm_init_cp0_context(&s3_context);
	brcm_pm_save_cp0_context(&s3_context);

	/* inhibit DDR_RSTb pulse */
	BDEV_UNSET(BCHP_DDR40_PHY_CONTROL_REGS_0_STANDBY_CONTROL, 0x0f);
	BDEV_SET(BCHP_DDR40_PHY_CONTROL_REGS_0_STANDBY_CONTROL, BIT(5) \| 0x05);

	/* save RTS */
	brcm_pm_save_restore_rts(BCHP_MEMC_ARB_0_REG_START,
	s3_context.memc0_rts, 0);

	/* save I/O context */

	local_flush_tlb_all();
	_dma_cache_wback_inv(0, ~0);

	retval = brcm_pm_s3_standby_asm(options, brcm_pm_dram_encode,
	dcache_linesz);

	/* CPU reconfiguration */
	local_flush_tlb_all();
	brcmstb_cpu_setup();
	cpumask_clear(&bmips_booted_mask);

	/* restore RTS */
	brcm_pm_save_restore_rts(BCHP_MEMC_ARB_0_REG_START,
	s3_context.memc0_rts, 1);

	/* restore I/O context */
	board_pinmux_setup();
	ebi_restore_settings();

	/* restore CP0 context */
	brcm_pm_restore_cp0_context(&s3_context);

	#if defined(BCHP_IRQ0_UART_IRQEN_uarta_MASK)
	/* 3548 style - separate register */
	BDEV_WR(BCHP_IRQ0_UART_IRQEN, BCHP_IRQ0_UART_IRQEN_uarta_MASK \|
	BCHP_IRQ0_UART_IRQEN_uartb_MASK \|
	BCHP_IRQ0_UART_IRQEN_uartc_MASK);
	BDEV_WR(BCHP_IRQ0_IRQEN, 0);
	#elif defined(BCHP_IRQ0_IRQEN_uarta_irqen_MASK)
	/* 7405 style - shared with L2 */
	BDEV_WR(BCHP_IRQ0_IRQEN, BCHP_IRQ0_IRQEN_uarta_irqen_MASK
	\| BCHP_IRQ0_IRQEN_uartb_irqen_MASK
	#if defined(BCHP_IRQ0_IRQEN_uartc_irqen_MASK)
	\| BCHP_IRQ0_IRQEN_uartc_irqen_MASK
	#endif
	);
	#endif

	local_irq_restore(flags);

	#if defined(CONFIG_BRCM_HAS_PCIE) && defined(CONFIG_PCI)
	BDEV_WR_F_RB(WKTMR_EVENT, wktmr_alarm_event, 1);
	BDEV_WR_F_RB(WKTMR_PRESCALER, wktmr_prescaler, WKTMR_FREQ);

	if (brcm_pcie_enabled) {
	brcm_early_pcie_setup();
	brcm_setup_pcie_bridge();
	}
	#endif

	#if CALCULATE_MEM_HASH
	for (ii = 0; ii < 4; ii++)
	hash[ii] = AON_READ_HASH(ii);
	printk(KERN_DEBUG "hash: %08x:%08x:%08x:%08x\n",
	hash[0], hash[1], hash[2], hash[3]);

	brcm_pm_dram_encoder_complete(xfer[0]);
	_failed:
	for (ii = 0; ii < 3; ii++)
	brcm_pm_dram_encoder_free_area(xfer[ii]);
	dma_unmap_single(NULL, pa_dst, outbuflen, DMA_BIDIRECTIONAL);

	#endif

	return retval;
	}

	static void __maybe_unused __raw_uart_putc(char c)
	{
	while (!(BDEV_RD(BCHP_UARTA_LSR) & BCHP_UARTA_LSR_THRE_MASK))
	;
	BDEV_WR_RB(BCHP_UARTA_THR, (u32)c);
	}