arch/ppc/boot/simple/qspan_pci.c - linux/kernel/git/torvalds/linux - Git at Google

 /*
  * LinuxPPC arch/ppc/kernel/qspan_pci.c   Dan Malek (dmalek@jlc.net)
  *
  * QSpan Motorola bus to PCI bridge.  The config address register
  * is located 0x500 from the base of the bridge control/status registers.
  * The data register is located at 0x504.
  * This is a two step operation.  First, the address register is written,
  * then the data register is read/written as required.
  * I don't know what to do about interrupts (yet).
  */

 #include <linux/types.h>
 #include <linux/kernel.h>
 #include <linux/pci.h>
 #include <asm/mpc8xx.h>

 /*
  * When reading the configuration space, if something does not respond
  * the bus times out and we get a machine check interrupt.  So, the
  * good ol' exception tables come to mind to trap it and return some
  * value.
  *
  * On an error we just return a -1, since that is what the caller wants
  * returned if nothing is present.  I copied this from __get_user_asm,
  * with the only difference of returning -1 instead of EFAULT.
  * There is an associated hack in the machine check trap code.
  *
  * The QSPAN is also a big endian device, that is it makes the PCI
  * look big endian to us.  This presents a problem for the Linux PCI
  * functions, which assume little endian.  For example, we see the
  * first 32-bit word like this:
  *	------------------------
  *	| Device ID | Vendor ID |
  *	------------------------
  * If we read/write as a double word, that's OK.  But in our world,
  * when read as a word, device ID is at location 0, not location 2 as
  * the little endian PCI would believe.  We have to switch bits in
  * the PCI addresses given to us to get the data to/from the correct
  * byte lanes.
  *
  * The QSPAN only supports 4 bits of "slot" in the dev_fn instead of 5.
  * It always forces the MS bit to zero.  Therefore, dev_fn values
  * greater than 128 are returned as "no device found" errors.
  *
  * The QSPAN can only perform long word (32-bit) configuration cycles.
  * The "offset" must have the two LS bits set to zero.  Read operations
  * require we read the entire word and then sort out what should be
  * returned.  Write operations other than long word require that we
  * read the long word, update the proper word or byte, then write the
  * entire long word back.
  *
  * PCI Bridge hack.  We assume (correctly) that bus 0 is the primary
  * PCI bus from the QSPAN.  If we are called with a bus number other
  * than zero, we create a Type 1 configuration access that a downstream
  * PCI bridge will interpret.
  */

 #define __get_pci_config(x, addr, op)		\
 	__asm__ __volatile__(				\
 		"1:	"op" %0,0(%1)\n"		\
 		"	eieio\n"			\
 		"2:\n"					\
 		".section .fixup,\"ax\"\n"		\
 		"3:	li %0,-1\n"			\
 		"	b 2b\n"				\
 		".section __ex_table,\"a\"\n"		\
 		"	.align 2\n"			\
 		"	.long 1b,3b\n"			\
 		".text"					\
 		: "=r"(x) : "r"(addr))

 #define QS_CONFIG_ADDR	((volatile uint *)(PCI_CSR_ADDR + 0x500))
 #define QS_CONFIG_DATA	((volatile uint *)(PCI_CSR_ADDR + 0x504))

 #define mk_config_addr(bus, dev, offset) \
 	(((bus)<<16) | ((dev)<<8) | (offset & 0xfc))

 #define mk_config_type1(bus, dev, offset) \
 	mk_config_addr(bus, dev, offset) | 1;

 /* Initialize the QSpan device registers after power up.
 */
 void
 qspan_init(void)
 {
 	uint	*qptr;


 	qptr = (uint *)PCI_CSR_ADDR;

 	/* PCI Configuration/status.  Upper bits written to clear
 	 * pending interrupt or status.  Lower bits enable QSPAN as
 	 * PCI master, enable memory and I/O cycles, and enable PCI
 	 * parity error checking.
 	 * IMPORTANT:  The last two bits of this word enable PCI
 	 * master cycles into the QBus.  The QSpan is broken and can't
 	 * meet the timing specs of the PQ bus for this to work.  Therefore,
 	 * if you don't have external bus arbitration, you can't use
 	 * this function.
 	 */
 #ifdef EXTERNAL_PQ_ARB
 	qptr[1] = 0xf9000147;
 #else
 	qptr[1] = 0xf9000144;
 #endif

 	/* PCI Misc configuration.  Set PCI latency timer resolution
 	 * of 8 cycles, set cache size to 4 x 32.
 	 */
 	qptr[3] = 0;

 	/* Set up PCI Target address mapping.  Enable, Posted writes,
 	 * 2Gbyte space (processor memory controller determines actual size).
 	 */
 	qptr[64] = 0x8f000080;

 	/* Map processor 0x80000000 to PCI 0x00000000.
 	 * Processor address bit 1 determines I/O type access (0x80000000)
 	 * or memory type access (0xc0000000).
 	 */
 	qptr[65] = 0x80000000;

 	/* Enable error logging and clear any pending error status.
 	*/
 	qptr[80] = 0x90000000;

 	qptr[512] = 0x000c0003;

 	/* Set up Qbus slave image.
 	*/
 	qptr[960] = 0x01000000;
 	qptr[961] = 0x000000d1;
 	qptr[964] = 0x00000000;
 	qptr[965] = 0x000000d1;

 }

 /* Functions to support PCI bios-like features to read/write configuration
  * space.  If the function fails for any reason, a -1 (0xffffffff) value
  * must be returned.
  */
 #define DEVICE_NOT_FOUND	(-1)
 #define SUCCESSFUL		0

 int qs_pci_read_config_byte(unsigned char bus, unsigned char dev_fn,
 				  unsigned char offset, unsigned char *val)
 {
 	uint	temp;
 	u_char	*cp;

 	if ((bus > 7) || (dev_fn > 127)) {
 		*val = 0xff;
 		return DEVICE_NOT_FOUND;
 	}

 	if (bus == 0)
 		*QS_CONFIG_ADDR = mk_config_addr(bus, dev_fn, offset);
 	else
 		*QS_CONFIG_ADDR = mk_config_type1(bus, dev_fn, offset);
 	__get_pci_config(temp, QS_CONFIG_DATA, "lwz");

 	offset ^= 0x03;
 	cp = ((u_char *)&temp) + (offset & 0x03);
 	*val = *cp;
 	return SUCCESSFUL;
 }

 int qs_pci_read_config_word(unsigned char bus, unsigned char dev_fn,
 				  unsigned char offset, unsigned short *val)
 {
 	uint	temp;
 	ushort	*sp;

 	if ((bus > 7) || (dev_fn > 127)) {
 		*val = 0xffff;
 		return DEVICE_NOT_FOUND;
 	}

 	if (bus == 0)
 		*QS_CONFIG_ADDR = mk_config_addr(bus, dev_fn, offset);
 	else
 		*QS_CONFIG_ADDR = mk_config_type1(bus, dev_fn, offset);
 	__get_pci_config(temp, QS_CONFIG_DATA, "lwz");
 	offset ^= 0x02;

 	sp = ((ushort *)&temp) + ((offset >> 1) & 1);
 	*val = *sp;
 	return SUCCESSFUL;
 }

 int qs_pci_read_config_dword(unsigned char bus, unsigned char dev_fn,
 				   unsigned char offset, unsigned int *val)
 {
 	if ((bus > 7) || (dev_fn > 127)) {
 		*val = 0xffffffff;
 		return DEVICE_NOT_FOUND;
 	}
 	if (bus == 0)
 		*QS_CONFIG_ADDR = mk_config_addr(bus, dev_fn, offset);
 	else
 		*QS_CONFIG_ADDR = mk_config_type1(bus, dev_fn, offset);
 	__get_pci_config(*val, QS_CONFIG_DATA, "lwz");
 	return SUCCESSFUL;
 }

 int qs_pci_write_config_byte(unsigned char bus, unsigned char dev_fn,
 				   unsigned char offset, unsigned char val)
 {
 	uint	temp;
 	u_char	*cp;

 	if ((bus > 7) || (dev_fn > 127))
 		return DEVICE_NOT_FOUND;

 	qs_pci_read_config_dword(bus, dev_fn, offset, &temp);

 	offset ^= 0x03;
 	cp = ((u_char *)&temp) + (offset & 0x03);
 	*cp = val;

 	if (bus == 0)
 		*QS_CONFIG_ADDR = mk_config_addr(bus, dev_fn, offset);
 	else
 		*QS_CONFIG_ADDR = mk_config_type1(bus, dev_fn, offset);
 	*QS_CONFIG_DATA = temp;

 	return SUCCESSFUL;
 }

 int qs_pci_write_config_word(unsigned char bus, unsigned char dev_fn,
 				   unsigned char offset, unsigned short val)
 {
 	uint	temp;
 	ushort	*sp;

 	if ((bus > 7) || (dev_fn > 127))
 		return DEVICE_NOT_FOUND;

 	qs_pci_read_config_dword(bus, dev_fn, offset, &temp);

 	offset ^= 0x02;
 	sp = ((ushort *)&temp) + ((offset >> 1) & 1);
 	*sp = val;

 	if (bus == 0)
 		*QS_CONFIG_ADDR = mk_config_addr(bus, dev_fn, offset);
 	else
 		*QS_CONFIG_ADDR = mk_config_type1(bus, dev_fn, offset);
 	*QS_CONFIG_DATA = temp;

 	return SUCCESSFUL;
 }

 int qs_pci_write_config_dword(unsigned char bus, unsigned char dev_fn,
 				    unsigned char offset, unsigned int val)
 {
 	if ((bus > 7) || (dev_fn > 127))
 		return DEVICE_NOT_FOUND;

 	if (bus == 0)
 		*QS_CONFIG_ADDR = mk_config_addr(bus, dev_fn, offset);
 	else
 		*QS_CONFIG_ADDR = mk_config_type1(bus, dev_fn, offset);
 	*(unsigned int *)QS_CONFIG_DATA = val;

 	return SUCCESSFUL;
 }
	/*
	* LinuxPPC arch/ppc/kernel/qspan_pci.c Dan Malek (dmalek@jlc.net)
	*
	* QSpan Motorola bus to PCI bridge. The config address register
	* is located 0x500 from the base of the bridge control/status registers.
	* The data register is located at 0x504.
	* This is a two step operation. First, the address register is written,
	* then the data register is read/written as required.
	* I don't know what to do about interrupts (yet).
	*/

	#include <linux/types.h>
	#include <linux/kernel.h>
	#include <linux/pci.h>
	#include <asm/mpc8xx.h>

	/*
	* When reading the configuration space, if something does not respond
	* the bus times out and we get a machine check interrupt. So, the
	* good ol' exception tables come to mind to trap it and return some
	* value.
	*
	* On an error we just return a -1, since that is what the caller wants
	* returned if nothing is present. I copied this from __get_user_asm,
	* with the only difference of returning -1 instead of EFAULT.
	* There is an associated hack in the machine check trap code.
	*
	* The QSPAN is also a big endian device, that is it makes the PCI
	* look big endian to us. This presents a problem for the Linux PCI
	* functions, which assume little endian. For example, we see the
	* first 32-bit word like this:
	* ------------------------
	* \| Device ID \| Vendor ID \|
	* ------------------------
	* If we read/write as a double word, that's OK. But in our world,
	* when read as a word, device ID is at location 0, not location 2 as
	* the little endian PCI would believe. We have to switch bits in
	* the PCI addresses given to us to get the data to/from the correct
	* byte lanes.
	*
	* The QSPAN only supports 4 bits of "slot" in the dev_fn instead of 5.
	* It always forces the MS bit to zero. Therefore, dev_fn values
	* greater than 128 are returned as "no device found" errors.
	*
	* The QSPAN can only perform long word (32-bit) configuration cycles.
	* The "offset" must have the two LS bits set to zero. Read operations
	* require we read the entire word and then sort out what should be
	* returned. Write operations other than long word require that we
	* read the long word, update the proper word or byte, then write the
	* entire long word back.
	*
	* PCI Bridge hack. We assume (correctly) that bus 0 is the primary
	* PCI bus from the QSPAN. If we are called with a bus number other
	* than zero, we create a Type 1 configuration access that a downstream
	* PCI bridge will interpret.
	*/

	#define __get_pci_config(x, addr, op) \
	__asm__ __volatile__( \
	"1: "op" %0,0(%1)\n" \
	" eieio\n" \
	"2:\n" \
	".section .fixup,\"ax\"\n" \
	"3: li %0,-1\n" \
	" b 2b\n" \
	".section __ex_table,\"a\"\n" \
	" .align 2\n" \
	" .long 1b,3b\n" \
	".text" \
	: "=r"(x) : "r"(addr))

	#define QS_CONFIG_ADDR ((volatile uint *)(PCI_CSR_ADDR + 0x500))
	#define QS_CONFIG_DATA ((volatile uint *)(PCI_CSR_ADDR + 0x504))

	#define mk_config_addr(bus, dev, offset) \
	(((bus)<<16) \| ((dev)<<8) \| (offset & 0xfc))

	#define mk_config_type1(bus, dev, offset) \
	mk_config_addr(bus, dev, offset) \| 1;

	/* Initialize the QSpan device registers after power up.
	*/
	void
	qspan_init(void)
	{
	uint *qptr;



	qptr = (uint *)PCI_CSR_ADDR;

	/* PCI Configuration/status. Upper bits written to clear
	* pending interrupt or status. Lower bits enable QSPAN as
	* PCI master, enable memory and I/O cycles, and enable PCI
	* parity error checking.
	* IMPORTANT: The last two bits of this word enable PCI
	* master cycles into the QBus. The QSpan is broken and can't
	* meet the timing specs of the PQ bus for this to work. Therefore,
	* if you don't have external bus arbitration, you can't use
	* this function.
	*/
	#ifdef EXTERNAL_PQ_ARB
	qptr[1] = 0xf9000147;
	#else
	qptr[1] = 0xf9000144;
	#endif

	/* PCI Misc configuration. Set PCI latency timer resolution
	* of 8 cycles, set cache size to 4 x 32.
	*/
	qptr[3] = 0;

	/* Set up PCI Target address mapping. Enable, Posted writes,
	* 2Gbyte space (processor memory controller determines actual size).
	*/
	qptr[64] = 0x8f000080;

	/* Map processor 0x80000000 to PCI 0x00000000.
	* Processor address bit 1 determines I/O type access (0x80000000)
	* or memory type access (0xc0000000).
	*/
	qptr[65] = 0x80000000;

	/* Enable error logging and clear any pending error status.
	*/
	qptr[80] = 0x90000000;

	qptr[512] = 0x000c0003;

	/* Set up Qbus slave image.
	*/
	qptr[960] = 0x01000000;
	qptr[961] = 0x000000d1;
	qptr[964] = 0x00000000;
	qptr[965] = 0x000000d1;

	}

	/* Functions to support PCI bios-like features to read/write configuration
	* space. If the function fails for any reason, a -1 (0xffffffff) value
	* must be returned.
	*/
	#define DEVICE_NOT_FOUND (-1)
	#define SUCCESSFUL 0

	int qs_pci_read_config_byte(unsigned char bus, unsigned char dev_fn,
	unsigned char offset, unsigned char *val)
	{
	uint temp;
	u_char *cp;

	if ((bus > 7) \|\| (dev_fn > 127)) {
	*val = 0xff;
	return DEVICE_NOT_FOUND;
	}

	if (bus == 0)
	*QS_CONFIG_ADDR = mk_config_addr(bus, dev_fn, offset);
	else
	*QS_CONFIG_ADDR = mk_config_type1(bus, dev_fn, offset);
	__get_pci_config(temp, QS_CONFIG_DATA, "lwz");

	offset ^= 0x03;
	cp = ((u_char *)&temp) + (offset & 0x03);
	val = cp;
	return SUCCESSFUL;
	}

	int qs_pci_read_config_word(unsigned char bus, unsigned char dev_fn,
	unsigned char offset, unsigned short *val)
	{
	uint temp;
	ushort *sp;

	if ((bus > 7) \|\| (dev_fn > 127)) {
	*val = 0xffff;
	return DEVICE_NOT_FOUND;
	}

	if (bus == 0)
	*QS_CONFIG_ADDR = mk_config_addr(bus, dev_fn, offset);
	else
	*QS_CONFIG_ADDR = mk_config_type1(bus, dev_fn, offset);
	__get_pci_config(temp, QS_CONFIG_DATA, "lwz");
	offset ^= 0x02;

	sp = ((ushort *)&temp) + ((offset >> 1) & 1);
	val = sp;
	return SUCCESSFUL;
	}

	int qs_pci_read_config_dword(unsigned char bus, unsigned char dev_fn,
	unsigned char offset, unsigned int *val)
	{
	if ((bus > 7) \|\| (dev_fn > 127)) {
	*val = 0xffffffff;
	return DEVICE_NOT_FOUND;
	}
	if (bus == 0)
	*QS_CONFIG_ADDR = mk_config_addr(bus, dev_fn, offset);
	else
	*QS_CONFIG_ADDR = mk_config_type1(bus, dev_fn, offset);
	__get_pci_config(*val, QS_CONFIG_DATA, "lwz");
	return SUCCESSFUL;
	}

	int qs_pci_write_config_byte(unsigned char bus, unsigned char dev_fn,
	unsigned char offset, unsigned char val)
	{
	uint temp;
	u_char *cp;

	if ((bus > 7) \|\| (dev_fn > 127))
	return DEVICE_NOT_FOUND;

	qs_pci_read_config_dword(bus, dev_fn, offset, &temp);

	offset ^= 0x03;
	cp = ((u_char *)&temp) + (offset & 0x03);
	*cp = val;

	if (bus == 0)
	*QS_CONFIG_ADDR = mk_config_addr(bus, dev_fn, offset);
	else
	*QS_CONFIG_ADDR = mk_config_type1(bus, dev_fn, offset);
	*QS_CONFIG_DATA = temp;

	return SUCCESSFUL;
	}

	int qs_pci_write_config_word(unsigned char bus, unsigned char dev_fn,
	unsigned char offset, unsigned short val)
	{
	uint temp;
	ushort *sp;

	if ((bus > 7) \|\| (dev_fn > 127))
	return DEVICE_NOT_FOUND;

	qs_pci_read_config_dword(bus, dev_fn, offset, &temp);

	offset ^= 0x02;
	sp = ((ushort *)&temp) + ((offset >> 1) & 1);
	*sp = val;

	if (bus == 0)
	*QS_CONFIG_ADDR = mk_config_addr(bus, dev_fn, offset);
	else
	*QS_CONFIG_ADDR = mk_config_type1(bus, dev_fn, offset);
	*QS_CONFIG_DATA = temp;

	return SUCCESSFUL;
	}

	int qs_pci_write_config_dword(unsigned char bus, unsigned char dev_fn,
	unsigned char offset, unsigned int val)
	{
	if ((bus > 7) \|\| (dev_fn > 127))
	return DEVICE_NOT_FOUND;

	if (bus == 0)
	*QS_CONFIG_ADDR = mk_config_addr(bus, dev_fn, offset);
	else
	*QS_CONFIG_ADDR = mk_config_type1(bus, dev_fn, offset);
	(unsigned int )QS_CONFIG_DATA = val;

	return SUCCESSFUL;
	}