arch/sparc/cpu/leon3/ambapp.c - manifest_repos/bootloader - Git at Google

 /* GRLIB AMBA Plug&Play information scanning, relies on assembler
  * routines.
  *
  * (C) Copyright 2010, 2015
  * Daniel Hellstrom, Cobham Gaisler, daniel@gaisler.com.
  *
  * SPDX-License-Identifier:	GPL-2.0+
  */

 /* #define DEBUG */

 #include <common.h>
 #include <malloc.h>
 #include <ambapp.h>
 #include <config.h>

 /************ C INTERFACE OF ASSEMBLER SCAN ROUTINES ************/
 struct ambapp_find_apb_info {
 	/* Address of APB device Plug&Play information */
 	struct ambapp_pnp_apb	*pnp;
 	/* AHB Bus index of where the APB-Master Bridge device was found */
 	int			ahb_bus_index;
 	int			dec_index;
 };

 struct ambapp_find_ahb_info {
 	/* Address of AHB device Plug&Play information */
 	struct ambapp_pnp_ahb	*pnp;
 	/* AHB Bus index of where the AHB device was found */
 	int			ahb_bus_index;
 	int			dec_index;
 };

 extern void ambapp_find_buses(unsigned int ioarea, struct ambapp_bus *abus);

 extern int ambapp_find_apb(struct ambapp_bus *abus, unsigned int dev_vend,
 	int index, struct ambapp_find_apb_info *result);

 extern int ambapp_find_ahb(struct ambapp_bus *abus, unsigned int dev_vend,
 	int index, int type, struct ambapp_find_ahb_info *result);

 /************ C ROUTINES USED BY U-BOOT AMBA CORE DRIVERS ************/
 struct ambapp_bus ambapp_plb __section(.data);

 void ambapp_bus_init(
 	unsigned int ioarea,
 	unsigned int freq,
 	struct ambapp_bus *abus)
 {
 	int i;

 	ambapp_find_buses(ioarea, abus);
 	for (i = 0; i < 6; i++)
 		if (abus->ioareas[i] == 0)
 			break;
 	abus->buses = i;
 	abus->freq = freq;
 }

 /* Parse APB PnP Information */
 void ambapp_apb_parse(struct ambapp_find_apb_info *info, ambapp_apbdev *dev)
 {
 	struct ambapp_pnp_apb *apb = info->pnp;
 	unsigned int apbbase = (unsigned int)apb & 0xfff00000;

 	dev->vendor = amba_vendor(apb->id);
 	dev->device = amba_device(apb->id);
 	dev->irq = amba_irq(apb->id);
 	dev->ver = amba_ver(apb->id);
 	dev->address = (apbbase | (((apb->iobar & 0xfff00000) >> 12))) &
 			(((apb->iobar &	0x0000fff0) << 4) | 0xfff00000);
 	dev->mask = amba_apb_mask(apb->iobar);
 	dev->ahb_bus_index = info->ahb_bus_index - 1;
 }

 /* Parse AHB PnP information */
 void ambapp_ahb_parse(struct ambapp_find_ahb_info *info, ambapp_ahbdev *dev)
 {
 	struct ambapp_pnp_ahb *ahb = info->pnp;
 	unsigned int ahbbase = (unsigned int)ahb & 0xfff00000;
 	int i, type;
 	unsigned int addr, mask, mbar;

 	dev->vendor = amba_vendor(ahb->id);
 	dev->device = amba_device(ahb->id);
 	dev->irq = amba_irq(ahb->id);
 	dev->ver = amba_ver(ahb->id);
 	dev->userdef[0] = ahb->custom[0];
 	dev->userdef[1] = ahb->custom[1];
 	dev->userdef[2] = ahb->custom[2];
 	dev->ahb_bus_index = info->ahb_bus_index - 1;
 	for (i = 0; i < 4; i++) {
 		mbar = ahb->mbar[i];
 		addr = amba_membar_start(mbar);
 		type = amba_membar_type(mbar);
 		if (type == AMBA_TYPE_AHBIO) {
 			addr = amba_ahbio_adr(addr, ahbbase);
 			mask = (((unsigned int)
 				(amba_membar_mask((~mbar))<<8)|0xff))+1;
 		} else {
 			/* AHB memory area, absolute address */
 			mask = (~((unsigned int)
 				(amba_membar_mask(mbar)<<20)))+1;
 		}
 		dev->address[i] = addr;
 		dev->mask[i] = mask;
 		dev->type[i] = type;
 	}
 }

 int ambapp_apb_find(struct ambapp_bus *abus, int vendor, int device,
 	int index, ambapp_apbdev *dev)
 {
 	unsigned int devid = AMBA_PNP_ID(vendor, device);
 	int found;
 	struct ambapp_find_apb_info apbdev;

 	found = ambapp_find_apb(abus, devid, index, &apbdev);
 	if (found == 1)
 		ambapp_apb_parse(&apbdev, dev);

 	return found;
 }

 int ambapp_apb_count(struct ambapp_bus *abus, int vendor, int device)
 {
 	unsigned int devid = AMBA_PNP_ID(vendor, device);
 	int found;
 	struct ambapp_find_apb_info apbdev;

 	found = ambapp_find_apb(abus, devid, 63, &apbdev);
 	if (found == 1)
 		return 64;
 	else
 		return 63 - apbdev.dec_index;
 }

 int ambapp_ahb_find(struct ambapp_bus *abus, int vendor, int device,
 	int index, ambapp_ahbdev *dev, int type)
 {
 	int found;
 	struct ambapp_find_ahb_info ahbdev;
 	unsigned int devid = AMBA_PNP_ID(vendor, device);

 	found = ambapp_find_ahb(abus, devid, index, type, &ahbdev);
 	if (found == 1)
 		ambapp_ahb_parse(&ahbdev, dev);

 	return found;
 }

 int ambapp_ahbmst_find(struct ambapp_bus *abus, int vendor, int device,
 	int index, ambapp_ahbdev *dev)
 {
 	return ambapp_ahb_find(abus, vendor, device, index, dev, DEV_AHB_MST);
 }

 int ambapp_ahbslv_find(struct ambapp_bus *abus, int vendor, int device,
 	int index, ambapp_ahbdev *dev)
 {
 	return ambapp_ahb_find(abus, vendor, device, index, dev, DEV_AHB_SLV);
 }

 int ambapp_ahb_count(struct ambapp_bus *abus, int vendor, int device, int type)
 {
 	int found;
 	struct ambapp_find_ahb_info ahbdev;
 	unsigned int devid = AMBA_PNP_ID(vendor, device);

 	found = ambapp_find_ahb(abus, devid, 63, type, &ahbdev);
 	if (found == 1)
 		return 64;
 	else
 		return 63 - ahbdev.dec_index;
 }

 int ambapp_ahbmst_count(struct ambapp_bus *abus, int vendor, int device)
 {
 	return ambapp_ahb_count(abus, vendor, device, DEV_AHB_MST);
 }

 int ambapp_ahbslv_count(struct ambapp_bus *abus, int vendor, int device)
 {
 	return ambapp_ahb_count(abus, vendor, device, DEV_AHB_SLV);
 }

 /* The define CONFIG_SYS_GRLIB_SINGLE_BUS may be defined on GRLIB systems
  * where only one AHB Bus is available - no bridges are present. This option
  * is available only to reduce the footprint.
  *
  * Defining this on a multi-bus GRLIB system may also work depending on the
  * design.
  */

 #ifndef CONFIG_SYS_GRLIB_SINGLE_BUS

 /* GAISLER AHB2AHB Version 1 Bridge Definitions */
 #define AHB2AHB_V1_FLAG_FFACT     0x0f0	/* Frequency factor against top bus */
 #define AHB2AHB_V1_FLAG_FFACT_DIR 0x100	/* Factor direction, 0=down, 1=up */
 #define AHB2AHB_V1_FLAG_MBUS      0x00c	/* Master bus number mask */
 #define AHB2AHB_V1_FLAG_SBUS      0x003	/* Slave bus number mask */

 /* Get Parent bus frequency. Note that since we go from a "child" bus
  * to a parent bus, the frequency factor direction is inverted.
  */
 unsigned int gaisler_ahb2ahb_v1_freq(ambapp_ahbdev *ahb, unsigned int freq)
 {
 	int dir;
 	unsigned char ffact;

 	/* Get division/multiple factor */
 	ffact = (ahb->userdef[0] & AHB2AHB_V1_FLAG_FFACT) >> 4;
 	if (ffact != 0) {
 		dir = ahb->userdef[0] & AHB2AHB_V1_FLAG_FFACT_DIR;

 		/* Calculate frequency by dividing or
 		 * multiplying system frequency
 		 */
 		if (dir)
 			freq = freq * ffact;
 		else
 			freq = freq / ffact;
 	}

 	return freq;
 }

 /* AHB2AHB and L2CACHE ver 2 is not supported yet. */
 unsigned int gaisler_ahb2ahb_v2_freq(ambapp_ahbdev *ahb, unsigned int freq)
 {
 	panic("gaisler_ahb2ahb_v2_freq: AHB2AHB ver 2 not supported\n");
 	return -1;
 }
 #endif

 /* Return the frequency of a AHB bus identified by index found
  * note that this is not the AHB Bus number.
  */
 unsigned int ambapp_bus_freq(struct ambapp_bus *abus, int ahb_bus_index)
 {
 	unsigned int freq = abus->freq;
 #ifndef CONFIG_SYS_GRLIB_SINGLE_BUS
 	unsigned int ioarea, ioarea_parent, bridge_pnp_ofs;
 	struct ambapp_find_ahb_info ahbinfo;
 	ambapp_ahbdev ahb;
 	int parent;

 	debug("ambapp_bus_freq: get freq on bus %d\n", ahb_bus_index);

 	while (ahb_bus_index != 0) {
 		debug("  BUS[0]: 0x%08x\n", abus->ioareas[0]);
 		debug("  BUS[1]: 0x%08x\n", abus->ioareas[1]);
 		debug("  BUS[2]: 0x%08x\n", abus->ioareas[2]);
 		debug("  BUS[3]: 0x%08x\n", abus->ioareas[3]);
 		debug("  BUS[4]: 0x%08x\n", abus->ioareas[4]);
 		debug("  BUS[5]: 0x%08x\n", abus->ioareas[5]);

 		/* Get I/O area of AHB bus */
 		ioarea = abus->ioareas[ahb_bus_index];

 		debug("  IOAREA: 0x%08x\n", ioarea);

 		/* Get parent bus */
 		parent = (ioarea & 0x7);
 		if (parent == 0) {
 			panic("%s: parent=0 indicates no parent! Stopping.\n",
 				__func__);
 			return -1;
 		}
 		parent = parent - 1;
 		bridge_pnp_ofs = ioarea & 0x7e0;

 		debug("  PARENT: %d\n", parent);
 		debug("  BRIDGE_OFS: 0x%08x\n", bridge_pnp_ofs);

 		/* Get AHB/AHB bridge PnP address */
 		ioarea_parent = (abus->ioareas[parent] & 0xfff00000) |
 				AMBA_CONF_AREA | AMBA_AHB_SLAVE_CONF_AREA;
 		ahbinfo.pnp = (struct ambapp_pnp_ahb *)
 				(ioarea_parent | bridge_pnp_ofs);

 		debug("  IOAREA PARENT: 0x%08x\n", ioarea_parent);
 		debug("  BRIDGE PNP: 0x%p\n", ahbinfo.pnp);

 		/* Parse the AHB information */
 		ahbinfo.ahb_bus_index = parent;
 		ambapp_ahb_parse(&ahbinfo, &ahb);

 		debug("  BRIDGE ID: VENDOR=%d(0x%x), DEVICE=%d(0x%x)\n",
 			ahb.vendor, ahb.vendor, ahb.device, ahb.device);

 		/* Different bridges may convert frequency differently */
 		if ((ahb.vendor == VENDOR_GAISLER) &&
 			((ahb.device == GAISLER_AHB2AHB) ||
 			(ahb.device == GAISLER_L2CACHE))) {
 			/* Get new frequency */
 			if (ahb.ver > 1)
 				freq = gaisler_ahb2ahb_v2_freq(&ahb, freq);
 			else
 				freq = gaisler_ahb2ahb_v1_freq(&ahb, freq);

 			debug("  NEW FREQ: %dHz\n", freq);
 		} else {
 			panic("%s: unsupported AMBA bridge\n", __func__);
 			return -1;
 		}

 		/* Step upwards towards system top bus */
 		ahb_bus_index = parent;
 	}
 #endif

 	debug("ambapp_bus_freq: %dHz\n", freq);

 	return freq;
 }
	/* GRLIB AMBA Plug&Play information scanning, relies on assembler
	* routines.
	*
	* (C) Copyright 2010, 2015
	* Daniel Hellstrom, Cobham Gaisler, daniel@gaisler.com.
	*
	* SPDX-License-Identifier: GPL-2.0+
	*/

	/* #define DEBUG */

	#include <common.h>
	#include <malloc.h>
	#include <ambapp.h>
	#include <config.h>

	/********** C INTERFACE OF ASSEMBLER SCAN ROUTINES **********/
	struct ambapp_find_apb_info {
	/* Address of APB device Plug&Play information */
	struct ambapp_pnp_apb *pnp;
	/* AHB Bus index of where the APB-Master Bridge device was found */
	int ahb_bus_index;
	int dec_index;
	};

	struct ambapp_find_ahb_info {
	/* Address of AHB device Plug&Play information */
	struct ambapp_pnp_ahb *pnp;
	/* AHB Bus index of where the AHB device was found */
	int ahb_bus_index;
	int dec_index;
	};

	extern void ambapp_find_buses(unsigned int ioarea, struct ambapp_bus *abus);

	extern int ambapp_find_apb(struct ambapp_bus *abus, unsigned int dev_vend,
	int index, struct ambapp_find_apb_info *result);

	extern int ambapp_find_ahb(struct ambapp_bus *abus, unsigned int dev_vend,
	int index, int type, struct ambapp_find_ahb_info *result);

	/********** C ROUTINES USED BY U-BOOT AMBA CORE DRIVERS **********/
	struct ambapp_bus ambapp_plb __section(.data);

	void ambapp_bus_init(
	unsigned int ioarea,
	unsigned int freq,
	struct ambapp_bus *abus)
	{
	int i;

	ambapp_find_buses(ioarea, abus);
	for (i = 0; i < 6; i++)
	if (abus->ioareas[i] == 0)
	break;
	abus->buses = i;
	abus->freq = freq;
	}

	/* Parse APB PnP Information */
	void ambapp_apb_parse(struct ambapp_find_apb_info info, ambapp_apbdev dev)
	{
	struct ambapp_pnp_apb *apb = info->pnp;
	unsigned int apbbase = (unsigned int)apb & 0xfff00000;

	dev->vendor = amba_vendor(apb->id);
	dev->device = amba_device(apb->id);
	dev->irq = amba_irq(apb->id);
	dev->ver = amba_ver(apb->id);
	dev->address = (apbbase \| (((apb->iobar & 0xfff00000) >> 12))) &
	(((apb->iobar & 0x0000fff0) << 4) \| 0xfff00000);
	dev->mask = amba_apb_mask(apb->iobar);
	dev->ahb_bus_index = info->ahb_bus_index - 1;
	}

	/* Parse AHB PnP information */
	void ambapp_ahb_parse(struct ambapp_find_ahb_info info, ambapp_ahbdev dev)
	{
	struct ambapp_pnp_ahb *ahb = info->pnp;
	unsigned int ahbbase = (unsigned int)ahb & 0xfff00000;
	int i, type;
	unsigned int addr, mask, mbar;

	dev->vendor = amba_vendor(ahb->id);
	dev->device = amba_device(ahb->id);
	dev->irq = amba_irq(ahb->id);
	dev->ver = amba_ver(ahb->id);
	dev->userdef[0] = ahb->custom[0];
	dev->userdef[1] = ahb->custom[1];
	dev->userdef[2] = ahb->custom[2];
	dev->ahb_bus_index = info->ahb_bus_index - 1;
	for (i = 0; i < 4; i++) {
	mbar = ahb->mbar[i];
	addr = amba_membar_start(mbar);
	type = amba_membar_type(mbar);
	if (type == AMBA_TYPE_AHBIO) {
	addr = amba_ahbio_adr(addr, ahbbase);
	mask = (((unsigned int)
	(amba_membar_mask((~mbar))<<8)\|0xff))+1;
	} else {
	/* AHB memory area, absolute address */
	mask = (~((unsigned int)
	(amba_membar_mask(mbar)<<20)))+1;
	}
	dev->address[i] = addr;
	dev->mask[i] = mask;
	dev->type[i] = type;
	}
	}

	int ambapp_apb_find(struct ambapp_bus *abus, int vendor, int device,
	int index, ambapp_apbdev *dev)
	{
	unsigned int devid = AMBA_PNP_ID(vendor, device);
	int found;
	struct ambapp_find_apb_info apbdev;

	found = ambapp_find_apb(abus, devid, index, &apbdev);
	if (found == 1)
	ambapp_apb_parse(&apbdev, dev);

	return found;
	}

	int ambapp_apb_count(struct ambapp_bus *abus, int vendor, int device)
	{
	unsigned int devid = AMBA_PNP_ID(vendor, device);
	int found;
	struct ambapp_find_apb_info apbdev;

	found = ambapp_find_apb(abus, devid, 63, &apbdev);
	if (found == 1)
	return 64;
	else
	return 63 - apbdev.dec_index;
	}

	int ambapp_ahb_find(struct ambapp_bus *abus, int vendor, int device,
	int index, ambapp_ahbdev *dev, int type)
	{
	int found;
	struct ambapp_find_ahb_info ahbdev;
	unsigned int devid = AMBA_PNP_ID(vendor, device);

	found = ambapp_find_ahb(abus, devid, index, type, &ahbdev);
	if (found == 1)
	ambapp_ahb_parse(&ahbdev, dev);

	return found;
	}

	int ambapp_ahbmst_find(struct ambapp_bus *abus, int vendor, int device,
	int index, ambapp_ahbdev *dev)
	{
	return ambapp_ahb_find(abus, vendor, device, index, dev, DEV_AHB_MST);
	}

	int ambapp_ahbslv_find(struct ambapp_bus *abus, int vendor, int device,
	int index, ambapp_ahbdev *dev)
	{
	return ambapp_ahb_find(abus, vendor, device, index, dev, DEV_AHB_SLV);
	}

	int ambapp_ahb_count(struct ambapp_bus *abus, int vendor, int device, int type)
	{
	int found;
	struct ambapp_find_ahb_info ahbdev;
	unsigned int devid = AMBA_PNP_ID(vendor, device);

	found = ambapp_find_ahb(abus, devid, 63, type, &ahbdev);
	if (found == 1)
	return 64;
	else
	return 63 - ahbdev.dec_index;
	}

	int ambapp_ahbmst_count(struct ambapp_bus *abus, int vendor, int device)
	{
	return ambapp_ahb_count(abus, vendor, device, DEV_AHB_MST);
	}

	int ambapp_ahbslv_count(struct ambapp_bus *abus, int vendor, int device)
	{
	return ambapp_ahb_count(abus, vendor, device, DEV_AHB_SLV);
	}

	/* The define CONFIG_SYS_GRLIB_SINGLE_BUS may be defined on GRLIB systems
	* where only one AHB Bus is available - no bridges are present. This option
	* is available only to reduce the footprint.
	*
	* Defining this on a multi-bus GRLIB system may also work depending on the
	* design.
	*/

	#ifndef CONFIG_SYS_GRLIB_SINGLE_BUS

	/* GAISLER AHB2AHB Version 1 Bridge Definitions */
	#define AHB2AHB_V1_FLAG_FFACT 0x0f0 /* Frequency factor against top bus */
	#define AHB2AHB_V1_FLAG_FFACT_DIR 0x100 /* Factor direction, 0=down, 1=up */
	#define AHB2AHB_V1_FLAG_MBUS 0x00c /* Master bus number mask */
	#define AHB2AHB_V1_FLAG_SBUS 0x003 /* Slave bus number mask */

	/* Get Parent bus frequency. Note that since we go from a "child" bus
	* to a parent bus, the frequency factor direction is inverted.
	*/
	unsigned int gaisler_ahb2ahb_v1_freq(ambapp_ahbdev *ahb, unsigned int freq)
	{
	int dir;
	unsigned char ffact;

	/* Get division/multiple factor */
	ffact = (ahb->userdef[0] & AHB2AHB_V1_FLAG_FFACT) >> 4;
	if (ffact != 0) {
	dir = ahb->userdef[0] & AHB2AHB_V1_FLAG_FFACT_DIR;

	/* Calculate frequency by dividing or
	* multiplying system frequency
	*/
	if (dir)
	freq = freq * ffact;
	else
	freq = freq / ffact;
	}

	return freq;
	}

	/* AHB2AHB and L2CACHE ver 2 is not supported yet. */
	unsigned int gaisler_ahb2ahb_v2_freq(ambapp_ahbdev *ahb, unsigned int freq)
	{
	panic("gaisler_ahb2ahb_v2_freq: AHB2AHB ver 2 not supported\n");
	return -1;
	}
	#endif

	/* Return the frequency of a AHB bus identified by index found
	* note that this is not the AHB Bus number.
	*/
	unsigned int ambapp_bus_freq(struct ambapp_bus *abus, int ahb_bus_index)
	{
	unsigned int freq = abus->freq;
	#ifndef CONFIG_SYS_GRLIB_SINGLE_BUS
	unsigned int ioarea, ioarea_parent, bridge_pnp_ofs;
	struct ambapp_find_ahb_info ahbinfo;
	ambapp_ahbdev ahb;
	int parent;

	debug("ambapp_bus_freq: get freq on bus %d\n", ahb_bus_index);

	while (ahb_bus_index != 0) {
	debug(" BUS[0]: 0x%08x\n", abus->ioareas[0]);
	debug(" BUS[1]: 0x%08x\n", abus->ioareas[1]);
	debug(" BUS[2]: 0x%08x\n", abus->ioareas[2]);
	debug(" BUS[3]: 0x%08x\n", abus->ioareas[3]);
	debug(" BUS[4]: 0x%08x\n", abus->ioareas[4]);
	debug(" BUS[5]: 0x%08x\n", abus->ioareas[5]);

	/* Get I/O area of AHB bus */
	ioarea = abus->ioareas[ahb_bus_index];

	debug(" IOAREA: 0x%08x\n", ioarea);

	/* Get parent bus */
	parent = (ioarea & 0x7);
	if (parent == 0) {
	panic("%s: parent=0 indicates no parent! Stopping.\n",
	__func__);
	return -1;
	}
	parent = parent - 1;
	bridge_pnp_ofs = ioarea & 0x7e0;

	debug(" PARENT: %d\n", parent);
	debug(" BRIDGE_OFS: 0x%08x\n", bridge_pnp_ofs);

	/* Get AHB/AHB bridge PnP address */
	ioarea_parent = (abus->ioareas[parent] & 0xfff00000) \|
	AMBA_CONF_AREA \| AMBA_AHB_SLAVE_CONF_AREA;
	ahbinfo.pnp = (struct ambapp_pnp_ahb *)
	(ioarea_parent \| bridge_pnp_ofs);

	debug(" IOAREA PARENT: 0x%08x\n", ioarea_parent);
	debug(" BRIDGE PNP: 0x%p\n", ahbinfo.pnp);

	/* Parse the AHB information */
	ahbinfo.ahb_bus_index = parent;
	ambapp_ahb_parse(&ahbinfo, &ahb);

	debug(" BRIDGE ID: VENDOR=%d(0x%x), DEVICE=%d(0x%x)\n",
	ahb.vendor, ahb.vendor, ahb.device, ahb.device);

	/* Different bridges may convert frequency differently */
	if ((ahb.vendor == VENDOR_GAISLER) &&
	((ahb.device == GAISLER_AHB2AHB) \|\|
	(ahb.device == GAISLER_L2CACHE))) {
	/* Get new frequency */
	if (ahb.ver > 1)
	freq = gaisler_ahb2ahb_v2_freq(&ahb, freq);
	else
	freq = gaisler_ahb2ahb_v1_freq(&ahb, freq);

	debug(" NEW FREQ: %dHz\n", freq);
	} else {
	panic("%s: unsupported AMBA bridge\n", __func__);
	return -1;
	}

	/* Step upwards towards system top bus */
	ahb_bus_index = parent;
	}
	#endif

	debug("ambapp_bus_freq: %dHz\n", freq);

	return freq;
	}