Global variable (BootTab/CPU) stuff

This commit is contained in:
Julian Barathieu 2019-04-05 10:20:10 +02:00
parent cd66216847
commit dc1cfa6151
12 changed files with 107 additions and 104 deletions

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@ -60,10 +60,7 @@ typedef enum TermColor_t TermColor_t;
#define _KeCurCPU 0
// Process_t structure of current CPU
#define KeCurCPU (cpuTable[_KeCurCPU])
// Access the BootInfo_t structure
#define BtGetBootInfo(x) (bootTab.x)
//#define KeCurCPU (cpuTable[_KeCurCPU])
//------------------------------------------//
@ -77,10 +74,13 @@ struct Processor_t
// CPU APIC id
int apicId;
// CPU Vendor String (always 12 characters)
char vendorStr[12];
// CPU Model code (enum in cpu.h)
int modelCode;
// CPU Features flag
uint featureFlag;
@ -176,19 +176,24 @@ struct BootInfo_t
//------------------------------------------//
extern volatile int cpuCount;
extern volatile BootInfo_t bootTab;
extern volatile Processor_t cpuTable[NCPUS];
extern int KeCPUCount;
extern Processor_t _KeCPUTable[NCPUS];
extern volatile Processor_t *KeCurCPU;
extern volatile BootInfo_t BtBootTab;
//------------------------------------------//
#define DEC_PER_CPU(pref, name, field, type) \
static inline type pref##Get##name() { return KeGetCurCPU().field; } \
static inline type pref##Get##name() { return KeGetCurCPU()->field; } \
static inline void _##pref##Set##name(type __val) \
{ KeGetCurCPU().field = __val; }
{ KeGetCurCPU()->field = __val; }
#define BARRIER() do{\
asm volatile("": : :"memory");__sync_synchronize();}while(0)
#define BARRIER() \
do { \
asm volatile("": : :"memory"); \
__sync_synchronize(); \
} while(0)
//------------------------------------------//

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@ -66,7 +66,7 @@ struct GdtEntry_t
uchar access; // determine what ring this segment can be used in
uchar granularity;
uchar highBase; // last 8 bits
} __attribute__((packed));
} __attribute__((__packed__));
// The gdt pointer
struct GdtPtr_t
@ -74,7 +74,7 @@ struct GdtPtr_t
uchar limit; // upper 16 bits
ushort base; // address of the first entry
}
__attribute__((packed));
__attribute__((__packed__));
// -------------------------------------------------------------------------- //

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@ -32,7 +32,7 @@
//------------------------------------------//
#define PANICSTR_SIZE 1024
extern volatile char KePanicStr[PANICSTR_SIZE];
extern volatile bool KeIsPanicking;
//------------------------------------------//

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@ -77,8 +77,8 @@ struct Process_t
//------------------------------------------//
#define PsCurProc (KeCurCPU.process)
#define PsCurThread (KeCurCPU.thread)
#define PsCurProc (KeCurCPU->process)
#define PsCurThread (KeCurCPU->thread)
//DEC_PER_CPU(Ps, CurProc, process, Process_t *);
//DEC_PER_CPU(Ps, CurThread, thread, Thread_t *);

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@ -61,10 +61,10 @@ extern const char *PsPrioClassesNames[];
// Re-scheduling and preemption
// XXX atomic operations
//
#define PsRequestReSched() (++KeCurCPU.needReSched)
#define PsDisablePreemption() (++KeCurCPU.preemptCount)
#define PsEnablePreemption() do { assert(KeCurCPU.preemptCount > 0); \
--KeCurCPU.preemptCount; } while(0)
#define PsRequestReSched() (++KeCurCPU->needReSched)
#define PsDisablePreemption() (++KeCurCPU->preemptCount)
#define PsEnablePreemption() do { assert(KeCurCPU->preemptCount > 0); \
--KeCurCPU->preemptCount; } while(0)
//------------------------------------------//

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@ -24,7 +24,7 @@
#include <kernel/buf.h>
extern error_t bputc(Buffer_t *buf, uchar ch);
error_t bputc(Buffer_t *buf, uchar ch);
error_t vbprintf(Buffer_t *buf, const char *fmt, va_list ap);
//
@ -123,7 +123,7 @@ error_t vbprintf(Buffer_t *buf, const char *fmt, va_list ap)
assert(buf && buf->initDone == INITOK);
if (!buf) return EINVAL;
if (!buf || !fmt) return EINVAL;
if (buf->state != BS_RDWR && buf->state != BS_WRONLY) {
return EBADF;
}
@ -241,7 +241,6 @@ error_t vbprintf(Buffer_t *buf, const char *fmt, va_list ap)
//
// The type field
//
type = *fmt++;
// Characters

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@ -44,69 +44,69 @@ void BtInitBootInfo(multiboot_info_t *mbi)
KalAlwaysAssert(mbi);
//Retrieves the bootloader flags to ensure infos are valid
BtGetBootInfo(btldr).grubFlags = mbi->flags;
BtBootTab.btldr.grubFlags = mbi->flags;
if (BtGetBootInfo(btldr).grubFlags & MULTIBOOT_INFO_BOOT_LOADER_NAME) {
BtGetBootInfo(btldr).grubName = (char*)(ulong)(mbi->boot_loader_name);
BtGetBootInfo(btldr).kernelAddr = (void*)&MB_header;
BtGetBootInfo(btldr).kernelEndAddr = (void*)newKernelEnd;
BtGetBootInfo(btldr).valid = 1;
if (BtBootTab.btldr.grubFlags & MULTIBOOT_INFO_BOOT_LOADER_NAME) {
BtBootTab.btldr.grubName = (char*)(ulong)(mbi->boot_loader_name);
BtBootTab.btldr.kernelAddr = (void*)&MB_header;
BtBootTab.btldr.kernelEndAddr = (void*)newKernelEnd;
BtBootTab.btldr.valid = 1;
}
if (BtGetBootInfo(btldr).grubFlags & MULTIBOOT_INFO_MODS) {
BtGetBootInfo(btldr).modulesCount = mbi->mods_count;
BtGetBootInfo(btldr).modulesAddr = (void*)(ulong)mbi->mods_addr;
if (BtBootTab.btldr.grubFlags & MULTIBOOT_INFO_MODS) {
BtBootTab.btldr.modulesCount = mbi->mods_count;
BtBootTab.btldr.modulesAddr = (void*)(ulong)mbi->mods_addr;
}
//Retrieves the drives informations
if (BtGetBootInfo(btldr).grubFlags & MULTIBOOT_INFO_DRIVE_INFO) {
BtGetBootInfo(drives).bufferLength = mbi->drives_length;
BtGetBootInfo(drives).bufferAddr = (void*)(ulong)mbi->drives_addr;
BtGetBootInfo(drives).bufferValid = 1;
if (BtBootTab.btldr.grubFlags & MULTIBOOT_INFO_DRIVE_INFO) {
BtBootTab.drives.bufferLength = mbi->drives_length;
BtBootTab.drives.bufferAddr = (void*)(ulong)mbi->drives_addr;
BtBootTab.drives.bufferValid = 1;
}
if (BtGetBootInfo(btldr).grubFlags & MULTIBOOT_INFO_BOOTDEV) {
BtGetBootInfo(drives).bootDrv = mbi->boot_device;
BtGetBootInfo(drives).drvValid = 1;
if (BtBootTab.btldr.grubFlags & MULTIBOOT_INFO_BOOTDEV) {
BtBootTab.drives.bootDrv = mbi->boot_device;
BtBootTab.drives.drvValid = 1;
}
//Retrieves the memory informations
if (BtGetBootInfo(btldr).grubFlags & MULTIBOOT_INFO_MEMORY) {
BtGetBootInfo(memory).lowMemory = mbi->mem_lower;
BtGetBootInfo(memory).upMemory = mbi->mem_upper;
BtGetBootInfo(memory).memValid = 1;
if (BtBootTab.btldr.grubFlags & MULTIBOOT_INFO_MEMORY) {
BtBootTab.memory.lowMemory = mbi->mem_lower;
BtBootTab.memory.upMemory = mbi->mem_upper;
BtBootTab.memory.memValid = 1;
}
if (BtGetBootInfo(btldr).grubFlags & MULTIBOOT_INFO_MEM_MAP) {
BtGetBootInfo(memory).mapAddr = (void*)(ulong)mbi->mmap_addr;
BtGetBootInfo(memory).mapLength = mbi->mmap_length;
BtGetBootInfo(memory).mapValid = 1;
if (BtBootTab.btldr.grubFlags & MULTIBOOT_INFO_MEM_MAP) {
BtBootTab.memory.mapAddr = (void*)(ulong)mbi->mmap_addr;
BtBootTab.memory.mapLength = mbi->mmap_length;
BtBootTab.memory.mapValid = 1;
}
// Retrieves video mode informations
if (BtGetBootInfo(btldr).grubFlags & MULTIBOOT_INFO_VBE_INFO) {
BtGetBootInfo(video).vbeControl = (void*)(ulong)mbi->vbe_control_info;
BtGetBootInfo(video).vbeModeInfo = (void*)(ulong)mbi->vbe_mode_info;
BtGetBootInfo(video).vbeMode = mbi->vbe_mode;
BtGetBootInfo(video).vbeInterfaceSeg = mbi->vbe_interface_seg;
BtGetBootInfo(video).vbeInterfaceOff = mbi->vbe_interface_off;
BtGetBootInfo(video).vbeInterfaceLen = mbi->vbe_interface_len;
BtGetBootInfo(video).vbeValid = 1;
if (BtBootTab.btldr.grubFlags & MULTIBOOT_INFO_VBE_INFO) {
BtBootTab.video.vbeControl = (void*)(ulong)mbi->vbe_control_info;
BtBootTab.video.vbeModeInfo = (void*)(ulong)mbi->vbe_mode_info;
BtBootTab.video.vbeMode = mbi->vbe_mode;
BtBootTab.video.vbeInterfaceSeg = mbi->vbe_interface_seg;
BtBootTab.video.vbeInterfaceOff = mbi->vbe_interface_off;
BtBootTab.video.vbeInterfaceLen = mbi->vbe_interface_len;
BtBootTab.video.vbeValid = 1;
}
if (BtGetBootInfo(btldr).grubFlags & MULTIBOOT_INFO_FRAMEBUFFER_INFO) {
BtGetBootInfo(video).framebufferAddr = (void*)mbi->framebuffer_addr;
BtGetBootInfo(video).framebufferPitch = mbi->framebuffer_pitch;
BtGetBootInfo(video).framebufferWidth = mbi->framebuffer_width;
BtGetBootInfo(video).framebufferHeight= mbi->framebuffer_height;
BtGetBootInfo(video).framebufferBpp = mbi->framebuffer_bpp;
BtGetBootInfo(video).framebufferType = mbi->framebuffer_type;
BtGetBootInfo(video).fbuValid = 1;
if (BtBootTab.btldr.grubFlags & MULTIBOOT_INFO_FRAMEBUFFER_INFO) {
BtBootTab.video.framebufferAddr = (void*)mbi->framebuffer_addr;
BtBootTab.video.framebufferPitch = mbi->framebuffer_pitch;
BtBootTab.video.framebufferWidth = mbi->framebuffer_width;
BtBootTab.video.framebufferHeight= mbi->framebuffer_height;
BtBootTab.video.framebufferBpp = mbi->framebuffer_bpp;
BtBootTab.video.framebufferType = mbi->framebuffer_type;
BtBootTab.video.fbuValid = 1;
}
// Retrieves the firmware infos
if (BtGetBootInfo(btldr).grubFlags & MULTIBOOT_INFO_CONFIG_TABLE) {
BtGetBootInfo(firmware).romTable = mbi->config_table;
BtGetBootInfo(firmware).romValid = 1;
if (BtBootTab.btldr.grubFlags & MULTIBOOT_INFO_CONFIG_TABLE) {
BtBootTab.firmware.romTable = mbi->config_table;
BtBootTab.firmware.romValid = 1;
}
if (BtGetBootInfo(btldr).grubFlags & MULTIBOOT_INFO_APM_TABLE) {
BtGetBootInfo(firmware).apmTable = mbi->apm_table;
BtGetBootInfo(firmware).apmValid = 1;
if (BtBootTab.btldr.grubFlags & MULTIBOOT_INFO_APM_TABLE) {
BtBootTab.firmware.apmTable = mbi->apm_table;
BtBootTab.firmware.apmValid = 1;
}
}
@ -118,11 +118,11 @@ void BtInitSanity(uint mbMagic){
if (!(mbMagic == MULTIBOOT_BOOTLOADER_MAGIC))
KeStartPanic("[Init] Magic number %x is incorrect\n", mbMagic);
tmp = (BtGetBootInfo(btldr).kernelEndAddr
- BtGetBootInfo(btldr).kernelAddr) / KB;
tmp = (BtBootTab.btldr.kernelEndAddr
- BtBootTab.btldr.kernelAddr) / KB;
DebugLog("[Init] Kernel successfully loaded at %p with %x magic\n"
" and it uses %d Kio\n\n",
BtGetBootInfo(btldr).kernelAddr,
BtBootTab.btldr.kernelAddr,
mbMagic,tmp);
}

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@ -24,11 +24,10 @@
#include <kernel/base.h>
volatile int cpuCount = 1;
volatile Processor_t cpuTable[NCPUS] = {0};
int KeCPUCount = 1;
Processor_t _KeCPUTable[NCPUS] = {0};
volatile BootInfo_t bootTab = {0};
Terminal_t *StdOut = 0, *StdDbg = 0;
volatile char KePanicStr[PANICSTR_SIZE] = {0};
volatile BootInfo_t BtBootTab = {0};
volatile bool KeIsPanicking = 0;
volatile Processor_t *KeCurCPU = &_KeCPUTable[0];

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@ -41,7 +41,7 @@
//
error_t bvgaflusher(Buffer_t *buf)
{
ushort *fbp = BtGetBootInfo(video).framebufferAddr;
ushort *fbp = BtBootTab.video.framebufferAddr;
const uchar color = 0xf;
uchar *currentLine = buf->wp - buf->lineLen - buf->lastLF;
@ -54,7 +54,7 @@ error_t bvgaflusher(Buffer_t *buf)
}
const size_t bufSize = buf->nLines * buf->lineLen;
ushort *fbe = BtGetBootInfo(video).framebufferAddr
ushort *fbe = BtBootTab.video.framebufferAddr
+ (bufSize * sizeof(ushort));
if (fbp < fbe) {
@ -73,8 +73,8 @@ error_t IoInitVGABuffer(void)
static char bvgabuffer[1 * MB];
BStdOut = BOpenLineBuf(bvgabuffer, BS_WRONLY,
BtGetBootInfo(video).framebufferWidth,
BtGetBootInfo(video).framebufferHeight,
BtBootTab.video.framebufferWidth,
BtBootTab.video.framebufferHeight,
8, bvgaflusher);
BStdDbg = BStdOut;

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@ -62,12 +62,12 @@ noreturn void KeStartPanic(const char *fmt, ...)
fmt = "(no message given)";
}
if (KePanicStr[0] != 0) {
if (KeIsPanicking) {
vbprintf(BStdOut, "\nDouble panic!", NULL);
KeHaltCPU();
}
KePanicStr[0] = 1;
KeIsPanicking = 1;
// We don't check vbprintf's output
// If it fails, what could we do anyway?

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@ -52,19 +52,19 @@ static error_t InitMemoryMap(void)
uint i = 0;
// sanity checks
if (!BtGetBootInfo(memory).memValid && BtGetBootInfo(memory).mapValid)
if (!BtBootTab.memory.memValid && BtBootTab.memory.mapValid)
return ENXIO;
if ((BtGetBootInfo(memory).upMemory / (MB/KB)) <= MINIMUM_RAM_SIZE)
if ((BtBootTab.memory.upMemory / (MB/KB)) <= MINIMUM_RAM_SIZE)
return ENOMEM;
// Ok then we can work ------------------------------------------------------ //
// the memory map provided by GRUB via the BIOS
currentEntry = (multiboot_memory_map_t*)BtGetBootInfo(memory).mapAddr;
currentEntry = (multiboot_memory_map_t*)BtBootTab.memory.mapAddr;
// End address of the map
mapEnd = (multiboot_memory_map_t*)
((ulong)currentEntry + (ulong)BtGetBootInfo(memory).mapLength);
((ulong)currentEntry + (ulong)BtBootTab.memory.mapLength);
// fill the map
while (currentEntry < mapEnd) {
@ -112,7 +112,7 @@ size_t MmGetAvailZoneSize(void *start) {
uint i;
// Because the kernel is the kernel
if (start < BtGetBootInfo(btldr).kernelEndAddr)
if (start < BtBootTab.btldr.kernelEndAddr)
return 0;
// Search the zone where the start address is
@ -137,8 +137,8 @@ void *MmGetFirstAvailZone(void *start) {
void *current = 0;
// Because the kernel is the kernel
if ((ulong)start < (ulong)BtGetBootInfo(btldr).kernelEndAddr) {
return MmGetFirstAvailZone(BtGetBootInfo(btldr).kernelEndAddr);
if ((ulong)start < (ulong)BtBootTab.btldr.kernelEndAddr) {
return MmGetFirstAvailZone(BtBootTab.btldr.kernelEndAddr);
}
// Search the zone where the start address is

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@ -46,13 +46,13 @@ Process_t procs[] = {
//------------------------------------------//
#define ReSchedFlag (KeCurCPU.needReSched)
#define PreemptCount (KeCurCPU.preemptCount)
#define ReSchedFlag (KeCurCPU->needReSched)
#define PreemptCount (KeCurCPU->preemptCount)
#define IdlePrioProcs (KeCurCPU.idlePrioProcs)
#define ReglPrioProcs (KeCurCPU.reglPrioProcs)
#define ServPrioProcs (KeCurCPU.servPrioProcs)
#define TimeCritProcs (KeCurCPU.timeCritProcs)
#define IdlePrioProcs (KeCurCPU->idlePrioProcs)
#define ReglPrioProcs (KeCurCPU->reglPrioProcs)
#define ServPrioProcs (KeCurCPU->servPrioProcs)
#define TimeCritProcs (KeCurCPU->timeCritProcs)
//------------------------------------------//