/* * 86Box A hypervisor and IBM PC system emulator that specializes in * running old operating systems and software designed for IBM * PC systems and compatibles from 1981 through fairly recent * system designs based on the PCI bus. * * This file is part of the 86Box distribution. * * Implementation of the IMS 8848/8849 chipset. * * * * Authors: Miran Grca, * Tiseno100, * * Copyright 2021 Miran Grca. * Copyright 2021 Tiseno100. */ #include #include #include #include #include #include #define HAVE_STDARG_H #include <86box/86box.h> #include "cpu.h" #include <86box/io.h> #include <86box/device.h> #include <86box/mem.h> #include <86box/smram.h> #include <86box/pci.h> #include <86box/pic.h> #include <86box/plat_unused.h> #include <86box/port_92.h> #include <86box/chipset.h> /* IMS 884x Configuration Registers Note: IMS 884x are rebadged ATMEL AT 40411/40412 chipsets By: Tiseno100, Miran Grca(OBattler) Register 00h: Bit 3: F0000-FFFFF Shadow Enable Bit 2: E0000-EFFFF Shadow Enable Bit 0: ???? Register 04h: Bit 3: Cache Write Hit Wait State Bit 2: Cache Read Hit Wait State Register 06h: Bit 3: System BIOS Cacheable (1: Yes / 0: No) Bit 1: Power Management Mode (1: IRQ / 0: SMI#) Register 08h: Bit 2: System BIOS Shadow Write (1: Enable / 0: Disable) Bit 1: System BIOS Shadow Read? Register 0Dh: Bit 0: IO 100H-3FFH Idle Detect (1: Enable / 0: Disable) Register 0Eh: Bit 7: DMA & Local Bus Idle Detect (1: Enable / 0: Disable) Bit 6: Floppy Disk Idle Detect (1: Enable / 0: Disable) Bit 5: IDE Idle Detect (1: Enable / 0: Disable) Bit 4: Serial Port Idle Detect (1: Enable / 0: Disable) Bit 3: Parallel Port Idle Detect (1: Enable / 0: Disable) Bit 2: Keyboard Idle Detect (1: Enable / 0: Disable) Bit 1: Video Idle Detect (1: Enable / 0: Disable) Register 12h: Bits 3-2: Power Saving Timer (00 = 1 MIN, 01 = 3 MIN, 10 = 5 MIN, 11 = 8 MIN) Bit 1: Base Memory (1: 512KB / 0: 640KB) Register 1Ah: Bit 3: Cache Write Hit W/S For PCI (1: Enabled / 0: Disable) Bit 2: Cache Read Hit W/S For PCI (1: Enabled / 0: Disable) Bit 1: VESA Clock Skew (1: 4ns/6ns, 0: No Delay/2ns) Register 1Bh: Bit 6: Enable SMRAM (always at 30000-4FFFF) in SMM Bit 5: ???? Bit 4: Software SMI# Bit 3: DC000-DFFFF Shadow Enable Bit 2: D8000-DBFFF Shadow Enable Bit 1: D4000-D7FFF Shadow Enable Bit 0: D0000-D3FFF Shadow Enable Register 1Ch: Bits 7-4: INTA IRQ routing (0 = disabled, 1 to F = IRQ) Bit 3: CC000-CFFFF Shadow Enable Bit 2: C8000-CBFFF Shadow Enable Bit 1: C4000-C7FFF Shadow Enable Bit 0: C0000-C3FFF Shadow Enable Register 1Dh: Bits 7-4: INTB IRQ routing (0 = disabled, 1 to F = IRQ) Register 1Eh: Bits 7-4: INTC IRQ routing (0 = disabled, 1 to F = IRQ) Bit 1: C4000-C7FFF Cacheable Bit 0: C0000-C3FFF Cacheable Register 21h: Bits 7-4: INTD IRQ routing (0 = disabled, 1 to F = IRQ) Register 22h: Bit 5: Local Bus Master #2 select (0 = VESA, 1 = PCI) Bit 4: Local Bus Master #1 select (0 = VESA, 1 = PCI) Bits 1-0: Internal HADS# Delay Always (00 = No Delay, 01 = 1 Clk, 10 = 2 Clks) Register 23h: Bit 7: Seven Bits Tag (1: Enabled / 0: Disable) Bit 3: Extend LBRDY#(VL Master) (1: Enabled / 0: Disable) Bit 2: Sync LRDY#(VL Slave) (1: Enabled / 0: Disable) Bit 0: HADS# Delay After LB. Cycle (1: Enabled / 0: Disable) */ typedef struct ims8848_t { uint8_t idx; uint8_t access_data; uint8_t pci_slot; uint8_t pad; uint8_t regs[256]; uint8_t pci_conf[256]; smram_t *smram; } ims8848_t; #ifdef ENABLE_IMS8848_LOG int ims8848_do_log = ENABLE_IMS8848_LOG; static void ims8848_log(const char *fmt, ...) { va_list ap; if (ims8848_do_log) { va_start(ap, fmt); pclog_ex(fmt, ap); va_end(ap); } } #else # define ims8848_log(fmt, ...) #endif /* Shadow write always enabled, 1B and 1C control C000-DFFF read. */ static void ims8848_recalc(ims8848_t *dev) { int state_on; uint32_t base; ims8848_log("SHADOW: 00 = %02X, 08 = %02X, 1B = %02X, 1C = %02X\n", dev->regs[0x00], dev->regs[0x08], dev->regs[0x1b], dev->regs[0x1c]); state_on = MEM_READ_INTERNAL; state_on |= (dev->regs[0x08] & 0x04) ? MEM_WRITE_INTERNAL : MEM_WRITE_EXTANY; for (uint8_t i = 0; i < 2; i++) { base = 0xe0000 + (i << 16); if (dev->regs[0x00] & (1 << (i + 2))) mem_set_mem_state_both(base, 0x10000, state_on); else mem_set_mem_state_both(base, 0x10000, MEM_READ_EXTANY | MEM_WRITE_INTERNAL); } for (uint8_t i = 0; i < 4; i++) { base = 0xc0000 + (i << 14); if (dev->regs[0x1c] & (1 << i)) mem_set_mem_state_both(base, 0x4000, MEM_READ_INTERNAL | MEM_WRITE_INTERNAL); else mem_set_mem_state_both(base, 0x4000, MEM_READ_EXTANY | MEM_WRITE_INTERNAL); base = 0xd0000 + (i << 14); if (dev->regs[0x1b] & (1 << i)) mem_set_mem_state_both(base, 0x4000, MEM_READ_INTERNAL | MEM_WRITE_INTERNAL); else mem_set_mem_state_both(base, 0x4000, MEM_READ_EXTANY | MEM_WRITE_INTERNAL); } flushmmucache_nopc(); } static void ims8848_base_memory(ims8848_t *dev) { /* We can use the proper mem_set_access to handle that. */ mem_set_mem_state_both(0x80000, 0x20000, (dev->regs[0x12] & 2) ? (MEM_READ_DISABLED | MEM_WRITE_DISABLED) : (MEM_READ_INTERNAL | MEM_WRITE_INTERNAL)); } static void ims8848_smram(ims8848_t *dev) { smram_disable_all(); smram_enable(dev->smram, 0x00030000, 0x00030000, 0x20000, dev->regs[0x1b] & 0x40, 1); } static void ims8848_write(uint16_t addr, uint8_t val, void *priv) { ims8848_t *dev = (ims8848_t *) priv; uint8_t old = dev->regs[dev->idx]; switch (addr) { case 0x22: ims8848_log("[W] IDX = %02X\n", val); dev->idx = val; break; case 0x23: ims8848_log("[W] IDX IN = %02X\n", val); if (((val & 0x0f) == ((dev->idx >> 4) & 0x0f)) && ((val & 0xf0) == ((dev->idx << 4) & 0xf0))) dev->access_data = 1; break; case 0x24: ims8848_log("[W] [%i] REG %02X = %02X\n", dev->access_data, dev->idx, val); if (dev->access_data) { dev->regs[dev->idx] = val; switch (dev->idx) { case 0x00: case 0x08: case 0x1b: case 0x1c: /* Shadow RAM */ ims8848_recalc(dev); if (dev->idx == 0x1b) { ims8848_smram(dev); if (!(old & 0x10) && (val & 0x10)) smi_raise(); } else if (dev->idx == 0x1c) pci_set_irq_routing(PCI_INTA, (val >> 4) ? (val >> 4) : PCI_IRQ_DISABLED); break; case 0x1d: case 0x1e: pci_set_irq_routing(PCI_INTB + (dev->idx - 0x1d), (val >> 4) ? (val >> 4) : PCI_IRQ_DISABLED); break; case 0x21: pci_set_irq_routing(PCI_INTD, (val >> 4) ? (val >> 4) : PCI_IRQ_DISABLED); break; case 0x12: /* Base Memory */ ims8848_base_memory(dev); break; default: break; } dev->access_data = 0; } break; default: break; } } static uint8_t ims8848_read(uint16_t addr, void *priv) { uint8_t ret = 0xff; ims8848_t *dev = (ims8848_t *) priv; #ifdef ENABLE_IMS8848_LOG uint8_t old_ad = dev->access_data; #endif switch (addr) { case 0x22: ims8848_log("[R] IDX = %02X\n", ret); ret = dev->idx; break; case 0x23: ims8848_log("[R] IDX IN = %02X\n", ret); ret = (dev->idx >> 4) | (dev->idx << 4); break; case 0x24: if (dev->access_data) { ret = dev->regs[dev->idx]; dev->access_data = 0; } ims8848_log("[R] [%i] REG %02X = %02X\n", old_ad, dev->idx, ret); break; default: break; } return ret; } static void ims8849_pci_write(int func, int addr, uint8_t val, void *priv) { ims8848_t *dev = (ims8848_t *) priv; ims8848_log("IMS 884x-PCI: dev->regs[%02x] = %02x POST: %02x\n", addr, val, inb(0x80)); if (func == 0) switch (addr) { case 0x04: dev->pci_conf[addr] = val; break; case 0x05: dev->pci_conf[addr] = val & 3; break; case 0x07: dev->pci_conf[addr] &= val & 0xf7; break; case 0x0c ... 0x0d: dev->pci_conf[addr] = val; break; case 0x52 ... 0x55: dev->pci_conf[addr] = val; break; default: break; } } static uint8_t ims8849_pci_read(int func, int addr, void *priv) { const ims8848_t *dev = (ims8848_t *) priv; uint8_t ret = 0xff; if (func == 0) ret = dev->pci_conf[addr]; return ret; } static void ims8848_reset(void *priv) { ims8848_t *dev = (ims8848_t *) priv; memset(dev->regs, 0x00, sizeof(dev->regs)); memset(dev->pci_conf, 0x00, sizeof(dev->pci_conf)); dev->pci_conf[0x00] = 0xe0; /* Integrated Micro Solutions (IMS) */ dev->pci_conf[0x01] = 0x10; dev->pci_conf[0x02] = 0x49; /* 8849 */ dev->pci_conf[0x03] = 0x88; dev->pci_conf[0x04] = 0x07; dev->pci_conf[0x07] = 0x02; dev->pci_conf[0x0b] = 0x06; ims8848_recalc(dev); /* Shadow RAM Setup */ ims8848_base_memory(dev); /* Base Memory Setup */ pci_set_irq_routing(PCI_INTA, PCI_IRQ_DISABLED); pci_set_irq_routing(PCI_INTB, PCI_IRQ_DISABLED); pci_set_irq_routing(PCI_INTC, PCI_IRQ_DISABLED); pci_set_irq_routing(PCI_INTD, PCI_IRQ_DISABLED); ims8848_smram(dev); } static void ims8848_close(void *priv) { ims8848_t *dev = (ims8848_t *) priv; smram_del(dev->smram); free(dev); } static void * ims8848_init(UNUSED(const device_t *info)) { ims8848_t *dev = (ims8848_t *) malloc(sizeof(ims8848_t)); memset(dev, 0, sizeof(ims8848_t)); device_add(&port_92_device); /* IMS 8848: 22h Index 23h Data Unlock 24h Data IMS 8849: PCI Device 0: IMS 8849 Dummy for compatibility reasons */ io_sethandler(0x0022, 0x0003, ims8848_read, NULL, NULL, ims8848_write, NULL, NULL, dev); pci_add_card(PCI_ADD_NORTHBRIDGE, ims8849_pci_read, ims8849_pci_write, dev, &dev->pci_slot); dev->smram = smram_add(); smram_set_separate_smram(1); cpu_cache_ext_enabled = 1; cpu_update_waitstates(); ims8848_reset(dev); return dev; } const device_t ims8848_device = { .name = "IMS 8848/8849", .internal_name = "ims8848", .flags = 0, .local = 0, .init = ims8848_init, .close = ims8848_close, .reset = ims8848_reset, { .available = NULL }, .speed_changed = NULL, .force_redraw = NULL, .config = NULL };