windows-nt/Source/XPSP1/NT/base/boot/detect/i386/pcienum.c

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2020-09-26 03:20:57 -05:00
/*++
Copyright (c) 2001 Microsoft Corporation
Module Name:
pcienum.c
Abstract:
This module contains support routines for the Pci bus enumeration.
Author:
Bassam Tabbara (bassamt) 05-Aug-2001
Environment:
Real mode
--*/
#include "hwdetect.h"
typedef VOID (*PINTERFACE_REFERENCE)(PVOID Context);
typedef VOID (*PINTERFACE_DEREFERENCE)(PVOID Context);
typedef PVOID PDEVICE_OBJECT;
#include "pci.h"
#include "pcienum.h"
#define PCI_FIXED_HDR_LENGTH 16 // Through BIST
#define UnusedParameter(x) (void)x
#define X86_FLAG_IF 0x0200
#define TURN_INTERRUPTS_OFF(_s_) \
__asm { \
__asm pushf \
__asm pop ax \
__asm mov _s_,ax \
__asm cli \
}
#define RESTORE_INTERRUPTS(_s_) \
do { \
if ((_s_) & X86_FLAG_IF) { \
__asm sti \
} \
} while (0)
//////////////////////////////////////////////////////////// PCI Mechanism #0.
//
static ULONG PciReadInt32_0(
UCHAR nBus,
UCHAR nDev,
UCHAR nFun,
UCHAR nReg)
{
UnusedParameter(nBus);
UnusedParameter(nDev);
UnusedParameter(nFun);
UnusedParameter(nReg);
return ~0u;
}
static VOID PciWriteInt32_0(
UCHAR nBus,
UCHAR nDev,
UCHAR nFun,
UCHAR nReg,
ULONG Data)
{
UnusedParameter(nBus);
UnusedParameter(nDev);
UnusedParameter(nFun);
UnusedParameter(nReg);
UnusedParameter(Data);
return;
}
//////////////////////////////////////////////////////////// PCI Mechanism #1.
//
static ULONG PciReadInt32_1(
UCHAR nBus,
UCHAR nDev,
UCHAR nFun,
UCHAR nReg)
{
USHORT fl;
ULONG data = 0;
PCI_TYPE1_CFG_BITS cfg;
cfg.u.bits.Reserved1 = 0;
cfg.u.bits.RegisterNumber = nReg >> 2;
cfg.u.bits.FunctionNumber = nFun;
cfg.u.bits.DeviceNumber = nDev;
cfg.u.bits.BusNumber = nBus;
cfg.u.bits.Reserved2 = 0;
cfg.u.bits.Enable = 1;
TURN_INTERRUPTS_OFF(fl);
WRITE_PORT_ULONG((PUSHORT)PCI_TYPE1_ADDR_PORT, (ULONG)cfg.u.AsULONG); // Select
data = READ_PORT_ULONG((PUSHORT)PCI_TYPE1_DATA_PORT); // Fetch
RESTORE_INTERRUPTS(fl);
return data;
}
static VOID PciWriteInt32_1(
UCHAR nBus,
UCHAR nDev,
UCHAR nFun,
UCHAR nReg,
ULONG Data)
{
USHORT fl;
PCI_TYPE1_CFG_BITS cfg;
cfg.u.bits.Reserved1 = 0;
cfg.u.bits.RegisterNumber = nReg >> 2;
cfg.u.bits.FunctionNumber = nFun;
cfg.u.bits.DeviceNumber = nDev;
cfg.u.bits.BusNumber = nBus;
cfg.u.bits.Reserved2 = 0;
cfg.u.bits.Enable = 1;
TURN_INTERRUPTS_OFF(fl);
WRITE_PORT_ULONG((PUSHORT)PCI_TYPE1_ADDR_PORT, cfg.u.AsULONG); // Select
WRITE_PORT_ULONG((PUSHORT)PCI_TYPE1_DATA_PORT, Data); // Write
RESTORE_INTERRUPTS(fl);
}
//////////////////////////////////////////////////////////// PCI Mechanism #2.
//
static ULONG PciReadInt32_2(
UCHAR nBus,
UCHAR nDev,
UCHAR nFun,
UCHAR nReg)
{
USHORT fl;
ULONG data = 0;
PCI_TYPE2_CSE_BITS cse;
PCI_TYPE2_ADDRESS_BITS adr;
cse.u.bits.Enable = 1;
cse.u.bits.FunctionNumber = nFun;
cse.u.bits.Key = 0xf;
adr.u.bits.RegisterNumber = nReg;
adr.u.bits.Agent = nDev;
adr.u.bits.AddressBase = PCI_TYPE2_ADDRESS_BASE;
TURN_INTERRUPTS_OFF(fl);
WRITE_PORT_UCHAR((PUCHAR)PCI_TYPE2_FORWARD_PORT, nBus); // Select bus
WRITE_PORT_UCHAR((PUCHAR)PCI_TYPE2_CSE_PORT, cse.u.AsUCHAR); // Select function & mapping
data = READ_PORT_ULONG((PUSHORT)adr.u.AsUSHORT); // Fetch
WRITE_PORT_UCHAR((PUCHAR)PCI_TYPE2_CSE_PORT, 0); // Disable mapping.
RESTORE_INTERRUPTS(fl);
return data;
}
static VOID PciWriteInt32_2(
UCHAR nBus,
UCHAR nDev,
UCHAR nFun,
UCHAR nReg,
ULONG Data)
{
USHORT fl;
PCI_TYPE2_CSE_BITS cse;
PCI_TYPE2_ADDRESS_BITS adr;
cse.u.bits.Enable = 1;
cse.u.bits.FunctionNumber = nFun;
cse.u.bits.Key = 0xf;
adr.u.bits.RegisterNumber = nReg;
adr.u.bits.Agent = nDev;
adr.u.bits.AddressBase = PCI_TYPE2_ADDRESS_BASE;
TURN_INTERRUPTS_OFF(fl);
WRITE_PORT_UCHAR((PUCHAR)PCI_TYPE2_FORWARD_PORT, nBus); // Select bus
WRITE_PORT_UCHAR((PUCHAR)PCI_TYPE2_CSE_PORT, cse.u.AsUCHAR); // Select function & mapping
WRITE_PORT_ULONG((PUSHORT)adr.u.AsUSHORT, Data); // Write
WRITE_PORT_UCHAR((PUCHAR)PCI_TYPE2_CSE_PORT, 0); // Disable mapping.
RESTORE_INTERRUPTS(fl);
}
/////////////////////////////////////////////////////////// PCI Configuration.
//
typedef ULONG (*PF_PCI_READ)(UCHAR nBus,
UCHAR nDev,
UCHAR nFun,
UCHAR nReg);
typedef VOID (*PF_PCI_WRITE)(UCHAR nBus,
UCHAR nDev,
UCHAR nFun,
UCHAR nReg,
ULONG Data);
static UCHAR s_nPciMajorRevision = 0;
static UCHAR s_nPciMinorRevision = 0;
static UCHAR s_nPciNumberOfBuses = 0;
static PF_PCI_READ s_pPciRead = PciReadInt32_0;
static PF_PCI_WRITE s_pPciWrite = PciWriteInt32_0;
//////////////////////////////////////////////////////////////////////////////
//
ULONG PciReadConfig(USHORT nDevIt, ULONG cbOffset, UCHAR *pbData, ULONG cbData)
{
ULONG cbDone;
UCHAR nBus = (UCHAR)PCI_ITERATOR_TO_BUS(nDevIt);
UCHAR nDev = (UCHAR)PCI_ITERATOR_TO_DEVICE(nDevIt);
UCHAR nFun = (UCHAR)PCI_ITERATOR_TO_FUNCTION(nDevIt);
// CONFIG space is a space of aligned DWORDs, according to specs.
// Therefore, if Offset is not aligned the caller is confused.
//
if ((cbOffset & 0x3) || (cbData & 0x3)) {
#if DBG
BlPrint("CPci::ReadConfig() called with Offset=x%x, Length=x%x\n", cbOffset, cbData);
#endif
return 0;
}
for (cbDone = 0; cbDone < cbData; cbDone += sizeof(ULONG)) {
*((ULONG*)pbData)++ = s_pPciRead(nBus, nDev, nFun,
(UCHAR)(cbOffset + cbDone));
}
return cbDone;
}
ULONG PciWriteConfig(USHORT nDevIt, ULONG cbOffset, UCHAR *pbData, ULONG cbData)
{
ULONG cbDone;
UCHAR nBus = (UCHAR)PCI_ITERATOR_TO_BUS(nDevIt);
UCHAR nDev = (UCHAR)PCI_ITERATOR_TO_DEVICE(nDevIt);
UCHAR nFun = (UCHAR)PCI_ITERATOR_TO_FUNCTION(nDevIt);
// CONFIG space is a space of aligned DWORDs, according to specs.
// Therefore, if Offset is not aligned the caller is confused.
//
if ((cbOffset & 0x3) || (cbData & 0x3)) {
#if DBG
BlPrint("CPci::ReadConfig() called with Offset=x%x, Length=x%x\n", cbOffset, cbData);
#endif
return 0;
}
for (cbDone = 0; cbDone < cbData; cbDone += sizeof(ULONG)) {
s_pPciWrite(nBus, nDev, nFun, (UCHAR)(cbOffset + cbDone),
*((ULONG*)pbData)++);
}
return cbDone;
}
USHORT PciFindDevice(USHORT VendorId, USHORT DeviceId, USHORT nBegDevIt)
{
USHORT nDevIt;
UCHAR nBus = 0;
UCHAR nDev = 0;
UCHAR nFun = 0;
if (nBegDevIt != 0) {
nBus = (UCHAR)PCI_ITERATOR_TO_BUS(nBegDevIt);
nDev = (UCHAR)PCI_ITERATOR_TO_DEVICE(nBegDevIt);
nFun = (UCHAR)(PCI_ITERATOR_TO_FUNCTION(nBegDevIt) + 1);
}
//
// for each PCI bus
//
for (; nBus < s_nPciNumberOfBuses; nBus++) {
//
// for each PCI Device on the bus
//
for (; nDev < PCI_MAX_DEVICES; nDev++) {
BOOLEAN bIsMultiFunction;
PCI_COMMON_CONFIG config;
//
// Check if we have a device on function 0
//
config.VendorID = PCI_INVALID_VENDORID;
PciReadConfig( PCI_TO_ITERATOR(nBus, nDev, 0),
0,
(UCHAR*)&config,
PCI_FIXED_HDR_LENGTH );
// No device on function 0, skip to next device
if (config.VendorID == PCI_INVALID_VENDORID) {
continue;
}
// check if the device is a multifunction device
bIsMultiFunction = config.HeaderType & PCI_MULTIFUNCTION;
for (; nFun < PCI_MAX_FUNCTION; nFun++) {
// function numbers greater than zero
// are only allowed on multifunction devices.
if (nFun > 0 && !bIsMultiFunction) {
break;
}
// Read configuration header.
//
nDevIt = PCI_TO_ITERATOR(nBus, nDev, nFun);
config.VendorID = PCI_INVALID_VENDORID;
PciReadConfig(nDevIt, 0, (UCHAR*)&config, PCI_FIXED_HDR_LENGTH);
// No function found, skip to next function
if (config.VendorID == PCI_INVALID_VENDORID) {
continue;
}
if (VendorId == 0 ||
(VendorId == config.VendorID &&
(DeviceId == 0 || DeviceId == config.DeviceID))) {
return nDevIt;
}
}
nFun = 0;
}
nDev = 0;
}
return 0;
}
BOOLEAN PciInit(PCI_REGISTRY_INFO *pPCIReg)
{
s_nPciMajorRevision = pPCIReg->MajorRevision;
s_nPciMinorRevision = pPCIReg->MinorRevision;
s_nPciNumberOfBuses = pPCIReg->NoBuses;
if ((pPCIReg->HardwareMechanism & 0x0F) == 1) {
s_pPciRead = PciReadInt32_1;
s_pPciWrite = PciWriteInt32_1;
}
else if ((pPCIReg->HardwareMechanism & 0x0F) == 2) {
s_pPciRead = PciReadInt32_2;
s_pPciWrite = PciWriteInt32_2;
}
else {
#if DBG
BlPrint("Unknown PCI HW Mechanism!\n");
#endif
return FALSE;
}
return TRUE;
}