/*
* pci.c
*
* Purpose: PCI configuration for the Coldfire builtin PCI bridge.
*
* Notes:
*
* This file is part of BaS_gcc.
*
* BaS_gcc is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* BaS_gcc 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 BaS_gcc. If not, see .
*
* Created on: 08.01.2013
* Author: Markus Froeschle
*/
#include
#include "pci.h"
#include "stdint.h"
#include "bas_printf.h"
#include "bas_string.h"
#include "util.h"
#include "wait.h"
#define pci_config_wait() wait(10000); /* FireBee USB not properly detected otherwise */
/*
* PCI device class descriptions displayed during PCI bus scan
*/
static struct pci_class
{
int classcode;
char *description;
} pci_classes[] =
{
{ 0x00, "device was built prior definition of the class code field" },
{ 0x01, "Mass Storage Controller" },
{ 0x02, "Network Controller" },
{ 0x03, "Display Controller" },
{ 0x04, "Multimedia Controller" },
{ 0x05, "Memory Controller" },
{ 0x06, "Bridge Device" },
{ 0x07, "Simple Communication Controller" },
{ 0x08, "Base System Peripherial" },
{ 0x09, "Input Device" },
{ 0x0a, "Docking Station" },
{ 0x0b, "Processor" },
{ 0x0c, "Serial Bus Controller" },
{ 0x0d, "Wireless Controller" },
{ 0x0e, "Intelligent I/O Controller" },
{ 0x0f, "Satellite Communication Controller" },
{ 0x10, "Encryption/Decryption Controller" },
{ 0x11, "Data Acquisition and Signal Processing Controller" },
{ 0xff, "Device does not fit any defined class" },
};
static int num_pci_classes = sizeof(pci_classes) / sizeof(struct pci_class);
#define NUM_CARDS 10
#define NUM_RESOURCES 6
/* holds the handle of a card at position = array index */
static int32_t handles[NUM_CARDS];
/* holds the card's resource descriptors; filled in pci_device_config() */
static struct pci_rd resource_descriptors[NUM_CARDS][NUM_RESOURCES];
/*
* retrieve handle for i'th device
*/
static int handle2index(int32_t handle)
{
int i;
for (i = 0; i < NUM_CARDS; i++)
{
if (handles[i] == handle)
{
return i;
}
}
return -1;
}
/*
* retrieve device class (in cleartext) for a PCI classcode
*/
static char *device_class(int classcode)
{
int i;
for (i = 0; i < num_pci_classes; i++)
{
if (pci_classes[i].classcode == classcode)
{
return pci_classes[i].description;
}
}
return "not found";
}
/*
* read an uint32_t from configuration space of card with handle and offset
*
* The returned value is in little endian format.
*/
uint32_t pci_read_config_longword(int32_t handle, int offset)
{
uint32_t value;
uint16_t bus = PCI_BUS_FROM_HANDLE(handle);
uint16_t device = PCI_DEVICE_FROM_HANDLE(handle);
uint16_t function = PCI_FUNCTION_FROM_HANDLE(handle);
/* initiate PCI configuration access to device */
MCF_PCI_PCICAR = MCF_PCI_PCICAR_E | /* enable configuration access special cycle */
MCF_PCI_PCICAR_BUSNUM(bus) |
MCF_PCI_PCICAR_DEVNUM(device) | /* device number, devices 0 - 9 are reserved */
MCF_PCI_PCICAR_FUNCNUM(function) | /* function number */
MCF_PCI_PCICAR_DWORD(offset / 4);
pci_config_wait();
value = * (volatile uint32_t *) PCI_IO_OFFSET; /* access device */
/* finish PCI configuration access special cycle (allow regular PCI accesses) */
MCF_PCI_PCICAR &= ~MCF_PCI_PCICAR_E;
pci_config_wait();
return value;
}
uint16_t pci_read_config_word(int32_t handle, int offset)
{
uint32_t value;
value = pci_read_config_longword(handle, offset);
return value >> ((1 - offset % 2) * 16) & 0xffff;
}
uint8_t pci_read_config_byte(int32_t handle, int offset)
{
uint32_t value;
value = pci_read_config_longword(handle, offset);
return value >> ((3 - offset % 4) * 8) & 0xff;
}
/*
* pci_write_config_longword()
*
* write an uint32_t value (must be in little endian format) to the configuration space of a PCI device
*/
int32_t pci_write_config_longword(int32_t handle, int offset, uint32_t value)
{
uint16_t bus = PCI_BUS_FROM_HANDLE(handle);
uint16_t device = PCI_DEVICE_FROM_HANDLE(handle);
uint16_t function = PCI_FUNCTION_FROM_HANDLE(handle);
/* initiate PCI configuration access to device */
MCF_PCI_PCICAR = MCF_PCI_PCICAR_E | /* enable configuration access special cycle */
MCF_PCI_PCICAR_BUSNUM(bus) |
MCF_PCI_PCICAR_DEVNUM(device) | /* device number, devices 0 - 9 are reserved */
MCF_PCI_PCICAR_FUNCNUM(function) | /* function number */
MCF_PCI_PCICAR_DWORD(offset / 4);
pci_config_wait();
* (volatile uint32_t *) PCI_IO_OFFSET = value; /* access device */
pci_config_wait();
/* finish configuration space access cycle */
MCF_PCI_PCICAR &= ~MCF_PCI_PCICAR_E;
pci_config_wait();
return PCI_SUCCESSFUL;
}
/*
* pci_get_resource
*
* get resource descriptor chain for handle
*/
struct pci_rd *pci_get_resource(int32_t handle)
{
int index = -1;
index = handle2index(handle);
if (index == -1)
return NULL;
return resource_descriptors[index];
}
/*
* pci_find_device()
*
* find index'th device by device_id and vendor_id. Special case: vendor id -1 (0xffff)
* matches all devices. You can search the whole bus by repeatedly calling this function
*/
int32_t pci_find_device(uint16_t device_id, uint16_t vendor_id, int index)
{
uint16_t bus;
uint16_t device;
uint16_t function = 0;
uint16_t n = 0;
int32_t handle;
for (bus = 0; bus < 2; bus++)
{
for (device = 10; device < 31; device++)
{
uint32_t value;
uint8_t htr;
handle = PCI_HANDLE(bus, device, 0);
value = pci_read_config_longword(handle, PCIIDR);
if (value != 0xffffffff) /* we have a device at this position */
{
#ifdef _NOT_USED_
xprintf("value=%08x, vendor_id = 0x%04x, device_id=0x%04x\r\n",
value, PCI_VENDOR_ID(value), PCI_DEVICE_ID(value));
#endif /* _NOT_USED_ */
if (vendor_id == 0xffff ||
(PCI_VENDOR_ID(value) == vendor_id && PCI_DEVICE_ID(value) == device_id))
{
if (n == index)
{
return handle;
}
n++;
}
/*
* There is a device at this position, but not the one we are looking for.
* Check to see if it is a multi-function device. We need to look "behind" it
* for the other functions in that case.
*/
if ((htr = pci_read_config_byte(handle, PCIHTR)) & 0x80)
{
/* yes, this is a multi-function device, look for more functions */
for (function = 1; function < 8; function++)
{
handle = PCI_HANDLE(bus, device, function);
value = pci_read_config_longword(handle, PCIIDR);
if (value != 0xFFFFFFFF) /* device found */
{
if (vendor_id == 0xffff ||
(PCI_VENDOR_ID(value) == vendor_id && PCI_DEVICE_ID(value) == device_id))
{
if (n == index)
{
return handle;
}
n++;
}
}
}
}
}
}
}
return PCI_DEVICE_NOT_FOUND;
}
int32_t pci_hook_interrupt(int32_t handle, void *handler, void *parameter)
{
/* FIXME: implement */
xprintf("pci_hook_interrupt() still not implemented\r\n");
return PCI_SUCCESSFUL;
}
int32_t pci_unhook_interrupt(int32_t handle)
{
/* FIXME: implement */
xprintf("pci_unhook_interrupt() still not implemented\r\n");
return PCI_SUCCESSFUL;
}
/*
* pci_device_config()
*
* Map card resources, adjust BARs and fill resource descriptors
*/
static void pci_device_config(uint16_t bus, uint16_t device, uint16_t function)
{
uint32_t address;
uint16_t handle;
int16_t index = - 1;
struct pci_rd *descriptors;
int i;
uint32_t value;
static uint32_t mem_address = PCI_MEMORY_OFFSET;
static uint32_t io_address = PCI_IO_OFFSET;
/* determine pci handle from bus, device + function number */
handle = PCI_HANDLE(bus, device, function);
/* find index into resource descriptor table for handle */
index = handle2index(handle);
if (index == -1)
{
xprintf("cannot find index for handle %d\r\n", handle);
return;
}
int barnum = 0;
descriptors = resource_descriptors[index];
for (i = 0; i < 6; i++) /* for all bars */
{
/*
* read BAR[i] value
*/
value = swpl(pci_read_config_longword(handle, PCIBAR0 + i));
/*
* write all bits of BAR[i]
*/
pci_write_config_longword(handle, 0x10 + i, 0xffffffff);
/*
* read back value to see which bits have been set
*/
address = swpl(pci_read_config_longword(handle, PCIBAR0 + i));
if (address) /* is bar in use? */
{
/*
* resource descriptor for this device
*/
struct pci_rd *rd = &descriptors[barnum];
if (IS_PCI_MEM_BAR(value))
{
/* adjust base address to card's alignment requirements */
int size = ~(address & 0xfffffff0) + 1;
xprintf("device 0x%x: BAR[%d] requests %d kBytes of memory\r\n", handle, i, size / 1024);
/* calculate a valid map adress with alignment requirements */
mem_address = (mem_address + size - 1) & ~(size - 1);
/* write it to the BAR */
pci_write_config_longword(handle, PCIBAR0 + i, swpl(mem_address));
/* read it back, just to be sure */
value = swpl(pci_read_config_longword(handle, PCIBAR0 + i));
xprintf("set PCIBAR%d on device 0x%02x to 0x%08x\r\n",
i, handle, value);
/* fill resource descriptor */
rd->next = sizeof(struct pci_rd);
rd->flags = 0 | FLG_8BIT | FLG_16BIT | FLG_32BIT;
rd->start = mem_address;
rd->length = size;
rd->offset = 0; /* PCI_MEMORY_OFFSET; */
rd->dmaoffset = 0;
/* adjust memory adress for next turn */
mem_address += size;
/* index to next unused resource descriptor */
barnum++;
}
else if (IS_PCI_IO_BAR(value)) /* same as above for I/O resources */
{
int size = ~(address & 0xfffffffc) + 1;
xprintf("device 0x%x: BAR[%d] requests %d bytes of memory\r\n", handle, i, size);
io_address = (io_address + size - 1) & ~(size - 1);
pci_write_config_longword(handle, PCIBAR0 + i, swpl(io_address));
value = swpl(pci_read_config_longword(handle, PCIBAR0 + i));
xprintf("set PCIBAR%d on device 0x%02x to 0x%08x\r\n",
i, handle, value);
rd->next = sizeof(struct pci_rd);
rd->flags = FLG_IO | FLG_8BIT | FLG_16BIT | FLG_32BIT | 1;
rd->start = io_address;
rd->offset = 0; /* PCI_IO_OFFSET; */
rd->length = size;
rd->dmaoffset = 0;
io_address += size;
barnum++;
}
}
}
/* mark end of resource chain */
if (barnum > 0)
descriptors[barnum - 1].flags |= FLG_LAST;
/*
* enable device finally
*/
value = swpl(pci_read_config_longword(handle, PCICSR));
value |= 0xffff035f;
pci_write_config_longword(handle, PCICSR, swpl(value));
value = swpl(pci_read_config_longword(handle, PCICSR));
xprintf("device 0x%02x PCICSR = 0x%08x\r\n", handle, value);
}
/*
* scan PCI bus and display devices found. Create a handle for each device and call pci_device_config() for it
*/
void pci_scan(void)
{
int16_t handle;
int16_t index = 0;
xprintf("\r\nPCI bus scan...\r\n\r\n");
xprintf(" Bus| Dev|Func|Vndr|D-ID|Hndl|\r\n");
xprintf("----+----+----+----+----+----+\r\n");
handle = pci_find_device(0x0, 0xFFFF, index);
while (handle > 0)
{
uint32_t value;
value = pci_read_config_longword(handle, PCIIDR);
xprintf(" %02x | %02x | %02x |%04x|%04x|%04x| %s (0x%02x)\r\n",
PCI_BUS_FROM_HANDLE(handle),
PCI_DEVICE_FROM_HANDLE(handle),
PCI_FUNCTION_FROM_HANDLE(handle),
PCI_VENDOR_ID(value), PCI_DEVICE_ID(value),
handle,
device_class(pci_read_config_byte(handle, PCICCR)),
pci_read_config_byte(handle, PCICCR));
if (PCI_VENDOR_ID(value) != 0x1057 && PCI_DEVICE_ID(value) != 0x5806) /* do not configure bridge */
{
/* save handle to index value so that we'll be able to later find our resources */
handles[index] = handle;
/* configure memory and I/O for card */
pci_device_config(PCI_BUS_FROM_HANDLE(handle),
PCI_DEVICE_FROM_HANDLE(handle),
PCI_FUNCTION_FROM_HANDLE(handle));
}
handle = pci_find_device(0x0, 0xFFFF, ++index);
}
xprintf("\r\n...finished\r\n");
}
/* start of PCI initialization code */
void init_eport(void)
{
/* concigure IRQ1-7 pins on EPORT falling edge triggered */
MCF_EPORT_EPPAR = MCF_EPORT_EPPAR_EPPA7(MCF_EPORT_EPPAR_FALLING) +
MCF_EPORT_EPPAR_EPPA6(MCF_EPORT_EPPAR_FALLING) +
MCF_EPORT_EPPAR_EPPA5(MCF_EPORT_EPPAR_FALLING) +
MCF_EPORT_EPPAR_EPPA4(MCF_EPORT_EPPAR_FALLING) +
MCF_EPORT_EPPAR_EPPA3(MCF_EPORT_EPPAR_FALLING) +
MCF_EPORT_EPPAR_EPPA2(MCF_EPORT_EPPAR_FALLING) +
MCF_EPORT_EPPAR_EPPA1(MCF_EPORT_EPPAR_FALLING);
MCF_EPORT_EPDDR = 0; /* clear data direction register. All pins as input */
MCF_EPORT_EPFR = 0; /* clear all EPORT interrupt flags */
MCF_EPORT_EPIER = 0xfe; /* enable all EPORT interrupts (for now) */
}
void init_xlbus_arbiter(void)
{
uint8_t clock_ratio;
/* setup XL bus arbiter */
clock_ratio = (MCF_PCI_PCIGSCR >> 24) & 0x07;
if (clock_ratio == 4)
{
/* device errata 26: Flexbus hang up in 4:1 clock ratio */
MCF_PCI_PCIGSCR |= 0x80000000; /* disable pipeline */
}
xprintf("PCIGSCR = %08x\r\n");
MCF_PCI_PCIGSCR |= 0x60000000; /* clear PERR and SERR in global status/command register */
xprintf("PCIGSCR = %08x\r\n");
/* FIXME: Firetos (boot2.S, l. 719) looks pretty strange at this place - is this a typo? */
}
void init_pci(void)
{
uint32_t value;
uint32_t new_value;
xprintf("initializing PCI bridge:");
init_eport();
init_xlbus_arbiter();
MCF_PCIARB_PACR = MCF_PCIARB_PACR_INTMPRI
+ MCF_PCIARB_PACR_EXTMPRI(0x1F)
+ MCF_PCIARB_PACR_INTMINTEN
+ MCF_PCIARB_PACR_EXTMINTEN(0x1F);
/* Setup burst parameters */
MCF_PCI_PCICR1 = MCF_PCI_PCICR1_CACHELINESIZE(4) + MCF_PCI_PCICR1_LATTIMER(16); /* TODO: test increased latency timer */
MCF_PCI_PCICR2 = MCF_PCI_PCICR2_MINGNT(16) + MCF_PCI_PCICR2_MAXLAT(16);
/* Turn on error signaling, 32 write retries on failure */
MCF_PCI_PCIICR = MCF_PCI_PCIICR_REE + MCF_PCI_PCIICR_IAE + MCF_PCI_PCIICR_TAE + 32;
MCF_PCI_PCIGSCR |= MCF_PCI_PCIGSCR_SEE;
/* Configure Initiator Windows */
/*
* Window starts at PCI_MEMORY_OFFSET, ends at PCI_MEMORY_OFFSET + PCI_MEMORY_SIZE - 1 (2 GB)
* There is no translation from M54xx address space to PCI address space (same addresses)
*/
/* initiator window 0 base / translation adress register */
MCF_PCI_PCIIW0BTAR = PCI_MEMORY_OFFSET | (((PCI_MEMORY_SIZE - 1) >> 8) & 0xffff0000);
/* | PCI_MEMORY_OFFSET >> 16; */
/* initiator window 1 base / translation adress register */
MCF_PCI_PCIIW1BTAR = (PCI_IO_OFFSET | ((PCI_IO_SIZE - 1) >> 8)) & 0xffff0000;
/* initiator window 2 base / translation address register */
MCF_PCI_PCIIW2BTAR = 0L; /* not used */
/* initiator window configuration register */
MCF_PCI_PCIIWCR = MCF_PCI_PCIIWCR_WINCTRL0_MEMRDLINE | MCF_PCI_PCIIWCR_WINCTRL1_IO;
/* initialize target control register */
MCF_PCI_PCITCR = 0;
value = MCF_PCI_PCISCR_M | /* memory access control enabled */
MCF_PCI_PCISCR_B | /* bus master enabled */
MCF_PCI_PCISCR_MW | /* memory write and invalidate enabled */
MCF_PCI_PCISCR_PER | /* parity errors enabled, PERR# will be asserted */
MCF_PCI_PCISCR_S; /* SERR enabbled */
MCF_PCI_PCISCR = value;
new_value = MCF_PCI_PCISCR;
if (new_value != value)
xprintf("MCF_PCI_PCISCR wanted: %08x, got %08x\r\n", value, new_value);
/* reset PCI devices */
MCF_PCI_PCIGSCR &= ~MCF_PCI_PCIGSCR_PR;
do ; while (MCF_PCI_PCIGSCR & 1); /* wait until reset finished */
xprintf("finished\r\n");
/* initialize resource descriptor table */
memset(&resource_descriptors, 0, NUM_CARDS * NUM_RESOURCES * sizeof(struct pci_rd));
/* initialize handles array */
memset(handles, 0, NUM_CARDS * sizeof(int32_t));
/*
* do normal initialization
*/
pci_scan();
}