arch/ppc/syslib/m8260_pci_erratum9.c - kernel/msm-5.4 - Gitiles

 /*
  * Workaround for device erratum PCI 9.
  * See Motorola's "XPC826xA Family Device Errata Reference."
  * The erratum applies to all 8260 family Hip4 processors.  It is scheduled
  * to be fixed in HiP4 Rev C.  Erratum PCI 9 states that a simultaneous PCI
  * inbound write transaction and PCI outbound read transaction can result in a
  * bus deadlock.  The suggested workaround is to use the IDMA controller to
  * perform all reads from PCI configuration, memory, and I/O space.
  *
  * Author:  andy_lowe@mvista.com
  *
  * 2003 (c) MontaVista Software, Inc. This file is licensed under
  * the terms of the GNU General Public License version 2. This program
  * is licensed "as is" without any warranty of any kind, whether express
  * or implied.
  */
 #include <linux/kernel.h>
 #include <linux/module.h>
 #include <linux/pci.h>
 #include <linux/types.h>
 #include <linux/string.h>

 #include <asm/io.h>
 #include <asm/pci-bridge.h>
 #include <asm/machdep.h>
 #include <asm/byteorder.h>
 #include <asm/mpc8260.h>
 #include <asm/immap_cpm2.h>
 #include <asm/cpm2.h>

 #include "m82xx_pci.h"

 #ifdef CONFIG_8260_PCI9
 /*#include <asm/mpc8260_pci9.h>*/ /* included in asm/io.h */

 #define IDMA_XFER_BUF_SIZE 64	/* size of the IDMA transfer buffer */

 /* define a structure for the IDMA dpram usage */
 typedef struct idma_dpram_s {
 	idma_t pram;				/* IDMA parameter RAM */
 	u_char xfer_buf[IDMA_XFER_BUF_SIZE];	/* IDMA transfer buffer */
 	idma_bd_t bd;				/* buffer descriptor */
 } idma_dpram_t;

 /* define offsets relative to start of IDMA dpram */
 #define IDMA_XFER_BUF_OFFSET (sizeof(idma_t))
 #define IDMA_BD_OFFSET (sizeof(idma_t) + IDMA_XFER_BUF_SIZE)

 /* define globals */
 static volatile idma_dpram_t *idma_dpram;

 /* Exactly one of CONFIG_8260_PCI9_IDMAn must be defined,
  * where n is 1, 2, 3, or 4.  This selects the IDMA channel used for
  * the PCI9 workaround.
  */
 #ifdef CONFIG_8260_PCI9_IDMA1
 #define IDMA_CHAN 0
 #define PROFF_IDMA PROFF_IDMA1_BASE
 #define IDMA_PAGE CPM_CR_IDMA1_PAGE
 #define IDMA_SBLOCK CPM_CR_IDMA1_SBLOCK
 #endif
 #ifdef CONFIG_8260_PCI9_IDMA2
 #define IDMA_CHAN 1
 #define PROFF_IDMA PROFF_IDMA2_BASE
 #define IDMA_PAGE CPM_CR_IDMA2_PAGE
 #define IDMA_SBLOCK CPM_CR_IDMA2_SBLOCK
 #endif
 #ifdef CONFIG_8260_PCI9_IDMA3
 #define IDMA_CHAN 2
 #define PROFF_IDMA PROFF_IDMA3_BASE
 #define IDMA_PAGE CPM_CR_IDMA3_PAGE
 #define IDMA_SBLOCK CPM_CR_IDMA3_SBLOCK
 #endif
 #ifdef CONFIG_8260_PCI9_IDMA4
 #define IDMA_CHAN 3
 #define PROFF_IDMA PROFF_IDMA4_BASE
 #define IDMA_PAGE CPM_CR_IDMA4_PAGE
 #define IDMA_SBLOCK CPM_CR_IDMA4_SBLOCK
 #endif

 void idma_pci9_init(void)
 {
 	uint dpram_offset;
 	volatile idma_t *pram;
 	volatile im_idma_t *idma_reg;
 	volatile cpm2_map_t *immap = cpm2_immr;

 	/* allocate IDMA dpram */
 	dpram_offset = cpm_dpalloc(sizeof(idma_dpram_t), 64);
 	idma_dpram = cpm_dpram_addr(dpram_offset);

 	/* initialize the IDMA parameter RAM */
 	memset((void *)idma_dpram, 0, sizeof(idma_dpram_t));
 	pram = &idma_dpram->pram;
 	pram->ibase = dpram_offset + IDMA_BD_OFFSET;
 	pram->dpr_buf = dpram_offset + IDMA_XFER_BUF_OFFSET;
 	pram->ss_max = 32;
 	pram->dts = 32;

 	/* initialize the IDMA_BASE pointer to the IDMA parameter RAM */
 	*((ushort *) &immap->im_dprambase[PROFF_IDMA]) = dpram_offset;

 	/* initialize the IDMA registers */
 	idma_reg = (volatile im_idma_t *) &immap->im_sdma.sdma_idsr1;
 	idma_reg[IDMA_CHAN].idmr = 0;		/* mask all IDMA interrupts */
 	idma_reg[IDMA_CHAN].idsr = 0xff;	/* clear all event flags */

 	printk(KERN_WARNING
 		"Using IDMA%d for MPC8260 device erratum PCI 9 workaround\n",
 		IDMA_CHAN + 1);

 	return;
 }

 /* Use the IDMA controller to transfer data from I/O memory to local RAM.
  * The src address must be a physical address suitable for use by the DMA
  * controller with no translation.  The dst address must be a kernel virtual
  * address.  The dst address is translated to a physical address via
  * virt_to_phys().
  * The sinc argument specifies whether or not the source address is incremented
  * by the DMA controller.  The source address is incremented if and only if sinc
  * is non-zero.  The destination address is always incremented since the
  * destination is always host RAM.
  */
 static void
 idma_pci9_read(u8 *dst, u8 *src, int bytes, int unit_size, int sinc)
 {
 	unsigned long flags;
 	volatile idma_t *pram = &idma_dpram->pram;
 	volatile idma_bd_t *bd = &idma_dpram->bd;
 	volatile cpm2_map_t *immap = cpm2_immr;

 	local_irq_save(flags);

 	/* initialize IDMA parameter RAM for this transfer */
 	if (sinc)
 		pram->dcm = IDMA_DCM_DMA_WRAP_64 | IDMA_DCM_SINC
 			  | IDMA_DCM_DINC | IDMA_DCM_SD_MEM2MEM;
 	else
 		pram->dcm = IDMA_DCM_DMA_WRAP_64 | IDMA_DCM_DINC
 			  | IDMA_DCM_SD_MEM2MEM;
 	pram->ibdptr = pram->ibase;
 	pram->sts = unit_size;
 	pram->istate = 0;

 	/* initialize the buffer descriptor */
 	bd->dst = virt_to_phys(dst);
 	bd->src = (uint) src;
 	bd->len = bytes;
 	bd->flags = IDMA_BD_V | IDMA_BD_W | IDMA_BD_I | IDMA_BD_L | IDMA_BD_DGBL
 		  | IDMA_BD_DBO_BE | IDMA_BD_SBO_BE | IDMA_BD_SDTB;

 	/* issue the START_IDMA command to the CP */
 	while (immap->im_cpm.cp_cpcr & CPM_CR_FLG);
 	immap->im_cpm.cp_cpcr = mk_cr_cmd(IDMA_PAGE, IDMA_SBLOCK, 0,
 					 CPM_CR_START_IDMA) | CPM_CR_FLG;
 	while (immap->im_cpm.cp_cpcr & CPM_CR_FLG);

 	/* wait for transfer to complete */
 	while(bd->flags & IDMA_BD_V);

 	local_irq_restore(flags);

 	return;
 }

 /* Use the IDMA controller to transfer data from I/O memory to local RAM.
  * The dst address must be a physical address suitable for use by the DMA
  * controller with no translation.  The src address must be a kernel virtual
  * address.  The src address is translated to a physical address via
  * virt_to_phys().
  * The dinc argument specifies whether or not the dest address is incremented
  * by the DMA controller.  The source address is incremented if and only if sinc
  * is non-zero.  The source address is always incremented since the
  * source is always host RAM.
  */
 static void
 idma_pci9_write(u8 *dst, u8 *src, int bytes, int unit_size, int dinc)
 {
 	unsigned long flags;
 	volatile idma_t *pram = &idma_dpram->pram;
 	volatile idma_bd_t *bd = &idma_dpram->bd;
 	volatile cpm2_map_t *immap = cpm2_immr;

 	local_irq_save(flags);

 	/* initialize IDMA parameter RAM for this transfer */
 	if (dinc)
 		pram->dcm = IDMA_DCM_DMA_WRAP_64 | IDMA_DCM_SINC
 			  | IDMA_DCM_DINC | IDMA_DCM_SD_MEM2MEM;
 	else
 		pram->dcm = IDMA_DCM_DMA_WRAP_64 | IDMA_DCM_SINC
 			  | IDMA_DCM_SD_MEM2MEM;
 	pram->ibdptr = pram->ibase;
 	pram->sts = unit_size;
 	pram->istate = 0;

 	/* initialize the buffer descriptor */
 	bd->dst = (uint) dst;
 	bd->src = virt_to_phys(src);
 	bd->len = bytes;
 	bd->flags = IDMA_BD_V | IDMA_BD_W | IDMA_BD_I | IDMA_BD_L | IDMA_BD_DGBL
 		  | IDMA_BD_DBO_BE | IDMA_BD_SBO_BE | IDMA_BD_SDTB;

 	/* issue the START_IDMA command to the CP */
 	while (immap->im_cpm.cp_cpcr & CPM_CR_FLG);
 	immap->im_cpm.cp_cpcr = mk_cr_cmd(IDMA_PAGE, IDMA_SBLOCK, 0,
 					 CPM_CR_START_IDMA) | CPM_CR_FLG;
 	while (immap->im_cpm.cp_cpcr & CPM_CR_FLG);

 	/* wait for transfer to complete */
 	while(bd->flags & IDMA_BD_V);

 	local_irq_restore(flags);

 	return;
 }

 /* Same as idma_pci9_read, but 16-bit little-endian byte swapping is performed
  * if the unit_size is 2, and 32-bit little-endian byte swapping is performed if
  * the unit_size is 4.
  */
 static void
 idma_pci9_read_le(u8 *dst, u8 *src, int bytes, int unit_size, int sinc)
 {
 	int i;
 	u8 *p;

 	idma_pci9_read(dst, src, bytes, unit_size, sinc);
 	switch(unit_size) {
 		case 2:
 			for (i = 0, p = dst; i < bytes; i += 2, p += 2)
 				swab16s((u16 *) p);
 			break;
 		case 4:
 			for (i = 0, p = dst; i < bytes; i += 4, p += 4)
 				swab32s((u32 *) p);
 			break;
 		default:
 			break;
 	}
 }
 EXPORT_SYMBOL(idma_pci9_init);
 EXPORT_SYMBOL(idma_pci9_read);
 EXPORT_SYMBOL(idma_pci9_read_le);

 static inline int is_pci_mem(unsigned long addr)
 {
 	if (addr >= M82xx_PCI_LOWER_MMIO &&
 		addr <= M82xx_PCI_UPPER_MMIO)
 		return 1;
 	if (addr >= M82xx_PCI_LOWER_MEM &&
 		addr <= M82xx_PCI_UPPER_MEM)
 		return 1;
 	return 0;
 }

 #define is_pci_mem(pa) ( (pa > 0x80000000) && (pa < 0xc0000000))
 int readb(volatile unsigned char *addr)
 {
 	u8 val;
 	unsigned long pa = iopa((unsigned long) addr);

 	if (!is_pci_mem(pa))
 		return in_8(addr);

 	idma_pci9_read((u8 *)&val, (u8 *)pa, sizeof(val), sizeof(val), 0);
 	return val;
 }

 int readw(volatile unsigned short *addr)
 {
 	u16 val;
 	unsigned long pa = iopa((unsigned long) addr);

 	if (!is_pci_mem(pa))
 		return in_le16(addr);

 	idma_pci9_read((u8 *)&val, (u8 *)pa, sizeof(val), sizeof(val), 0);
 	return swab16(val);
 }

 unsigned readl(volatile unsigned *addr)
 {
 	u32 val;
 	unsigned long pa = iopa((unsigned long) addr);

 	if (!is_pci_mem(pa))
 		return in_le32(addr);

 	idma_pci9_read((u8 *)&val, (u8 *)pa, sizeof(val), sizeof(val), 0);
 	return swab32(val);
 }

 int inb(unsigned port)
 {
 	u8 val;
 	u8 *addr = (u8 *)(port + _IO_BASE);

 	idma_pci9_read((u8 *)&val, (u8 *)addr, sizeof(val), sizeof(val), 0);
 	return val;
 }

 int inw(unsigned port)
 {
 	u16 val;
 	u8 *addr = (u8 *)(port + _IO_BASE);

 	idma_pci9_read((u8 *)&val, (u8 *)addr, sizeof(val), sizeof(val), 0);
 	return swab16(val);
 }

 unsigned inl(unsigned port)
 {
 	u32 val;
 	u8 *addr = (u8 *)(port + _IO_BASE);

 	idma_pci9_read((u8 *)&val, (u8 *)addr, sizeof(val), sizeof(val), 0);
 	return swab32(val);
 }

 void insb(unsigned port, void *buf, int ns)
 {
 	u8 *addr = (u8 *)(port + _IO_BASE);

 	idma_pci9_read((u8 *)buf, (u8 *)addr, ns*sizeof(u8), sizeof(u8), 0);
 }

 void insw(unsigned port, void *buf, int ns)
 {
 	u8 *addr = (u8 *)(port + _IO_BASE);

 	idma_pci9_read((u8 *)buf, (u8 *)addr, ns*sizeof(u16), sizeof(u16), 0);
 }

 void insl(unsigned port, void *buf, int nl)
 {
 	u8 *addr = (u8 *)(port + _IO_BASE);

 	idma_pci9_read((u8 *)buf, (u8 *)addr, nl*sizeof(u32), sizeof(u32), 0);
 }

 void *memcpy_fromio(void *dest, unsigned long src, size_t count)
 {
 	unsigned long pa = iopa((unsigned long) src);

 	if (is_pci_mem(pa))
 		idma_pci9_read((u8 *)dest, (u8 *)pa, count, 32, 1);
 	else
 		memcpy(dest, (void *)src, count);
 	return dest;
 }

 EXPORT_SYMBOL(readb);
 EXPORT_SYMBOL(readw);
 EXPORT_SYMBOL(readl);
 EXPORT_SYMBOL(inb);
 EXPORT_SYMBOL(inw);
 EXPORT_SYMBOL(inl);
 EXPORT_SYMBOL(insb);
 EXPORT_SYMBOL(insw);
 EXPORT_SYMBOL(insl);
 EXPORT_SYMBOL(memcpy_fromio);

 #endif	/* ifdef CONFIG_8260_PCI9 */

 /* Indirect PCI routines adapted from arch/ppc/kernel/indirect_pci.c.
  * Copyright (C) 1998 Gabriel Paubert.
  */
 #ifndef CONFIG_8260_PCI9
 #define cfg_read(val, addr, type, op)	*val = op((type)(addr))
 #else
 #define cfg_read(val, addr, type, op) \
 	idma_pci9_read_le((u8*)(val),(u8*)(addr),sizeof(*(val)),sizeof(*(val)),0)
 #endif

 #define cfg_write(val, addr, type, op)	op((type *)(addr), (val))

 static int indirect_write_config(struct pci_bus *pbus, unsigned int devfn, int where,
 			 int size, u32 value)
 {
 	struct pci_controller *hose = pbus->sysdata;
 	u8 cfg_type = 0;
 	if (ppc_md.pci_exclude_device)
 		if (ppc_md.pci_exclude_device(pbus->number, devfn))
 			return PCIBIOS_DEVICE_NOT_FOUND;

 	if (hose->set_cfg_type)
 		if (pbus->number != hose->first_busno)
 			cfg_type = 1;

 	out_be32(hose->cfg_addr,
 		 (((where & 0xfc) | cfg_type) << 24) | (devfn << 16)
 		 | ((pbus->number - hose->bus_offset) << 8) | 0x80);

 	switch (size)
 	{
 		case 1:
 			cfg_write(value, hose->cfg_data + (where & 3), u8, out_8);
 			break;
 		case 2:
 			cfg_write(value, hose->cfg_data + (where & 2), u16, out_le16);
 			break;
 		case 4:
 			cfg_write(value, hose->cfg_data + (where & 0), u32, out_le32);
 			break;
 	}
 	return PCIBIOS_SUCCESSFUL;
 }

 static int indirect_read_config(struct pci_bus *pbus, unsigned int devfn, int where,
 			 int size, u32 *value)
 {
 	struct pci_controller *hose = pbus->sysdata;
 	u8 cfg_type = 0;
 	if (ppc_md.pci_exclude_device)
 		if (ppc_md.pci_exclude_device(pbus->number, devfn))
 			return PCIBIOS_DEVICE_NOT_FOUND;

 	if (hose->set_cfg_type)
 		if (pbus->number != hose->first_busno)
 			cfg_type = 1;

 	out_be32(hose->cfg_addr,
 		 (((where & 0xfc) | cfg_type) << 24) | (devfn << 16)
 		 | ((pbus->number - hose->bus_offset) << 8) | 0x80);

 	switch (size)
 	{
 		case 1:
 			cfg_read(value, hose->cfg_data + (where & 3), u8 *, in_8);
 			break;
 		case 2:
 			cfg_read(value, hose->cfg_data + (where & 2), u16 *, in_le16);
 			break;
 		case 4:
 			cfg_read(value, hose->cfg_data + (where & 0), u32 *, in_le32);
 			break;
 	}
 	return PCIBIOS_SUCCESSFUL;
 }

 static struct pci_ops indirect_pci_ops =
 {
 	.read = indirect_read_config,
 	.write = indirect_write_config,
 };

 void
 setup_m8260_indirect_pci(struct pci_controller* hose, u32 cfg_addr, u32 cfg_data)
 {
 	hose->ops = &indirect_pci_ops;
 	hose->cfg_addr = (unsigned int *) ioremap(cfg_addr, 4);
 	hose->cfg_data = (unsigned char *) ioremap(cfg_data, 4);
 }
	/*
	* Workaround for device erratum PCI 9.
	* See Motorola's "XPC826xA Family Device Errata Reference."
	* The erratum applies to all 8260 family Hip4 processors. It is scheduled
	* to be fixed in HiP4 Rev C. Erratum PCI 9 states that a simultaneous PCI
	* inbound write transaction and PCI outbound read transaction can result in a
	* bus deadlock. The suggested workaround is to use the IDMA controller to
	* perform all reads from PCI configuration, memory, and I/O space.
	*
	* Author: andy_lowe@mvista.com
	*
	* 2003 (c) MontaVista Software, Inc. This file is licensed under
	* the terms of the GNU General Public License version 2. This program
	* is licensed "as is" without any warranty of any kind, whether express
	* or implied.
	*/
	#include <linux/kernel.h>
	#include <linux/module.h>
	#include <linux/pci.h>
	#include <linux/types.h>
	#include <linux/string.h>

	#include <asm/io.h>
	#include <asm/pci-bridge.h>
	#include <asm/machdep.h>
	#include <asm/byteorder.h>
	#include <asm/mpc8260.h>
	#include <asm/immap_cpm2.h>
	#include <asm/cpm2.h>

	#include "m82xx_pci.h"

	#ifdef CONFIG_8260_PCI9
	/#include <asm/mpc8260_pci9.h>/ /* included in asm/io.h */

	#define IDMA_XFER_BUF_SIZE 64 /* size of the IDMA transfer buffer */

	/* define a structure for the IDMA dpram usage */
	typedef struct idma_dpram_s {
	idma_t pram; /* IDMA parameter RAM */
	u_char xfer_buf[IDMA_XFER_BUF_SIZE]; /* IDMA transfer buffer */
	idma_bd_t bd; /* buffer descriptor */
	} idma_dpram_t;

	/* define offsets relative to start of IDMA dpram */
	#define IDMA_XFER_BUF_OFFSET (sizeof(idma_t))
	#define IDMA_BD_OFFSET (sizeof(idma_t) + IDMA_XFER_BUF_SIZE)

	/* define globals */
	static volatile idma_dpram_t *idma_dpram;

	/* Exactly one of CONFIG_8260_PCI9_IDMAn must be defined,
	* where n is 1, 2, 3, or 4. This selects the IDMA channel used for
	* the PCI9 workaround.
	*/
	#ifdef CONFIG_8260_PCI9_IDMA1
	#define IDMA_CHAN 0
	#define PROFF_IDMA PROFF_IDMA1_BASE
	#define IDMA_PAGE CPM_CR_IDMA1_PAGE
	#define IDMA_SBLOCK CPM_CR_IDMA1_SBLOCK
	#endif
	#ifdef CONFIG_8260_PCI9_IDMA2
	#define IDMA_CHAN 1
	#define PROFF_IDMA PROFF_IDMA2_BASE
	#define IDMA_PAGE CPM_CR_IDMA2_PAGE
	#define IDMA_SBLOCK CPM_CR_IDMA2_SBLOCK
	#endif
	#ifdef CONFIG_8260_PCI9_IDMA3
	#define IDMA_CHAN 2
	#define PROFF_IDMA PROFF_IDMA3_BASE
	#define IDMA_PAGE CPM_CR_IDMA3_PAGE
	#define IDMA_SBLOCK CPM_CR_IDMA3_SBLOCK
	#endif
	#ifdef CONFIG_8260_PCI9_IDMA4
	#define IDMA_CHAN 3
	#define PROFF_IDMA PROFF_IDMA4_BASE
	#define IDMA_PAGE CPM_CR_IDMA4_PAGE
	#define IDMA_SBLOCK CPM_CR_IDMA4_SBLOCK
	#endif

	void idma_pci9_init(void)
	{
	uint dpram_offset;
	volatile idma_t *pram;
	volatile im_idma_t *idma_reg;
	volatile cpm2_map_t *immap = cpm2_immr;

	/* allocate IDMA dpram */
	dpram_offset = cpm_dpalloc(sizeof(idma_dpram_t), 64);
	idma_dpram = cpm_dpram_addr(dpram_offset);

	/* initialize the IDMA parameter RAM */
	memset((void *)idma_dpram, 0, sizeof(idma_dpram_t));
	pram = &idma_dpram->pram;
	pram->ibase = dpram_offset + IDMA_BD_OFFSET;
	pram->dpr_buf = dpram_offset + IDMA_XFER_BUF_OFFSET;
	pram->ss_max = 32;
	pram->dts = 32;

	/* initialize the IDMA_BASE pointer to the IDMA parameter RAM */
	((ushort ) &immap->im_dprambase[PROFF_IDMA]) = dpram_offset;

	/* initialize the IDMA registers */
	idma_reg = (volatile im_idma_t *) &immap->im_sdma.sdma_idsr1;
	idma_reg[IDMA_CHAN].idmr = 0; /* mask all IDMA interrupts */
	idma_reg[IDMA_CHAN].idsr = 0xff; /* clear all event flags */

	printk(KERN_WARNING
	"Using IDMA%d for MPC8260 device erratum PCI 9 workaround\n",
	IDMA_CHAN + 1);

	return;
	}

	/* Use the IDMA controller to transfer data from I/O memory to local RAM.
	* The src address must be a physical address suitable for use by the DMA
	* controller with no translation. The dst address must be a kernel virtual
	* address. The dst address is translated to a physical address via
	* virt_to_phys().
	* The sinc argument specifies whether or not the source address is incremented
	* by the DMA controller. The source address is incremented if and only if sinc
	* is non-zero. The destination address is always incremented since the
	* destination is always host RAM.
	*/
	static void
	idma_pci9_read(u8 dst, u8 src, int bytes, int unit_size, int sinc)
	{
	unsigned long flags;
	volatile idma_t *pram = &idma_dpram->pram;
	volatile idma_bd_t *bd = &idma_dpram->bd;
	volatile cpm2_map_t *immap = cpm2_immr;

	local_irq_save(flags);

	/* initialize IDMA parameter RAM for this transfer */
	if (sinc)
	pram->dcm = IDMA_DCM_DMA_WRAP_64 \| IDMA_DCM_SINC
	\| IDMA_DCM_DINC \| IDMA_DCM_SD_MEM2MEM;
	else
	pram->dcm = IDMA_DCM_DMA_WRAP_64 \| IDMA_DCM_DINC
	\| IDMA_DCM_SD_MEM2MEM;
	pram->ibdptr = pram->ibase;
	pram->sts = unit_size;
	pram->istate = 0;

	/* initialize the buffer descriptor */
	bd->dst = virt_to_phys(dst);
	bd->src = (uint) src;
	bd->len = bytes;
	bd->flags = IDMA_BD_V \| IDMA_BD_W \| IDMA_BD_I \| IDMA_BD_L \| IDMA_BD_DGBL
	\| IDMA_BD_DBO_BE \| IDMA_BD_SBO_BE \| IDMA_BD_SDTB;

	/* issue the START_IDMA command to the CP */
	while (immap->im_cpm.cp_cpcr & CPM_CR_FLG);
	immap->im_cpm.cp_cpcr = mk_cr_cmd(IDMA_PAGE, IDMA_SBLOCK, 0,
	CPM_CR_START_IDMA) \| CPM_CR_FLG;
	while (immap->im_cpm.cp_cpcr & CPM_CR_FLG);

	/* wait for transfer to complete */
	while(bd->flags & IDMA_BD_V);

	local_irq_restore(flags);

	return;
	}

	/* Use the IDMA controller to transfer data from I/O memory to local RAM.
	* The dst address must be a physical address suitable for use by the DMA
	* controller with no translation. The src address must be a kernel virtual
	* address. The src address is translated to a physical address via
	* virt_to_phys().
	* The dinc argument specifies whether or not the dest address is incremented
	* by the DMA controller. The source address is incremented if and only if sinc
	* is non-zero. The source address is always incremented since the
	* source is always host RAM.
	*/
	static void
	idma_pci9_write(u8 dst, u8 src, int bytes, int unit_size, int dinc)
	{
	unsigned long flags;
	volatile idma_t *pram = &idma_dpram->pram;
	volatile idma_bd_t *bd = &idma_dpram->bd;
	volatile cpm2_map_t *immap = cpm2_immr;

	local_irq_save(flags);

	/* initialize IDMA parameter RAM for this transfer */
	if (dinc)
	pram->dcm = IDMA_DCM_DMA_WRAP_64 \| IDMA_DCM_SINC
	\| IDMA_DCM_DINC \| IDMA_DCM_SD_MEM2MEM;
	else
	pram->dcm = IDMA_DCM_DMA_WRAP_64 \| IDMA_DCM_SINC
	\| IDMA_DCM_SD_MEM2MEM;
	pram->ibdptr = pram->ibase;
	pram->sts = unit_size;
	pram->istate = 0;

	/* initialize the buffer descriptor */
	bd->dst = (uint) dst;
	bd->src = virt_to_phys(src);
	bd->len = bytes;
	bd->flags = IDMA_BD_V \| IDMA_BD_W \| IDMA_BD_I \| IDMA_BD_L \| IDMA_BD_DGBL
	\| IDMA_BD_DBO_BE \| IDMA_BD_SBO_BE \| IDMA_BD_SDTB;

	/* issue the START_IDMA command to the CP */
	while (immap->im_cpm.cp_cpcr & CPM_CR_FLG);
	immap->im_cpm.cp_cpcr = mk_cr_cmd(IDMA_PAGE, IDMA_SBLOCK, 0,
	CPM_CR_START_IDMA) \| CPM_CR_FLG;
	while (immap->im_cpm.cp_cpcr & CPM_CR_FLG);

	/* wait for transfer to complete */
	while(bd->flags & IDMA_BD_V);

	local_irq_restore(flags);

	return;
	}

	/* Same as idma_pci9_read, but 16-bit little-endian byte swapping is performed
	* if the unit_size is 2, and 32-bit little-endian byte swapping is performed if
	* the unit_size is 4.
	*/
	static void
	idma_pci9_read_le(u8 dst, u8 src, int bytes, int unit_size, int sinc)
	{
	int i;
	u8 *p;

	idma_pci9_read(dst, src, bytes, unit_size, sinc);
	switch(unit_size) {
	case 2:
	for (i = 0, p = dst; i < bytes; i += 2, p += 2)
	swab16s((u16 *) p);
	break;
	case 4:
	for (i = 0, p = dst; i < bytes; i += 4, p += 4)
	swab32s((u32 *) p);
	break;
	default:
	break;
	}
	}
	EXPORT_SYMBOL(idma_pci9_init);
	EXPORT_SYMBOL(idma_pci9_read);
	EXPORT_SYMBOL(idma_pci9_read_le);

	static inline int is_pci_mem(unsigned long addr)
	{
	if (addr >= M82xx_PCI_LOWER_MMIO &&
	addr <= M82xx_PCI_UPPER_MMIO)
	return 1;
	if (addr >= M82xx_PCI_LOWER_MEM &&
	addr <= M82xx_PCI_UPPER_MEM)
	return 1;
	return 0;
	}

	#define is_pci_mem(pa) ( (pa > 0x80000000) && (pa < 0xc0000000))
	int readb(volatile unsigned char *addr)
	{
	u8 val;
	unsigned long pa = iopa((unsigned long) addr);

	if (!is_pci_mem(pa))
	return in_8(addr);

	idma_pci9_read((u8 )&val, (u8 )pa, sizeof(val), sizeof(val), 0);
	return val;
	}

	int readw(volatile unsigned short *addr)
	{
	u16 val;
	unsigned long pa = iopa((unsigned long) addr);

	if (!is_pci_mem(pa))
	return in_le16(addr);

	idma_pci9_read((u8 )&val, (u8 )pa, sizeof(val), sizeof(val), 0);
	return swab16(val);
	}

	unsigned readl(volatile unsigned *addr)
	{
	u32 val;
	unsigned long pa = iopa((unsigned long) addr);

	if (!is_pci_mem(pa))
	return in_le32(addr);

	idma_pci9_read((u8 )&val, (u8 )pa, sizeof(val), sizeof(val), 0);
	return swab32(val);
	}

	int inb(unsigned port)
	{
	u8 val;
	u8 addr = (u8 )(port + _IO_BASE);

	idma_pci9_read((u8 )&val, (u8 )addr, sizeof(val), sizeof(val), 0);
	return val;
	}

	int inw(unsigned port)
	{
	u16 val;
	u8 addr = (u8 )(port + _IO_BASE);

	idma_pci9_read((u8 )&val, (u8 )addr, sizeof(val), sizeof(val), 0);
	return swab16(val);
	}

	unsigned inl(unsigned port)
	{
	u32 val;
	u8 addr = (u8 )(port + _IO_BASE);

	idma_pci9_read((u8 )&val, (u8 )addr, sizeof(val), sizeof(val), 0);
	return swab32(val);
	}

	void insb(unsigned port, void *buf, int ns)
	{
	u8 addr = (u8 )(port + _IO_BASE);

	idma_pci9_read((u8 )buf, (u8 )addr, ns*sizeof(u8), sizeof(u8), 0);
	}

	void insw(unsigned port, void *buf, int ns)
	{
	u8 addr = (u8 )(port + _IO_BASE);

	idma_pci9_read((u8 )buf, (u8 )addr, ns*sizeof(u16), sizeof(u16), 0);
	}

	void insl(unsigned port, void *buf, int nl)
	{
	u8 addr = (u8 )(port + _IO_BASE);

	idma_pci9_read((u8 )buf, (u8 )addr, nl*sizeof(u32), sizeof(u32), 0);
	}

	void memcpy_fromio(void dest, unsigned long src, size_t count)
	{
	unsigned long pa = iopa((unsigned long) src);

	if (is_pci_mem(pa))
	idma_pci9_read((u8 )dest, (u8 )pa, count, 32, 1);
	else
	memcpy(dest, (void *)src, count);
	return dest;
	}

	EXPORT_SYMBOL(readb);
	EXPORT_SYMBOL(readw);
	EXPORT_SYMBOL(readl);
	EXPORT_SYMBOL(inb);
	EXPORT_SYMBOL(inw);
	EXPORT_SYMBOL(inl);
	EXPORT_SYMBOL(insb);
	EXPORT_SYMBOL(insw);
	EXPORT_SYMBOL(insl);
	EXPORT_SYMBOL(memcpy_fromio);

	#endif /* ifdef CONFIG_8260_PCI9 */

	/* Indirect PCI routines adapted from arch/ppc/kernel/indirect_pci.c.
	* Copyright (C) 1998 Gabriel Paubert.
	*/
	#ifndef CONFIG_8260_PCI9
	#define cfg_read(val, addr, type, op) *val = op((type)(addr))
	#else
	#define cfg_read(val, addr, type, op) \
	idma_pci9_read_le((u8)(val),(u8)(addr),sizeof((val)),sizeof((val)),0)
	#endif

	#define cfg_write(val, addr, type, op) op((type *)(addr), (val))

	static int indirect_write_config(struct pci_bus *pbus, unsigned int devfn, int where,
	int size, u32 value)
	{
	struct pci_controller *hose = pbus->sysdata;
	u8 cfg_type = 0;
	if (ppc_md.pci_exclude_device)
	if (ppc_md.pci_exclude_device(pbus->number, devfn))
	return PCIBIOS_DEVICE_NOT_FOUND;

	if (hose->set_cfg_type)
	if (pbus->number != hose->first_busno)
	cfg_type = 1;

	out_be32(hose->cfg_addr,
	(((where & 0xfc) \| cfg_type) << 24) \| (devfn << 16)
	\| ((pbus->number - hose->bus_offset) << 8) \| 0x80);

	switch (size)
	{
	case 1:
	cfg_write(value, hose->cfg_data + (where & 3), u8, out_8);
	break;
	case 2:
	cfg_write(value, hose->cfg_data + (where & 2), u16, out_le16);
	break;
	case 4:
	cfg_write(value, hose->cfg_data + (where & 0), u32, out_le32);
	break;
	}
	return PCIBIOS_SUCCESSFUL;
	}

	static int indirect_read_config(struct pci_bus *pbus, unsigned int devfn, int where,
	int size, u32 *value)
	{
	struct pci_controller *hose = pbus->sysdata;
	u8 cfg_type = 0;
	if (ppc_md.pci_exclude_device)
	if (ppc_md.pci_exclude_device(pbus->number, devfn))
	return PCIBIOS_DEVICE_NOT_FOUND;

	if (hose->set_cfg_type)
	if (pbus->number != hose->first_busno)
	cfg_type = 1;

	out_be32(hose->cfg_addr,
	(((where & 0xfc) \| cfg_type) << 24) \| (devfn << 16)
	\| ((pbus->number - hose->bus_offset) << 8) \| 0x80);

	switch (size)
	{
	case 1:
	cfg_read(value, hose->cfg_data + (where & 3), u8 *, in_8);
	break;
	case 2:
	cfg_read(value, hose->cfg_data + (where & 2), u16 *, in_le16);
	break;
	case 4:
	cfg_read(value, hose->cfg_data + (where & 0), u32 *, in_le32);
	break;
	}
	return PCIBIOS_SUCCESSFUL;
	}

	static struct pci_ops indirect_pci_ops =
	{
	.read = indirect_read_config,
	.write = indirect_write_config,
	};

	void
	setup_m8260_indirect_pci(struct pci_controller* hose, u32 cfg_addr, u32 cfg_data)
	{
	hose->ops = &indirect_pci_ops;
	hose->cfg_addr = (unsigned int *) ioremap(cfg_addr, 4);
	hose->cfg_data = (unsigned char *) ioremap(cfg_data, 4);
	}