android_kernel_xiaomi_sm8350/arch/powerpc/platforms/iseries/setup.c

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/*
* Copyright (c) 2000 Mike Corrigan <mikejc@us.ibm.com>
* Copyright (c) 1999-2000 Grant Erickson <grant@lcse.umn.edu>
*
* Description:
* Architecture- / platform-specific boot-time initialization code for
* the IBM iSeries LPAR. Adapted from original code by Grant Erickson and
* code by Gary Thomas, Cort Dougan <cort@fsmlabs.com>, and Dan Malek
* <dan@net4x.com>.
*
* This program 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
* 2 of the License, or (at your option) any later version.
*/
#undef DEBUG
#include <linux/config.h>
#include <linux/init.h>
#include <linux/threads.h>
#include <linux/smp.h>
#include <linux/param.h>
#include <linux/string.h>
#include <linux/initrd.h>
#include <linux/seq_file.h>
#include <linux/kdev_t.h>
#include <linux/major.h>
#include <linux/root_dev.h>
#include <linux/kernel.h>
#include <linux/if_ether.h> /* ETH_ALEN */
#include <asm/processor.h>
#include <asm/machdep.h>
#include <asm/page.h>
#include <asm/mmu.h>
#include <asm/pgtable.h>
#include <asm/mmu_context.h>
#include <asm/cputable.h>
#include <asm/sections.h>
#include <asm/iommu.h>
#include <asm/firmware.h>
#include <asm/system.h>
#include <asm/time.h>
#include <asm/paca.h>
#include <asm/cache.h>
#include <asm/sections.h>
#include <asm/abs_addr.h>
#include <asm/iseries/hv_types.h>
#include <asm/iseries/hv_lp_config.h>
#include <asm/iseries/hv_call_event.h>
#include <asm/iseries/hv_call_xm.h>
#include <asm/iseries/it_lp_queue.h>
#include <asm/iseries/mf.h>
#include <asm/iseries/it_exp_vpd_panel.h>
#include <asm/iseries/hv_lp_event.h>
#include <asm/iseries/lpar_map.h>
#include <asm/udbg.h>
#include <asm/irq.h>
#include "naca.h"
#include "setup.h"
#include "irq.h"
#include "vpd_areas.h"
#include "processor_vpd.h"
#include "main_store.h"
#include "call_sm.h"
#include "call_hpt.h"
#include "call_pci.h"
#include "pci.h"
#ifdef DEBUG
#define DBG(fmt...) udbg_printf(fmt)
#else
#define DBG(fmt...)
#endif
/* Function Prototypes */
static unsigned long build_iSeries_Memory_Map(void);
static void iseries_shared_idle(void);
static void iseries_dedicated_idle(void);
#ifdef CONFIG_PCI
extern void iSeries_pci_final_fixup(void);
#else
static void iSeries_pci_final_fixup(void) { }
#endif
extern int rd_size; /* Defined in drivers/block/rd.c */
extern unsigned long embedded_sysmap_start;
extern unsigned long embedded_sysmap_end;
extern unsigned long iSeries_recal_tb;
extern unsigned long iSeries_recal_titan;
struct MemoryBlock {
unsigned long absStart;
unsigned long absEnd;
unsigned long logicalStart;
unsigned long logicalEnd;
};
/*
* Process the main store vpd to determine where the holes in memory are
* and return the number of physical blocks and fill in the array of
* block data.
*/
static unsigned long iSeries_process_Condor_mainstore_vpd(
struct MemoryBlock *mb_array, unsigned long max_entries)
{
unsigned long holeFirstChunk, holeSizeChunks;
unsigned long numMemoryBlocks = 1;
struct IoHriMainStoreSegment4 *msVpd =
(struct IoHriMainStoreSegment4 *)xMsVpd;
unsigned long holeStart = msVpd->nonInterleavedBlocksStartAdr;
unsigned long holeEnd = msVpd->nonInterleavedBlocksEndAdr;
unsigned long holeSize = holeEnd - holeStart;
printk("Mainstore_VPD: Condor\n");
/*
* Determine if absolute memory has any
* holes so that we can interpret the
* access map we get back from the hypervisor
* correctly.
*/
mb_array[0].logicalStart = 0;
mb_array[0].logicalEnd = 0x100000000;
mb_array[0].absStart = 0;
mb_array[0].absEnd = 0x100000000;
if (holeSize) {
numMemoryBlocks = 2;
holeStart = holeStart & 0x000fffffffffffff;
holeStart = addr_to_chunk(holeStart);
holeFirstChunk = holeStart;
holeSize = addr_to_chunk(holeSize);
holeSizeChunks = holeSize;
printk( "Main store hole: start chunk = %0lx, size = %0lx chunks\n",
holeFirstChunk, holeSizeChunks );
mb_array[0].logicalEnd = holeFirstChunk;
mb_array[0].absEnd = holeFirstChunk;
mb_array[1].logicalStart = holeFirstChunk;
mb_array[1].logicalEnd = 0x100000000 - holeSizeChunks;
mb_array[1].absStart = holeFirstChunk + holeSizeChunks;
mb_array[1].absEnd = 0x100000000;
}
return numMemoryBlocks;
}
#define MaxSegmentAreas 32
#define MaxSegmentAdrRangeBlocks 128
#define MaxAreaRangeBlocks 4
static unsigned long iSeries_process_Regatta_mainstore_vpd(
struct MemoryBlock *mb_array, unsigned long max_entries)
{
struct IoHriMainStoreSegment5 *msVpdP =
(struct IoHriMainStoreSegment5 *)xMsVpd;
unsigned long numSegmentBlocks = 0;
u32 existsBits = msVpdP->msAreaExists;
unsigned long area_num;
printk("Mainstore_VPD: Regatta\n");
for (area_num = 0; area_num < MaxSegmentAreas; ++area_num ) {
unsigned long numAreaBlocks;
struct IoHriMainStoreArea4 *currentArea;
if (existsBits & 0x80000000) {
unsigned long block_num;
currentArea = &msVpdP->msAreaArray[area_num];
numAreaBlocks = currentArea->numAdrRangeBlocks;
printk("ms_vpd: processing area %2ld blocks=%ld",
area_num, numAreaBlocks);
for (block_num = 0; block_num < numAreaBlocks;
++block_num ) {
/* Process an address range block */
struct MemoryBlock tempBlock;
unsigned long i;
tempBlock.absStart =
(unsigned long)currentArea->xAdrRangeBlock[block_num].blockStart;
tempBlock.absEnd =
(unsigned long)currentArea->xAdrRangeBlock[block_num].blockEnd;
tempBlock.logicalStart = 0;
tempBlock.logicalEnd = 0;
printk("\n block %ld absStart=%016lx absEnd=%016lx",
block_num, tempBlock.absStart,
tempBlock.absEnd);
for (i = 0; i < numSegmentBlocks; ++i) {
if (mb_array[i].absStart ==
tempBlock.absStart)
break;
}
if (i == numSegmentBlocks) {
if (numSegmentBlocks == max_entries)
panic("iSeries_process_mainstore_vpd: too many memory blocks");
mb_array[numSegmentBlocks] = tempBlock;
++numSegmentBlocks;
} else
printk(" (duplicate)");
}
printk("\n");
}
existsBits <<= 1;
}
/* Now sort the blocks found into ascending sequence */
if (numSegmentBlocks > 1) {
unsigned long m, n;
for (m = 0; m < numSegmentBlocks - 1; ++m) {
for (n = numSegmentBlocks - 1; m < n; --n) {
if (mb_array[n].absStart <
mb_array[n-1].absStart) {
struct MemoryBlock tempBlock;
tempBlock = mb_array[n];
mb_array[n] = mb_array[n-1];
mb_array[n-1] = tempBlock;
}
}
}
}
/*
* Assign "logical" addresses to each block. These
* addresses correspond to the hypervisor "bitmap" space.
* Convert all addresses into units of 256K chunks.
*/
{
unsigned long i, nextBitmapAddress;
printk("ms_vpd: %ld sorted memory blocks\n", numSegmentBlocks);
nextBitmapAddress = 0;
for (i = 0; i < numSegmentBlocks; ++i) {
unsigned long length = mb_array[i].absEnd -
mb_array[i].absStart;
mb_array[i].logicalStart = nextBitmapAddress;
mb_array[i].logicalEnd = nextBitmapAddress + length;
nextBitmapAddress += length;
printk(" Bitmap range: %016lx - %016lx\n"
" Absolute range: %016lx - %016lx\n",
mb_array[i].logicalStart,
mb_array[i].logicalEnd,
mb_array[i].absStart, mb_array[i].absEnd);
mb_array[i].absStart = addr_to_chunk(mb_array[i].absStart &
0x000fffffffffffff);
mb_array[i].absEnd = addr_to_chunk(mb_array[i].absEnd &
0x000fffffffffffff);
mb_array[i].logicalStart =
addr_to_chunk(mb_array[i].logicalStart);
mb_array[i].logicalEnd = addr_to_chunk(mb_array[i].logicalEnd);
}
}
return numSegmentBlocks;
}
static unsigned long iSeries_process_mainstore_vpd(struct MemoryBlock *mb_array,
unsigned long max_entries)
{
unsigned long i;
unsigned long mem_blocks = 0;
if (cpu_has_feature(CPU_FTR_SLB))
mem_blocks = iSeries_process_Regatta_mainstore_vpd(mb_array,
max_entries);
else
mem_blocks = iSeries_process_Condor_mainstore_vpd(mb_array,
max_entries);
printk("Mainstore_VPD: numMemoryBlocks = %ld \n", mem_blocks);
for (i = 0; i < mem_blocks; ++i) {
printk("Mainstore_VPD: block %3ld logical chunks %016lx - %016lx\n"
" abs chunks %016lx - %016lx\n",
i, mb_array[i].logicalStart, mb_array[i].logicalEnd,
mb_array[i].absStart, mb_array[i].absEnd);
}
return mem_blocks;
}
static void __init iSeries_get_cmdline(void)
{
char *p, *q;
/* copy the command line parameter from the primary VSP */
HvCallEvent_dmaToSp(cmd_line, 2 * 64* 1024, 256,
HvLpDma_Direction_RemoteToLocal);
p = cmd_line;
q = cmd_line + 255;
while(p < q) {
if (!*p || *p == '\n')
break;
++p;
}
*p = 0;
}
static void __init iSeries_init_early(void)
{
DBG(" -> iSeries_init_early()\n");
ppc64_interrupt_controller = IC_ISERIES;
#if defined(CONFIG_BLK_DEV_INITRD)
/*
* If the init RAM disk has been configured and there is
* a non-zero starting address for it, set it up
*/
if (naca.xRamDisk) {
initrd_start = (unsigned long)__va(naca.xRamDisk);
initrd_end = initrd_start + naca.xRamDiskSize * HW_PAGE_SIZE;
initrd_below_start_ok = 1; // ramdisk in kernel space
ROOT_DEV = Root_RAM0;
if (((rd_size * 1024) / HW_PAGE_SIZE) < naca.xRamDiskSize)
rd_size = (naca.xRamDiskSize * HW_PAGE_SIZE) / 1024;
} else
#endif /* CONFIG_BLK_DEV_INITRD */
{
/* ROOT_DEV = MKDEV(VIODASD_MAJOR, 1); */
}
iSeries_recal_tb = get_tb();
iSeries_recal_titan = HvCallXm_loadTod();
/*
* Initialize the hash table management pointers
*/
hpte_init_iSeries();
/*
* Initialize the DMA/TCE management
*/
iommu_init_early_iSeries();
/* Initialize machine-dependency vectors */
#ifdef CONFIG_SMP
smp_init_iSeries();
#endif
/* Associate Lp Event Queue 0 with processor 0 */
HvCallEvent_setLpEventQueueInterruptProc(0, 0);
mf_init();
/* If we were passed an initrd, set the ROOT_DEV properly if the values
* look sensible. If not, clear initrd reference.
*/
#ifdef CONFIG_BLK_DEV_INITRD
if (initrd_start >= KERNELBASE && initrd_end >= KERNELBASE &&
initrd_end > initrd_start)
ROOT_DEV = Root_RAM0;
else
initrd_start = initrd_end = 0;
#endif /* CONFIG_BLK_DEV_INITRD */
DBG(" <- iSeries_init_early()\n");
}
struct mschunks_map mschunks_map = {
/* XXX We don't use these, but Piranha might need them. */
.chunk_size = MSCHUNKS_CHUNK_SIZE,
.chunk_shift = MSCHUNKS_CHUNK_SHIFT,
.chunk_mask = MSCHUNKS_OFFSET_MASK,
};
EXPORT_SYMBOL(mschunks_map);
void mschunks_alloc(unsigned long num_chunks)
{
klimit = _ALIGN(klimit, sizeof(u32));
mschunks_map.mapping = (u32 *)klimit;
klimit += num_chunks * sizeof(u32);
mschunks_map.num_chunks = num_chunks;
}
/*
* The iSeries may have very large memories ( > 128 GB ) and a partition
* may get memory in "chunks" that may be anywhere in the 2**52 real
* address space. The chunks are 256K in size. To map this to the
* memory model Linux expects, the AS/400 specific code builds a
* translation table to translate what Linux thinks are "physical"
* addresses to the actual real addresses. This allows us to make
* it appear to Linux that we have contiguous memory starting at
* physical address zero while in fact this could be far from the truth.
* To avoid confusion, I'll let the words physical and/or real address
* apply to the Linux addresses while I'll use "absolute address" to
* refer to the actual hardware real address.
*
* build_iSeries_Memory_Map gets information from the Hypervisor and
* looks at the Main Store VPD to determine the absolute addresses
* of the memory that has been assigned to our partition and builds
* a table used to translate Linux's physical addresses to these
* absolute addresses. Absolute addresses are needed when
* communicating with the hypervisor (e.g. to build HPT entries)
*
* Returns the physical memory size
*/
static unsigned long __init build_iSeries_Memory_Map(void)
{
u32 loadAreaFirstChunk, loadAreaLastChunk, loadAreaSize;
u32 nextPhysChunk;
u32 hptFirstChunk, hptLastChunk, hptSizeChunks, hptSizePages;
u32 totalChunks,moreChunks;
u32 currChunk, thisChunk, absChunk;
u32 currDword;
u32 chunkBit;
u64 map;
struct MemoryBlock mb[32];
unsigned long numMemoryBlocks, curBlock;
/* Chunk size on iSeries is 256K bytes */
totalChunks = (u32)HvLpConfig_getMsChunks();
mschunks_alloc(totalChunks);
/*
* Get absolute address of our load area
* and map it to physical address 0
* This guarantees that the loadarea ends up at physical 0
* otherwise, it might not be returned by PLIC as the first
* chunks
*/
loadAreaFirstChunk = (u32)addr_to_chunk(itLpNaca.xLoadAreaAddr);
loadAreaSize = itLpNaca.xLoadAreaChunks;
/*
* Only add the pages already mapped here.
* Otherwise we might add the hpt pages
* The rest of the pages of the load area
* aren't in the HPT yet and can still
* be assigned an arbitrary physical address
*/
if ((loadAreaSize * 64) > HvPagesToMap)
loadAreaSize = HvPagesToMap / 64;
loadAreaLastChunk = loadAreaFirstChunk + loadAreaSize - 1;
/*
* TODO Do we need to do something if the HPT is in the 64MB load area?
* This would be required if the itLpNaca.xLoadAreaChunks includes
* the HPT size
*/
printk("Mapping load area - physical addr = 0000000000000000\n"
" absolute addr = %016lx\n",
chunk_to_addr(loadAreaFirstChunk));
printk("Load area size %dK\n", loadAreaSize * 256);
for (nextPhysChunk = 0; nextPhysChunk < loadAreaSize; ++nextPhysChunk)
mschunks_map.mapping[nextPhysChunk] =
loadAreaFirstChunk + nextPhysChunk;
/*
* Get absolute address of our HPT and remember it so
* we won't map it to any physical address
*/
hptFirstChunk = (u32)addr_to_chunk(HvCallHpt_getHptAddress());
hptSizePages = (u32)HvCallHpt_getHptPages();
hptSizeChunks = hptSizePages >>
(MSCHUNKS_CHUNK_SHIFT - HW_PAGE_SHIFT);
hptLastChunk = hptFirstChunk + hptSizeChunks - 1;
printk("HPT absolute addr = %016lx, size = %dK\n",
chunk_to_addr(hptFirstChunk), hptSizeChunks * 256);
/*
* Determine if absolute memory has any
* holes so that we can interpret the
* access map we get back from the hypervisor
* correctly.
*/
numMemoryBlocks = iSeries_process_mainstore_vpd(mb, 32);
/*
* Process the main store access map from the hypervisor
* to build up our physical -> absolute translation table
*/
curBlock = 0;
currChunk = 0;
currDword = 0;
moreChunks = totalChunks;
while (moreChunks) {
map = HvCallSm_get64BitsOfAccessMap(itLpNaca.xLpIndex,
currDword);
thisChunk = currChunk;
while (map) {
chunkBit = map >> 63;
map <<= 1;
if (chunkBit) {
--moreChunks;
while (thisChunk >= mb[curBlock].logicalEnd) {
++curBlock;
if (curBlock >= numMemoryBlocks)
panic("out of memory blocks");
}
if (thisChunk < mb[curBlock].logicalStart)
panic("memory block error");
absChunk = mb[curBlock].absStart +
(thisChunk - mb[curBlock].logicalStart);
if (((absChunk < hptFirstChunk) ||
(absChunk > hptLastChunk)) &&
((absChunk < loadAreaFirstChunk) ||
(absChunk > loadAreaLastChunk))) {
mschunks_map.mapping[nextPhysChunk] =
absChunk;
++nextPhysChunk;
}
}
++thisChunk;
}
++currDword;
currChunk += 64;
}
/*
* main store size (in chunks) is
* totalChunks - hptSizeChunks
* which should be equal to
* nextPhysChunk
*/
return chunk_to_addr(nextPhysChunk);
}
/*
* Document me.
*/
static void __init iSeries_setup_arch(void)
{
if (get_lppaca()->shared_proc) {
ppc_md.idle_loop = iseries_shared_idle;
printk(KERN_DEBUG "Using shared processor idle loop\n");
} else {
ppc_md.idle_loop = iseries_dedicated_idle;
printk(KERN_DEBUG "Using dedicated idle loop\n");
}
/* Setup the Lp Event Queue */
setup_hvlpevent_queue();
printk("Max logical processors = %d\n",
itVpdAreas.xSlicMaxLogicalProcs);
printk("Max physical processors = %d\n",
itVpdAreas.xSlicMaxPhysicalProcs);
}
static void iSeries_show_cpuinfo(struct seq_file *m)
{
seq_printf(m, "machine\t\t: 64-bit iSeries Logical Partition\n");
}
static void __init iSeries_progress(char * st, unsigned short code)
{
printk("Progress: [%04x] - %s\n", (unsigned)code, st);
mf_display_progress(code);
}
static void __init iSeries_fixup_klimit(void)
{
/*
* Change klimit to take into account any ram disk
* that may be included
*/
if (naca.xRamDisk)
klimit = KERNELBASE + (u64)naca.xRamDisk +
(naca.xRamDiskSize * HW_PAGE_SIZE);
else {
/*
* No ram disk was included - check and see if there
* was an embedded system map. Change klimit to take
* into account any embedded system map
*/
if (embedded_sysmap_end)
klimit = KERNELBASE + ((embedded_sysmap_end + 4095) &
0xfffffffffffff000);
}
}
static int __init iSeries_src_init(void)
{
/* clear the progress line */
ppc_md.progress(" ", 0xffff);
return 0;
}
late_initcall(iSeries_src_init);
static inline void process_iSeries_events(void)
{
asm volatile ("li 0,0x5555; sc" : : : "r0", "r3");
}
static void yield_shared_processor(void)
{
unsigned long tb;
HvCall_setEnabledInterrupts(HvCall_MaskIPI |
HvCall_MaskLpEvent |
HvCall_MaskLpProd |
HvCall_MaskTimeout);
tb = get_tb();
/* Compute future tb value when yield should expire */
HvCall_yieldProcessor(HvCall_YieldTimed, tb+tb_ticks_per_jiffy);
/*
* The decrementer stops during the yield. Force a fake decrementer
* here and let the timer_interrupt code sort out the actual time.
*/
get_lppaca()->int_dword.fields.decr_int = 1;
ppc64_runlatch_on();
process_iSeries_events();
}
static void iseries_shared_idle(void)
{
while (1) {
while (!need_resched() && !hvlpevent_is_pending()) {
local_irq_disable();
ppc64_runlatch_off();
/* Recheck with irqs off */
if (!need_resched() && !hvlpevent_is_pending())
yield_shared_processor();
HMT_medium();
local_irq_enable();
}
ppc64_runlatch_on();
if (hvlpevent_is_pending())
process_iSeries_events();
preempt_enable_no_resched();
schedule();
preempt_disable();
}
}
static void iseries_dedicated_idle(void)
{
[PATCH] sched: resched and cpu_idle rework Make some changes to the NEED_RESCHED and POLLING_NRFLAG to reduce confusion, and make their semantics rigid. Improves efficiency of resched_task and some cpu_idle routines. * In resched_task: - TIF_NEED_RESCHED is only cleared with the task's runqueue lock held, and as we hold it during resched_task, then there is no need for an atomic test and set there. The only other time this should be set is when the task's quantum expires, in the timer interrupt - this is protected against because the rq lock is irq-safe. - If TIF_NEED_RESCHED is set, then we don't need to do anything. It won't get unset until the task get's schedule()d off. - If we are running on the same CPU as the task we resched, then set TIF_NEED_RESCHED and no further action is required. - If we are running on another CPU, and TIF_POLLING_NRFLAG is *not* set after TIF_NEED_RESCHED has been set, then we need to send an IPI. Using these rules, we are able to remove the test and set operation in resched_task, and make clear the previously vague semantics of POLLING_NRFLAG. * In idle routines: - Enter cpu_idle with preempt disabled. When the need_resched() condition becomes true, explicitly call schedule(). This makes things a bit clearer (IMO), but haven't updated all architectures yet. - Many do a test and clear of TIF_NEED_RESCHED for some reason. According to the resched_task rules, this isn't needed (and actually breaks the assumption that TIF_NEED_RESCHED is only cleared with the runqueue lock held). So remove that. Generally one less locked memory op when switching to the idle thread. - Many idle routines clear TIF_POLLING_NRFLAG, and only set it in the inner most polling idle loops. The above resched_task semantics allow it to be set until before the last time need_resched() is checked before going into a halt requiring interrupt wakeup. Many idle routines simply never enter such a halt, and so POLLING_NRFLAG can be always left set, completely eliminating resched IPIs when rescheduling the idle task. POLLING_NRFLAG width can be increased, to reduce the chance of resched IPIs. Signed-off-by: Nick Piggin <npiggin@suse.de> Cc: Ingo Molnar <mingo@elte.hu> Cc: Con Kolivas <kernel@kolivas.org> Signed-off-by: Andrew Morton <akpm@osdl.org> Signed-off-by: Linus Torvalds <torvalds@osdl.org>
2005-11-09 00:39:04 -05:00
set_thread_flag(TIF_POLLING_NRFLAG);
while (1) {
[PATCH] sched: resched and cpu_idle rework Make some changes to the NEED_RESCHED and POLLING_NRFLAG to reduce confusion, and make their semantics rigid. Improves efficiency of resched_task and some cpu_idle routines. * In resched_task: - TIF_NEED_RESCHED is only cleared with the task's runqueue lock held, and as we hold it during resched_task, then there is no need for an atomic test and set there. The only other time this should be set is when the task's quantum expires, in the timer interrupt - this is protected against because the rq lock is irq-safe. - If TIF_NEED_RESCHED is set, then we don't need to do anything. It won't get unset until the task get's schedule()d off. - If we are running on the same CPU as the task we resched, then set TIF_NEED_RESCHED and no further action is required. - If we are running on another CPU, and TIF_POLLING_NRFLAG is *not* set after TIF_NEED_RESCHED has been set, then we need to send an IPI. Using these rules, we are able to remove the test and set operation in resched_task, and make clear the previously vague semantics of POLLING_NRFLAG. * In idle routines: - Enter cpu_idle with preempt disabled. When the need_resched() condition becomes true, explicitly call schedule(). This makes things a bit clearer (IMO), but haven't updated all architectures yet. - Many do a test and clear of TIF_NEED_RESCHED for some reason. According to the resched_task rules, this isn't needed (and actually breaks the assumption that TIF_NEED_RESCHED is only cleared with the runqueue lock held). So remove that. Generally one less locked memory op when switching to the idle thread. - Many idle routines clear TIF_POLLING_NRFLAG, and only set it in the inner most polling idle loops. The above resched_task semantics allow it to be set until before the last time need_resched() is checked before going into a halt requiring interrupt wakeup. Many idle routines simply never enter such a halt, and so POLLING_NRFLAG can be always left set, completely eliminating resched IPIs when rescheduling the idle task. POLLING_NRFLAG width can be increased, to reduce the chance of resched IPIs. Signed-off-by: Nick Piggin <npiggin@suse.de> Cc: Ingo Molnar <mingo@elte.hu> Cc: Con Kolivas <kernel@kolivas.org> Signed-off-by: Andrew Morton <akpm@osdl.org> Signed-off-by: Linus Torvalds <torvalds@osdl.org>
2005-11-09 00:39:04 -05:00
if (!need_resched()) {
while (!need_resched()) {
ppc64_runlatch_off();
HMT_low();
if (hvlpevent_is_pending()) {
HMT_medium();
ppc64_runlatch_on();
process_iSeries_events();
}
}
HMT_medium();
}
ppc64_runlatch_on();
preempt_enable_no_resched();
schedule();
preempt_disable();
}
}
#ifndef CONFIG_PCI
void __init iSeries_init_IRQ(void) { }
#endif
static int __init iseries_probe(void)
{
unsigned long root = of_get_flat_dt_root();
if (!of_flat_dt_is_compatible(root, "IBM,iSeries"))
return 0;
powerpc_firmware_features |= FW_FEATURE_ISERIES;
powerpc_firmware_features |= FW_FEATURE_LPAR;
/*
* The Hypervisor only allows us up to 256 interrupt
* sources (the irq number is passed in a u8).
*/
virt_irq_max = 255;
return 1;
}
define_machine(iseries) {
.name = "iSeries",
.setup_arch = iSeries_setup_arch,
.show_cpuinfo = iSeries_show_cpuinfo,
.init_IRQ = iSeries_init_IRQ,
.get_irq = iSeries_get_irq,
.init_early = iSeries_init_early,
.pcibios_fixup = iSeries_pci_final_fixup,
.restart = mf_reboot,
.power_off = mf_power_off,
.halt = mf_power_off,
.get_boot_time = iSeries_get_boot_time,
.set_rtc_time = iSeries_set_rtc_time,
.get_rtc_time = iSeries_get_rtc_time,
.calibrate_decr = generic_calibrate_decr,
.progress = iSeries_progress,
.probe = iseries_probe,
/* XXX Implement enable_pmcs for iSeries */
};
struct blob {
unsigned char data[PAGE_SIZE * 2];
unsigned long next;
};
struct iseries_flat_dt {
struct boot_param_header header;
u64 reserve_map[2];
struct blob dt;
struct blob strings;
};
static struct iseries_flat_dt iseries_dt;
static void __init dt_init(struct iseries_flat_dt *dt)
{
dt->header.off_mem_rsvmap =
offsetof(struct iseries_flat_dt, reserve_map);
dt->header.off_dt_struct = offsetof(struct iseries_flat_dt, dt);
dt->header.off_dt_strings = offsetof(struct iseries_flat_dt, strings);
dt->header.totalsize = sizeof(struct iseries_flat_dt);
dt->header.dt_strings_size = sizeof(struct blob);
/* There is no notion of hardware cpu id on iSeries */
dt->header.boot_cpuid_phys = smp_processor_id();
dt->dt.next = (unsigned long)&dt->dt.data;
dt->strings.next = (unsigned long)&dt->strings.data;
dt->header.magic = OF_DT_HEADER;
dt->header.version = 0x10;
dt->header.last_comp_version = 0x10;
dt->reserve_map[0] = 0;
dt->reserve_map[1] = 0;
}
static void __init dt_check_blob(struct blob *b)
{
if (b->next >= (unsigned long)&b->next) {
DBG("Ran out of space in flat device tree blob!\n");
BUG();
}
}
static void __init dt_push_u32(struct iseries_flat_dt *dt, u32 value)
{
*((u32*)dt->dt.next) = value;
dt->dt.next += sizeof(u32);
dt_check_blob(&dt->dt);
}
#ifdef notyet
static void __init dt_push_u64(struct iseries_flat_dt *dt, u64 value)
{
*((u64*)dt->dt.next) = value;
dt->dt.next += sizeof(u64);
dt_check_blob(&dt->dt);
}
#endif
static unsigned long __init dt_push_bytes(struct blob *blob, char *data, int len)
{
unsigned long start = blob->next - (unsigned long)blob->data;
memcpy((char *)blob->next, data, len);
blob->next = _ALIGN(blob->next + len, 4);
dt_check_blob(blob);
return start;
}
static void __init dt_start_node(struct iseries_flat_dt *dt, char *name)
{
dt_push_u32(dt, OF_DT_BEGIN_NODE);
dt_push_bytes(&dt->dt, name, strlen(name) + 1);
}
#define dt_end_node(dt) dt_push_u32(dt, OF_DT_END_NODE)
static void __init dt_prop(struct iseries_flat_dt *dt, char *name,
char *data, int len)
{
unsigned long offset;
dt_push_u32(dt, OF_DT_PROP);
/* Length of the data */
dt_push_u32(dt, len);
/* Put the property name in the string blob. */
offset = dt_push_bytes(&dt->strings, name, strlen(name) + 1);
/* The offset of the properties name in the string blob. */
dt_push_u32(dt, (u32)offset);
/* The actual data. */
dt_push_bytes(&dt->dt, data, len);
}
static void __init dt_prop_str(struct iseries_flat_dt *dt, char *name,
char *data)
{
dt_prop(dt, name, data, strlen(data) + 1); /* + 1 for NULL */
}
static void __init dt_prop_u32(struct iseries_flat_dt *dt, char *name, u32 data)
{
dt_prop(dt, name, (char *)&data, sizeof(u32));
}
static void __init dt_prop_u64(struct iseries_flat_dt *dt, char *name, u64 data)
{
dt_prop(dt, name, (char *)&data, sizeof(u64));
}
static void __init dt_prop_u64_list(struct iseries_flat_dt *dt, char *name,
u64 *data, int n)
{
dt_prop(dt, name, (char *)data, sizeof(u64) * n);
}
static void __init dt_prop_u32_list(struct iseries_flat_dt *dt, char *name,
u32 *data, int n)
{
dt_prop(dt, name, (char *)data, sizeof(u32) * n);
}
#ifdef notyet
static void __init dt_prop_empty(struct iseries_flat_dt *dt, char *name)
{
dt_prop(dt, name, NULL, 0);
}
#endif
static void __init dt_cpus(struct iseries_flat_dt *dt)
{
unsigned char buf[32];
unsigned char *p;
unsigned int i, index;
struct IoHriProcessorVpd *d;
u32 pft_size[2];
/* yuck */
snprintf(buf, 32, "PowerPC,%s", cur_cpu_spec->cpu_name);
p = strchr(buf, ' ');
if (!p) p = buf + strlen(buf);
dt_start_node(dt, "cpus");
dt_prop_u32(dt, "#address-cells", 1);
dt_prop_u32(dt, "#size-cells", 0);
pft_size[0] = 0; /* NUMA CEC cookie, 0 for non NUMA */
pft_size[1] = __ilog2(HvCallHpt_getHptPages() * HW_PAGE_SIZE);
for (i = 0; i < NR_CPUS; i++) {
if (lppaca[i].dyn_proc_status >= 2)
continue;
snprintf(p, 32 - (p - buf), "@%d", i);
dt_start_node(dt, buf);
dt_prop_str(dt, "device_type", "cpu");
index = lppaca[i].dyn_hv_phys_proc_index;
d = &xIoHriProcessorVpd[index];
dt_prop_u32(dt, "i-cache-size", d->xInstCacheSize * 1024);
dt_prop_u32(dt, "i-cache-line-size", d->xInstCacheOperandSize);
dt_prop_u32(dt, "d-cache-size", d->xDataL1CacheSizeKB * 1024);
dt_prop_u32(dt, "d-cache-line-size", d->xDataCacheOperandSize);
/* magic conversions to Hz copied from old code */
dt_prop_u32(dt, "clock-frequency",
((1UL << 34) * 1000000) / d->xProcFreq);
dt_prop_u32(dt, "timebase-frequency",
((1UL << 32) * 1000000) / d->xTimeBaseFreq);
dt_prop_u32(dt, "reg", i);
dt_prop_u32_list(dt, "ibm,pft-size", pft_size, 2);
dt_end_node(dt);
}
dt_end_node(dt);
}
static void __init dt_model(struct iseries_flat_dt *dt)
{
char buf[16] = "IBM,";
/* "IBM," + mfgId[2:3] + systemSerial[1:5] */
strne2a(buf + 4, xItExtVpdPanel.mfgID + 2, 2);
strne2a(buf + 6, xItExtVpdPanel.systemSerial + 1, 5);
buf[11] = '\0';
dt_prop_str(dt, "system-id", buf);
/* "IBM," + machineType[0:4] */
strne2a(buf + 4, xItExtVpdPanel.machineType, 4);
buf[8] = '\0';
dt_prop_str(dt, "model", buf);
dt_prop_str(dt, "compatible", "IBM,iSeries");
}
static void __init dt_vdevices(struct iseries_flat_dt *dt)
{
u32 reg = 0;
HvLpIndexMap vlan_map;
int i;
char buf[32];
dt_start_node(dt, "vdevice");
dt_prop_str(dt, "device_type", "vdevice");
dt_prop_str(dt, "compatible", "IBM,iSeries-vdevice");
dt_prop_u32(dt, "#address-cells", 1);
dt_prop_u32(dt, "#size-cells", 0);
snprintf(buf, sizeof(buf), "vty@%08x", reg);
dt_start_node(dt, buf);
dt_prop_str(dt, "device_type", "serial");
dt_prop_u32(dt, "reg", reg);
dt_end_node(dt);
reg++;
snprintf(buf, sizeof(buf), "v-scsi@%08x", reg);
dt_start_node(dt, buf);
dt_prop_str(dt, "device_type", "vscsi");
dt_prop_str(dt, "compatible", "IBM,v-scsi");
dt_prop_u32(dt, "reg", reg);
dt_end_node(dt);
reg++;
vlan_map = HvLpConfig_getVirtualLanIndexMap();
for (i = 0; i < HVMAXARCHITECTEDVIRTUALLANS; i++) {
unsigned char mac_addr[ETH_ALEN];
if ((vlan_map & (0x8000 >> i)) == 0)
continue;
snprintf(buf, 32, "l-lan@%08x", reg + i);
dt_start_node(dt, buf);
dt_prop_str(dt, "device_type", "network");
dt_prop_str(dt, "compatible", "IBM,iSeries-l-lan");
dt_prop_u32(dt, "reg", reg + i);
dt_prop_u32(dt, "linux,unit_address", i);
mac_addr[0] = 0x02;
mac_addr[1] = 0x01;
mac_addr[2] = 0xff;
mac_addr[3] = i;
mac_addr[4] = 0xff;
mac_addr[5] = HvLpConfig_getLpIndex_outline();
dt_prop(dt, "local-mac-address", (char *)mac_addr, ETH_ALEN);
dt_prop(dt, "mac-address", (char *)mac_addr, ETH_ALEN);
dt_prop_u32(dt, "max-frame-size", 9000);
dt_prop_u32(dt, "address-bits", 48);
dt_end_node(dt);
}
reg += HVMAXARCHITECTEDVIRTUALLANS;
for (i = 0; i < HVMAXARCHITECTEDVIRTUALDISKS; i++) {
snprintf(buf, 32, "viodasd@%08x", reg + i);
dt_start_node(dt, buf);
dt_prop_str(dt, "device_type", "block");
dt_prop_str(dt, "compatible", "IBM,iSeries-viodasd");
dt_prop_u32(dt, "reg", reg + i);
dt_prop_u32(dt, "linux,unit_address", i);
dt_end_node(dt);
}
reg += HVMAXARCHITECTEDVIRTUALDISKS;
for (i = 0; i < HVMAXARCHITECTEDVIRTUALCDROMS; i++) {
snprintf(buf, 32, "viocd@%08x", reg + i);
dt_start_node(dt, buf);
dt_prop_str(dt, "device_type", "block");
dt_prop_str(dt, "compatible", "IBM,iSeries-viocd");
dt_prop_u32(dt, "reg", reg + i);
dt_prop_u32(dt, "linux,unit_address", i);
dt_end_node(dt);
}
reg += HVMAXARCHITECTEDVIRTUALCDROMS;
for (i = 0; i < HVMAXARCHITECTEDVIRTUALTAPES; i++) {
snprintf(buf, 32, "viotape@%08x", reg + i);
dt_start_node(dt, buf);
dt_prop_str(dt, "device_type", "byte");
dt_prop_str(dt, "compatible", "IBM,iSeries-viotape");
dt_prop_u32(dt, "reg", reg + i);
dt_prop_u32(dt, "linux,unit_address", i);
dt_end_node(dt);
}
dt_end_node(dt);
}
struct pci_class_name {
u16 code;
char *name;
char *type;
};
static struct pci_class_name __initdata pci_class_name[] = {
{ PCI_CLASS_NETWORK_ETHERNET, "ethernet", "network" },
};
static struct pci_class_name * __init dt_find_pci_class_name(u16 class_code)
{
struct pci_class_name *cp;
for (cp = pci_class_name;
cp < &pci_class_name[ARRAY_SIZE(pci_class_name)]; cp++)
if (cp->code == class_code)
return cp;
return NULL;
}
/*
* This assumes that the node slot is always on the primary bus!
*/
static void __init scan_bridge_slot(struct iseries_flat_dt *dt,
HvBusNumber bus, struct HvCallPci_BridgeInfo *bridge_info)
{
HvSubBusNumber sub_bus = bridge_info->subBusNumber;
u16 vendor_id;
u16 device_id;
u32 class_id;
int err;
char buf[32];
u32 reg[5];
int id_sel = ISERIES_GET_DEVICE_FROM_SUBBUS(sub_bus);
int function = ISERIES_GET_FUNCTION_FROM_SUBBUS(sub_bus);
HvAgentId eads_id_sel = ISERIES_PCI_AGENTID(id_sel, function);
u8 devfn;
struct pci_class_name *cp;
/*
* Connect all functions of any device found.
*/
for (id_sel = 1; id_sel <= bridge_info->maxAgents; id_sel++) {
for (function = 0; function < 8; function++) {
HvAgentId agent_id = ISERIES_PCI_AGENTID(id_sel,
function);
err = HvCallXm_connectBusUnit(bus, sub_bus,
agent_id, 0);
if (err) {
if (err != 0x302)
printk(KERN_DEBUG
"connectBusUnit(%x, %x, %x) "
"== %x\n",
bus, sub_bus, agent_id, err);
continue;
}
err = HvCallPci_configLoad16(bus, sub_bus, agent_id,
PCI_VENDOR_ID, &vendor_id);
if (err) {
printk(KERN_DEBUG
"ReadVendor(%x, %x, %x) == %x\n",
bus, sub_bus, agent_id, err);
continue;
}
err = HvCallPci_configLoad16(bus, sub_bus, agent_id,
PCI_DEVICE_ID, &device_id);
if (err) {
printk(KERN_DEBUG
"ReadDevice(%x, %x, %x) == %x\n",
bus, sub_bus, agent_id, err);
continue;
}
err = HvCallPci_configLoad32(bus, sub_bus, agent_id,
PCI_CLASS_REVISION , &class_id);
if (err) {
printk(KERN_DEBUG
"ReadClass(%x, %x, %x) == %x\n",
bus, sub_bus, agent_id, err);
continue;
}
devfn = PCI_DEVFN(ISERIES_ENCODE_DEVICE(eads_id_sel),
function);
cp = dt_find_pci_class_name(class_id >> 16);
if (cp && cp->name)
strncpy(buf, cp->name, sizeof(buf) - 1);
else
snprintf(buf, sizeof(buf), "pci%x,%x",
vendor_id, device_id);
buf[sizeof(buf) - 1] = '\0';
snprintf(buf + strlen(buf), sizeof(buf) - strlen(buf),
"@%x", PCI_SLOT(devfn));
buf[sizeof(buf) - 1] = '\0';
if (function != 0)
snprintf(buf + strlen(buf),
sizeof(buf) - strlen(buf),
",%x", function);
dt_start_node(dt, buf);
reg[0] = (bus << 16) | (devfn << 8);
reg[1] = 0;
reg[2] = 0;
reg[3] = 0;
reg[4] = 0;
dt_prop_u32_list(dt, "reg", reg, 5);
if (cp && (cp->type || cp->name))
dt_prop_str(dt, "device_type",
cp->type ? cp->type : cp->name);
dt_prop_u32(dt, "vendor-id", vendor_id);
dt_prop_u32(dt, "device-id", device_id);
dt_prop_u32(dt, "class-code", class_id >> 8);
dt_prop_u32(dt, "revision-id", class_id & 0xff);
dt_prop_u32(dt, "linux,subbus", sub_bus);
dt_prop_u32(dt, "linux,agent-id", agent_id);
dt_prop_u32(dt, "linux,logical-slot-number",
bridge_info->logicalSlotNumber);
dt_end_node(dt);
}
}
}
static void __init scan_bridge(struct iseries_flat_dt *dt, HvBusNumber bus,
HvSubBusNumber sub_bus, int id_sel)
{
struct HvCallPci_BridgeInfo bridge_info;
HvAgentId agent_id;
int function;
int ret;
/* Note: hvSubBus and irq is always be 0 at this level! */
for (function = 0; function < 8; ++function) {
agent_id = ISERIES_PCI_AGENTID(id_sel, function);
ret = HvCallXm_connectBusUnit(bus, sub_bus, agent_id, 0);
if (ret != 0) {
if (ret != 0xb)
printk(KERN_DEBUG "connectBusUnit(%x, %x, %x) "
"== %x\n",
bus, sub_bus, agent_id, ret);
continue;
}
printk("found device at bus %d idsel %d func %d (AgentId %x)\n",
bus, id_sel, function, agent_id);
ret = HvCallPci_getBusUnitInfo(bus, sub_bus, agent_id,
iseries_hv_addr(&bridge_info),
sizeof(struct HvCallPci_BridgeInfo));
if (ret != 0)
continue;
printk("bridge info: type %x subbus %x "
"maxAgents %x maxsubbus %x logslot %x\n",
bridge_info.busUnitInfo.deviceType,
bridge_info.subBusNumber,
bridge_info.maxAgents,
bridge_info.maxSubBusNumber,
bridge_info.logicalSlotNumber);
if (bridge_info.busUnitInfo.deviceType ==
HvCallPci_BridgeDevice)
scan_bridge_slot(dt, bus, &bridge_info);
else
printk("PCI: Invalid Bridge Configuration(0x%02X)",
bridge_info.busUnitInfo.deviceType);
}
}
static void __init scan_phb(struct iseries_flat_dt *dt, HvBusNumber bus)
{
struct HvCallPci_DeviceInfo dev_info;
const HvSubBusNumber sub_bus = 0; /* EADs is always 0. */
int err;
int id_sel;
const int max_agents = 8;
/*
* Probe for EADs Bridges
*/
for (id_sel = 1; id_sel < max_agents; ++id_sel) {
err = HvCallPci_getDeviceInfo(bus, sub_bus, id_sel,
iseries_hv_addr(&dev_info),
sizeof(struct HvCallPci_DeviceInfo));
if (err) {
if (err != 0x302)
printk(KERN_DEBUG "getDeviceInfo(%x, %x, %x) "
"== %x\n",
bus, sub_bus, id_sel, err);
continue;
}
if (dev_info.deviceType != HvCallPci_NodeDevice) {
printk(KERN_DEBUG "PCI: Invalid System Configuration"
"(0x%02X) for bus 0x%02x id 0x%02x.\n",
dev_info.deviceType, bus, id_sel);
continue;
}
scan_bridge(dt, bus, sub_bus, id_sel);
}
}
static void __init dt_pci_devices(struct iseries_flat_dt *dt)
{
HvBusNumber bus;
char buf[32];
u32 buses[2];
int phb_num = 0;
/* Check all possible buses. */
for (bus = 0; bus < 256; bus++) {
int err = HvCallXm_testBus(bus);
if (err) {
/*
* Check for Unexpected Return code, a clue that
* something has gone wrong.
*/
if (err != 0x0301)
printk(KERN_ERR "Unexpected Return on Probe"
"(0x%02X): 0x%04X", bus, err);
continue;
}
printk("bus %d appears to exist\n", bus);
snprintf(buf, 32, "pci@%d", phb_num);
dt_start_node(dt, buf);
dt_prop_str(dt, "device_type", "pci");
dt_prop_str(dt, "compatible", "IBM,iSeries-Logical-PHB");
dt_prop_u32(dt, "#address-cells", 3);
dt_prop_u32(dt, "#size-cells", 2);
buses[0] = buses[1] = bus;
dt_prop_u32_list(dt, "bus-range", buses, 2);
scan_phb(dt, bus);
dt_end_node(dt);
phb_num++;
}
}
static void __init build_flat_dt(struct iseries_flat_dt *dt,
unsigned long phys_mem_size)
{
u64 tmp[2];
dt_init(dt);
dt_start_node(dt, "");
dt_prop_u32(dt, "#address-cells", 2);
dt_prop_u32(dt, "#size-cells", 2);
dt_model(dt);
/* /memory */
dt_start_node(dt, "memory@0");
dt_prop_str(dt, "name", "memory");
dt_prop_str(dt, "device_type", "memory");
tmp[0] = 0;
tmp[1] = phys_mem_size;
dt_prop_u64_list(dt, "reg", tmp, 2);
dt_end_node(dt);
/* /chosen */
dt_start_node(dt, "chosen");
dt_prop_str(dt, "bootargs", cmd_line);
dt_end_node(dt);
dt_cpus(dt);
dt_vdevices(dt);
dt_pci_devices(dt);
dt_end_node(dt);
dt_push_u32(dt, OF_DT_END);
}
void * __init iSeries_early_setup(void)
{
unsigned long phys_mem_size;
iSeries_fixup_klimit();
/*
* Initialize the table which translate Linux physical addresses to
* AS/400 absolute addresses
*/
phys_mem_size = build_iSeries_Memory_Map();
iSeries_get_cmdline();
build_flat_dt(&iseries_dt, phys_mem_size);
return (void *) __pa(&iseries_dt);
}
static void hvputc(char c)
{
if (c == '\n')
hvputc('\r');
HvCall_writeLogBuffer(&c, 1);
}
void __init udbg_init_iseries(void)
{
udbg_putc = hvputc;
}