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|
/* coherent hypertransport initialization for AMD64
*
* written by Stefan Reinauer <stepan@openbios.org>
* (c) 2003-2004 by SuSE Linux AG
*
* This code is licensed under GPL.
*/
/*
* This algorithm assumes a grid configuration as follows:
*
* nodes : 1 2 4 6 8
* org. : 1x1 2x1 2x2 2x3 2x4
*
*/
#include <device/pci_def.h>
#include <device/pci_ids.h>
#include <device/hypertransport_def.h>
#include "arch/romcc_io.h"
#include "amdk8.h"
/* when generating a temporary row configuration we
* don't want broadcast to be enabled for that node.
*/
#define generate_temp_row(...) ((generate_row(__VA_ARGS__)&(~0x0f0000))|0x010000)
#define clear_temp_row(x) fill_row(x,7,DEFAULT)
#define enable_bsp_routing() enable_routing(0)
#define NODE_HT(x) PCI_DEV(0,24+x,0)
#define NODE_MP(x) PCI_DEV(0,24+x,1)
#define NODE_MC(x) PCI_DEV(0,24+x,3)
#define DEFAULT 0x00010101 /* default row entry */
typedef uint8_t u8;
typedef uint32_t u32;
typedef int bool;
#define TRUE (-1)
#define FALSE (0)
static u8 link_to_register(int ldt)
{
/*
* [ 0: 3] Request Route
* [0] Route to this node
* [1] Route to Link 0
* [2] Route to Link 1
* [3] Route to Link 2
*/
if (ldt&0x08) return 0x40;
if (ldt&0x04) return 0x20;
if (ldt&0x02) return 0x00;
/* we should never get here */
print_debug("Unknown Link\n");
return 0;
}
static int link_connection(int src, int dest)
{
/* we generate the needed link information from the rows
* by taking the Request Route of the according row.
*/
return generate_row(src, dest, CONFIG_MAX_CPUS) & 0x0f;
}
static void disable_probes(void)
{
/* disable read/write/fill probes for uniprocessor setup
* they don't make sense if only one cpu is available
*/
/* Hypetransport Transaction Control Register
* F0:0x68
* [ 0: 0] Disable read byte probe
* 0 = Probes issues
* 1 = Probes not issued
* [ 1: 1] Disable Read Doubleword probe
* 0 = Probes issued
* 1 = Probes not issued
* [ 2: 2] Disable write byte probes
* 0 = Probes issued
* 1 = Probes not issued
* [ 3: 3] Disable Write Doubleword Probes
* 0 = Probes issued
* 1 = Probes not issued.
* [10:10] Disable Fill Probe
* 0 = Probes issued for cache fills
* 1 = Probes not issued for cache fills.
*/
u32 val;
print_spew("Disabling read/write/fill probes for UP... ");
val=pci_read_config32(NODE_HT(0), 0x68);
val |= (1<<10)|(1<<9)|(1<<8)|(1<<4)|(1<<3)|(1<<2)|(1<<1)|(1 << 0);
pci_write_config32(NODE_HT(0), 0x68, val);
print_spew("done.\r\n");
}
static void enable_routing(u8 node)
{
u32 val;
/* HT Initialization Control Register
* F0:0x6C
* [ 0: 0] Routing Table Disable
* 0 = Packets are routed according to routing tables
* 1 = Packets are routed according to the default link field
* [ 1: 1] Request Disable (BSP should clear this)
* 0 = Request packets may be generated
* 1 = Request packets may not be generated.
* [ 3: 2] Default Link (Read-only)
* 00 = LDT0
* 01 = LDT1
* 10 = LDT2
* 11 = CPU on same node
* [ 4: 4] Cold Reset
* - Scratch bit cleared by a cold reset
* [ 5: 5] BIOS Reset Detect
* - Scratch bit cleared by a cold reset
* [ 6: 6] INIT Detect
* - Scratch bit cleared by a warm or cold reset not by an INIT
*
*/
/* Enable routing table */
print_spew("Enabling routing table for node ");
print_spew_hex8(node);
val=pci_read_config32(NODE_HT(node), 0x6c);
val &= ~((1<<1)|(1<<0));
pci_write_config32(NODE_HT(node), 0x6c, val);
print_spew(" done.\r\n");
}
#if CONFIG_MAX_CPUS > 1
static void rename_temp_node(u8 node)
{
uint32_t val;
print_spew("Renaming current temporary node to ");
print_spew_hex8(node);
val=pci_read_config32(NODE_HT(7), 0x60);
val &= (~7); /* clear low bits. */
val |= node; /* new node */
pci_write_config32(NODE_HT(7), 0x60, val);
print_spew(" done.\r\n");
}
static bool check_connection(u8 src, u8 dest, u8 link)
{
/* See if we have a valid connection to dest */
u32 val;
/* Detect if the coherent HT link is connected. */
val = pci_read_config32(NODE_HT(src), 0x98+link);
if ( (val&0x17) != 0x03)
return 0;
/* Verify that the coherent hypertransport link is
* established and actually working by reading the
* remode node's vendor/device id
*/
val = pci_read_config32(NODE_HT(dest),0);
if(val != 0x11001022)
return 0;
return 1;
}
static unsigned read_freq_cap(device_t dev, unsigned pos)
{
/* Handle bugs in valid hypertransport frequency reporting */
unsigned freq_cap;
uint32_t id;
freq_cap = pci_read_config16(dev, pos);
freq_cap &= ~(1 << HT_FREQ_VENDOR); /* Ignore Vendor HT frequencies */
id = pci_read_config32(dev, 0);
/* AMD 8131 Errata 48 */
if (id == (PCI_VENDOR_ID_AMD | (PCI_DEVICE_ID_AMD_8131_PCIX << 16))) {
freq_cap &= ~(1 << HT_FREQ_800Mhz);
}
/* AMD 8151 Errata 23 */
if (id == (PCI_VENDOR_ID_AMD | (PCI_DEVICE_ID_AMD_8151_SYSCTRL << 16))) {
freq_cap &= ~(1 << HT_FREQ_800Mhz);
}
/* AMD K8 Unsupported 1Ghz? */
if (id == (PCI_VENDOR_ID_AMD | (0x1100 << 16))) {
freq_cap &= ~(1 << HT_FREQ_1000Mhz);
}
return freq_cap;
}
static int optimize_connection(device_t node1, uint8_t link1, device_t node2, uint8_t link2)
{
static const uint8_t link_width_to_pow2[]= { 3, 4, 0, 5, 1, 2, 0, 0 };
static const uint8_t pow2_to_link_width[] = { 0x7, 4, 5, 0, 1, 3 };
uint16_t freq_cap1, freq_cap2, freq_cap, freq_mask;
uint8_t width_cap1, width_cap2, width_cap, width, old_width, ln_width1, ln_width2;
uint8_t freq, old_freq;
int needs_reset;
/* Set link width and frequency */
/* Initially assume everything is already optimized and I don't need a reset */
needs_reset = 0;
/* Get the frequency capabilities */
freq_cap1 = read_freq_cap(node1, link1 + PCI_HT_CAP_HOST_FREQ_CAP);
freq_cap2 = read_freq_cap(node2, link2 + PCI_HT_CAP_HOST_FREQ_CAP);
/* Calculate the highest possible frequency */
freq = log2(freq_cap1 & freq_cap2);
/* See if I am changing the link freqency */
old_freq = pci_read_config8(node1, link1 + PCI_HT_CAP_HOST_FREQ);
needs_reset |= old_freq != freq;
old_freq = pci_read_config8(node2, link2 + PCI_HT_CAP_HOST_FREQ);
needs_reset |= old_freq != freq;
/* Set the Calulcated link frequency */
pci_write_config8(node1, link1 + PCI_HT_CAP_HOST_FREQ, freq);
pci_write_config8(node2, link2 + PCI_HT_CAP_HOST_FREQ, freq);
/* Get the width capabilities */
width_cap1 = pci_read_config8(node1, link1 + PCI_HT_CAP_HOST_WIDTH);
width_cap2 = pci_read_config8(node2, link2 + PCI_HT_CAP_HOST_WIDTH);
/* Calculate node1's input width */
ln_width1 = link_width_to_pow2[width_cap1 & 7];
ln_width2 = link_width_to_pow2[(width_cap2 >> 4) & 7];
if (ln_width1 > ln_width2) {
ln_width1 = ln_width2;
}
width = pow2_to_link_width[ln_width1];
/* Calculate node1's output width */
ln_width1 = link_width_to_pow2[(width_cap1 >> 4) & 7];
ln_width2 = link_width_to_pow2[width_cap2 & 7];
if (ln_width1 > ln_width2) {
ln_width1 = ln_width2;
}
width |= pow2_to_link_width[ln_width1] << 4;
/* See if I am changing node1's width */
old_width = pci_read_config8(node1, link1 + PCI_HT_CAP_HOST_WIDTH + 1);
needs_reset |= old_width != width;
/* Set node1's widths */
pci_write_config8(node1, link1 + PCI_HT_CAP_HOST_WIDTH + 1, width);
/* Calculate node2's width */
width = ((width & 0x70) >> 4) | ((width & 0x7) << 4);
/* See if I am changing node2's width */
old_width = pci_read_config8(node2, link2 + PCI_HT_CAP_HOST_WIDTH + 1);
needs_reset |= old_width != width;
/* Set node2's widths */
pci_write_config8(node2, link2 + PCI_HT_CAP_HOST_WIDTH + 1, width);
return needs_reset;
}
static void fill_row(u8 node, u8 row, u32 value)
{
pci_write_config32(NODE_HT(node), 0x40+(row<<2), value);
}
static void setup_row(u8 source, u8 dest, u8 cpus)
{
fill_row(source,dest,generate_row(source,dest,cpus));
}
static void setup_temp_row(u8 source, u8 dest, u8 cpus)
{
fill_row(source,7,generate_temp_row(source,dest,cpus));
}
static void setup_node(u8 node, u8 cpus)
{
u8 row;
for(row=0; row<cpus; row++)
setup_row(node, row, cpus);
}
static void setup_remote_row(u8 source, u8 dest, u8 cpus)
{
fill_row(7, dest, generate_row(source, dest, cpus));
}
static void setup_remote_node(u8 node, u8 cpus)
{
static const uint8_t pci_reg[] = {
0x44, 0x4c, 0x54, 0x5c, 0x64, 0x6c, 0x74, 0x7c,
0x40, 0x48, 0x50, 0x58, 0x60, 0x68, 0x70, 0x78,
0x84, 0x8c, 0x94, 0x9c, 0xa4, 0xac, 0xb4, 0xbc,
0x80, 0x88, 0x90, 0x98, 0xa0, 0xa8, 0xb0, 0xb8,
0xc4, 0xcc, 0xd4, 0xdc,
0xc0, 0xc8, 0xd0, 0xd8,
0xe0, 0xe4, 0xe8, 0xec,
};
uint8_t row;
int i;
print_spew("setup_remote_node: ");
for(row=0; row<cpus; row++)
setup_remote_row(node, row, cpus);
/* copy the default resource map from node 0 */
for(i = 0; i < sizeof(pci_reg)/sizeof(pci_reg[0]); i++) {
uint32_t value;
uint8_t reg;
reg = pci_reg[i];
value = pci_read_config32(NODE_MP(0), reg);
pci_write_config32(NODE_MP(7), reg, value);
}
print_spew("done\r\n");
}
#endif
#if CONFIG_MAX_CPUS > 2
static void setup_temp_node(u8 node, u8 cpus)
{
u8 row;
for(row=0; row<cpus; row++)
fill_row(7,row,generate_row(node,row,cpus));
}
#endif
static void setup_uniprocessor(void)
{
print_spew("Enabling UP settings\r\n");
disable_probes();
}
struct setup_smp_result {
int cpus;
int needs_reset;
};
#if CONFIG_MAX_CPUS > 1
static struct setup_smp_result setup_smp(void)
{
struct setup_smp_result result;
result.cpus = 2;
result.needs_reset = 0;
print_spew("Enabling SMP settings\r\n");
setup_row(0, 0, result.cpus);
/* Setup and check a temporary connection to node 1 */
setup_temp_row(0, 1, result.cpus);
if (!check_connection(0, 7, link_to_register(link_connection(0,1)))) {
print_debug("No connection to Node 1.\r\n");
clear_temp_row(0); /* delete temp connection */
setup_uniprocessor(); /* and get up working */
result.cpus = 1;
return result;
}
/* We found 2 nodes so far */
setup_node(0, result.cpus); /* Node 1 is there. Setup Node 0 correctly */
setup_remote_node(1, result.cpus); /* Setup the routes on the remote node */
rename_temp_node(1); /* Rename Node 7 to Node 1 */
enable_routing(1); /* Enable routing on Node 1 */
clear_temp_row(0); /* delete temporary connection */
result.needs_reset =
optimize_connection(NODE_HT(0), 0x80 + link_to_register(link_connection(0,1)),
NODE_HT(1), 0x80 + link_to_register(link_connection(1,0)) );
#if CONFIG_MAX_CPUS > 2
result.cpus=4;
/* Setup and check temporary connection from Node 0 to Node 2 */
setup_temp_row(0,2, result.cpus);
if (!check_connection(0, 7, link_to_register(link_connection(0,2))) ) {
print_debug("No connection to Node 2.\r\n");
clear_temp_row(0); /* delete temp connection */
result.cpus = 2;
return result;
}
/* We found 3 nodes so far. Now setup a temporary
* connection from node 0 to node 3 via node 1
*/
setup_temp_row(0,1, result.cpus); /* temp. link between nodes 0 and 1 */
setup_temp_row(1,3, result.cpus); /* temp. link between nodes 1 and 3 */
if (!check_connection(1, 7, link_to_register(link_connection(1,3)))) {
print_debug("No connection to Node 3.\r\n");
clear_temp_row(0); /* delete temp connection */
clear_temp_row(1); /* delete temp connection */
result.cpus = 2;
return result;
}
/* We found 4 nodes so far. Now setup all nodes for 4p */
setup_node(0, result.cpus); /* The first 2 nodes are configured */
setup_node(1, result.cpus); /* already. Just configure them for 4p */
setup_temp_row(0,2, result.cpus);
setup_temp_node(2, result.cpus);
rename_temp_node(2);
enable_routing(2);
setup_temp_row(0,1, result.cpus);
setup_temp_row(1,3, result.cpus);
setup_temp_node(3, result.cpus);
rename_temp_node(3);
enable_routing(3); /* enable routing on node 3 (temp.) */
clear_temp_row(0);
clear_temp_row(1);
clear_temp_row(2);
clear_temp_row(3);
/* optimize physical connections - by LYH */
result.needs_reset = optimize_connection(
NODE_HT(0), 0x80 + link_to_register(link_connection(0,2)),
NODE_HT(2), 0x80 + link_to_register(link_connection(2,0)) );
result.needs_reset = optimize_connection(
NODE_HT(1), 0x80 + link_to_register(link_connection(1,3)),
NODE_HT(3), 0x80 + link_to_register(link_connection(3,1)) );
result.needs_reset = optimize_connection(
NODE_HT(2), 0x80 + link_to_register(link_connection(2,3)),
NODE_HT(3), 0x80 + link_to_register(link_connection(3,2)) );
#endif /* CONFIG_MAX_CPUS > 2 */
print_debug_hex8(result.cpus);
print_debug(" nodes initialized.\r\n");
return result;
}
#endif
#if CONFIG_MAX_CPUS > 1
static unsigned verify_mp_capabilities(unsigned cpus)
{
unsigned node, row, mask;
bool mp_cap=TRUE;
if (cpus > 2) {
mask=0x06; /* BigMPCap */
} else {
mask=0x02; /* MPCap */
}
for (node=0; node<cpus; node++) {
if ((pci_read_config32(NODE_MC(node), 0xe8) & mask) != mask) {
mp_cap = FALSE;
}
}
if (mp_cap) {
return cpus;
}
/* one of our cpus is not mp capable */
print_err("One of the CPUs is not MP capable. Going back to UP\r\n");
for (node = cpus; node > 0; node--) {
for (row = cpus; row > 0; row--) {
fill_row(NODE_HT(node-1), row-1, DEFAULT);
}
}
setup_uniprocessor();
return 1;
}
#endif
static void coherent_ht_finalize(unsigned cpus)
{
unsigned node;
bool rev_a0;
/* set up cpu count and node count and enable Limit
* Config Space Range for all available CPUs.
* Also clear non coherent hypertransport bus range
* registers on Hammer A0 revision.
*/
#if 1
print_debug("coherent_ht_finalize\r\n");
#endif
rev_a0 = is_cpu_rev_a0();
for (node = 0; node < cpus; node++) {
device_t dev;
uint32_t val;
dev = NODE_HT(node);
/* Set the Total CPU and Node count in the system */
val = pci_read_config32(dev, 0x60);
val &= (~0x000F0070);
val |= ((cpus-1)<<16)|((cpus-1)<<4);
pci_write_config32(dev, 0x60, val);
/* Only respond to real cpu pci configuration cycles
* and optimize the HT settings
*/
val=pci_read_config32(dev, 0x68);
val &= ~((HTTC_BUF_REL_PRI_MASK << HTTC_BUF_REL_PRI_SHIFT) |
(HTTC_MED_PRI_BYP_CNT_MASK << HTTC_MED_PRI_BYP_CNT_SHIFT) |
(HTTC_HI_PRI_BYP_CNT_MASK << HTTC_HI_PRI_BYP_CNT_SHIFT));
val |= HTTC_LIMIT_CLDT_CFG |
(HTTC_BUF_REL_PRI_8 << HTTC_BUF_REL_PRI_SHIFT) |
HTTC_RSP_PASS_PW |
(3 << HTTC_MED_PRI_BYP_CNT_SHIFT) |
(3 << HTTC_HI_PRI_BYP_CNT_SHIFT);
pci_write_config32(dev, 0x68, val);
if (rev_a0) {
print_debug("shit it is an old cup\n");
pci_write_config32(dev, 0x94, 0);
pci_write_config32(dev, 0xb4, 0);
pci_write_config32(dev, 0xd4, 0);
}
}
#if 1
print_debug("done\r\n");
#endif
}
static int apply_cpu_errata_fixes(unsigned cpus, int needs_reset)
{
unsigned node;
for(node = 0; node < cpus; node++) {
device_t dev;
uint32_t cmd;
dev = NODE_MC(node);
if (is_cpu_pre_c0()) {
/* Errata 66
* Limit the number of downstream posted requests to 1
*/
cmd = pci_read_config32(dev, 0x70);
if ((cmd & (3 << 0)) != 2) {
cmd &= ~(3<<0);
cmd |= (2<<0);
pci_write_config32(dev, 0x70, cmd );
needs_reset = 1;
}
cmd = pci_read_config32(dev, 0x7c);
if ((cmd & (3 << 4)) != 0) {
cmd &= ~(3<<4);
cmd |= (0<<4);
pci_write_config32(dev, 0x7c, cmd );
needs_reset = 1;
}
/* Clock Power/Timing Low */
cmd = pci_read_config32(dev, 0xd4);
if (cmd != 0x000D0001) {
cmd = 0x000D0001;
pci_write_config32(dev, 0xd4, cmd);
needs_reset = 1; /* Needed? */
}
}
else {
uint32_t cmd_ref;
/* Errata 98
* Set Clk Ramp Hystersis to 7
* Clock Power/Timing Low
*/
cmd_ref = 0x04e20707; /* Registered */
cmd = pci_read_config32(dev, 0xd4);
if(cmd != cmd_ref) {
pci_write_config32(dev, 0xd4, cmd_ref );
needs_reset = 1; /* Needed? */
}
}
}
return needs_reset;
}
static int optimize_link_read_pointers(unsigned cpus, int needs_reset)
{
unsigned node;
for(node = 0; node < cpus; node = node + 1) {
device_t f0_dev, f3_dev;
uint32_t cmd_ref, cmd;
int link;
f0_dev = NODE_HT(node);
f3_dev = NODE_MC(node);
cmd_ref = cmd = pci_read_config32(f3_dev, 0xdc);
for(link = 0; link < 3; link = link + 1) {
uint32_t link_type;
unsigned reg;
reg = 0x98 + (link * 0x20);
link_type = pci_read_config32(f0_dev, reg);
if (link_type & LinkConnected) {
cmd &= 0xff << (link *8);
/* FIXME this assumes the device on the other
* side is an AMD device */
cmd |= 0x25 << (link *8);
}
}
if (cmd != cmd_ref) {
pci_write_config32(f3_dev, 0xdc, cmd);
needs_reset = 1;
}
}
return needs_reset;
}
static int setup_coherent_ht_domain(void)
{
struct setup_smp_result result;
result.cpus = 1;
result.needs_reset = 0;
enable_bsp_routing();
#if CONFIG_MAX_CPUS == 1
setup_uniprocessor();
#else
result = setup_smp();
result.cpus = verify_mp_capabilities(result.cpus);
#endif
coherent_ht_finalize(result.cpus);
result.needs_reset = apply_cpu_errata_fixes(result.cpus, result.needs_reset);
#if CONFIG_MAX_CPUS > 1 /* Why doesn't this work on the solo? */
result.needs_reset = optimize_link_read_pointers(result.cpus, result.needs_reset);
#endif
return result.needs_reset;
}
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